JP2006264976A - Belt driving control device, belt device and image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize high-precision belt driving by specifying with high precision the pitch line distance (PLD) that effects the belt movement speed. <P>SOLUTION: This belt driving control device controls driving of a belt by controlling rotation of a driving support rotary body for transmitting rotational driving force among a plurality of support rotary bodies to which the belt 103 is extended; and has a control means for controlling the rotation of the driving support rotary body so as to reduce a variation in a belt moving speed generated by a PLD variation in the peripheral direction of the belt on the basis of rotation information on turning angle displacement or a turning angle speed in the two support rotary bodies 101 and 102 mutually difference in a degree of having influence on the relationship between the belt moving speed and one's own turning angle speed by the PLD of a belt part different in a diameter and/or wound on oneself. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a belt drive control device that performs drive control of a belt that is stretched over a plurality of support rotating bodies, a belt device that uses the belt drive control device, and an image forming apparatus that uses the belt device. is there.

  Conventionally, as an apparatus that uses such a belt, there is an image forming apparatus that uses a belt such as a photosensitive belt, an intermediate transfer belt, and a paper conveying belt. In such an image forming apparatus, high-precision drive control of the belt is essential to obtain a high-quality image. In particular, a direct transfer tandem type image forming apparatus that is excellent in image forming speed and suitable for downsizing requires high-precision drive control of a conveyance belt that conveys a recording sheet as a recording material. In this image forming apparatus, a recording sheet is transported using a transport belt, and sequentially passes through a plurality of image forming units that form different monochrome images arranged along the transport direction. As a result, it is possible to obtain a color image by superimposing single color images on a recording sheet.

Here, an example of an electrophotographic direct transfer type tandem type image forming apparatus will be specifically described with reference to FIG. In this image forming apparatus, for example, image forming units 18Y, 18M, 18C, and 18K that form monochrome images of yellow, magenta, cyan, and black are sequentially arranged in the conveyance direction of the recording paper. The electrostatic latent images formed on the surfaces of the photosensitive drums 40Y, 40M, 40C, and 40K by a laser exposure unit (not shown) are developed by the image forming units 18Y, 18M, 18C, and 18K, thereby developing toner images ( A visible image is formed. Then, after being sequentially superimposed and transferred onto a recording paper (not shown) that is attached to the transport belt 210 and transported by an electrostatic force, the toner is melted and pressed by the fixing device 25, whereby a color image is formed on the recording paper. It is formed. The conveyor belt 210 is stretched around the driving roller 215 and the driven roller 214 arranged in parallel with each other with an appropriate tension. The drive roller 215 is rotationally driven at a predetermined rotational speed by a drive motor (not shown), and accordingly, the transport belt 210 also moves endlessly at a predetermined speed. The recording paper is supplied to the image forming units 18Y, 18M, 18C, and 18K of the transport belt 210 at a predetermined timing by the paper feed mechanism, and is moved and transported at the same speed as the transport speed of the transport belt 210. The image forming unit sequentially passes.
In such an image forming apparatus, color shift occurs if the moving speed of the recording paper, that is, the moving speed of the conveying belt 210 is not maintained at a constant speed. This color misalignment occurs when the transfer positions of the single color images superimposed on the recording paper are relatively misaligned. When color misalignment occurs, for example, a fine line image formed by overlapping images of multiple colors appears blurred, or around the outline of a black character image formed in a background image formed by overlapping images of multiple colors White spots may occur on the screen.
As shown in FIG. 14, the single color images formed on the surfaces of the photosensitive drums 40Y, 40M, 40C, and 40K of the image forming units 18Y, 18M, 18C, and 18K are temporarily sequentially placed on the intermediate transfer belt 10. There is also a tandem type image forming apparatus that employs an intermediate transfer method in which images are transferred so as to overlap each other and then collectively transferred onto a recording sheet. Also in this apparatus, if the moving speed of the intermediate transfer belt 10 is not maintained at a constant speed, a color shift similarly occurs.

  In addition to the tandem type image forming apparatus described above, a belt as an image carrier such as a recording material conveyance member that conveys a recording material, or a photosensitive member or an intermediate transfer member that carries an image transferred to the recording material. In the image forming apparatus using the belt, banding occurs if the moving speed of the belt is not maintained at a constant speed. This banding is image density unevenness caused by the belt moving speed becoming faster or slower during image transfer. That is, the image portion transferred when the belt moving speed is relatively high has a shape that is stretched in the belt circumferential direction from the original shape, and conversely, the image transferred when the belt moving speed is relatively slow. The portion has a shape reduced in the belt circumferential direction rather than the original shape. As a result, the density of the stretched image portion is reduced, and the density of the reduced image portion is increased. As a result, image density unevenness occurs in the belt circumferential direction, and banding occurs. This banding is noticeable to human eyes when forming a light monochromatic image.

  The belt moving speed varies depending on various causes. Among the causes, in the case of a single layer belt, there is belt thickness unevenness in the belt circumferential direction. This unevenness in the belt thickness is caused by, for example, uneven thickness in the belt circumferential direction seen in a belt produced by a centrifugal firing method using a cylindrical mold. When such uneven belt thickness exists in the belt, the belt moving speed increases when a portion with a thick belt is wound around the driving roller that drives the belt, and conversely when the portion with a thin belt is wound. The moving speed becomes slow. As a result, the belt moving speed varies. Hereinafter, the reason will be specifically described.

  FIG. 15 is a graph showing an example of belt thickness unevenness (belt thickness deviation distribution) in the circumferential direction of the intermediate transfer belt 10 used in the image forming apparatus as shown in FIG. The horizontal axis of this graph is obtained by replacing the length of one belt circumference (belt circumference) with an angle of 2π [rad]. The vertical axis represents the belt thickness deviation value with reference to the average belt thickness (100 [μm]) in the belt circumferential direction (reference value 0). Hereinafter, in the belt having such belt thickness unevenness, the deviation distribution for one round in the belt circumferential direction, which is a problem in the present invention, is referred to as belt thickness fluctuation. Here, the terms “belt thickness unevenness” and “belt thickness fluctuation” used in this specification will be described. First, “belt thickness unevenness” refers to the belt thickness deviation distribution measured by a film thickness measuring instrument, etc., and there is belt thickness unevenness in the belt circumferential direction (conveyance path direction) and depth direction (roller axis direction). To do. On the other hand, "belt thickness fluctuation" means that the belt rotation speed is affected by the rotation speed of the driven roller relative to the rotational angular speed of the driving roller and the rotational angular speed of the driven roller relative to the belt conveyance speed when mounted on the belt drive control device. 2 shows a belt thickness deviation distribution resulting from the above.

FIG. 16 is an enlarged view of the belt portion wound around the drive roller as viewed from the axial direction of the drive roller.
The moving speed of the belt 103 is determined by the distance from the roller surface to the belt pitch line, that is, the pitch line distance (hereinafter referred to as “PLD (Pitch Line Distance)”). In the PLD, when the belt 103 is a single layer belt made of a uniform belt material and the absolute values of the degree of expansion and contraction between the inner peripheral surface side and the outer peripheral surface side of the belt 103 substantially coincide with each other, the center in the belt thickness direction. Is equivalent to the distance between the belt and the inner peripheral surface of the belt, that is, the roller surface. Therefore, in the case of a single-layer belt, the relationship between the PLD and the belt thickness is substantially constant, so that the moving speed of the belt 103 can be determined by the belt thickness variation. However, in a belt composed of a plurality of layers and the like, the stretchability differs between the hard layer and the soft layer. As a result, the distance between the position shifted from the center in the belt thickness direction and the roller surface becomes PLD. Further, the PLD may change depending on the belt winding angle with respect to the driving roller 105.

“PLD _ave ” in the formula shown in the above equation 1 is an average value of PLD over one round of the belt. For example, in the case of a single-layer belt having an average thickness of 100 [μm], PLD _ave is 50 [μm]. Further, “f (d)” is a function indicating the variation of PLD over one belt revolution. Here, “d” indicates the position from the reference point on the belt circumference (phase when the belt circumference is 2π). f (d) is a periodic function having a high correlation with the belt thickness deviation value shown in FIG. If the PLD fluctuates in the belt circumferential direction, the rotational angular velocity or rotational angular displacement of the driven roller with respect to the rotational angular velocity or rotational displacement of the driving roller, or the belt traveling speed or the belt traveling distance with respect to the belt traveling speed or the belt traveling distance. Will fluctuate.

以下、本明細書において、上記数２に示す式中{ }内をローラ実効半径といい、その定常部分（ｒ＋ＰＬＤ_ave）をローラ実効半径Ｒとする。そして、ｆ（ｄ）をＰＬＤ変動という。 The relationship between the belt moving speed V and the rotational angular speed ω of the driving roller 105 is expressed by the following equation (2). “R” in this equation is the radius of the drive roller 105. In addition, the degree to which f (d) indicating the fluctuation of the PLD affects the relationship between the belt moving speed or belt moving distance and the rotational angular velocity or rotational angular displacement of the roller varies depending on the contact state of the belt with the roller and the amount of winding. There is a case. This degree of influence is expressed by a PLD fluctuation effective coefficient κ.

Hereinafter, in the present specification, the inside of {} in the formula shown in Equation 2 above is referred to as a roller effective radius, and the steady portion (r + PLD _ave ) is referred to as a roller effective radius R. F (d) is referred to as PLD fluctuation.

From the equation shown in the above equation 2, it can be seen that the presence of the PLD fluctuation f (d) changes the relationship between the belt moving speed V and the rotational angular speed ω of the driving roller 105. That is, even if the driving roller 105 rotates at a constant rotational angular velocity (ω = constant), the moving speed V of the belt 103 changes due to the PLD fluctuation f (d). Here, for example, in the case of a single layer belt, when a belt portion thicker than the average belt thickness is wound around the driving roller 105, the PLD fluctuation f (d) having a high correlation with the thickness deviation of the belt 103 takes a positive value, Roller effective radius increases. Therefore, even if the drive roller 105 rotates at a constant rotational angular velocity (ω = constant), the belt moving speed V increases. Conversely, when a belt portion thinner than the average belt thickness is wound around the drive roller 105, the belt thickness fluctuation f (d) takes a negative value, and the effective roller radius decreases. Therefore, even if the drive roller 105 rotates at a constant rotational angular velocity (ω = constant), the belt moving speed V decreases.
Therefore, even if the rotational angular velocity ω of the driving roller 105 is constant, the moving speed of the belt 103 is not constant due to the PLD fluctuation f (d). Therefore, even if the driving of the belt 103 is controlled only from the rotational angular velocity ω of the driving roller 105, the belt 103 cannot be driven at a desired moving speed.

The relationship between the belt moving speed V and the rotational angular velocity of the driven roller is the same as the relationship between the belt moving speed V and the rotational angular velocity ω of the driving roller 105 described above. That is, when the rotational angular velocity of the driven roller is detected by a rotary encoder or the like and the belt moving speed V is obtained from the detected rotational angular velocity, the equation shown in the above equation 2 can be used. Therefore, for example, in the case of a single layer belt, when a belt portion thicker than the average belt thickness is wound around the driven roller, as in the case of the driving roller 105, the PLD fluctuation f (d ) Takes a positive value, and the roller effective radius increases. Therefore, even if the belt 103 moves at a constant moving speed (V = constant), the rotational angular speed of the driven roller decreases. On the contrary, when the belt portion thinner than the average belt thickness is wound around the driven roller, the PLD fluctuation f (d) takes a negative value and the roller effective radius decreases. Therefore, even if the belt 103 is moving at a constant moving speed, the rotational angular speed of the driven roller increases.
Therefore, even if the moving speed of the belt 103 is constant, the rotational angular speed of the driven roller is not constant due to the PLD fluctuation f (d). Therefore, even if it is attempted to control the driving of the belt 103 only from the rotational angular velocity of the driven roller, the belt 103 cannot be driven at a desired moving speed.

As an apparatus capable of performing belt drive control in consideration of such PLD fluctuation f (d), there are image forming apparatuses described in Patent Document 1 and Patent Document 2.
In Patent Document 1, before a belt formed by a centrifugal molding method in which PLD fluctuations are likely to be generated by a sine wave over one circumference of the belt is incorporated into the apparatus main body, a thickness profile (belt thickness unevenness) in the entire belt circumference in advance in the manufacturing process. An image forming apparatus is disclosed in which data is measured and the data is stored in a flash ROM. In this image forming apparatus, a reference mark serving as a home position, which is a reference position for matching the phase between the thickness profile data of the entire circumference and the actual belt thickness unevenness, is attached and detected based on the position. The belt drive control is performed so as to cancel the fluctuation of the belt moving speed due to the belt thickness fluctuation.
Patent Document 2 discloses an image forming apparatus that detects periodic fluctuations in belt movement speed by forming a detection pattern on a belt and detecting the pattern with a detection sensor. In this image forming apparatus, the rotational speed of the drive roller is controlled so as to cancel the detected fluctuations in the periodic belt moving speed.

JP 2000-310897 A Japanese Patent No. 3186610

However, the image forming apparatus described in Patent Document 1 requires a measuring process for measuring belt thickness unevenness in the belt manufacturing stage, and a highly accurate belt thickness measuring instrument is required in the measuring process. Therefore, there is a problem that the manufacturing cost increases significantly. In addition, when a belt is replaced with a new one, there is a problem that it is necessary to input thickness profile data unique to the new belt to the apparatus. Further, since this image forming apparatus uses uneven belt thickness without using the PLD fluctuation f (d), accurate belt drive control is possible in the case of a single-layer belt, but in the case of a multi-layer belt. Accurate belt drive control is not possible.
Further, in the image forming apparatus described in Patent Document 2, it is necessary to form a detection pattern for at least one round of the belt on the belt in order to detect fluctuations in the belt moving speed. Therefore, there is a problem that a large amount of toner is consumed for forming this detection pattern. In particular, in order to detect fluctuations in belt movement speed with higher accuracy, if the average value of belt movement speed fluctuation information for multiple belt rotations is to be grasped as belt movement speed fluctuations, detection for multiple belt rotations is required. Therefore, the problem of toner consumption becomes more serious.

  The present applicant has proposed a belt drive control device that can solve these problems in Japanese Patent Application No. 2002-230537 (hereinafter referred to as “prior application”). In this belt drive control device, the rotational angular displacement or rotational angular velocity of the driven support rotator is detected, and from the detected data, the driven support rotator has a frequency corresponding to the periodic thickness fluctuation in the circumferential direction of the belt. Extract AC component of rotational angular velocity. The amplitude and phase of the extracted AC component correspond to the amplitude and phase of periodic thickness fluctuations in the circumferential direction of the belt. Therefore, based on the amplitude and phase of this AC component, the rotational angular velocity of the drive support rotator is lowered at the timing when the thick belt portion contacts the drive support rotator, and conversely the drive occurs at the timing when the thin belt portion contacts the drive support rotator. Control is performed to increase the rotational angular velocity of the support rotator. According to this method, it is possible to drive the belt at a desired moving speed without being affected by the thickness variation in the circumferential direction of the belt. In addition, since there is no need for a measurement process for measuring belt thickness unevenness in the belt manufacturing stage, there is no increase in manufacturing cost as in the apparatus of Patent Document 1. Further, it is not necessary to input thickness profile data to the apparatus when replacing the belt with a new one. In addition, since it is not necessary to form a detection pattern as in the apparatus of Patent Document 2, toner is not consumed for belt drive control.

  However, in the belt drive control device proposed in the above-mentioned prior application, the belt thickness variation is approximated to a periodic function of a sin function (cos function), so it is known in advance how the belt thickness variation occurs over one belt revolution. There is a problem that it is necessary to keep. That is, it is known in advance whether the frequency component included in the belt thickness fluctuation is only the fundamental frequency component having the same period as the cycle of the belt or the higher-order frequency component is also included. There is a problem that it is necessary. In addition, the seam belt of the seam belt having joints is often thicker than the other parts, and belt thickness fluctuations in the partially protruding parts may occur. Such a belt thickness variation is difficult to approximate to a periodic function, and there is a problem that a control error is included in that portion.

  The present invention has been made in view of the background described above, and the object of the present invention is to solve the above-described problems in the same manner as proposed in the prior application, and the prior application is It is an object of the present invention to provide a belt drive control device that can solve the problems involved, a belt device using the belt drive control device, and an image forming apparatus using the belt device.

In order to achieve the above object, a first aspect of the present invention provides a plurality of support rotators including a driven support rotator that rotates along with the movement of the belt and a drive support rotator that transmits a driving force to the belt. In the belt drive control device for controlling the drive of the belt, the diameter of the plurality of support rotating bodies is different, or the pitch line distance of the belt portion wound around the belt is the movement of the belt. The belt generated by the variation of the pitch line distance in the circumferential direction of the belt based on the rotation angle displacement or the rotation information of the rotation angular velocity in two supporting rotating bodies having different degrees of influence on the relationship between the speed and the self rotation angular velocity It is characterized by having a control means for performing the drive control so that the fluctuation of the moving speed is small.
According to a second aspect of the present invention, there is provided a plurality of support rotators including a driven support rotator that rotates along with the movement of the belt and a drive support rotator that transmits a driving force to the belt. In the belt drive control device for controlling the drive of the belt, among the plurality of supporting rotating bodies, the diameters are different from each other, or the thickness of the belt portion wound around the belt is determined by the movement speed of the belt and the rotation angular speed of the belt. Based on the rotational information of the rotational angular displacement or rotational angular velocity of the two supporting rotating bodies having different degrees of influence on the relationship, the movement speed fluctuation of the belt caused by the belt thickness fluctuation in the circumferential direction of the belt is reduced. It has a control means for performing the drive control.
According to a third aspect of the present invention, in the belt drive control device according to the first or second aspect, the control means is configured to obtain the two support rotators respectively obtained from rotation information of the two support rotators detected at the same time. The above-described drive control is performed using approximate rotation fluctuation information obtained by assuming that the rotation fluctuation information is in phase with each other.
According to a fourth aspect of the present invention, in the belt drive control device according to the first or second aspect, the control means includes two pieces of rotational fluctuation information having different phases included in the rotational information of one or both of the two supporting rotating bodies. One of the values is reduced, and the drive control is performed using the processing result.
According to a fifth aspect of the present invention, in the belt drive control device according to the fourth aspect, the processing is performed on two pieces of rotational fluctuation information having different phases included in rotational information of one or both of the two supporting rotating bodies. A delay time which is a belt passing time required for the belt to move a distance between the two supporting rotators on the belt moving path and a gain based on the above degree of the two supporting rotators are given. The addition process is performed, and the addition process is further repeated n (n ≧ 1) times for the process result, and the gain at the n-th addition process is the first addition process. characterized in that used after 2 ^n-1 power gain G, it is performed using those 2 ^n-1 times the belt passage time as the delay time in the n-th addition processing in Than it is.
According to a sixth aspect of the present invention, in the belt drive control device according to the fourth aspect, the ratio of the belt movement path length between the two support rotators to the entire belt circumference is 2 Nb (Nb Is a natural number), and the above processing is performed on the belt movement path with respect to two pieces of rotational fluctuation information having different phases included in the rotational information of one or both of the two supporting rotating bodies. The result obtained by adding the delay time, which is the belt passing time required for the belt to move the distance between the two support rotators, and the gain based on the above degree of the two support rotators is added. Further, the process of performing the addition process is repeated Nb times, and the gain G at the time of the first addition process is multiplied by 2 ^n-1 as the gain at the time of the n-th addition process. , And the delay time during the n-th addition process is obtained by multiplying the belt passing time by 2 ^n-1 .
The invention of claim 7 is the belt drive control device according to claim 4, wherein the processing is performed on two pieces of rotational fluctuation information having different phases included in the rotational information of one or both of the two supporting rotating bodies. Outputs a delay time, which is a belt passing time required for the belt to move the distance between the two support rotators on the belt movement path, and a gain based on the above-mentioned degree of the two support rotators. The output information is fed back and added to the two pieces of rotation fluctuation information.
According to an eighth aspect of the present invention, in the belt drive control device according to the third, fourth, sixth, or seventh aspect, the variation for storing rotational variation information for a period corresponding to the time required for the belt to make one revolution is stored. It has an information storage means.
The invention according to claim 9 is the belt drive control device according to claim 8, wherein the control means has an allowable range of difference between the rotation fluctuation information stored in the fluctuation information storage means and the newly obtained rotation fluctuation information. The process of obtaining the rotation fluctuation information again is performed at a timing exceeding.
According to a tenth aspect of the present invention, in the belt drive control device according to the third, fourth, fifth, sixth, seventh or eighth aspect, the control means performs a process of obtaining the rotation variation information again at a predetermined timing. It is a feature.
According to an eleventh aspect of the present invention, in the belt drive control device according to the third, fourth, fifth, sixth, seventh or eighth aspect, the control means performs the drive control while performing the process for obtaining the rotation variation information. It is characterized by this.
The invention according to claim 12 is the belt drive control device according to claim 3, 4, 5, 6, 7, 8, 9, 10 or 11, wherein the past information for at least one round of the belt storing past rotation variation information is stored. Storage means, and the control means performs the drive control using information obtained from past rotation fluctuation information stored in the past information storage means and newly obtained rotation fluctuation information. It is a feature.
The invention according to claim 13 is a belt stretched around a plurality of support rotators including a driven support rotator that rotates along with the movement of the belt and a drive support rotator that transmits a driving force to the belt. And a belt device including a drive source that generates a rotational driving force for driving the belt and a belt drive control device that performs drive control of the belt. Or, alternatively, the rotational angular displacement or rotational angular velocity of two supporting rotating bodies that differ from each other in the degree that the thickness or pitch line distance of the belt portion wound around the belt affects the relationship between the moving speed of the belt and the rotational angular velocity of the belt. And a belt drive control device according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12. It is characterized in that using the apparatus.
The invention according to claim 14 is the belt device according to claim 13, wherein all of the two support rotating bodies are driven support rotating bodies that rotate along with the movement of the belt. It is.
Further, the invention of claim 15 is the belt device of claim 14, wherein the drive source has feedback control means for detecting its own rotational angular displacement or rotational angular velocity and feeding back the rotational angular displacement or rotational angular velocity. It is characterized by.
According to a sixteenth aspect of the present invention, in the belt device of the thirteenth aspect, the two support rotators include the drive support rotator.
The invention according to claim 17 uses the belt drive control device according to claim 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 as the belt drive control device. Alternatively, in the belt device of 16, in order to grasp the reference belt movement position of the belt, the belt device has mark detection means for detecting a mark indicating the reference position on the belt, and the control means of the belt drive control device includes The rotation fluctuation information is acquired based on the detection timing by the mark detection means, and the drive control is performed.
The invention according to claim 18 uses the belt drive control device according to claim 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 as the belt drive control device. Alternatively, in the belt device of 16, the control means of the belt drive control device may be configured to obtain an average time required for the belt to make one turn, or to obtain information on the relationship between the fluctuation of the pitch line distance and the belt moving position in advance. The drive control is performed after grasping based on the grasped belt circumference.
The invention according to claim 19 is the belt device according to claim 13, 14, 15, 16, 17 or 18 in which the belt drive control device according to claim 3 is used as the belt drive control device. The belt circumferential direction distance is set so that the error generated by the approximation falls within a predetermined allowable range.
The invention of claim 20 is the belt device of claim 13, 14, 15, 16, 17, 18 or 19, wherein the belt has a joint at at least one place in the belt circumferential direction. It is what.
The invention of claim 21 is the belt device of claim 13, 14, 15, 16, 17, 18, 19 or 20, wherein the belt has a plurality of layers in the belt thickness direction. It is a feature.
According to a twenty-second aspect of the invention, in the belt device of the thirteenth, fourteenth, fifteenth, sixteenth, seventeenth, eighteenth, nineteenth, twenty-first, or twenty-first aspect, at least one of the plurality of supporting rotating bodies includes a plurality over the rotation direction. The belt has a meshing portion that meshes with the plurality of teeth.
Further, the invention of claim 23 is a latent image carrier comprising a belt stretched over a plurality of support rotators, a latent image forming means for forming a latent image on the latent image carrier, and the latent image carrier. An image forming apparatus comprising: a developing unit that develops the latent image on the image; and a transfer unit that transfers a visible image on the latent image carrier to a recording material. Item 13, 14, 15, 16, 17, 18, 19, 20, 21 or 22 belt device is used.
According to a twenty-fourth aspect of the present invention, there is provided a latent image carrier, a latent image forming unit that forms a latent image on the latent image carrier, a developing unit that develops the latent image on the latent image carrier, An intermediate transfer member composed of a belt stretched over a support rotating member, a first transfer means for transferring a visible image on the latent image carrier to the intermediate transfer member, and a visible image on the intermediate transfer member. An image forming apparatus provided with a second transfer means for transferring to a material, wherein the intermediate transfer body is driven as a belt device according to claim 13, 14, 15, 16, 17, 18, 19, 20, 21. Alternatively, 22 belt devices are used.
According to a twenty-fifth aspect of the present invention, there is provided a latent image carrier, a latent image forming unit for forming a latent image on the latent image carrier, a developing unit for developing a latent image on the latent image carrier, A recording material conveying member comprising a belt stretched around a support rotating member, and a visible image on the latent image bearing member via the intermediate transfer member or directly without using the intermediate transfer member; An image forming apparatus provided with a transfer means for transferring to a recording material being conveyed, wherein the belt device for driving the recording material conveyance member is defined by claim 13, 14, 15, 16, 17, 18, 19, The belt device of 20, 21 or 22 is used.

When the belt is moved endlessly due to the difference in the diameter of the support rotator, the winding angle of the belt with respect to the support rotator, the material of the belt, the layer structure of the belt, and the like, It has been found that the proportion of the PLD fluctuation component generated in the rotational angular velocity is different. That is, it has been found that when two rotating supports rotate with respect to the same belt, the magnitudes of the PLD fluctuations detected as the rotational angular velocity fluctuations of the respective rotating supports differ. If this is utilized, PLD fluctuation | variation can be specified from the rotation angle displacement or rotation angular velocity of two support rotary bodies. Therefore, based on the detection result of the rotational angular displacement or rotational angular velocity of these two supporting rotating bodies, the rotation control of the driving supporting rotating body is performed so that the fluctuation of the belt moving speed caused by the PLD fluctuation in the circumferential direction of the belt becomes small. It can be performed. Examples of the two supporting rotating bodies include those having different roller diameters and those having different PLD fluctuation effective coefficients κ. Strictly speaking, as will be described in detail later, In the case where β shown is not 0 or G shown in the following Equation 29 is not 1, there are examples in which the ratio between the roller effective radius R and the PLD fluctuation effective coefficient κ is different from each other.
In the first aspect of the invention, as described above, the PLD fluctuation can be specified based on the detection result of the rotational angular displacement or the rotational angular velocity of the two supporting rotating bodies. In the invention of claim 2, the belt thickness fluctuation having a high correlation with the PLD fluctuation can be specified in the case of the single-layer belt based on the detection result of the rotation angular displacement or the rotation angular velocity of the two supporting rotating bodies. This eliminates the need for a measurement process for measuring belt thickness unevenness in the belt manufacturing stage, so that the manufacturing cost does not increase. Further, when replacing the belt with a new one, there is no need to input data relating to unevenness of the belt thickness to the apparatus. Further, since it is not necessary to form a detection pattern, toner is not consumed for belt drive control. Further, it is not necessary to know in advance how the PLD fluctuation or the belt thickness fluctuation occurs over one belt circumference. Further, in the present invention, a belt having a partially protruding PLD fluctuation or belt thickness fluctuation that is difficult to approximate to a periodic function with the apparatus of the prior application, as described later, the PLD fluctuation or belt thickness fluctuation. Can be specified with high accuracy.
Furthermore, in the present invention, the PLD fluctuation or the belt thickness fluctuation specified from the rotational angular displacement or rotational angular velocity of the two supporting rotating bodies is the two supporting rotations if the supporting rotating body is a driven supporting rotating body. The influence of the contact state between the body and the belt is taken into consideration. On the other hand, the belt thickness unevenness measured by the belt thickness measuring device as in the device described in Patent Document 1 does not take into consideration the influence of the contact state between the support rotating body and the belt. The belt thickness unevenness actually exists not only in the belt circumferential direction but also in the belt width direction orthogonal thereto. Here, when a belt having belt thickness unevenness in the belt width direction is stretched over the support rotator, the relationship between the moving speed of the belt portion wound around the support rotator and the rotation angular speed of the support rotator is The belt portion largely depends on the thickest portion in the belt width direction. That is, the relationship between the moving speed of the belt portion and the rotational angular velocity of the support rotator varies depending on the belt thickness unevenness in the belt width direction of the belt portion wound around the support rotator. This is because the thickest part in the belt width direction comes into contact with the support rotator with the largest frictional force with the support rotator. Therefore, if belt drive control is performed based on the belt thickness unevenness measured by the belt thickness measuring instrument in which the influence of the contact state between the support rotating body and the belt is not considered, a control error due to the belt thickness unevenness in the belt width direction occurs. . On the other hand, in the present invention, belt drive control can be performed based on PLD fluctuation or belt thickness fluctuation in consideration of the influence of the contact state between the support rotating body and the belt. A control error can be prevented from occurring. Therefore, according to the present invention, it is possible to perform belt drive control with higher accuracy.
In particular, according to the first aspect of the present invention, the PLD fluctuation itself, which is a direct cause of the fluctuation of the belt moving speed, can be specified. Even belts or perforated belts that are driven in mesh with the gears on the support rotator are capable of accurate belt drive control.

As described above, according to the inventions of claims 1 to 25, it is possible to solve the above-described problem as well as to the problem proposed by the prior application and to solve the problems associated with the prior application. The effect is played.
Furthermore, according to the invention of claims 1 to 25, the belt drive control can be performed with higher accuracy than in the case where the belt drive control is performed based on the belt thickness unevenness in the belt circumferential direction measured by the belt thickness measuring instrument. An excellent effect is also possible.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic configuration diagram showing an example of a copying machine as an image forming apparatus to which the present invention is applied. In FIG. 1, reference numeral 100 denotes a copying machine main body, reference numeral 200 denotes a paper feed table on which the copying machine is placed, reference numeral 300 denotes a scanner mounted on the copying machine main body 100, and reference numeral 400 further denotes an automatic document transport mounted thereon. Device (ADF). This copier is a tandem type electrophotographic copier that employs an intermediate transfer (indirect transfer) system.

  In the center of the copying machine main body 100, an intermediate transfer belt 10 including a belt which is an intermediate transfer member serving as an image carrier is provided. The intermediate transfer belt 10 is stretched around support rollers 14, 15, and 16 as three support rotating bodies, and rotates in the clockwise direction in the drawing. An intermediate transfer belt cleaning device 17 for removing residual toner remaining on the intermediate transfer belt 10 after image transfer is provided on the left side of the second support roller 15 in the drawing among these three support rollers. Further, among the three support rollers, a belt portion stretched between the first support roller 14 and the second support roller 15 has yellow (Y), magenta (M), A tandem image forming unit 20 in which four image forming units 18 of cyan (C) and black (K) are arranged side by side is arranged oppositely. In the present embodiment, the third support roller 16 is a drive roller. An exposure device 21 as a latent image forming unit is provided above the tandem image forming unit 20.

  A secondary transfer device 22 as a second transfer unit is provided on the opposite side of the tandem image forming unit 20 with the intermediate transfer belt 10 interposed therebetween. In the secondary transfer device 22, a secondary transfer belt 24 that is a belt as a recording material conveying member is stretched between two rollers 23. The secondary transfer belt 24 is provided so as to be pressed against the third support roller 16 via the intermediate transfer belt 10. The secondary transfer device 22 transfers an image on the intermediate transfer belt 10 to a sheet as a recording material. A fixing device 25 for fixing the image transferred on the sheet is provided on the left side of the secondary transfer device 22 in the drawing. The fixing device 25 has a configuration in which a pressure roller 27 is pressed against a fixing belt 26 that is a belt. The secondary transfer device 22 described above also has a sheet conveyance function for conveying the sheet after image transfer to the fixing device 25. Of course, a transfer roller or a non-contact charger may be disposed as the secondary transfer device 22, and in such a case, it is difficult to provide this sheet conveying function together. In the present embodiment, a sheet reversing device for reversing the sheet so as to record images on both sides of the sheet is provided below the secondary transfer device 22 and the fixing device 25 in parallel with the tandem image forming unit 20 described above. 28 is also provided.

When making a copy using the copying machine, a document is set on the document table 30 of the automatic document feeder 400. Alternatively, the automatic document feeder 400 is opened, a document is set on the contact glass 32 of the scanner 300, and the automatic document feeder 400 is closed and pressed by it. Thereafter, when a start switch (not shown) is pressed, when the document is set on the automatic document feeder 400, the document is conveyed and moved onto the contact glass 32. On the other hand, when an original is set on the contact glass 32, the scanner 300 is immediately driven. Next, the first traveling body 33 and the second traveling body 34 travel. Then, the first traveling body 33 emits light from the light source and further reflects the reflected light from the document surface toward the second traveling body 34 and is reflected by the mirror of the second traveling body 34 and passes through the imaging lens 35. The document is placed in the reading sensor 36 and the original content is read.
In parallel with this document reading, the drive roller 16 is rotated by a drive motor which is a drive source (not shown). As a result, the intermediate transfer belt 10 moves in the clockwise direction in the drawing, and the remaining two support rollers (driven rollers) 14 and 15 rotate along with the movement. At the same time, the photosensitive drums 40Y, 40M, 40C, and 40K serving as latent image carriers are rotated in the individual image forming units 18 so that yellow, magenta, cyan, and black are separately provided on the photosensitive drums. Each information is exposed and developed to form a single color toner image (visualized image). Then, the toner images on the photosensitive drums 40Y, 40M, 40C, and 40K are sequentially transferred onto the intermediate transfer belt 10 so as to overlap each other, thereby forming a composite color image on the intermediate transfer belt 10.

In parallel with such image formation, one of the paper feed rollers 42 of the paper feed table 200 is selectively rotated, and the sheet is fed out from one of the paper feed cassettes 44 provided in the paper bank 43 in multiple stages. The sheets are separated one by one and are put into the paper feed path 46, transported by the transport roller 47, guided to the paper feed path in the copying machine main body 100, and abutted against the registration roller 49 and stopped. Alternatively, the sheet feed roller 50 is rotated to feed out the sheets on the manual feed tray 51, separated one by one by the separation roller 52, put into the manual feed path 53, and abutted against the registration roller 49 and stopped. Then, the registration roller 49 is rotated in synchronization with the composite color image on the intermediate transfer belt 10, the sheet is fed between the intermediate transfer belt 10 and the secondary transfer device 22, and transferred by the secondary transfer device 22. A color image is transferred onto the sheet. The image-transferred sheet is conveyed by the secondary transfer belt 24 and sent to the fixing device 25. The fixing device 25 applies heat and pressure to fix the transferred image, and then the switching roller 55 is used to switch the discharge image. The paper is discharged at 56 and stacked on the paper discharge tray 57. Alternatively, it is switched by the switching claw 55 and put into the sheet reversing device 28, where it is reversed and guided again to the transfer position, and the image is recorded also on the back surface, and then discharged onto the discharge tray 57 by the discharge roller 56.
The intermediate transfer belt 10 after the image transfer is removed by the intermediate transfer belt cleaning device 17 to remove residual toner remaining on the intermediate transfer belt 10 after the image transfer, so that the tandem image forming unit 20 can prepare for another image formation. Here, the registration roller 49 is generally used while being grounded, but it is also possible to apply a bias for removing paper dust from the sheet.

  This copier can be used to make a black and white copy. In that case, the intermediate transfer belt 10 is separated from the photosensitive drums 40Y, 40M, and 40C by means not shown. These photosensitive drums 40Y, 40M, and 40C are temporarily stopped from driving. Only the black photosensitive drum 40K is brought into contact with the intermediate transfer belt 10 to perform image formation and transfer.

Next, the configuration of the intermediate transfer belt 10 of this embodiment will be described. Note that the following description is not limited to the intermediate transfer belt, but is the same for a belt that is widely driven and controlled.
As the intermediate transfer belt, a single-layer belt mainly composed of a fluorine-based resin, a polycarbonate resin, a polyimide resin, or the like, or a multi-layer elastic belt having an entire belt layer or a part of the belt as an elastic member is used. In general, the belt used in the image forming apparatus is not limited to the intermediate transfer belt, and a plurality of functions are required. In recent years, in order to simultaneously achieve a plurality of required functions, a multi-layer belt having a plurality of layers in the belt thickness direction is often used. For example, the intermediate transfer belt 10 is required to have a plurality of functions such as toner releasability, photosensitive member nip property, durability, tensile property, high driving roller friction property, and photosensitive member low friction property.

The toner releasability is a function necessary for improving the transfer property from the intermediate transfer belt 10 to the recording paper and improving the cleaning property for the residual transfer toner remaining on the intermediate transfer belt.
The photoconductor nip property is a function necessary for improving transferability to the intermediate transfer belt 10 by being in close contact with the photoconductor drums 40Y, 40M, 40C, and 40K.
Durability is a function necessary for reducing running costs by allowing long-term use with less cracking and wear due to use over time.
The tensile property is a function necessary for controlling the belt moving speed and the belt moving position with high accuracy by preventing expansion and contraction in the belt circumferential direction when the belt is driven.
The high friction property with respect to the driving roller is a function necessary for preventing the slip between the driving roller 16 and the intermediate transfer belt 10 and realizing stable and highly accurate driving.
Low friction against the photoconductor is necessary to suppress load fluctuations by causing slippage between the photoconductor drums 40Y, 40M, 40C, and 40K and the intermediate transfer belt 10 even if a speed difference occurs between them. Function.
In order to simultaneously realize these functions at a high level, for example, an intermediate transfer belt composed of a multi-layer belt as described below is used.

FIG. 17 is an explanatory diagram showing an example of the layer structure of the intermediate transfer belt 10.
The intermediate transfer belt 10 of this example is an endless belt having a five-layer structure made of different materials, and is formed so that the thickness of the belt is 500 to 700 [μm] or less. The first layer, the second layer, the third layer, the fourth layer, and the fifth layer are sequentially formed from the belt surface side (the surface side in contact with the photosensitive drum).
The first layer is a polyurethane resin coat layer filled with fluorine. By this layer, low friction between the photosensitive drums 40Y, 40M, 40C, and 40K and the intermediate transfer belt 10 (anti-photosensitive member low friction) and toner releasability are realized.
The second layer is a silicon-acrylic copolymer coat layer that plays a role in improving the durability of the first layer and preventing the third layer from aging.
The third layer is a rubber layer (elastic layer) made of chloroprene having a thickness of about 400 to 500 [μm], and has a Young's modulus of 1 to 20 [Mpa]. Since the third layer is deformed in the secondary transfer portion according to local unevenness due to a toner image or recording paper having poor smoothness, the transfer pressure is not excessively increased with respect to the toner image. Occurrence of omission is suppressed. In addition, since good adhesion to a recording paper with poor smoothness is obtained, a transfer image with excellent uniformity can be obtained.
The fourth layer is a polyvinylidene fluoride layer having a thickness of about 100 [μm] and serves to prevent expansion and contraction in the belt circumferential direction. The Young's modulus is 500 to 1000 [Mpa].
The fifth layer has a polyurethane coat layer and realizes a high friction coefficient with the drive roller 16.

Examples of other materials include the following.
In the first layer and the second layer, the photosensitive material is prevented from being contaminated by an elastic material, and the surface friction resistance to the surface of the intermediate transfer belt 10 is reduced to reduce the adhesion of the toner, thereby improving the cleaning performance. One or more kinds of polyurethane, polyester, epoxy resin and the like may be used in order to improve the secondary transfer property to the recording paper. Also, in order to reduce the surface energy and improve the lubricity, one or more kinds of powders or particles such as fluororesin, fluorine compound, fluorocarbon, titanium dioxide, silicon carbide, etc., or particles of each other are used. The same type having different diameters may be dispersed. Moreover, you may use the thing which formed the fluorine rich layer on the surface by heat-processing like a fluorine-type rubber material, and made surface energy small.
In the third elastic layer, butyl rubber, fluorine rubber, acrylic rubber, EPDM, NBR, acrylonitrile-butadiene-styrene rubber natural rubber, isoprene rubber, styrene-butadiene rubber, butadiene rubber, ethylene-propylene rubber, ethylene-propylene ter Polymer, chloroprene rubber, chlorosulfonated polyethylene, chlorinated polyethylene, urethane rubber, syndiotactic 1,2-polybutadiene, epichlorohydrin rubber, ricone rubber, fluorine rubber, polysulfide rubber, polynorbornene rubber, hydrogenated nitrile rubber , One kind selected from the group consisting of thermoplastic elastomers (for example, polystyrene, polyolefin, polyvinyl chloride, polyurethane, polyamide, polyurea, polyester, fluororesin) It may be used two or more kinds.
As the fourth layer, polycarbonate, fluororesin (ETFE, PVDF), polystyrene, chloropolystyrene, poly-α-methylstyrene, styrene-butadiene copolymer, styrene-vinyl chloride copolymer, styrene-vinyl acetate copolymer Polymer, styrene-maleic acid copolymer, styrene-acrylic acid ester copolymer (styrene-methyl acrylate copolymer, styrene-ethyl acrylate copolymer, styrene-butyl acrylate copolymer, styrene-acrylic acid Octyl copolymer and styrene-phenyl acrylate copolymer), styrene-methacrylic acid ester copolymer (styrene-methyl methacrylate copolymer, styrene-ethyl methacrylate copolymer, styrene-phenyl methacrylate copolymer) Coalesce etc.), styrene-α-chloroacrylic acid Styrenic resins such as methyl copolymers, styrene-acrylonitrile-acrylic acid ester copolymers (monopolymers or copolymers containing styrene or substituted styrene), methyl methacrylate resins, butyl methacrylate resins, ethyl acrylate Resin, butyl acrylate resin, modified acrylic resin (silicone modified acrylic resin, vinyl chloride resin modified acrylic resin, acrylic / urethane resin, etc.), vinyl chloride resin, styrene-vinyl acetate copolymer, vinyl chloride-vinyl acetate copolymer , Rosin-modified maleic resin, phenol resin, epoxy resin, polyester resin, polyester polyurethane resin, polyethylene, polypropylene, polybutadiene, polyvinylidene chloride, ionomer resin, polyurethane resin, silicone resin, ketone resin, ethylene - it can be used ethyl acrylate copolymer, xylene resin and polyvinyl butyral resin, polyamide resin, one kind or two kinds or more selected from the group consisting of modified polyphenylene oxide resin.

As a method for preventing elongation as an elastic belt, there are a method of forming a rubber layer in a core resin layer that is less stretched as in the fourth layer, a method of putting a material for preventing elongation in the core layer, etc. It is not related to the manufacturing method.
Examples of materials constituting the core layer for preventing elongation include natural fibers such as cotton and silk, polyester fibers, nylon fibers, acrylic fibers, polyolefin fibers, polyvinyl alcohol fibers, polyvinyl chloride fibers, polyvinylidene chloride fibers, and polyurethanes. 1 or 2 types selected from the group consisting of synthetic fibers such as fibers, polyacetal fibers, polyfluoroethylene fibers and phenol fibers, inorganic fibers such as carbon fibers, glass fibers and boron fibers, and metal fibers such as iron fibers and copper fibers By using the above, it is possible to use a woven fabric or yarn. Of course, the material is not limited to the above. The yarn may be twisted in any manner, such as one or a plurality of filaments twisted, a single twisted yarn, various twisted yarns, a double yarn, or the like. Further, for example, fibers of a material selected from the above material group may be blended. Of course, the yarn can be used after being subjected to an appropriate conductive treatment. On the other hand, the woven fabric can be any woven fabric such as knitted weave. Of course, a woven fabric that has been woven can also be used, and naturally conductive treatment can be applied.
The manufacturing method for providing the core layer is not particularly limited. For example, a method in which a woven fabric woven in a cylindrical shape is covered with a mold and a coating layer is provided thereon, a woven fabric woven in a cylindrical shape is immersed in liquid rubber or the like, and a coating layer is formed on one or both sides of the core layer For example, a method of providing a coating layer on a spirally wound thread around a mold or the like at an arbitrary pitch can be given.

  Depending on the layer, a conductive material for adjusting the resistance value may be included, for example, carbon black, graphite, metal powder such as aluminum or nickel, tin oxide, titanium oxide, antimony oxide, indium oxide, potassium titanate, antimony oxide- Conductive metal oxides such as tin oxide composite oxide (ATO) and indium oxide-tin oxide composite oxide (ITO), and conductive metal oxides are made of insulating fine particles such as barium sulfate, magnesium silicate, and calcium carbonate. It may be coated. However, it is a matter of course that the present invention is not limited to these materials.

  By the way, in the case of a single layer belt having a uniform belt material, since the degree of expansion and contraction of the inner peripheral surface and the outer peripheral surface of the belt coincides, the belt pitch line that determines the moving speed of the belt as shown in FIG. It becomes the center in the thickness direction. However, in the case of the multi-layer belt as described above, the belt pitch line does not become the central portion in the belt thickness direction. In the multi-layer belt, when there is a layer with a large Young's modulus protruding from among the plurality of layers constituting the belt, the belt pitch line is present at substantially the center of the layer. This is because a layer having a high Young's modulus (hereinafter referred to as “tensile layer”) is used as a core wire to prevent expansion and contraction in the belt circumferential direction, and other layers expand and contract and wind around the support roller. In the case of the intermediate transfer belt 10, the fourth layer which is the tensile layer protrudes and has a large Young's modulus, and therefore the belt pitch line exists inside the fourth layer. When there is a tensile layer having a large Young's modulus and protruding in this way, the thickness unevenness of the tensile layer in the belt circumferential direction greatly affects the fluctuation of the PLD. In short, in a multi-layer belt, the PLD is determined mainly by the influence of a layer having a large Young's modulus among the plurality of layers constituting the belt.

In addition, the PLD also varies when the position of the fourth layer (tensile layer) is displaced in the belt thickness direction over the entire circumference of the belt. For example, if there is uneven thickness in the fifth layer existing between the fourth layer (tensile layer) and the support roller, the position of the fourth layer (tensile layer) in the belt thickness direction depends on the uneven thickness. Change and the PLD fluctuates.
Also, in the case of an endless belt (seam belt) with joints, the manufacturing method is to create a fourth layer of polyvinylidene fluoride sheet and overlap the end of the sheet by about 2 [mm] for fusion bonding In many cases, the other layers are sequentially formed after the endless shape. In this case, the melt-bonded part (joint part) changes in physical properties due to melting and has different stretchability from the other parts. Therefore, even if the thickness is the same as the other parts, the PLD of the joint part is the It deviates greatly from PLD. In such a portion, even if there is no belt thickness variation, PLD variation occurs, and when this portion is wound around the drive roller, belt speed variation occurs. In addition, seam belts with joints do not require such a mold and can adjust the belt circumference compared to seamless belts that require unique molds for products with different belt circumferences. There is an advantage that the manufacturing cost can be suppressed in that it is free.

Next, drive control of the intermediate transfer belt 10, which is a characteristic part of the present invention, will be described.
In the copying machine of this embodiment, it is necessary to move the intermediate transfer belt 10 at a constant speed. In practice, however, the belt moving speed varies due to component errors, environment, and changes over time. When the belt moving speed of the intermediate transfer belt 10 fluctuates, the actual belt moving position deviates from the target belt moving position, and the leading edge position of each toner image on the photosensitive drums 40Y, 40M, and 40C is the intermediate transfer belt 10. A color shift occurs due to a shift. Further, when the belt moving speed is relatively high, the toner image portion transferred onto the intermediate transfer belt 10 has a shape that is stretched in the belt circumferential direction rather than the original shape, and conversely, the belt moving speed is relatively high. At a later time, the toner image portion transferred onto the intermediate transfer belt 10 has a shape reduced in the belt circumferential direction from the original shape. In this case, in the image finally formed on the sheet, a periodic change in image density (banding) appears in a direction corresponding to the belt circumferential direction.
Therefore, the configuration and operation for maintaining the intermediate transfer belt 10 at a constant speed with high accuracy will be described below. Note that the following description is not limited to the intermediate transfer belt 10, but is the same for a belt that is widely driven and controlled.

In the present embodiment, the rotational angular velocities ω _{1 of} two rollers having different roller diameters or different degrees of influence of the PLD of the belt portion wound around the belt on the relationship between the moving speed of the belt and the rotational angular speed of the belt are different. , Ω ₂ are continuously detected, and the PLD fluctuation f (t) is obtained from the two types of rotational angular velocities ω ₁ , ω ₂ . In the case of a single-layer belt, the PLD has a certain relationship with the belt thickness, and the PLD variation has a certain relationship with the belt thickness variation, so that the belt portion having a different roller diameter or wound around itself. Continuously detecting the rotational angular velocities of two rollers having different degrees of influence of the thickness of the belt on the relationship between the moving speed of the belt and the rotational angular speed of the belt, and obtaining the belt thickness fluctuation from these two rotational angular velocities. It may be. The PLD fluctuation f (t) is a periodic function indicating the time change of the PLD of the belt portion that passes through a specific point on the belt moving path while the belt makes one round. Since the PLD fluctuation f (t) greatly affects the moving speed V of the belt as described above, the PLD fluctuation f (t) is obtained with high accuracy from the rotational angular velocities ω ₁ and ω _{2 of the} two support rollers. If belt drive control is performed based on the PLD fluctuation f (t), the belt moving speed V can be controlled with high accuracy.
In the present embodiment, three types of methods are given as examples for obtaining the PLD fluctuation f (t) with high accuracy. The first method is a method in which the two rollers are arranged close to each other in the belt moving direction (PLD fluctuation recognition method 1). The second is a method of performing filter processing that does not affect the positional relationship between the two rollers (PLD fluctuation recognition method 2). The third is a method of performing the filtering process by setting the arrangement relationship of the two rollers (belt transport distance between the two rollers) to 1 / integer with respect to one belt cycle (PLD fluctuation recognition method 3). ).

[Method for recognizing PLD fluctuation 1]
FIG. 2 is a schematic diagram showing a main part of the belt device. This belt device includes a belt 103 and a first roller 101 and a second roller 102 as support rotating bodies around which the belt 103 is stretched. The belt 103 is wound around the first roller 101 at a belt winding angle θ ₁ and is wound around the second roller 102 at a belt winding angle θ ₂ . The belt 103 moves endlessly in the direction of arrow A in the figure. The first roller 101 and the second roller 102 are each provided with a rotary encoder as a detecting means. As these rotary encoders, any encoder that can detect the rotational angular displacement or rotational angular velocity of each of the rollers 101 and 102 may be used. In the present embodiment, a roller capable of detecting the rotational angular velocities ω ₁ and ω ₂ of the rollers 101 and 102 is used. As this rotary encoder, for example, timing marks at regular intervals are formed on concentric circles on a disk made of a transparent member such as transparent glass or plastic, and are fixed coaxially to the rollers 101 and 102. A known optical encoder that optically detects the timing mark can be used. Further, for example, a magnetic recording in which a timing mark is magnetically recorded on a concentric circle on a disk made of a magnetic material, is fixed coaxially to each of the rollers 101 and 102, and the timing mark is detected by a magnetic head. An encoder can also be used. A known tacho generator can also be used. In the present embodiment, the rotational angular velocity can be obtained, for example, by measuring a time interval of pulses continuously output from the rotary encoder and reciprocal thereof. The rotation angle displacement can be obtained by counting the number of pulses continuously output from the rotary encoder.

ここで、「ω₁」は第１ローラ１０１の回転角速度であり、「ω₂」は第２ローラ１０２の回転角速度であり、「Ｖ」はベルト移動速度であり、「Ｒ₁」は第１ローラ１０１のローラ実効半径であり、「Ｒ₂」は第２ローラ１０２のローラ実効半径である。
また、「κ₁」は、第１ローラ１０１のベルト巻付角θ₁、ベルト材質、ベルト層構造等によって決まる第１ローラ１０１のＰＬＤ変動実効係数であり、ＰＬＤがベルト移動速度Ｖに影響する度合いを決定するパラメータである。同様に、「κ₂」は、第２ローラ１０２のＰＬＤ変動実効係数である。ローラ１０１，１０２それぞれの関係式である上記数３及び上記数４において互いに異なるＰＬＤ変動実効係数を設定しているのは、ベルト巻付状態（変形曲率）が異なることや、各ローラに対するベルト巻付量が異なることなどが原因で、ＰＬＤ変動が、ベルト移動速度（ベルト移動量）とローラの回転角速度（回転角変位）との関係に影響する度合いが異なる場合があるためである。なお、これらのＰＬＤ変動実効係数κ₁，κ₂は、一般に、ベルト材質が均一で一層構造のベルトを用い、かつ、ベルト巻付角θ₁，θ₂が十分に大きいとき、いずれも同じ値となる。
また、「ｆ（ｔ）」は、ベルト移動経路上の特定地点を通過するベルト部分のＰＬＤの時間変化を示すベルトが１周する周期と同じ周期をもった周期関数であり、ベルト１周にわたるベルト周方向のＰＬＤの平均値ＰＬＤ_aveからの偏差を示すものである。ここでは、上記特定地点を、第１ローラ１０１に巻き付いた箇所とする。したがって、時間ｔ＝０のとき、第１ローラ１０１に巻き付いたベルト部分のＰＬＤ変動量はｆ（０）となる。なお、ＰＬＤ変動の関数としては、時間関数ｆ（ｔ）ではなく、上述した関数ｆ（ｄ）を用いてもよい。ｆ（ｔ）とｆ（ｄ）は相互に変換することができる。
また、「τ」は、第１ローラ１０１から第２ローラ１０２までベルト１０３が移動するのに要する平均時間であり、以下、「遅れ時間」という。この遅れ時間τは、第１ローラ１０１に巻き付いたベルト部分におけるＰＬＤ変動ｆ（ｔ）と、第２ローラ１０２に巻き付いたベルト部分におけるＰＬＤ変動ｆ（ｔ−τ）との位相差としての意味をもつ。 The relationship between the rotational angular velocities of the first roller 101 and the second roller 102 and the belt moving speed V is represented by the following equations 3 and 4.

Here, “ω ₁ ” is the rotational angular velocity of the first roller 101, “ω ₂ ” is the rotational angular velocity of the second roller 102, “V” is the belt moving speed, and “R ₁ ” is the first angular velocity. “R ₂ ” is the effective roller radius of the roller 101, and “R ₂ ” is the effective roller radius of the second roller 102.
“Κ ₁ ” is a PLD fluctuation effective coefficient of the first roller 101 determined by the belt winding angle θ _{1 of} the first roller 101, the belt material, the belt layer structure, etc., and PLD affects the belt moving speed V. It is a parameter that determines the degree. Similarly, “κ ₂ ” is a PLD fluctuation effective coefficient of the second roller 102. The different PLD fluctuation effective coefficients in the above equations 3 and 4 which are the relational expressions of the rollers 101 and 102 are set because the belt winding state (deformation curvature) is different and the belt winding for each roller is different. This is because the degree of influence of the PLD fluctuation on the relationship between the belt moving speed (belt moving amount) and the rotational angular velocity (rotational angular displacement) of the roller may be different due to different attachment amounts. These PLD fluctuation effective coefficients κ ₁ and κ ₂ are generally the same value when the belt material is uniform and a _single- layer belt is used and the belt winding angles θ ₁ and θ ₂ are sufficiently large. It becomes.
Further, “f (t)” is a periodic function having the same cycle as the cycle in which the belt makes one turn indicating the time change of the PLD of the belt portion passing through a specific point on the belt movement path, and covers one belt turn. shows the deviations from the mean PLD _ave of the belt circumferential direction of the PLD. Here, the specific point is a place wound around the first roller 101. Therefore, when the time t = 0, the PLD fluctuation amount of the belt portion wound around the first roller 101 is f (0). Note that the function f (d) described above may be used instead of the time function f (t) as a function of PLD fluctuation. f (t) and f (d) can be converted into each other.
“Τ” is an average time required for the belt 103 to move from the first roller 101 to the second roller 102, and is hereinafter referred to as “delay time”. The delay time τ has a meaning as a phase difference between the PLD fluctuation f (t) in the belt portion wound around the first roller 101 and the PLD fluctuation f (t−τ) in the belt portion wound around the second roller 102. Have.

Although it is difficult to obtain the average value PLD _ave of the PLD only from the layer structure of the belt and the material and physical properties of each layer, for example, by performing a simple test drive on the belt, the average value of the belt moving speed is obtained. Can be sought. That is, the average value of the belt moving speed when the driving roller is driven at a constant rotational angular velocity is {(radius r of driving roller + PLD _ave ) × constant rotational angular speed ω ₀₁ of the driving roller}. The average value of the belt moving speed when the driving roller is driven at a constant rotational angular speed is obtained from (belt circumference) / (time required for one revolution of the belt). The belt circumference and the time required for one round of the belt can be accurately measured. Therefore, the average value of the belt moving speed when the driving roller is driven at a constant rotational angular speed can be accurately calculated. Further, since the radius r of the driving roller and the constant rotational angular velocity ω ₀₁ of the driving roller can be accurately grasped, PLD _ave can be accurately calculated. The method for calculating PLD _ave is not limited to this.

そして、ローラ実効半径Ｒ₁，Ｒ₂に対し、ＰＬＤ変動ｆ（ｔ）は十分小さいことから、上記数５に示す式を下記数６に示す式に近似することができる。

Since the belt moving speed V at the time t of the belt portion wound around the second roller 102 is the same as the belt moving speed V at the time t of the belt portion wound around the first roller 101, the above equations 3 and 4 are satisfied. From the equation, the following equation (5) can be derived.

Since the PLD fluctuation f (t) is sufficiently small with respect to the roller effective radii R ₁ and R ₂ , the above equation 5 can be approximated to the following equation 6.

In the recognition method 1, the first roller 101 and the second roller 102 are arranged close to each other in the belt circumferential direction. That is, if the first roller 101 and the second roller 102 are arranged close to each other so that the delay time τ becomes sufficiently small, it can be approximated as f (t) = f (t−τ). Note that the condition (allowable range) of the delay time τ for approximation will be described later. When approximated as f (t) = f (t−τ), the formula shown in the above equation 6 becomes the following equation 7.

As can be seen from the equation shown in Equation 7, the rotational angular velocity omega ₂ of the rotational angular velocity omega ₁ and the second roller 102 of the first roller 101 at time t, it can be determined PLD fluctuation f (t). In particular, if the driving control of the belt 103 is performed so that the rotational angular velocity ω ₁ of the first roller 101 is constant, ω ₁ is constant, and only by detecting the rotational angular velocity ω ₂ of the second roller 102, PLD The fluctuation f (t) can be obtained. Further, assuming that there is noise or the like, it is possible to execute correction control for all the fluctuation frequency components included in the obtained PLD fluctuation f (t) through the noise removal filter processing. The error can be accurately controlled within an allowable range up to a frequency at which τ can be ignored due to the relationship between the period of a certain fluctuation frequency component and the delay time τ.

このように、ＰＬＤ変動ｆ（ｔ）の認識感度βは、各ローラ１０１，１０２の回転角速度ω₁，ω₂に関係することなく、各ローラにおけるローラ実効半径（ｒ＋ＰＬＤ_ave）であるＲ₁，Ｒ₂とＰＬＤ変動実効係数であるκ₁，κ₂との比率の差となる。したがって、この差が大きければ大きいほど高まることになる。実際には、ローラ半径ｒはＰＬＤ_aveに比べてかなり大きい値をとるため、認識感度βは、各ローラの半径ｒ₁，ｒ₂とＰＬＤ変動実効係数κ₁，κ₂との比率の差となり、この比率の両ローラ間の差が大きければ大きいほど認識感度βが高まることになる。なお、この認識感度βは、その符号に関係なく、その絶対値が大きいほど、ｆ（ｔ）の認識精度が高まることを示すものであるので、上記比率が異っていれば、２つのローラ１０１，１０２のいずれの径を大きくしても、またいずれのＰＬＤ変動実効係数を大きくしても、かまわない。 Further, as can be seen from the equation (7), the recognition sensitivity β of the PLD fluctuation f (t) is expressed by the following equation (8).

Thus, the recognition sensitivity β of the PLD fluctuation f (t) is not related to the rotational angular velocities ω ₁ and ω ₂ of the rollers 101 and 102, but R ₁ , which is the roller effective radius (r + PLD _ave ) at each roller. This is the difference in the ratio between R ₂ and PLD fluctuation effective coefficients κ ₁ and κ ₂ . Therefore, the larger this difference is, the higher it is. Actually, since the roller radius r is considerably larger than that of PLD _ave , the recognition sensitivity β is a difference in ratio between the radius r ₁ , r _{2 of} each roller and the PLD fluctuation effective coefficient κ ₁ , κ _2. The greater the difference between the two rollers in this ratio, the higher the recognition sensitivity β. This recognition sensitivity β indicates that the recognition accuracy of f (t) increases as the absolute value increases regardless of the sign. Therefore, if the ratio is different, the two rollers It does not matter which of the diameters 101 and 102 is made larger and which PLD fluctuation effective coefficient is made larger.

Here, if the belt winding angles θ ₁ and θ ₂ are decreased in order to adjust the PLD fluctuation effective coefficients κ ₁ and κ ₂ , slippage of the belt 103 or the like is likely to occur in the roller. In this case, the relationship between the belt moving speed and the roller rotation angle becomes unstable. Therefore, it is desirable that the belt winding angles θ ₁ and θ ₂ of the rollers 101 and 102 are sufficiently large. Therefore, when the recognition sensitivity β of the PLD fluctuation f (t) is sufficiently increased, it is better to adjust the roller diameter r than to adjust the PLD fluctuation effective coefficients κ ₁ and κ ₂ of the rollers 101 and 102. Accordingly, the belt wrapping angles θ ₁ and θ ₂ of the rollers 101 and 102 are both sufficiently large so that the PLD fluctuation effective coefficients κ ₁ and κ ₂ have the same value, and are sufficiently recognized. It is preferable to set the roller diameter of each of the rollers 101 and 102 so that the sensitivity β is obtained.
Therefore, in the present embodiment, in order to obtain the PLD fluctuation f (t) with high accuracy, the two rollers 101 and 102 having different diameters are used. Then, the rotational angular velocities ω ₁ and ω ₂ obtained from the output results of the rotary encoders provided on the rollers 101 and 102 over the entire circumference of the belt are substituted into the equation shown in Equation 7 above, and the PLD fluctuation f ( t) is derived. By repeating this and deriving the PLD fluctuations f (t) for a plurality of rounds and averaging the derived PLD fluctuations f (t), the PLD fluctuations f (t) with higher accuracy can be recognized.

In particular, as described above, assuming that the rotational angular velocity ω ₁ of the first roller 101 is a constant rotational angular velocity ω ₀₁ , ω ₁ in the equation shown in Equation 7 becomes a constant, and the equation is expressed in Equation 9 below. It becomes an expression. In this case, the calculation process for obtaining the PLD fluctuation f (t) is simplified. That is, the PLD fluctuation f (t) is obtained from the rotation information detected by the second roller based on the rotation information that the first roller has a constant rotation angular velocity. Specifically, first, drive control of the belt 103 is performed using the output from the rotary encoder of the first roller 101 so that the rotational angular velocity ω ₁ becomes the rotational angular velocity ω ₀₁ . Thereafter, by using the output from the rotary encoder of the second roller 102, the rotational angular velocity ω ₂ is substituted into the following equation 9 to derive the PLD fluctuation f (t). The same applies to the case where the PLD fluctuation f (t) is derived from the output of the rotary encoder of the first roller 101 with the rotational angular velocity ω ₂ of the second roller 102 set to a constant rotational angular velocity ω ₀₂ .

  In particular, if the roller having the constant rotational angular velocity among the two rollers 101 and 102 is a drive roller using a stepping motor or a DC servo motor as a drive source, only the rotary encoder is provided on the other roller. Just do it. That is, in this case, there is an advantage that only one rotary encoder is required. However, on the other hand, the drive roller slips easily from the belt 103 as described above, and if there is a gear or the like in the drive transmission system, the drive transmission error causes the rotational angular velocity of the drive roller. Variations may occur. Thereby, the recognition accuracy of the PLD fluctuation f (t) may be lowered. Therefore, when the PLD fluctuation f (t) is obtained with higher accuracy, the two rollers 101 and 102 are preferably driven rollers.

Next, the condition (allowable range) of the delay time τ will be described.
The delay time τ is determined by the belt circumferential distance between the two rollers 101 and 102 (hereinafter referred to as “roller distance”) and the average value of the belt moving speed. In many cases, the average value of the belt moving speed cannot be easily changed depending on the specifications of the product in which the belt device is installed and the relationship with other devices mounted on the product. Therefore, here, how to set the distance between the rollers will be described.

  When f (t) = f (t−τ) is approximated as in this recognition method 1, an error occurs between the PLD fluctuation f (t) derived by this recognition method 1 and the actual PLD fluctuation. If the fluctuation of the belt moving speed of the belt 103 and the deviation of the belt moving position caused by this error are within the allowable range, there is no practical problem.

The n-th harmonic component f _n (t) of the PLD fluctuation f (t) can be expressed by the following equation (10). In this equation, “ΔBn” is the amplitude of the nth harmonic component, “ω _n ” is the angular frequency of the nth harmonic component, and “α _n ” is the phase of the nth harmonic component. is there.

ここで、第２ローラ１０２の回転角速度ω₂の変動成分（上記数１１の式中の右辺第２項）をΔω₂とすると、この変動成分Δω₂は、上記数１１の式中の右辺第２項の大かっこ内を計算することにより、下記の数１２に示す式となる。

ただし、上記数１２の式中の「Ｋ」は、下記の数１３に示すものであり、上記数１２の式中の「Ｐ」は、下記の数１４に示すものである。

When such an nth harmonic component f _n (t) is present in the PLD fluctuation f (t), the belt drive control is performed when the first roller 101 is rotated at the constant angular velocity ω ₀₁ . The rotational angular velocity ω ₂ of the two rollers 102 is expressed by the following formula 11 from the formula shown in the above formula 6.

Here, if the fluctuation component of the rotational angular velocity ω ₂ of the second roller 102 (the second term on the right side in the equation 11) is Δω ₂ , the fluctuation component Δω ₂ is the first value on the right side in the equation 11 above. By calculating within the brackets of the two terms, the following equation 12 is obtained.

However, “K” in the equation (12) is shown in the following equation (13), and “P” in the equation (12) is shown in the following equation (14).

つまり、近似した第ｎ次高調波成分ｆ_n'（ｔ）は、上記数１２に示した式より、下記の数１６に示す式とすることができる。

In this recognition method 1, since it approximates to f (t) = f (t−τ), f _n (t) = f _n (t−) is also applied to the n-th harmonic component f _n (t). τ). Assuming that the n-th harmonic component when approximated in this way is f _n ′ (t), the fluctuation component Δω ₂ is represented by the following equation (15) from the equation (9).

That is, the approximated nth-order harmonic component f _n ′ (t) can be expressed by the following equation (16) from the equation (12).

第１ローラ１０１の目標回転角速度ω_1cのＰＬＤ変動ｆ（ｔ）を補正する成分をΔω_1cとし、これに着目して上記数１７の式を変形すると、下記の数１８に示す式が得られる。

On the other hand, using the PLD fluctuation f (t) obtained by the recognition method 1, the target rotational angular velocity ω _1c for controlling the rotational angular velocity ω ₁ of the first roller 101 so as to keep the belt moving speed constant is derived. The target rotational angular velocity ω _1c is expressed by the following equation (17). Note that “ω _1a ” in this equation is the target average rotational angular velocity of the first roller 101. When there is no PLD fluctuation and the belt moving speed is a constant speed V ₀ , V ₀ = R ₁ × ω _1a .

When the component for correcting the PLD fluctuation f (t) of the target rotational angular velocity ω _1c of the first roller 101 is Δω _1c , paying attention to this, the above equation 17 is transformed, and the following equation 18 is obtained. .

この数１９の式に、上記数１０に示した式の第ｎ次高調波成分ｆ_n（ｔ）及び上記数１６に示した式の近似した第ｎ次高調波成分ｆ_n'（ｔ）を代入して、変形すると、下記の数２０が得られる。

ただし、上記数２０の式中の「Ｅ」は、下記の数２１に示すものであり、この数２１の式中の「Ａ」は、下記の数２２に示すものである。また、上記数２０の式中の「Ｃ」は、下記の数２３に示すものであり、初期位相を表す定数である。

Here, the nth-order harmonic component f _n (t) of the PLD fluctuation f (t) in the equation shown in Equation 18 above is originally shown in Equation 10 above. The approximated nth-order harmonic component f _n ′ (t) obtained from the equation (16). The error component Δω _{1c_err} of the control target value at this time is as shown in the following _Expression 19.

In the equation (19), the n-th harmonic component f _n (t) in the equation (10) and the approximated n-th harmonic component f _n ′ (t) in the equation (16) are obtained. Substituting and transforming gives the following equation (20).

However, “E” in the equation (20) is shown in the following equation (21), and “A” in the equation (21) is shown in the following equation (22). Further, “C” in the formula 20 is the constant shown in the following formula 23 and representing the initial phase.

Then, if the equation shown in Equation 20 is converted into an error V _{1c_err} of the belt moving speed, the following Equation 24 is obtained.

Thus, in this recognition method 1, the error V _{1c_err} occurs in the belt moving speed due to the delay time τ determined by the distance between the rollers. Therefore, even if it is attempted to suppress the belt movement speed fluctuation due to the PLD fluctuation by the recognition method 1, some belt movement speed fluctuation remains. In general, the belt movement speed fluctuation generated in the belt 103 is caused not only by the PLD fluctuation but also by the eccentricity of gears and the accumulated pitch error in the drive transmission system. Therefore, the permissible range of the belt movement speed variation due to the PLD variation is an allowable range assigned to the PLD variation in design. Here, in the drive control of the intermediate transfer belt 10 in the copying machine of the present embodiment, as described above, color misregistration and banding occur due to fluctuations in the belt moving speed. Such color misalignment and banding are caused by the actual belt moving position deviating from the target belt moving position due to fluctuations in the belt moving speed. Getting worse. The color misregistration and banding are perceived by humans who have seen the image on the sheet, and the allowable range for suppressing the level to practically no problem is, for example, the banding change interval (for banding) ( It can be defined by a spatial frequency fs indicating (distance). Since this spatial frequency fs has a fixed relationship {f = F × fs (F: constant)} with the temporal frequency f, it seems to be within the allowable range of the spatial frequency fs determined as the allowable range of banding. In addition, an allowable range of the deviation amount of the belt moving position can be defined. As a result, an allowable range of fluctuations in the belt moving speed can be defined.

ここで、例えば、バンディングが人間に知覚されないような許容範囲を求める場合、ＰＬＤ変動ｆ（ｔ）がもつ周波数成分ごとに、ベルト移動位置のズレ量Ｘ_errTを、ＰＬＤ変動ｆ（ｔ）によるベルト移動速度の変動について割付けられた下記の数２６の式で示す許容位置ズレ量Ｘ_err以下となるようにする。したがって、上記数２５に示した式の各周波数成分の最大値（振幅値）がその許容位置ズレ量Ｘ_err以下となるように、遅れ時間τの値、第１ローラ１０１及び第２ローラ１０２の径、ＰＬＤ変動実効係数κに関係する巻付角などを決定する。なお、複数の感光体ドラム上のそれぞれに形成された各色のトナー像を重ね合わせるとき、上記数２５に示した式のようなベルト移動位置のズレ量Ｘ_errTが発生すると、色ズレも生じる。この色ズレからの制約によっても、各周波数成分の許容位置ズレ量Ｘ_errが決定される。

The amount X _errT of the belt movement position generated by approximation as in the present recognition method 1 is the above-described _equation 24 indicating the belt movement speed error V _{1c_err} due to the use of the _nth harmonic component f _n ′ (t). Is integrated with the first to nth frequency components, and the following equation 25 is obtained. In this equation, “i” indicates the order of the frequency component present in the PLD fluctuation f (t).

Here, for example, when _obtaining an allowable range in which banding is not perceived by humans, the belt movement position deviation amount X _errT is calculated for each frequency component of the PLD fluctuation f (t) by the belt according to the PLD fluctuation f (t). The allowable positional deviation amount X _err shown by the following expression 26 assigned to the fluctuation of the moving speed is set to be equal to or less. Therefore, the value of the delay time τ and the values of the first roller 101 and the second roller 102 are set so that the maximum value (amplitude value) of each frequency component of the equation shown in the above equation 25 is equal to or less than the allowable positional deviation amount _Xerr . The diameter, the winding angle related to the PLD fluctuation effective coefficient κ, and the like are determined. It should be noted that when the toner images of the respective colors formed on the plurality of photosensitive drums are superposed, if a shift amount X _errT of the belt moving position as expressed by the equation 25 is generated, a color shift also occurs. The allowable positional deviation amount _{Xerr of} each frequency component is also determined by the restriction from the color deviation.

As a specific example, the radius ratio between the first roller 101 and the second roller 102 is 2, the diameters are φ30 and φ15, and the PLD fluctuation effective coefficients κ ₁ and κ ₂ of these rollers are 0.5. . Further, the circumference of the belt 103 is set to 1000 mm which is generally used as the intermediate transfer belt 10 of the tandem type image forming apparatus such as the copying machine of the present embodiment. And the influence about only the primary component of a PLD fluctuation frequency component was calculated | required.
FIG. 3 shows an ideal control when the approximation is not performed and the control numerical value obtained when the approximation obtained from the formula 25 is performed by changing the distance between rollers corresponding to the delay time τ. It is the graph which showed the error rate which is a ratio with respect to the ideal control numerical value with the difference with a numerical value. For example, when the error rate is 0%, the control is ideally performed, and when the error rate is 100%, the control effect is not expected as in the case where the control is not performed. From this graph, it can be seen that when the distance between the rollers is set to 50 [mm] or less, the error rate is about 50%, and the control effect of about half the influence on the speed fluctuation due to the PLD fluctuation can be obtained.

[Method for recognizing PLD fluctuation 2]
As described above, in the recognition method 1, since the control error increases as the distance between the rollers increases, it is necessary to reduce the distance between the rollers. As a result, the degree of freedom in device layout is reduced. Therefore, in the present recognition method 2, a method for obtaining the PLD fluctuation f (t) with high accuracy from the rotational angular velocities ω ₁ and ω _{2 of the} two rollers 101 and 102 without depending on the distance between the rollers will be described. In the following example, the case where the diameters of these rollers 101 and 102 are larger in the second roller 102 than in the first roller 101 is taken as an example, but the same principle can be used in the reverse case. Strictly speaking, when the value obtained by dividing the roller effective radius R by the PLD fluctuation effective coefficient κ is compared as described below, the roller 102 is larger than the roller 101.

このようにｆ（ｔ）の係数が１となるように規格化された上記数２７の式の右辺をｇｆ（ｔ）と定義すると、下記の数２８に示す式が得られる。ただし、この数２８の式中の「Ｇ」は、下記の数２９に示すものである。

各ローラ１０１，１０２間におけるローラ実効半径ＲとＰＬＤ変動実効係数κとの関係から、Ｇは１より小さい値をとる。また、上記数２７の式からわかるように、ｇｆ（ｔ）は、ローラ実効半径Ｒ₁，Ｒ₂及びＰＬＤ変動実効係数κ₁，κ₂を用い、各ローラ１０１，１０２の回転角速度ω₁，ω₂から得られるものである。このｇｆ（ｔ）からＰＬＤ変動ｆ（ｔ）を求める。 The relationship between the rotational angular velocities ω ₁ and ω ₂ between the first roller 101 and the second roller 102 is expressed by the formula shown in the above formula 6, and when this formula is modified, the formula shown in the following formula 27 is obtained.

When the right side of the equation (27) normalized so that the coefficient of f (t) is 1 is defined as gf (t), the following equation (28) is obtained. However, “G” in the equation 28 is as shown in the following equation 29.

From the relationship between the roller effective radius R and the PLD fluctuation effective coefficient κ between the rollers 101 and 102, G takes a value smaller than 1. Further, as can be seen from the equation (27), gf (t) uses the roller effective radii R ₁ and R ₂ and the PLD fluctuation effective coefficients κ ₁ and κ _2, and the rotational angular velocities ω ₁ , It is obtained from ω ₂ . The PLD fluctuation f (t) is obtained from this gf (t).

  FIG. 4 is a control block diagram for explaining the recognition method 2. In this figure, F (s) obtained by Laplace transform of f (t), which is a time function, is used, and “s” in the figure is a Laplace operator. F (s) = L {f (t)} (where L {x} represents the Laplace transform of x). Also, in FIG. 4, the 0th stage shown at the top of the figure represents the formula shown in the above equation 28 for convenience, and the first and subsequent stages surrounded by a broken line in the figure are the filter sections. It is.

このとき、Ｇ²はＧよりも十分に小さいので（Ｇ＞＞Ｇ²）、ｈ（ｔ）は、上記ｇｆ（ｔ）よりもＰＬＤ変動ｆ（ｔ）に近いものとなる。このときの誤差ε₁は、下記の数３１に示す式のようになる。

また、第２段目の出力Ｉ（ｓ）の時間関数ｉ（ｔ）は、下記の数３２に示すようになる。

このとき、Ｇ⁴はＧ²よりも十分に小さいので（Ｇ²＞＞Ｇ⁴）、ｉ（ｔ）は、上記ｈ（ｔ）よりも更にＰＬＤ変動ｆ（ｔ）に近いものとなる。このときの誤差ε₂は、下記の数３３に示す式のようになる。

さらに、第３段目の出力Ｊ（ｓ）の時間関数ｊ（ｔ）は、下記の数３４に示すようになる。

このとき、Ｇ⁸はＧ⁴よりも十分に小さいので（Ｇ⁴＞＞Ｇ⁸）、ｊ（ｔ）は、上記ｉ（ｔ）よりも更にＰＬＤ変動ｆ（ｔ）に近いものとなる。このときの誤差ε₃は、下記の数３５に示す式のようになる。

When gF (s), that is, the left side of the equation (27) (data obtained from the detected rotational angular velocities ω ₁ and ω ₂ ) is input to this filter unit, the time of the first stage output H (s) Function h (t), that is, L ⁻¹ {H (s)} (where L ⁻¹ {y} represents the inverse Laplace transform of y. The same applies to I (s) and J (s). .) Is as shown in Equation 30 below.

At this time, since G ² is sufficiently smaller than G (G >> G ² ), h (t) is closer to the PLD fluctuation f (t) than gf (t). The error ε _{1 at} this time is expressed by the following equation (31).

Further, the time function i (t) of the output I (s) at the second stage is as shown in the following equation (32).

At this time, since G ⁴ is sufficiently smaller than G ² (G ² >> G ⁴ ), i (t) is closer to the PLD fluctuation f (t) than h (t). The error ε _{2 at} this time is expressed by the following equation 33.

Further, the time function j (t) of the output J (s) at the third stage is as shown in the following Expression 34.

At this time, since G ⁸ is sufficiently smaller than G ⁴ (G ⁴ >> G ⁸ ), j (t) is closer to the PLD fluctuation f (t) than i (t). The error ε _{3 at} this time is expressed by the following equation (35).

According to the following sequence that generalizes the above results, the PLD fluctuation f (t) can be obtained using the data on the left side of the equation shown in the above equation 27, which is data obtained from the detected rotational angular velocities ω ₁ and ω _2. For example, the PLD fluctuation f (t) can be obtained with high accuracy from the detected rotational angular velocities ω ₁ and ω ₂ without depending on the distance between the rollers.
(First step)
A value g ₁ (t) obtained by adding gf (t) and data delayed by the delay time τ by multiplying gf (t) by G is obtained.
(Second step)
g ₁ (t) is multiplied by G ² and the delay time τ is doubled to obtain a value obtained by adding the data delayed by time 2τ and g ₁ (t) to obtain g ₂ (t).
(Third step)
g ₂ (t) to obtain the G ⁴ times to the delay time τ of 4 times the delayed time 4τ data and g ₂ (t) the value obtained by adding the g ₃ (t).
・
・
・
(Nth step)
those g _n-1 (t) is 2 ^n-1 th power of G, adds the data obtained by delaying the delay time τ 2 ^n-1 times the time, and g _n-1 (t) The obtained value g _n (t) is obtained.

For the n-th stage in the filter section shown in FIG. 4, the delay element for the input data (or signal) that is the output data of the previous stage is 2 ^n-1 times the delay time τ, and the gain element is the above-mentioned It operates to add the input data (or signal) to the data (or signal) obtained as a value obtained by raising G to the 2 ^n-1 power. Then, the output data g _n (t) at the final stage is obtained as the PLD fluctuation f (t). Note that the greater the number of steps n, the higher the recognition accuracy of the PLD fluctuation f (t).

FIG. 5 is a control block diagram obtained by Z-transforming the control block diagram of FIG. In FIG. 5, gf (n) is expressed as gf _n, and f (n) is expressed as f _n.
The sampling time of the input data input to the filter unit (FIR filter) shown in FIG. 5 is Ts, the delay time τ is M × Ts (M is a natural number), and the time Tb required for the belt 103 to make one revolution. Is N × Ts (N is a natural number). In this case, the number of samplings during one revolution of the belt 103 is N. The PLD fluctuation f (t) obtained according to the control block diagram shown in FIG. 5 is composed of a data string of N PLD fluctuation values f (n) obtained every sampling time Ts. Since the process in the filter unit at this time is a digital process, the filter process can be executed using a DSP (Digital Signal Processor), a μCPU, or the like.

  Further, the FIR filter shown in FIG. 5 can be converted into an IIR filter. When the control block diagram of FIG. 5 is expressed by a continuous system, it becomes as shown in FIG. 6A, and when this is expressed discretely for digital processing, it becomes as shown in FIG. 6B.

As described above, the rotational angular velocities ω ₁ and ω ₂ of the _two rollers 101 and 102 rotate under the influence of PLD fluctuations f (t) and f (t−τ) having different phases. Since the effective radius R of the roller and / or the PLD fluctuation effective coefficient κ are different from each other, the proportion of the PLD fluctuation component in the roller effective radius is different. Therefore, the magnitudes of rotational angular velocity fluctuations due to detected PLD fluctuations are different from each other. The present inventors pay attention to this point and can derive the PLD fluctuation f (t) with high accuracy without depending on the frequency characteristics by using the above-described FIR filter, IIR filter, and algorithm processing similar to these filters. I found. Here, in order to derive the PLD fluctuation f (t), normalization is performed so that the coefficient of f (t) becomes 1. However, when G becomes larger than 1, the PLD fluctuation f (t−τ) is obtained. May be normalized so that the PLD fluctuation f (t−τ) is derived by the same algorithm processing. At this time, the coefficient on the PLD fluctuation f (t) side is the reciprocal of G. That is, t ′ = t−τ, τ ′ = Tb−τ (Tb is the time for one round of the belt), and if the left side of Equation 27 is multiplied by (−1 / G), the right side is expressed as f (t ′ ) − (1 / G) f (t′−τ ′), the PLD fluctuation can be detected using the FIR filter or the IIR filter in the same manner as described above.

[Method for recognizing PLD fluctuation 3]
As described above, in the recognition method 2, since there is no restriction on the arrangement of the rollers, the degree of freedom in apparatus layout is increased. However, until the recognition error of the PLD fluctuation f (t) reaches ε ₃ shown in Equation 35, the calculation processing time up to the third step described above is required. For example, in the process of the first step, since the data delayed by the delay time τ, that is, the data of the past τ time is used, the time function of the output of the first step becomes h (t) shown in the above equation 30. τ time is required. Further, in order for the time function of the output to become i (t) shown in the above equation 32 in the processing of the second step, 2τ time (3τ time in total with the first step) is required. Similarly, in order for the output time function to become j (t) shown in the above equation 34 in the process of the third step, 4τ hours (7τ time in total from the first step) are required. Thus, in order to reduce the error with high accuracy in recognition of the PLD fluctuation f (t) in the recognition method 2 described above, many steps are required and a lot of processing time is required. Therefore, in the present recognition method 3, the ratio of the belt conveyance section (distance) between the rollers and the entire belt conveyance section (circumferential length) is 1: 2 Nb (Nb: natural number) in the above two roller arrangements. to, a method of calculating the rotational angular velocity omega ₁ of the two rollers 101 and 102, PLD fluctuation f in a short time from omega ₂ (t) to a high precision.

  In this recognition method 3, the two roller arrangements are set so that the ratio of the belt conveyance section (distance) between the rollers and the entire belt conveyance section (circumferential length) has a relationship of 1: 2 Nb (Nb: natural number). . That is, when Nb = 1, the ratio of the conveyance sections is 1: 2, and therefore, the two roller arrangements are in a positional relationship that is farthest from each other in the belt conveyance path. If the entire belt circumference is 1000 [mm], the belt conveyance section (distance) between the two rollers is 500 [mm]. Similarly, when Nb = 2, the belt conveyance section (distance) between the two rollers is 250 [mm]. By adding conditions to the layout of the roller arrangement in this way, accurate belt PLD fluctuation f (t) can be obtained in a shorter time by the same arithmetic processing as the arithmetic block diagrams of FIG. 4 and FIG. Can be requested.

Hereinafter, the process of the recognition method 3 will be described.
First, the case of Nb = 1 will be described. In this case, the first roller 101 and the second roller 102 are installed at the farthest positions on the belt conveyance path. Then, gf (t) shown in the above equation 28 is obtained from the respective rotational angular velocities ω ₁ and ω ₂ . This gf (t) is calculated by the same process as the FIR filter process (non-feedback type process) shown in FIGS. 4 and 5 described in the recognition method 2 to calculate the PLD fluctuation f (t). However, the required arithmetic processing steps are up to Nb steps. That is, when Nb = 1, the process is up to the first step, and thus the process is up to the process of calculating H (s) or h _n up to the first stage of the FIR filter of FIG. 4 or FIG. This processing result is shown in the above equation 30 as described in the recognition method 2 above. Here, if the rotation angle of the belt is 2π [rad], the positional relationship between the two rollers is π [rad]. The τ time indicates the belt conveyance time between the two rollers when the belt is conveyed at a predetermined specified speed. Therefore, 2τ time is 2π [rad] when converted to the belt rotation angle. Since the PLD fluctuation f (t) is a periodic function that repeats every rotation of the belt, f (t−2τ) included in the second term on the right side in the equation shown in Equation 30 may be f (t). it can. Therefore, in the present recognition method 3, when Nb = 1, the above equation 30 can be transformed into the following equation 36.

Therefore, the PLD fluctuation f (t) can be obtained without error by dividing the output data h (t) of the first stage of the FIR filter by (1-G ² ). The time required to execute this calculation process is τ time because data of τ time past is used.
As described above, according to the present recognition method 3, when Nb = 1, it is possible to obtain the PLD fluctuation f (t) with high accuracy without a recognition error in the processing time of τ time as in the recognition method 2.

Similarly, in the case of Nb = 2, becomes because the processing up to the second step, until the processing for calculating the I (s) or I _n up to the second-stage FIR filter of FIG. 4 or FIG. 5. This processing result is shown in the above equation 32 as described in the recognition method 2 above. Here, 4τ time is 2π [rad] when converted to the belt rotation angle. Therefore, f (t−4τ) included in the second term on the right side in the equation shown in the above equation 32 can be f (t), and the equation shown in the above equation 32 can be expressed by the following equation 37. It can be deformed.

Therefore, by dividing the second-stage output data i (t) of the FIR filter by (1-G ⁴ ), the PLD fluctuation f (t) can be obtained without error. The time required to execute this calculation process is 3τ time. Thus, according to the present recognition method 3, when Nb = 2, it is possible to obtain the PLD fluctuation f (t) with high accuracy without a recognition error in the processing time of 3τ time as in the recognition method 2.

  As described above, in the present recognition method 3, the above-described two roller arrangements have a relationship in which the ratio of the belt conveyance section (distance) between the rollers and the total belt conveyance section (circumferential length) is 1: 2 Nb (Nb: natural number). By setting so as to be, the PLD fluctuation f (t) can be obtained with high accuracy from the data after the Nb step of the FIR filter processing of the recognition method 2 without any recognition error. Further, since the FIR filter processing is completed in the Nb-th step as compared with the recognition method 2, the PLD fluctuation f (t) can be derived in a shorter time.

Next, specific belt drive control for suppressing fluctuations in the belt moving speed due to PLD fluctuations using the PLD fluctuations f (t) obtained by the recognition method 1, the recognition method 2 or the recognition method 3 will be described. .
For specific belt drive control using the PLD fluctuation f (t), a plurality of control methods are conceivable depending on the apparatus configuration. Here, a control example (belt drive control example 1) for a device configuration having a mechanism for detecting the home position of the belt 103 and a control example (belt drive control example 2) for a device configuration without such a mechanism. Take two examples.

[Belt drive control example 1]
In order to perform appropriate belt drive control according to the PLD fluctuation using the PLD fluctuation f (t), it is necessary to grasp the phase of the PLD fluctuation on the belt 103 (phase when the belt circumference is 2π). There is. As a method of grasping this phase, first, as in this belt drive control example 1, the home position mark of the belt 103 is determined in advance and detected, and time measurement information by a timer, drive motor rotation angle information, There is a method for grasping this phase by using any one of the rotation angle information by the rotary encoder output.
FIG. 7 is a schematic diagram showing an apparatus configuration for detecting the home position mark of the belt 103 in this belt drive control example 1. As shown in FIG. In the present control example 1, the home position mark 103a is provided on the belt 103, and this is detected by the mark detection sensor 104 as a mark detection means, thereby grasping the phase that is the reference for one round of the belt. In this example, a metal film affixed to a predetermined position on the belt 103 is used as the home position mark 103a, and a reflective photosensor provided on a fixed member is used as the mark detection sensor 104. The mark detection sensor 104 outputs a pulse signal when the home position mark 103a passes the detection area. The position where the home position mark 103a is provided is the belt inner peripheral surface or the belt width direction end of the belt outer peripheral surface so as not to affect image formation. An image forming substance such as toner or ink may adhere to the home position mark 103 a or the sensor surface of the mark detection sensor 104. In this case, the home position of the belt 103 may be erroneously recognized. Therefore, in order to eliminate such erroneous recognition, it is desirable to add a function for accurately detecting the belt home position while managing the sensor output amplitude, pulse width, and pulse interval to the mark detection sensor 104. . Although at least one home position mark 103a is required, a plurality of home position marks 103a may be provided and patterned so as to easily eliminate erroneous recognition.

FIG. 8 is an explanatory diagram for explaining a control operation of the first belt drive control example. In the illustrated example, the position of the mark detection sensor 104 is different from the position shown in FIG. 3 for convenience of explanation.
The rotational driving force generated by the driving motor 106 is transmitted to the driving roller 105 through a speed reduction mechanism including a driving gear 106a and a driven gear 105a. As a result, the driving roller 105 rotates and the belt 103 moves in the direction of arrow A in the figure. As the belt 103 moves, the first roller 101 and the second roller 102 rotate together. These rollers 101 and 102 are provided with rotary encoders 101a and 102a, respectively, and output signals thereof are input to the angular velocity detection units 111 and 112 of the digital signal processing unit. This rotary encoder may be connected via a speed reducer such as a gear. The first roller 101 and the second roller 102 are subjected to surface treatment so that no slip occurs between the inner peripheral surface of the belt 103 and the belt winding angle is set. In this example, the diameter of the second roller 102 is larger than that of the first roller 101. The motor control signal calculated and output by the digital signal processing unit is input to the servo amplifier 117 via the DA converter 116, and the servo amplifier 117 drives the drive motor 106 according to the control signal.

In the digital signal processor, the first angular velocity detector 111 detects the rotational angular velocity ω ₁ of the first roller 101 from the output signal of the first rotary encoder 101a. Similarly, the second angular velocity detector 112 detects the rotational angular velocity ω ₂ of the second roller 102 from the output signal of the second rotary encoder 102a. The controller 110 calculates a control target value ω _ref1 according to the PLD fluctuation data of the belt 103 in accordance with a target belt speed command from the copying machine main body. Specifically, first, the belt 103 is driven so that the rotational angular velocity ω ₁ of the first roller 101 is maintained at the command control target value ω _ref1 based on the target belt speed command from the copying machine main body. That is, the belt 103 is driven so that the rotational angular velocity ω ₁ of the first roller 101 is constant. Therefore, the command control target value ω _{ref1 at} this time is the above-described constant rotational angular velocity ω ₀₁ . When the rotational angular velocity ω ₁ of the first roller 101 becomes constant, the rotational angular velocity of the second roller 102 is detected by the recognition method 1, the recognition method 2 or the recognition method 3 with reference to the pulse signal from the mark detection sensor 104. Data of PLD fluctuation f (t) is acquired from ω ₂ . Then, an appropriate correction control target value ω _ref1 according to the data of the PLD fluctuation f (t) is generated and output.

The correction control target value ω _ref1 output from the controller 110 in this way is compared with the rotational angular velocity ω ₁ of the first roller 101 by the comparator 113, and the deviation is output from the comparator 113. This deviation is input to the gain (K) 114 and the phase compensator 115, and a motor control signal is output from the phase compensator 115. The deviation input to the gain (K) 114 is a deviation between the control target value ω _ref1 obtained by correcting the PLD fluctuation of the belt 103 and the detected rotational angular velocity ω ₁ of the first roller 101. In this embodiment, this deviation is caused by a slip between the driving roller 105 and the belt 103, a drive transmission error due to the eccentricity of the driving gear 106a and the driven gear 105a, a belt moving speed fluctuation due to the eccentricity of the driving roller 105, and the like. . This deviation is reduced by the motor control signal, and the drive motor 106 is driven so that the belt 103 moves at a constant speed. For this purpose, for example, a PID controller is used to adjust the motor control signal so that the belt 103 to be controlled has less deviation from the target speed and is stable without overshoot and oscillation. The

In order to maintain the belt moving speed V at a constant speed V ₀ , the rotational angular speed ω ₁ of the first roller 101 may be controlled to be expressed by the following equation (38). If the rotational angular velocity ω ₂ of the second roller 102 is controlled, the control is performed so that the following equation 39 is obtained.

In this belt drive control example 1, even if the belt 103 has a PLD fluctuation in the belt circumferential direction, as described above, the correction control in which the rotational angular velocity ω ₁ of the first roller 101 is corrected by the PLD fluctuation f (t). Control is performed to achieve the target value ω _ref1 . Therefore, fluctuations in the belt moving speed due to PLD fluctuations can be suppressed.

[Belt drive control example 2]
Next, a belt drive control example 2 in which the mechanism for detecting the home position as shown in FIG. 7 is eliminated and the cost is reduced will be described.
The basic process is the same as in the belt drive control example 1 described above, but in this belt drive control example 2, instead of the pulse signal of the mark detection sensor 104, the home position of the belt 103 is virtually specified. The home position of the belt 103 is grasped using the virtual home position signal. For example, using the cumulative rotation angle of the rollers obtained by the rotary encoders 101a and 102a as the virtual home position signal, it is predicted that the belt 103 has made one round from an arbitrary position. In this case, since the accumulated rotation angle when the roller rotates while the belt 103 makes one revolution can be grasped in advance, it can be predicted that the belt 103 has made one revolution from the accumulated rotation angle. At this time, the time at which the counting of the cumulative rotation angle is started is t = 0 of the PLD fluctuation f (t). This time corresponds to the time when a pulse signal is received from the mark detection sensor in the belt drive control example 1.

The virtual home position signal is set to be generated every rotation period of the belt 103. Various setting methods can be considered in addition to the cumulative rotation angle of the roller described above. For example, it is predicted that the belt 103 has made one revolution from an arbitrary position using the cumulative rotation angle of the drive motor 106, and a virtual home position signal is generated when the cumulative rotation angle corresponding to one revolution of the belt is reached. The method of setting to can be considered. In addition, if the belt 103 moves at a predetermined average moving speed, the time required to make one round of the belt is predicted from the average moving speed, and when the time corresponding to one round of the belt is reached, A method of setting to generate a virtual home position signal is conceivable.
In this belt drive control example 2, the prediction that the belt 103 has made one revolution is actual due to PLDave, which is the average PLD value of the belt, the accuracy of parts such as the roller diameter, environmental changes, aging of parts, etc. Error occurs.

この式に、上記数３８に示した式を代入して変形すると、下記の数４１に示す式となる。

このときの第２ローラ１０２の回転角速度ω_2dは、下記の数４２に示すとおりである。

そして、この式に、上記数４１に示した式を代入して変形すると、下記の数４３に示す式となる。

したがって、仮想ホームポジション信号から得られる仮想ホームポジションが実際のホームポジションと時間ｄだけズレていることによる、第２ローラ１０２の回転角速度のズレ量ω_2δは、下記の数４４に示す式のとおりである。第２ローラの回転角速度のズレ量ω_2δは、第２ローラの回転角速度検出データω_2dと第２ローラのあるべき基準データω_ref2との差として求められる。

この式に、上記数４０に示した式及び上記数４３に示した式を代入して変形すると、下記の数４５に示す式が得られる。

If there is an error between the belt revolution estimated by the virtual home position signal and the actual belt revolution, the phase of the PLD fluctuation f (t) is cumulatively shifted. For this reason, if the belt drive control described above is performed based on the data of the PLD fluctuation f (t), the fluctuation of the belt moving speed occurs and becomes large.
This point will be described in detail. Even when the PLD fluctuation f (t) is obtained based on the virtual home position signal, when the target rotational angular velocity of the first roller 101 is controlled by ω _ref1 shown in the above equation 38, The rotational angular velocity ω ₂ detected by the second roller 102 must be ω _ref2 shown in the equation 39 above. Here, if the virtual home position obtained from the virtual home position signal is shifted from the actual home position by a time d, the belt moving speed V _{d at} this time is expressed by the following equation (40).

Substituting the equation shown in Equation 38 above into this equation and transforming it yields the equation shown in Equation 41 below.

The rotational angular velocity ω _2d of the second roller 102 at this time is as shown in the following _equation (42).

Then, by substituting the equation shown in Equation 41 into this equation and transforming it, the following Equation 43 is obtained.

Accordingly, the deviation ω _2δ of the rotational angular velocity of the second roller 102 due to the deviation of the virtual home position obtained from the virtual home position signal by the time d from the actual home position is as shown in the following equation 44. It is. The amount of deviation ω _2δ of the rotational angular velocity of the second roller is obtained as a difference between the rotational angular velocity detection data ω _2d of the second roller and the reference data ω _ref2 that should be in the second roller.

By substituting the equation shown in the above equation 40 and the equation shown in the above equation 43 into this equation and modifying it, the following equation 45 is obtained.

The deviation amount ω _2δ expressed by the equation shown in the above formula 45 is a fluctuation component (first term) generated when the virtual home position is shifted from the actual home position by the time d in the first roller 101, and the second Similarly, it can be seen that the roller 102 is also the result of superimposing the fluctuation component (second term) generated when the virtual home position is shifted from the actual home position by the time d.
When the absolute value of the deviation amount ω _2δ exceeds a certain value, or when the average of the absolute value of the deviation amount ω _2δ in one round of the belt, or the square root of the square average exceeds a certain value. Then, the currently recognized PLD fluctuation f (t) is corrected. This correction is a state where the control was the rotational angular velocity omega ₁ of the first roller 101 at a constant rotational angular velocity omega ₀₁ detects the rotational angular velocity omega ₂ of the second roller 102, thereby obtaining a new PLD variation f (t) Then, using this data of f (t), control is performed so that the rotational angular velocity ω ₁ of the first roller 101 matches the reference rotational angular velocity ω _ref1 .

[Update of PLD fluctuation]
Next, a process for updating the PLD fluctuation f (t) obtained once will be described.
Depending on the belt material, the belt thickness changes due to changes in the environment (temperature and humidity) and wear due to use over time, or the Young's modulus changes due to repeated bending and stretching, so that the PLD of the belt 103 changes over time. The PLD fluctuation of the belt 103 may change. Further, when the belt 103 is replaced, the PLD variation may change from the PLD variation before the replacement. Further, as described in the belt drive control example 2 above, the virtual home position may deviate from the actual home position. In such a case, it is necessary to update the PLD fluctuation f (t).

  Regarding the method of updating the PLD fluctuation f (t), there are roughly two methods, that is, a method of updating intermittently and a method of updating continuously. As the former method, there is a method of monitoring whether the belt drive control based on the PLD fluctuation f (t) is appropriately performed and updating the PLD fluctuation f (t) only when it is determined that the belt driving control is not properly performed. . Further, there is a method of periodically updating the PLD fluctuation f (t) without performing such monitoring. As the latter method, there is a method in which the PLD fluctuation f (t) is always obtained and the PLD fluctuation f (t) is continuously updated.

これは、上記数４５に示した式と同様に、第１ローラ１０１においてＰＬＤ変動ｆ（ｔ）がｇ（ｔ）へ変化したことによって発生する変動成分（第１項）と、第２ローラ１０２においてＰＬＤ変動ｆ（ｔ）がｇ（ｔ）へ変化したことによって発生する変動成分（第２項）とが重畳した結果であると言える。したがって、以下に示すＰＬＤ変動ｆ（ｔ）がｇ（ｔ）へ変化したときの更新方法は、上記ベルト駆動制御例２のように仮想ホームポジションがズレることによる誤差も含めて、補正することができる。 Here, the principle of updating the PLD fluctuation f (t) once obtained will be described.
If the PLD fluctuation f (t) is obtained accurately once, the rotational angular velocity ω ₁ of the first roller 101 is maintained at ω _ref1 expressed by the above equation (38). Here, when the actual PLD fluctuation changes from f (t) to g (t), the change ω _2ε of the rotational angular velocity of the second roller 102 is expressed by the following equation (46).

This is because, similarly to the equation shown in the above formula 45, the fluctuation component (first term) generated when the PLD fluctuation f (t) in the first roller 101 changes to g (t), and the second roller 102. It can be said that this is the result of superimposing the fluctuation component (second term) generated when the PLD fluctuation f (t) changes to g (t). Therefore, the update method when the PLD fluctuation f (t) shown below changes to g (t) can be corrected including the error caused by the deviation of the virtual home position as in the belt drive control example 2 described above. it can.

上記ε（ｔ）は、上述したズレ量ω_2εに基づいて、上記認識方法１のように第１ローラ１０１と第２ローラ１０２とのローラ間距離を短くして検出したり、上記認識方法２のようにフィルタ処理によって検出したり、ローラ間距離を限定して上記認識方法３のようにフィルタ処理によって検出したりして求めることができる。そして、このε（ｔ）を求めたら、変化前のＰＬＤ変動ｆ（ｔ）にε（ｔ）を加えた新たなＰＬＤ変動ｆ'（ｔ）を求める。新たなＰＬＤ変動ｆ'（ｔ）は、下記の数４９に示す式のとおり、変化後のＰＬＤ変動ｇ（ｔ）に等しい。

したがって、ＰＬＤ変動ｆ（ｔ）に代えて新たに求めたＰＬＤ変動ｆ'（ｔ）を用いてベルト駆動制御を行えば、変化後のＰＬＤ変動ｇ（ｔ）に応じた適切なベルト駆動制御を行うことができる。
なお、ここでは、上記ω_2εから上記ε（ｔ）を求め、このε（ｔ）を用いてＰＬＤ変動ｆ（ｔ）をｇ（ｔ）に修正して更新する方法について説明したが、このｇ（ｔ）を直接求めて更新する方法であってもよい。 When the equation shown in the above equation 46 is transformed using the equation shown in the following equation 47, the equation shown in the following equation 48 is obtained. “G” in the equation 48 is the same as that shown in the above equation 29.

The ε (t) is detected by reducing the distance between the first roller 101 and the second roller 102 as in the recognition method 1 based on the above-described deviation amount ω _2ε , or the recognition method 2 It can be obtained by detecting by filtering, or by detecting by filtering as in the recognition method 3 with the distance between rollers limited. After obtaining ε (t), a new PLD fluctuation f ′ (t) is obtained by adding ε (t) to the PLD fluctuation f (t) before the change. The new PLD fluctuation f ′ (t) is equal to the changed PLD fluctuation g (t) as shown in the following equation 49.

Therefore, if belt drive control is performed using the newly obtained PLD fluctuation f ′ (t) instead of the PLD fluctuation f (t), appropriate belt drive control corresponding to the changed PLD fluctuation g (t) is performed. It can be carried out.
Here, the method of obtaining ε (t) from ω _2ε and correcting and updating the PLD fluctuation f (t) to g (t) using ε (t) has been described. A method in which (t) is directly obtained and updated may be used.

Next, the installation location of the rotary encoder for detecting the rotational angular velocities ω ₁ and ω ₂ of the two rollers 101 and 102 necessary for performing the belt drive control described above will be described.
In the belt drive control described above, the rotational angular velocities of two rollers having different diameters (strictly speaking, the recognition sensitivity β shown in Equation 8 is not zero or G shown in Equation 29 is not 1) are detected. If it is possible, belt movement speed fluctuation due to PLD fluctuation of the belt 103 can be suppressed. For example, the following three types of installation locations of the rotary encoder for detecting the rotational angular velocity are conceivable. First, as shown in FIG. 8, a rotary encoder is installed on two driven rollers having different diameters other than the driving roller 105 (installation example 1 of the rotary encoder). The second is a case where a rotary encoder is installed on the drive roller 105 and one driven roller having a diameter different from that of the drive roller (installation example 2 of the rotary encoder). Third, a rotary encoder is installed on the driving roller 105 and the two driven rollers 101 and 102 having different diameters, or the driving roller 105 and the driven rollers 101 and 102 having different diameters from each other. This is a case where a rotary encoder is installed in 102 (Installation Example 3 of the rotary encoder). When the rotary encoder is installed on the drive roller 105, not only the rotary encoder is provided on the roller shaft of the drive roller 105 but also the motor shaft of the drive motor 106 is included.

[Rotary encoder installation example 1]
In this installation example 1, as shown in FIG. 8, the rotary encoders are installed on two driven rollers 101 and 102 having different diameters. In this case, as described above, the first roller 101 has a function capable of feedback control so that the rotational angular velocity ω ₁ of the first roller 101 becomes the control target value ω _ref1 determined by the controller 110. Therefore, the PLD fluctuation f (t) can be obtained with high accuracy in a state where the transmission error of the drive transmission system and the slip between the drive roller and the belt are corrected. For example, in the state in which the driving roller is feedback-controlled in this way, by obtaining the PLD fluctuation f (t) from the detection result of the rotational angular velocity ω ₂ of the second roller 101, the transmission error of the driving transmission system, the driving roller 105 and the belt The PLD fluctuation f (t) with high accuracy that does not depend on the slip with 103 can be obtained.

[Rotation encoder installation example 2]
FIG. 9 is an explanatory diagram for explaining a control operation in the present installation example 2.
In this installation example 2, the motor and the driving roller are connected via a gear. However, a DC servo motor is used as the driving motor 106, and the encoder is attached to the motor shaft, or the driving roller shaft is used as the rotational angular velocity. It has a function that can detect and feedback control. In addition to the DC servo motor, a stepping motor capable of controlling the rotational angular velocity with the input drive pulse frequency may be used. In this case, since the rotational angular velocity can be controlled by the input drive pulse frequency to the stepping motor without the feedback from the encoder, it is not necessary to install the encoder on the motor shaft or the drive roller. Even this installation example 2, the rotation angular velocity ωm of the driving roller 105 and driven roller 102, it is possible to detect omega _2. Further, the rotational angular velocity ωm of the motor shaft and the rotational angular velocity of the drive roller 105 rotate with a fixed relationship. Therefore, the rotational angular velocity ωm of the motor shaft corresponds to the rotational angular velocity ω ₁ of the first roller 101 in the installation example 1 described above. However, when a reduction mechanism is provided, the equivalent to the rotational angular velocity ω ₁ is obtained in a state where the reduction ratio is taken into consideration. As a result, also in the installation example 2, the PLD fluctuation f (t) can be obtained with high accuracy as in the installation example 1. However, in the present installation example 2, the rotational angular velocity ω ₂ of the second roller 102 detected by the angular velocity detection unit 112 includes fluctuation due to a drive transmission system error and slip between the drive roller 105 and the belt 103. Therefore, it is necessary to reduce these fluctuations and obtain the PLD fluctuation f (t). In particular, the friction coefficient is increased by exposing the surface of the roller so as not to cause a slip between the driving roller 105 and the belt 103. However, in this installation example 2, since it is not necessary to provide the rotary encoder 101a on the driven roller 101, the number of parts can be reduced by that amount, and the cost can be reduced compared to the installation example 1. .

[Installation example 3 of rotary encoder]
FIG. 10 is an explanatory diagram for describing a control operation in the third installation example.
In this installation example 3, as in the installation example 2, a drive motor 106 that can drive and control the rotational angular velocity, such as a DC servo motor or a stepping motor, is employed. Further, in the third installation example, as in the first installation example, the rotary encoders 101a and 102a are installed on the two driven rollers 101 and 102 having different diameters. Therefore, in this installation example 3, similarly to the installation example 1, the PLD fluctuation f (t) can be obtained with the same high accuracy as the installation example 1. In addition, the present installation example 3 is configured to acquire information on the rotational angular velocity ωm of the motor shaft, that is, configured to take a minor loop, and a more stable control system can be designed.

Further, the motor shaft rotates at a constant rotational angular velocity, that is, the driving roller 105 is driven at a constant rotational angular velocity, and the average rotational angular velocity of the first roller 101 and the second roller 102 is obtained, whereby the first roller 101 And the diameter ratio of the 2nd roller 102 can be calculated | required correctly. As a result, for example, the diameters of the first roller 101 and the second roller 102 change due to manufacturing variations, environmental changes, aging, etc., and the roller effective radius R ₁ , Even if R ₂ deviates from the actual one, the diameter ratio can be corrected.
Here, the effective roller radius R represents (r + PLD _ave ) as described above, and varies depending on variations in the roller radius and the PLD _ave of the belt. In the above equation 27, the roller effective radius R is an important parameter. As the accuracy of this ratio increases, the detection accuracy of PLD fluctuations increases. This is the same when the recognition method 1 or the recognition method 3 is used. The ratio of the effective roller radius R of the first roller 101 and the second roller 102 is obtained by controlling the first roller 101 to a constant rotational angular velocity to obtain the rotational angular velocity ratio or the rotational angular ratio of the first roller 101 and the second roller 102. Therefore, the same can be said for the rotary encoder installation examples 1 and 2. In the rotary encoder installation example 3, the PLD fluctuation effective coefficients κ ₁ and κ ₂ of the rollers 101 and 102 can be corrected. That is, the PLD fluctuation f ₂ (t) is obtained using the rotational angular velocities ω _d and ω ₂ of the driving roller 105 and the second roller 102. Further, the PLD fluctuation f ₁ (t) is obtained by using the rotational angular velocities ω _d and ω ₁ of the driving roller 105 and the first roller 101. The two PLD fluctuations f ₁ (t) and f ₂ (t) thus determined are for the same belt 103 and should be equal to each other. However, if the roller effective radii R ₁ and R _{2 of the} rollers 101 and 102 are accurate, they may not be equal to each other due to setting value errors of the PLD fluctuation effective coefficients κ ₁ and κ ₂ . In such a case, the PLD fluctuation effective coefficient ratios pκ ₁ = κ ₁ / κ _d and pκ ₂ = κ ₂ / κ _d such that the two PLD fluctuations f ₁ (t) and f ₂ (t) coincide with each other. By calculating (κ _d : PLD fluctuation effective coefficient at the driving roller section) and correcting the ratio of the PLD fluctuation effective coefficient κ ₂ / κ ₁ , the ratio R ₁ / R ₂ of the roller effective radius is as described above. Since it can be obtained with high accuracy, it can be understood that the PLD fluctuation f (t) can be recognized with higher accuracy than the equation (27). This is effective when the effective roller radius of either the first roller 101 or the second roller and the PLD fluctuation effective coefficient are likely to fluctuate.

ただし、ω_dは駆動ローラの回転角速度、Ｒ_dは駆動ローラ実効半径、τ₁は駆動ローラ１０５と第１ローラ１０１間をベルトが通過することによって決まる遅延時間である。

ただし、τ₂は駆動ローラ１０５と第２ローラ１０２間をベルトが通過することによって決まる遅延時間である。 Here, a method for obtaining the ratio of the PLD fluctuation effective coefficient κ of the first roller 101 and the second roller 102 will be described. The relationship between the driving roller 105 and the first roller 101 can be expressed by the following equations 50 and 51 so that the equation 27 can be easily estimated from the equation. Further, the relationship between the driving roller 105 and the second roller 102 can be expressed by the following equations 52 and 53.

Here, ω _d is the rotational angular velocity of the driving roller, R _d is the effective radius of the driving roller, and τ ₁ is a delay time determined by the belt passing between the driving roller 105 and the first roller 101.

However, τ ₂ is a delay time determined by the belt passing between the driving roller 105 and the second roller 102.

Here, the ratios pR _{1 and} pR ₂ of the effective roller radius are obtained by the method described above, R ₂ on the left side of the above equation 52 is replaced with R ₂ = (pR ₁ / pR ₂ ) R ₁ , and By changing the PLD fluctuation effective coefficient ratio pκ ₁ = κ ₁ / κ _d or pκ ₂ = κ ₂ / κ _d corresponding to the PLD fluctuation effective coefficient κ ₁ , κ ₂ that tends to fluctuate, the PLD fluctuation derivation result is f ₁ (t) = f ₂ (t). Then, the PLD fluctuation effective coefficient ratio κ ₂ / κ ₁ between the first roller and the second roller is obtained from the obtained effective coefficient ratios (pκ ₂ / pκ ₁ = (κ ₂ / κ _d ) / (κ ₁ ). / Κ _d ) = κ ₂ / κ ₁ ). Thereby, the PLD fluctuation f (t) can be recognized with higher accuracy. If the fluctuation of the roller effective radius R _{1 on} the left side of the above equation (50) is obtained in advance with little fluctuation, the accuracy becomes higher. Alternatively, if the variation is obtained in advance less the effective roller radius R ₂ on the left side of the formula in Formula 52, likewise, more accuracy is high. However, in order to derive the roller effective radius ratio and the PLD fluctuation effective coefficient ratio, it is preferable to drive at low speed so that there is no slip with the belt at the drive roller portion when detecting rotation information.

[Example 1]
Next, a specific example of updating the PLD fluctuation f (t) (hereinafter, this example is referred to as “Example 1”) will be described. The first embodiment uses the above-described method 2 for recognizing the PLD fluctuation f (t). Further, there is no mechanism for detecting the home position of the belt 103 as in the belt drive control example 2, and the rotary encoder is provided on the motor shaft of the drive motor 106 as in the installation example 3 of the rotary encoder. This is an example in which a controllable one is adopted and the rotary encoders 101a and 102a are respectively installed on two driven rollers 101 and 102 having different diameters. Of course, as described above, the present invention can be implemented even in a configuration in which the rotary encoder is not provided on the motor shaft.

FIG. 11 is an explanatory diagram for explaining an update process according to the first embodiment. In this figure, a rotary encoder 106 b installed in the drive motor 106 is provided in a DC servo motor employed as the drive motor 106. In addition, a digital signal processing unit as control means surrounded by a broken line in the figure is constituted by a digital circuit, a DSP, a μCPU, a RAM, a ROM, a FIFO (Fast In Fast Out), and the like. Of course, the specific hardware configuration is not limited to this configuration. Some control blocks in the figure are processed by calculation in firmware.
In the first embodiment, since there is no mechanism for detecting the home position of the belt 103, as described in the belt drive control example 2, the virtual home position shifts and a phase error occurs. Further, the actual PLD fluctuation of the belt 103 may change due to environmental changes and changes with time. Therefore, it is necessary to update the PLD fluctuation f (t) obtained in the past. In the first embodiment, whether to update intermittently or continuously can be arbitrarily determined according to the load of an arithmetic processing unit such as a CPU.

  In the case where the update is performed intermittently, in the first embodiment, by checking the fluctuation of the belt moving speed, it is monitored whether the accuracy of the PLD fluctuation f (t) is within a certain allowable range. When it exceeds, PLD fluctuation f (t) is updated. Specifically, as described above, the absolute value of the value of ε (t) shown in the above equation 47, the average of the absolute value, the mean square, or the square root of the mean square is a predetermined allowable range. If it exceeds the allowable range, a process for updating the PLD fluctuation f (t) is performed. Of course, a process of periodically updating may be performed in accordance with the operating time or operating amount of the copying machine. If the absolute value of the ε (t) value, the average of the absolute value, the root mean square, or the square root of the root mean square does not fall within the allowable range even after the update process is performed, the initial values that are assumed are incorrect. Since there is an error, an error is reported.

More specifically, the controller 410 first turns off the switches SW1 and SW2, and the rotation angular velocity ω of the first roller 101 obtained by the rotation angular velocity reference signal data ω ₀₁ (= V ₀ / R ₁ ) and the angular velocity detection unit 111. ₁ and the belt 103 is driven so that the first roller 101 has a constant rotational angular velocity ω ₀₁ . The two phase compensators 115a and 115b function to eliminate steady-state errors and perform stable feedback control. When the rotational angular velocity ω ₁ of the first roller 101 becomes a constant rotational angular velocity ω ₀₁ , the rotational angular velocity ω ₂ of the second roller 102 obtained by the angular velocity detecting unit 112 is expressed by the following formula 54 It becomes like the formula shown. “G” in the formula 54 is the same as that shown in the above formula 29. In the first embodiment, since digital processing is premised, tn representing time discretely is used instead of time t. Therefore, the PLD fluctuation f (t) described above is replaced with f (tn).

The PLD fluctuation f (tn) is obtained from the rotation angular velocity ω ₂ of the second roller 102, and data for one round of the belt is stored in the FIFO 419 as fluctuation information storage means. In this process, first, the fixed data (R ₁ · ω ₀₁ ) / R ₂ calculated in the block 1302 is obtained from the detected rotational angular velocity ω ₂ of the second roller 102 in a state where the switches SW1 and SW2 are OFF. , And subtracted by the subtracter 1313. The value output from the subtracter 1313 is multiplied by fixed data R ₂ / (κ ₁ · ω ₀₁ ) in the block 1304, and the output data is input to the FIR filter (or IIR filter) in the block 1315. The That is, the output data of the block 1304 is f (tn) −Gf (tn−τ), and this data is input to the FIR filter (or IIR filter). The output of this filter is each data (nth time discrete PLD fluctuation data) fn constituting a data string of PLD fluctuation f (tn). The controller 410 observes the rotational angular velocity ω ₁ of the first roller 101, the rotational angular velocity ω ₁ is constant, and the time elapses when accurate PLD fluctuation data fn is output from the FIR filter (or IIR filter). Later, the switch SW1 is turned on. This is because the delay element is included in both the FIR filter and the IIR filter, so that the accurate PLD fluctuation data fn is not output at the initial stage of the filter execution. Then, the controller 410 counts the number of encoder output pulses of the first roller 101 and confirms that the belt 103 has moved one round, and then turns off the switch SW1. The PLD fluctuation data fn output from the FIR filter (or IIR filter) is accumulated in the PLD fluctuation data FIFO 419 having a capacity capable of storing the PLD fluctuation data fn for exactly one belt revolution. In the first embodiment, when the data in the FIFO 419 is empty, the PLD fluctuation data fn is stored by turning on the switch SW1.

この数５５に示す式の中かっこ内の演算処理は、ブロック１３０９で行われる。そして、図１１に示す２つのスイッチＳＷ２をオンにすることで、第１ローラ１０１の基準データω_ref1が減算部１３１０から出力されることになる。 As described above, the PLD fluctuation data fn is accumulated in the FIFO 419 in accordance with the rotation of the belt 103. If the PLD fluctuation data fn is used and the reference data ω _ref1 of the first roller 101 is generated according to the following equation 55, drive control corresponding to the PLD fluctuation f (tn) is performed.

The calculation processing in the curly braces of the expression shown in Expression 55 is performed in block 1309. Then, the reference data ω _ref1 of the first roller 101 is output from the subtraction unit 1310 by turning on the two switches SW2 shown in FIG.

Further, by turning on the switch SW2, processing for detecting the control error ω _2ε represented by the equation shown in the above equation 48 is performed. In this process, first, the rotation angular velocity fluctuation of the second roller 102 is calculated in block 1307 and 1308, a constant rotational angular velocity omega ₀₁ block 1301 is added predicted from PLD variation data fn are accumulated in the FIFO419 After that, it is calculated by the block 1302 and subtracted by the subtractor 1313 from the rotational angular velocity ω ₂ detected by each speed detector 112. The output from the subtractor 1313 is ω _{2ε in} the equation shown in the above equation (48). This is input to block 1304. As a result, the output of the FIR filter 1315 is input to the controller 410 as PLD fluctuation error data εn. Then, when the PLD fluctuation error data εn exceeds a predetermined value, the controller 410 turns on the switch SW1 for a time corresponding to one revolution of the belt to obtain new PLD fluctuation data fn, which is stored in the FIFO 419. Update. Note that when both the switches SW1 and SW2 are turned on in a state where the PLD fluctuation data fn before update has already been stored in the FIFO 419, the adder 1306 corrects the PLD fluctuation shown in the equation 49 above. The corrected PLD fluctuation data is re-stored in the FIFO 419.

  When the PLD fluctuation data fn is accumulated in the FIFO 419, the data fn for a plurality of belt circumferences may be taken and averaged to be stored in the FIFO 419. In this case, the FIFO 419 also functions as past information storage means. Similarly, PLD fluctuation error data εn is also obtained by taking data εn for a plurality of belt circumferences and using the averaged data to reduce errors due to random fluctuations caused by gear backlash and noise. You may make it do.

Next, the case of continuously updating will be described. In this case, the PLD fluctuation correction shown in the equation 49 is always executed. That is, in FIG. 11, both the switches SW1 and SW2 are turned on.
More specifically, first, compared when PLD fluctuation data FIFO419 is empty, the controller 410 turns off the switch SW1, and a rotational angular velocity omega ₁ of the first roller 101 determined by the reference signal omega ₀₁ and the angular velocity detecting section 111 Then, the belt 103 is driven so that the first roller 101 has a constant rotational angular velocity ω ₀₁ . When the output of the FIR filter or IIR filter 1315 is stabilized, the switch SW1 is turned on and the PLD fluctuation data fn is accumulated in the FIFO 419 for one belt revolution. Thereafter, when both the switches SW1 and SW2 are turned on, the sum of the output data εn of the FIR filter 1315 and the output data of the FIFO 419 becomes new PLD fluctuation data fn input to the FIFO 419 again. This data εn is PLD fluctuation error data obtained from the output of the FIR filter or IIR filter based on the relationship of the equations shown in the above equations 46 and 48. In this case, the PLD fluctuation data fn whose error has been corrected rotates corresponding to one belt period in the FIFO. If the PLD fluctuation data fn is used to generate the reference signal ω _ref1 of the first roller 101 according to the formula shown in the above equation 55, the drive control corresponding to the PLD fluctuation f (tn) is performed. At this time, if the controller 410 determines that the PLD fluctuation error data εn exceeds a predetermined value, the abnormality is notified to the copying machine main body.

  In the first embodiment, the storage input data of the PLD fluctuation data fn is realized by using the FIFO 419 that shifts by the clock signal and the memory function of the block 1307 that outputs the input data after being delayed for a certain time. It may be realized by a memory function.

[Example 2]
Next, another embodiment (hereinafter, this embodiment is referred to as “embodiment 2”) for updating the PLD fluctuation f (t) will be described. In the second embodiment, a case where the PLD fluctuation data fn is not corrected as in the first embodiment but the newly obtained PLD fluctuation data fn is sequentially accumulated and controlled in the FIFO 419 will be described. Further, in the following description, an example will be described in which PLD fluctuation data fn newly obtained in the FIFO 419 is sequentially accumulated and continuously updated using the PLD fluctuation data fn one belt before.

First, each rotational speed ω ₂ of the second roller 102 is detected, and then PLD fluctuation data gn is newly obtained from data excluding the reference data ω _ref1 calculated from the PLD fluctuation data fn stored in the FIFO 419. That is, the rotational angular velocity ω ₂ ′ of the second roller 102 is detected based on the virtual home position while the belt is driven and controlled based on the PLD fluctuation data fn currently stored in the FIFO 419. Then, the reference data ω _ref1 at this time is _multiplied by (R ₁ / R ₂ ), subtracted from the rotation angular velocity ω ₂ ′, and new reference data is obtained by using the signal ω ₂ ″ obtained from this Based on this, drive control is performed.

ここで、上記信号ω₂''は下記の数５７に示す式から求まる。

したがって、上記数５５及び上記数５６に示した式から、下記の数５８に示す式が得られる。この数５８の式中の「Ｇ」は、上記数２９に示したものと同じであり、本実施例２における第１ローラ１０１及び第２ローラ１０２のローラ径比の関係から１よりも小さい値をとる。

この数５８に示す式から、ＰＬＤ変動データｇ（ｔｎ）を求めることができる。具体的には、例えば上述したＦＩＲフィルタやＩＩＲフィルタにより、新たなＰＬＤ変動データｇｎのデータ列として得ることができる。 The rotational angular velocity ω ₂ ′ of the second roller 102 detected on the basis of the virtual home position is expressed by the following equation 56.

Here, the signal ω ₂ ″ is obtained from the following equation 57.

Therefore, the following equation 58 is obtained from the equations 55 and 56. “G” in the equation 58 is the same as that shown in the equation 29, and is smaller than 1 due to the relationship of the roller diameter ratio between the first roller 101 and the second roller 102 in the second embodiment. Take.

PLD fluctuation data g (tn) can be obtained from the equation shown in Equation 58. Specifically, it can be obtained as a data string of new PLD fluctuation data gn by, for example, the above-described FIR filter or IIR filter.

FIG. 12 is an explanatory diagram for explaining an update process according to the second embodiment. In this figure, the rotary encoder 106b installed in the drive motor 106 is provided in the DC servo motor employed as the drive motor 106, as in the first embodiment. In addition, the digital signal processing unit surrounded by a broken line in the figure includes a digital circuit, a DSP, a μCPU, a RAM, a ROM, a FIFO (Fast In Fast Out), and the like. Of course, the specific hardware configuration is not limited to this configuration. Some control blocks in the figure are processed by calculation in firmware.
In the second embodiment, first, the controller 510 turns off the switch SW1, and compares the reference data ω ₀₁ (= V ₀ / R ₁ ) with the rotational angular velocity ω ₁ of the first roller 101 obtained by the angular velocity detection unit 111. Then, the belt 103 is driven so that the first roller 101 has a constant rotational angular velocity ω ₀₁ . When the rotational angular velocity ω ₁ of the first roller 101 becomes a constant rotational angular velocity ω ₀₁ , the rotational angular velocity ω ₂ of the second roller 102 obtained by the angular velocity detecting unit 112 is expressed by the following equation 59.

Here, ω ₀₁ output from the subtractor 1310 is multiplied by (R ₁ / R ₂ ) in the block 1302, and the fixed data (R ₁ · ω ₀₁ ) / R ₂ is input to the subtractor 1313. The value output from the subtractor 1313 is multiplied by fixed data R ₂ / (κ ₁ · ω ₀₁ ) in block 1304. This output data is input to the FIR filter or IIR filter of block 1315. That is, the output data of the block 1304 is f (tn) −Gf (tn−τ), and this data is input to the FIR filter or IIR filter. The output of this filter becomes each PLD fluctuation data fn constituting a data string of PLD fluctuation f (tn). The controller 510 observes the rotational angular velocity ω ₁ of the first roller 101, and the time elapsed when the rotational angular velocity ω ₁ is constant and accurate PLD fluctuation data fn is output from the FIR filter (or IIR filter). Later, the switch SW1 is turned on. This is because the delay element is included in both the FIR filter and the IIR filter, so that the accurate PLD fluctuation data fn is not output at the initial stage of the filter execution. If the PLD fluctuation data fn is used to calculate the reference data ω _ref1 of the first roller 101 in the block 1309 according to the equation shown in the above equation 55, the drive control corresponding to the PLD fluctuation f (tn) is performed. Become.

In the second embodiment, the FIFO 419 is inserted when the digital signal processing including the derivation calculation of the PLD fluctuation data fn or the multiplication of the block 1309 takes time. That is, the reference signal ω _ref1 is generated from the PLD fluctuation data fn for one belt revolution. Further, since the rotational angular velocity ω ₁ of the first roller 101 is controlled by the reference data ω _ref1 , the rotational angular velocity detection data ω ₁ of the first roller 101 is directly blocked as shown by the one-dot chain line in the figure. It may be configured to input to 1302.
In the second embodiment, the signal ω ₂ ″ includes variations in the roller diameters of the first roller 101 and the second roller 102, changes due to temperature, or DC component errors due to calculation errors. Then, an error occurs in the filter processing of the subsequent FIR filter or IIR filter. When this error becomes a problem, a high-pass filter for removing the DC component of the signal ω ₂ ″ is inserted before the filter processing of the FIR filter or IIR filter.
In the first and second embodiments, the example using the recognition method 2 of the PLD fluctuation f (t) has been described. However, the recognition method 1 and the recognition method 3 described above can be used in the same manner. When the recognition method 1 is used, a 1 / (1-G) multiplication block is inserted in place of the FIR or IIR filter of the block 1315. In the recognition method 1, the output data f (tn) −Gf (tn−τ) of the block 1304 is approximated to f (tn) = f (tn−τ), and (1−G) f This is because the PLD fluctuation data fn is calculated as (tn). When the recognition method 3 is used, an Nb stage FIR filter and a 1 / (1-G ^m ) multiplication block (m = 2 ^Nb ) are inserted instead of the FIR or IIR filter of the block 1315. .

In the first and second embodiments described above, based on the rotational angular velocity ω ₂ of the second roller 102 detected by the angular velocity detection unit 112, the rotation cycle of the first roller 101 and the second roller 102, other cycle fluctuations, Furthermore, a low-pass filter may be inserted in order to remove fluctuations in the high frequency range including noise. Thereby, correction control of belt movement speed fluctuation due to PLD fluctuation can be stably suppressed with higher accuracy. This low-pass filter may be provided before the FIR filter or IIR filter or after the angular velocity detection unit 112. In the first and second embodiments, averaging may be performed to reduce random detection errors caused by gear backlash or noise. That is, the data fn for the belt N (natural number) rounds is fetched into a RAM (Random Access Memory) in the form of first-in first-out (FIFO: First In First Out), and the data for N belts or less in the RAM is averaged. This is used as PLD fluctuation data. When the PLD fluctuation data is continuously updated, the reference data is generated with data obtained by averaging the PLD fluctuation data from before one rotation of the belt to at most N rotations.
In the first and second embodiments, the reference data ω _ref1 indicating the rotational angular velocity is converted into data indicating the rotational angular displacement, and this is obtained from the output of the rotary encoder 101 a provided on the first roller 101. It is also possible to perform control in comparison with rotational angular displacement.
In the first and second embodiments, the reference data ω _ref1 is converted into a pulse train so as to control the pulse phase that is continuously output based on the output of the rotary encoder 101a provided on the first roller 101. It may be converted to perform PLL control.

[Modification]
Next, a modification of the above embodiment will be described.
In the above-described embodiment, the electrophotographic image forming apparatus has been described. However, in the present modification, an inkjet image forming apparatus will be described. However, the description of the same points as in the above embodiment will be omitted.

  FIG. 18 is a perspective view showing the internal configuration of the ink jet recording apparatus according to this modification. FIG. 19 is a side view of the mechanism portion of the ink jet recording apparatus. This ink jet recording apparatus has a carriage 610 that can move in the main scanning direction inside the apparatus main body 601. A recording head 611 is traversed on the carriage 610. In addition, an ink cartridge 612 that supplies ink to the recording head 611 is also stored inside the apparatus main body 601. A sheet feeding cassette 603 on which a plurality of recording sheets 602 can be stacked is detachably attached to the lower part of the apparatus main body 601 from the front side. Further, a manual feed tray 604 for manually feeding the recording paper 602 is attached to the apparatus main body 601 so as to be able to be turned over. The inkjet recording apparatus takes in a recording sheet 602 fed from a paper feed cassette 603 or a manual feed tray 604, forms an image on the recording sheet by a recording head 611 of a carriage 610, and then discharges the recording sheet 602 mounted on the back side. The paper is discharged onto a paper tray 605.

  The printing mechanism unit includes the carriage 610 and the ink cartridge 612. This printing mechanism unit holds a carriage 610 slidably in a main scanning direction by a main guide rod 613 that is a guide member horizontally mounted on left and right side plates (not shown). The carriage 610 is held by the main guide rod 613 so that the discharge directions of the ink droplets of yellow (Y), cyan (C), magenta (M), and black (Bk) discharged from the recording head 611 are directed downward. Has been. A sub tank 614 for supplying ink of each color to the recording head 611 is mounted on the carriage 610. Each color sub-tank 614 is connected to an ink cartridge 612 that is replaceably mounted via an ink supply tube 615, and receives ink from the ink cartridge 612. The carriage 610 is slidably fitted to the main guide rod 613 on the back side. In order to move and scan the carriage 610 in the main scanning direction, a timing belt 619 is provided between a driving pulley 617 and a driven pulley 618 that are rotationally driven by a main scanning motor 616, and the timing belt 619 is attached to the carriage 610. It is fixed to.

  In this modification, the recording head 611 uses an individual recording head for each color. However, the recording head 611 may include a single recording head having nozzles that eject ink droplets of each color. Further, the recording head 611 is a piezo type that pressurizes ink through a vibration plate that forms a liquid chamber (ink flow path) wall surface with an electromechanical conversion element such as a piezoelectric element, and bubbles are generated by film boiling by a heating resistor. A bubble type that pressurizes ink by generating it, or an electrostatic type that pressurizes ink by displacing the diaphragm with an electrostatic force between the diaphragm that forms the wall surface of the ink flow path and the electrode facing it , Etc. can be used. In this modification, an electrostatic ink jet head is used.

  The ink jet recording apparatus reverses the paper feed roller 620 and the friction pad 621 for separating and feeding the recording paper 602 from the paper feed cassette 603, the guide member 622 for guiding the recording paper 602, and the fed recording paper 602. The sheet feeding cassette 603 is loaded with a conveying roller 623 that conveys the recording sheet 602, a conveying roller 624 that is pressed against the peripheral surface of the conveying roller 623, and a leading end roller 625 that defines a feeding angle of the recording paper 602 from the conveying roller 623. The set recording paper 602 is conveyed below the recording head 611. The transport roller 623 is rotationally driven by a sub-scanning motor 626 through a gear train (not shown).

  The ink jet recording apparatus is provided with an electrostatic conveyance belt 627 that guides the recording paper 602 fed from the conveyance roller 623 to the lower side of the recording head 611 corresponding to the moving range of the carriage 610 in the main scanning direction. The electrostatic conveyance belt 627 can attract the recording sheet 602 conveyed by charging using the charger 628 to the surface, and can keep the sheet surface and the head surface parallel to each other. A paper discharge roller 629 for sending the recording paper 602 to the paper discharge tray 605 is disposed on the downstream side of the electrostatic transport belt 627 in the paper transport direction. A maintenance / recovery mechanism 630 for maintaining and recovering the reliability of the recording head 611 is disposed at one end of the carriage 610 in the moving direction. During printing standby, the carriage 610 is positioned to the maintenance / recovery mechanism 630 so that the recording head 611 is capped by capping means or the like.

  The belt drive control device described in the above embodiment can also be used for drive control of the electrostatic conveyance belt 627 and the timing belt 619. The electrostatic transport belt 627 needs to be transported with high accuracy because positional deviation and density unevenness occur when the belt transport amount during paper transport varies. Similarly, the timing belt 619 also requires high-accuracy conveyance control because positional deviation and density unevenness occur when the speed variation of the carriage 610 occurs during scanning.

The electrostatic conveyance belt 627 will be described. Since the electrostatic conveyance belt 627 is a single layer belt made of polyimide (PI) as a main material and has a thickness deviation distribution over one circumference of the belt, PLD fluctuation occurs when the belt is driven. . The rotational angular velocity or the rotational angular displacement of the transport roller 623 can be obtained by installing a rotary encoder on the shaft of the transport roller 623 or using a rotation detection unit built in the sub-scanning motor 626. Further, a rotary encoder (not shown) is installed on the shaft of the driven roller 631 around which the electrostatic conveyance belt 627 is stretched, and the rotational angular velocity or the rotational angular displacement of the driven roller 631 is obtained. The radius ratio of the conveyance roller 623 and the driven roller 631 is 2: 1. Since two rotational angular velocities of the conveying roller 623 and the driven roller 631 having different diameters are obtained in this way, the rotational angular velocity ω ₁ of the conveying roller 623 and the rotational angular velocity ω ₂ of the driven roller 631 are obtained as in the above-described embodiment. 11 and FIG. 12, the electrostatic conveyance belt 627 can be driven at a desired movement speed and movement amount.

Next, the timing belt 619 will be described.
FIG. 20 is a schematic configuration diagram showing the carriage drive mechanism. The timing belt 619 is a toothed endless belt made of a polyurethane belt having a belt circumferential length of 1.2 [m], a belt tooth number of 300, and a belt width of 15 [mm]. The timing belt 619 includes a wire rope having a strand diameter of 0.1 [mm] bundled as a tensile body along the circumferential direction of the belt. The drive pulley 617 is a toothed pulley having 18 teeth, and the driven pulley 618 is a toothed pulley having 27 teeth. The tension pulley 633 is installed to apply an appropriate tension to the timing belt 619. The tension pulley 633 may be removed by giving the driven pulley 618 a function of applying tension. However, if a roller having a rotary encoder is provided with a tension mechanism, a rotation detection error may occur due to the displacement of the roller due to the tension.

The timing belt 619 has PLD fluctuation over the entire circumference of the belt due to an installation error of a wire rope (tensile body) or a polyurethane rubber thickness deviation due to a mold error at the time of manufacture. The rotational angular velocity or the rotational angular displacement of the drive pulley 617 can be obtained by installing a rotary encoder on the shaft of the drive pulley 617 or using a rotation detection means built in the main scanning motor 616. Further, a rotary encoder (not shown) is installed on the shaft of the driven pulley 618, and the rotational angular velocity or the rotational angular displacement of the driven pulley 618 is obtained. The drive pulley 617 and the driven pulley 618 have a radius ratio of 2: 3. Since two rotational angular velocities of the driving pulley 617 and the driven pulley 618 having different diameters are obtained in this way, the rotational angular velocity ω ₁ of the driving pulley 617 and the rotational angular velocity ω ₂ of the driven pulley 618 are obtained as in the above-described embodiment. 11 and FIG. 12, the timing belt 619 can be driven at a desired movement speed and movement amount.

In addition, the carriage 610 includes a carriage grip 634 that grips the timing belt 619 so that the carriage 610 can be fixed at an arbitrary position of the timing belt 619. The carriage grip 634 is detachable from the timing belt 619. Therefore, the carriage 610 can be attached to and detached from the timing belt 619. When recognizing the PLD variation, the carriage 610 is detached from the timing belt and the timing belt 619 is driven to recognize the PLD variation over one revolution of the timing belt 619.
As a conventional means for detecting the scanning position of the carriage 610, a linear encoder mechanism that reads a high-accuracy scale pattern provided along the belt circumferential direction on the timing belt 619 with a sensor provided on the carriage 610 is generally used. Use. However, in this modification, since the rotary encoder is provided on the pulleys 617 and 618 around which the timing belt 619 is stretched, the scanning position of the carriage 610 can be detected from the output of the rotary encoder. Therefore, according to this modification, there is an advantage that it is not necessary to form a highly accurate scale pattern on the timing belt 619 and it is not necessary to provide a sensor on the carriage 610. This advantage is particularly beneficial in devices where the carriage 610 has a long scanning distance.

As described above, the belt drive control device in the embodiment is a drive roller 105 that is a drive support rotating body to which a rotational driving force is transmitted among the support rollers 101, 102, and 105 as a plurality of support rotating bodies around which the belt 103 is stretched. By controlling the rotation of the belt 103, the driving of the belt 103 is controlled. In this belt drive control device, the effective radius of the rollers is different among the plurality of support rollers, or the PLD of the belt portion wound around the belt is the moving speed V of the belt and the rotation angular velocities ω ₁ and ω _{2 of the} belt. Of the belt moving speed V caused by the PLD fluctuation in the circumferential direction of the belt 103 based on the detection result of the rotational angular displacement or rotational angular velocity of the two first rollers 101 and the second rollers 102 that have different degrees of influence on the relationship with each other. A digital signal processing unit is provided as control means for controlling the rotation of the drive roller 105 so that the fluctuation is reduced. In this embodiment, the digital signal processing unit obtains PLD fluctuation information f (t) using an arbitrary point on the moving path of the belt 103 as a virtual home position, and uses the PLD fluctuation information f (t). The rotation control is performed. According to this apparatus, as described above, the two driven rollers 101 depend on the size of the effective roller radii R ₁ and R ₂ , the wrapping angles θ ₁ and θ _{2 of} the belt, the material of the belt, the layer structure of the belt, and the like. , 102 using the difference in the magnitude of the PLD fluctuation in the belt circumferential direction detected from the rotational angular velocities ω ₁ , ω ₂ of the rollers 102, 102 from the rotational angular displacements or rotational angular velocities ω ₁ , ω _{2 of} these rollers 101, 102. The PLD fluctuation given to the relationship between the belt moving speed V and the rotational angular velocities ω ₁ and ω ₂ of the rollers 101 and 102 can be specified with high accuracy even if the fluctuation is complicated. As a result, the belt 103 can be driven and controlled with high accuracy so that fluctuations in the belt moving speed due to PLD fluctuations are reduced.
Further, when the belt 103 is a single layer belt made of a uniform belt material, drive control may be performed using belt thickness fluctuation that has a constant relationship with PLD fluctuation. That is, among the plurality of support rollers, the effective roller radius is different, or the thickness of the belt portion wound around itself affects the relationship between the moving speed V of the belt and the rotational angular velocities ω ₁ and ω ₂ of the belt. Based on the detection results of the rotational angular displacement or rotational angular velocity of the two first rollers 101 and second rollers 102 having different degrees, the variation in the belt moving speed V caused by the belt thickness variation in the circumferential direction of the belt 103 is reduced. As described above, the rotation of the drive roller 105 is controlled.
Further, in this embodiment, as described in the PLD fluctuation recognition method 1, the 2 recognized from the rotational angular displacements or rotational angular velocities ω ₁ and ω _{2 of the} two rollers 101 and 102 detected at the same time, respectively. The rotation control is performed using the approximate PLD fluctuation information obtained by assuming that the PLD fluctuation information f (t) and f (t−τ), which are the rotation fluctuation information of the two rollers, have the same phase. Thereby, the process for calculating | requiring PLD fluctuation information f (t) can be simplified. Note that if the distance between the two rollers 101 and 102 is sufficiently close, the delay time τ becomes sufficiently small. Therefore, even if f (t) = f (t−τ), the PLD fluctuation information f (T) can be obtained with sufficiently high accuracy.
Further, in this embodiment, as described in the PLD fluctuation recognition method 2, based on the detection results of the rotational angular displacements or rotational angular velocities ω ₁ and ω ₂ of the two rollers 101 and 102 detected at the same time, respectively. Based on the obtained data (data on the left side of the equation shown in the above equation 27), or the rotational angular displacement or rotational angular speed ω ₂ of the other one of these rollers 101 and 102 while maintaining one of the angular speeds ω _01. Since the obtained data is detection information including two pieces of PLD fluctuation information f (t) and f (t−τ), the coefficient of one PLD fluctuation information is 1 according to the equation shown in the above equation (27). Is performed to reduce the error Gf (t−τ) between the obtained time function gf (t) and the time function f (t) which is PLD fluctuation information to be obtained. As fluctuation information To perform the above rotation control. However, the coefficient of the other PLD fluctuation information after the above normalization is made smaller than 1. Further, the process for reducing the error is a time function gf (t) in which the coefficient of the PLD fluctuation information is 1, and a time τ required for the belt 103 to move between the rollers 101 and 102. The degree of κ ₁ , κ ₂ and the effective radii R ₁ , R _{2 of the} corresponding delay elements and the PLD of each belt portion wound around these rollers 101, 102 affect the moving speed V of each belt portion. After adding a gain element based on the above, by performing addition processing for adding the original time function gf (t) data, the processing result h (t) is used as the PLD fluctuation information f (t) and the rotation is performed. Take control. Thus, the PLD fluctuation information f (t) can be obtained with high accuracy without depending on the distance between the two rollers 101 and 102. As a result, the degree of freedom of device layout can be increased.
In particular, in the present embodiment, as described in the method 2 for recognizing PLD fluctuations, the process of reducing the error gives a gain to the input time function, and belts between the two rollers 101 and 102. Processing obtained by performing addition processing for adding the input time function to a signal obtained by delaying or advancing the phase of the input time function by a delay time τ, which is a movement time required for the movement of 103 For the result, the process of further performing the addition process is repeated a predetermined number of times, and the gain at the first addition process is multiplied by 2 ^n-1 as the gain at the n-th addition process. the used, which carried out using those 2 ^n-1 times the predetermined time τ during the first addition process as the predetermined time τ in the n-th addition processing, the number 2 As the gain G is smaller than 1 in the time of the first addition process which is obtained from the formula shown in, effective in effective PLD fluctuation coefficient kappa _1, kappa ₂ and said two supporting rotating bodies of the two supporting rotating bodies The radii R ₁ and R ₂ are set. Since such processing can be performed using an FIR filter or the like, stable processing is possible.
As shown in FIG. 6, the process of reducing the error gives the input time function a gain G obtained from the equation shown in the above equation 29, and between the two rollers 101 and 102 described above. An addition process is performed in which a phase obtained by delaying or advancing the phase of the input time function by the movement time required for the belt to move is fed back and added to the input time function. It may be used as PLD fluctuation information f (t). In this case, since the subordinate (non-feedback) arithmetic processing using the FIR filter is performed in the feedback type, the same processing can be performed with a small arithmetic processing or a simple circuit configuration.
In the present embodiment, as described in the PLD fluctuation recognition method 3, the ratio of the belt conveyance section (distance) between the two rollers 101 and 102 and the entire belt conveyance section (circumferential length) is 1: 2 Nb. (Nb: natural number) The rollers are arranged so as to have a relationship, and data obtained based on the detection results of the rotational angular displacements or rotational angular velocities ω ₁ , ω ₂ of the two rollers 101, 102 detected at the same time (above The data obtained on the basis of the other rotational angular displacement or rotational angular velocity ω ₂ while maintaining one of these rollers 101 and 102 at the constant angular velocity ω ₀₁ , Since the detection information includes two pieces of PLD fluctuation information f (t) and f (t−τ), normalization is performed so that the coefficient of one PLD fluctuation information is 1 according to the equation shown in the above equation (27). Sought Performs time processing to reduce an error Gf (t-τ) of the function gf (t) and the determined desired PLD fluctuation information in a time function f (t) ^{has, 1 / (1-G m} ) (m = 2 Nb ) Is used as the PLD fluctuation information to perform the rotation control. In the process of reducing the error, a gain is given to the input time function, and the input is performed for a delay time τ which is a moving time required for the belt 103 to move between the two rollers 101 and 102. For the processing result obtained by performing the addition process for adding the input time function to the delayed or advanced phase of the time function, the process of performing the addition process is repeated Nb times. Then, as the gain in the n-th addition process, the gain G obtained by raising the gain G in the first addition process to the power of 2 ⁿ⁻¹ is used as the predetermined time τ in the n-th addition process. This is performed using a value obtained by multiplying the predetermined time τ during the addition process by 2 ⁿ⁻¹ . At this time, the PLD fluctuation effective coefficients κ ₁ and κ _{2 of the} two support rotating bodies and the 2 are set so that the gain G at the time of the first addition processing obtained from the equation 29 is smaller than ₁ . The effective radii R ₁ and R ₂ for the two supporting rotating bodies are set. Since such processing can be performed using an FIR filter, stable processing is possible. Further, the PLD fluctuation f (t) can be obtained with higher accuracy in a shorter time than the recognition method 2.
In the present embodiment, a PLD fluctuation data FIFO 419 is provided as fluctuation information storage means for storing PLD fluctuation information f (t) for a period corresponding to the time Tb required for the belt 103 to make one revolution. . Thereby, it is possible to secure the calculation time for recognition and correction of the PLD fluctuation information f (t) and the calculation time for other processing of the calculation device.
In the present embodiment, a process for obtaining the PLD fluctuation information f (t) again at a predetermined timing is performed. As a result, the PLD fluctuation f (t) can be obtained again at the timing when the PLD fluctuation of the belt 103 changes beyond the allowable range depending on the environment and use over time. As a result, even if the PLD fluctuation of the belt 103 changes, highly accurate belt drive control can be maintained. In particular, as described in the first embodiment, the predetermined timing is determined based on the difference between the PLD fluctuation data predicted based on the belt movement position of the belt 103 and the PLD fluctuation information f (t) and the actual PLD fluctuation data. If the timing exceeds the allowable range, the belt drive control can be maintained more stably and accurately.
In the present embodiment, as described in the second embodiment, the rotation control may be performed while performing the process of obtaining the PLD fluctuation information f (t). In this case, the belt drive control can be maintained more stably and accurately. In this case, it is not necessary to store the PLD fluctuation information f (t) for one rotation of the belt, so that such storage means is not necessary.
In the present embodiment, as described above, the PLD fluctuation data FIFO 419 is provided as past information storage means for storing the past PLD fluctuation information for at least one belt revolution, and the past PLD fluctuation information stored in the PLD fluctuation data FIFO 419 is stored. The rotation control may be performed by using the PLD fluctuation information f (t) obtained by performing an averaging process or the like from the newly obtained PLD fluctuation information. In this case, the PLD fluctuation information obtained in the past and the newly obtained PLD fluctuation information can be averaged, so that the PLD fluctuation information f (t) can be obtained with higher accuracy. As a result, the influence of detection errors due to random fluctuations caused by gear backlash or noise can be reduced.
Further, the belt device in this embodiment includes a belt 103 that is stretched around a plurality of rollers including support rollers 101, 102, and 105, and a drive motor 106 as a drive source that generates a rotational drive force for driving the belt 103. Among these rollers, the roller radius is different, or the degree to which the PLD of the belt portion wound around the roller affects the relationship between the moving speed V of the belt and the rotation angular velocities ω ₁ and ω ₂ of the belt. Rotational encoders 101a, 102a and angular velocity detectors 111, 112 as detection means for detecting rotational angular displacements or rotational angular velocities ω ₁ , ω ₂ in two different first rollers 101 and second rollers 102; Among these rollers, the driving of the belt 103 is controlled by controlling the rotation of the driving roller 105 to which the rotational driving force is transmitted. As gate drive control device, and using the above-described belt driving controller. Thereby, as described above, a belt device capable of controlling the driving of the belt 103 with high accuracy is realized.
Moreover, in the installation example 1 of the rotary encoder according to the present embodiment, the two rollers 101 and 102 are all driven rollers that rotate along with the movement of the belt 103. In this case, when obtaining the PLD fluctuation f (t), it does not depend on fluctuation components (such as slip between the driving roller 105 and the belt 103) that cause the recognition error. Therefore, the PLD fluctuation f (t) can be obtained with higher accuracy.
In particular, as described in the installation example 3 of the rotary encoder of the present embodiment, the drive motor 106 detects its own rotational angular displacement or rotational angular velocity ωm, and the rotational angular displacement or rotational angular velocity ωm is targeted. If a device having feedback control means for performing feedback control so as to obtain a rotational angular displacement or a rotational angular velocity is used, a more stable control system can be designed. In addition, since the PLD fluctuation effective coefficients κ ₁ and κ ₂ of the driven rollers 101 and 102 described above can be corrected, the PLD fluctuation f (t) can be obtained with higher accuracy.
In the installation example 2 of the rotary encoder of the present embodiment, the driving roller 105 is included in the two rollers related to the rotational angular displacement or rotational angular velocity for obtaining the PLD fluctuation information f (t). The detection means for detecting the rotational angular displacement or rotational angular velocity of the driving roller 105 detects the rotational angular displacement or rotational angular velocity ωm of the driving motor 106 or the target rotational angular displacement input to the driving motor 106. Alternatively, a device that detects the target rotational angular velocity is used. Thus, for example, if a pulse motor is used as the drive motor, it is sufficient to provide at least one rotary encoder, so that the cost can be reduced. That is, one of the rotational angular displacement or rotational angular velocity for obtaining the PLD fluctuation information f (t) is the rotational angular displacement or rotational angular velocity of the driving roller 105 that can guarantee the rotational angular displacement or rotational angular velocity to be constant. The PLD fluctuation information f (t) can be obtained only by the rotational angular displacement or rotational angular velocity ω ₂ of the roller 102, and the recognition process can be simplified.
In the present embodiment, as described in the belt drive control example 1, in order to grasp the reference belt movement position of the belt 103, the home position mark 103a that is a mark indicating the reference position on the belt 103 is set. A mark detection sensor 104 is provided as mark detection means for detection. Then, after grasping the relationship between the belt movement position corresponding to the obtained PLD fluctuation information f (t) and the actual belt movement position based on the detection timing by the mark detection sensor 104, the rotation control is performed. Thereby, since the reference position in the belt circumference can be determined, the obtained PLD fluctuation information f (t) can be used for the belt drive control in a state adapted to the PLD fluctuation of the belt 103, and the belt drive control is appropriately performed. It can be carried out.
In the present embodiment, as described in the belt drive control example 2 above, the relationship between the belt movement position corresponding to the obtained PLD fluctuation information f (t) and the actual belt movement position is grasped in advance. The above rotation control is performed after grasping based on the average time required for the belt 103 to make one revolution or the belt circumferential length grasped in advance. As a result, the reference position (virtual home position) in one circumference of the belt can be determined without providing the home position mark 103a on the belt 103 or the mark detection sensor 104. Therefore, cost reduction can be achieved.
In the present embodiment, as described in the above-described PLD fluctuation recognition method 1, the belt circumferential distance (the distance between the rollers) between the two rollers 101 and 102 is the above-described f (t) = f. The allowable range X _err of each frequency component generated by approximation of (t−τ) is set so as to be within a predetermined total displacement error X _errT . Thereby, even if f (t) = f (t−τ) is approximated, the PLD fluctuation information f (t) can be obtained with sufficiently high accuracy.
In addition, when the belt 103 is a seam belt having a joint at at least one place in the belt circumferential direction, the joint portion is thicker than the other portions, or the physical properties have changed and the other portions. The elasticity may be different. In such a case, even if the joint part has the same thickness as the other part, the PLD of the joint part is greatly deviated from the PLD of the other part. According to the belt drive control device of the present embodiment, as described above, the PLD fluctuation can be specified with high accuracy even for the belt having the protruding PLD fluctuation. Therefore, even such a seam belt can be controlled with high accuracy by suppressing sudden belt speed fluctuation that may occur when the joint portion is wound around the driving roller.
Further, when the belt 103 is a multi-layer belt having a plurality of layers in the belt thickness direction, even if the belt thickness is the same, the PLD varies depending on the layer structure and the like, and belt speed variation occurs. According to the belt drive control device of the present embodiment, as described above, the PLD fluctuation is specified and the drive control is performed based on the PLD fluctuation. Therefore, it is possible to drive and control the multi-layer belt with high accuracy.
In addition, as described in the modification, the driving pulley 617 and the driven pulley 618 among the plurality of supporting rotating bodies have a plurality of teeth in the rotation direction, and the timing belt 619 includes the plurality of teeth. In the case of having teeth that mesh with each other, the PLD also fluctuates in this timing belt 619 and belt speed fluctuations occur. That is, the belt PLD fluctuation can occur without being limited to the shape and structure of the belt, and the belt moving speed fluctuates if the PLD fluctuation occurs. Therefore, not only the belt driven by the friction with the surface of the support roller like the intermediate transfer belt 10 but also the toothed belt such as the timing belt 619 in the modified example, the belt moving speed due to the PLD fluctuation occurs. obtain. Also for such a belt, as described in the above modification, it is possible to specify PLD fluctuation and perform drive control based on the PLD fluctuation, and to perform drive control with high accuracy.

The above description is the same even if the rotational angular velocity is converted into rotational angular displacement. This is because the rotational angular velocity is obtained by integrating the rotational angular velocities, and the relationship between the PLD fluctuation f (t) and the rotational angular displacement of the roller is obtained similarly. Specifically, the rotation angle displacement variation is obtained by removing the average increase (the inclination component of the rotation angle displacement) from the detected rotation angle displacement, and from the rotation angle displacement variation, the recognition method 1 described above for the rotation angular velocity variation. The PLD fluctuation f (t) is acquired by the same method as the recognition method 2 or the recognition method 3.
Further, in the above-described embodiment, when the belt 103 moves in the reverse direction, considering that the belt is rotating, the above-described explanation is that the delay time τ is Tb−τ (Tb: belt one rotation time). Replace it. At this time, 2 (Tb−τ) = 2Tb−2τ = Tb−2τ, and in the case of N (Tb−τ) (N: natural number), N (Tb−τ) = Tb−Nτ. That is, when the PLD fluctuation f (t) is detected using the FIR filter or IIR filter described in the present recognition method 2, if the delay time is processed as N (Tb−τ) time, the delay time processing becomes longer. However, the same applies to the delay time processing of Tb−Nτ time.
The above-described embodiment is an example of drive control of the intermediate transfer belt of the tandem type image forming apparatus. The present invention is useful for driving control of belts (paper conveyance belts, photoconductor belts, intermediate transfer belts, fixing belts, etc.) used in image forming apparatuses using electrophotographic technology, ink jet technology, and printing technology. Just as you did. This is because very high accuracy is required for drive control of the belt of such an image forming apparatus. Therefore, the present invention is also useful for an image forming apparatus other than a tandem type image forming apparatus or an apparatus other than an image forming apparatus for those requiring very high accuracy for belt drive control.

1 is a schematic configuration diagram of an entire copying machine according to an embodiment. The schematic diagram which shows the principal part of a belt apparatus. A graph showing the error rate, which is the ratio of the control value obtained when approximation is performed and the ideal control value when approximation is not performed to the ideal control value when the distance between rollers is changed . The control block diagram for demonstrating the recognition method 2 using a filter process. FIG. 5 is a control block diagram representing the control block diagram of FIG. FIG. 5 is a control block diagram expressing the control block diagram of FIG. 4 in another form (IIR type filter). FIG. 7B is a control block diagram in which the control block diagram of FIG. 6A is a discrete expression for digital processing. FIG. 3 is a schematic diagram showing a device configuration for detecting a belt home position in belt drive control example 1; Explanatory drawing for demonstrating control operation | movement of the same belt drive control example 1. FIG. Explanatory drawing for demonstrating the control action in the installation example 2 of a rotary encoder. Explanatory drawing for demonstrating the control action in the installation example 3 of a rotary encoder. Explanatory drawing for demonstrating the update process in Example 1. FIG. Explanatory drawing for demonstrating the update process in Example 2. FIG. 1 is a schematic configuration diagram showing an example of a direct transfer tandem image forming apparatus. 1 is a schematic configuration diagram illustrating an example of an intermediate transfer type tandem image forming apparatus. 6 is a graph showing an example of belt thickness unevenness (belt thickness deviation distribution) in the circumferential direction of an intermediate transfer belt of an intermediate transfer type tandem type image forming apparatus. The enlarged view when the belt part wound around the drive roller is seen from the axial direction of the drive roller. FIG. 3 is an explanatory diagram illustrating an example of a layer structure of an intermediate transfer belt provided in the copier according to the embodiment. The perspective view which shows the internal structure of the inkjet recording device which concerns on a modification. The side view of the mechanism part of the same inkjet recording device. FIG. 2 is a schematic configuration diagram illustrating a carriage drive mechanism provided in the ink jet recording apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Intermediate transfer belt 14,15,16 Support roller 18 Image formation part 40Y, 40M, 40C, 40K Photosensitive drum 101 1st roller 102 2nd roller 101a, 102a, 106b Rotary encoder 103 Belt 103a Home position mark 104 Mark detection Sensor 105 Drive roller 106 Drive motor 110, 410, 510 Controller 111, 112 Angular velocity detector 210 Conveying belt 214 Followed roller 215 Drive roller 419 PLD fluctuation data FIFO
610 Carriage 611 Recording head 617 Drive pulley 618 Driven pulley 619 Timing belt

Claims (25)

Belt drive control for performing drive control of the belt spanned across a plurality of support rotators including a driven support rotator that rotates along with the movement of the belt and a drive support rotator that transmits driving force to the belt. In the device
Among the plurality of supporting rotating bodies, the diameters are different from each other, or the degree to which the pitch line distance of the belt portion wound around the belt affects the relationship between the moving speed of the belt and the rotational angular speed of the belt is different from each other. Control means for performing the drive control based on the rotational information of the rotational angular displacement or rotational angular velocity of the support rotating body so as to reduce fluctuations in the moving speed of the belt caused by fluctuations in the pitch line distance in the circumferential direction of the belt. A belt drive control device comprising: Belt drive control for performing drive control of the belt spanned across a plurality of support rotators including a driven support rotator that rotates along with the movement of the belt and a drive support rotator that transmits driving force to the belt. In the device
Of the plurality of supporting rotating bodies, two supporting rotations having different diameters or different degrees of influence on the relationship between the moving speed of the belt and the rotational angular speed of the belt are different. Control means for performing the drive control based on the rotation information of the rotation angle displacement or the rotation angular velocity in the body so that the movement speed fluctuation of the belt caused by the belt thickness fluctuation in the circumferential direction of the belt is reduced. A belt drive control device. In the belt drive control device according to claim 1 or 2,
The control means uses the approximate rotation fluctuation information obtained by assuming that the rotation fluctuation information of the two support rotors obtained from the rotation information of the two support rotors detected at the same time are in phase with each other, A belt drive control device performing the drive control. In the belt drive control device according to claim 1 or 2,
The control means performs a process of reducing one value of two pieces of rotation fluctuation information having different phases included in the rotation information of one or both of the two support rotating bodies, and uses the processing result. A belt drive control device that performs the drive control. In the belt drive control device according to claim 4,
In the above processing, the belt moves the distance between the two support rotators on the belt movement path with respect to two rotation fluctuation information having different phases included in the rotation information of one or both of the two support rotators. A process of adding a delay time, which is a belt passing time required for the above, and a gain based on the above-described degree of the two support rotating bodies, and further performing the addition process on the processing result. (N ≧ 1) is repeated, and the gain obtained by raising the gain G in the first addition process to the power of 2 ⁿ⁻¹ is used as the gain in the ^n- th addition process, and the n-th addition is performed. A belt drive control device characterized in that the delay time at the time of processing is performed using a value obtained by multiplying the belt passage time by 2 ^n-1 . In the belt drive control device according to claim 4,
The two support rotators are arranged such that the ratio of the belt movement path length between the two support rotators and the belt total circumference is 2 Nb (Nb is a natural number),
In the above processing, the belt moves the distance between the two support rotators on the belt movement path with respect to two pieces of rotation fluctuation information having different phases included in the rotation information of one or both of the two support rotators. A process of adding a delay time, which is a belt passing time required for the above, and a gain based on the above-mentioned degree of the two supporting rotating bodies is added, and the result of the addition is further processed as Nb. The delay at the time of the n-th addition process is performed by using the gain G at the time of the first addition process multiplied by 2 ^n-1 as the gain at the time of the n-th addition process. A belt drive control device characterized in that it is performed using a time obtained by multiplying the belt passing time by 2 ^n-1 as time. In the belt drive control device according to claim 4,
In the above processing, the belt moves the distance between the two support rotators on the belt movement path with respect to two rotation fluctuation information having different phases included in the rotation information of one or both of the two support rotators. Output information is obtained by giving a delay time, which is a belt passing time required for the above, and a gain based on the above-mentioned degree of the two supporting rotating bodies, and the output information is fed back and added to the two rotation fluctuation information. A belt drive control device that performs processing. The belt drive control device according to claim 3, 4, 5, 6, or 7,
A belt drive control device comprising fluctuation information storage means for storing rotation fluctuation information for a period corresponding to a time required for the belt to make one revolution. In the belt drive control device according to claim 8,
The control means performs a process of obtaining the rotation fluctuation information again at a timing when a difference between the rotation fluctuation information stored in the fluctuation information storage means and the newly obtained rotation fluctuation information exceeds an allowable range. A belt drive control device. In the belt drive control device according to claim 3, 4, 5, 6, 7 or 8,
The belt drive control device, wherein the control means performs a process of obtaining the rotation variation information again at a predetermined timing. In the belt drive control device according to claim 3, 4, 5, 6, 7 or 8,
The belt drive control device, wherein the control means performs the drive control while performing a process for obtaining the rotation variation information. In the belt drive control device according to claim 3, 4, 5, 6, 7, 8, 9, 10 or 11,
Having past information storage means for storing at least one revolution of the belt for storing past rotation variation information;
The belt drive control characterized in that the control means performs the drive control using information obtained from past rotation fluctuation information stored in the past information storage means and newly obtained rotation fluctuation information. apparatus. A belt stretched over a plurality of support rotators including a driven support rotator that rotates along with the movement of the belt and a drive support rotator that transmits a driving force to the belt; and for driving the belt In a belt device including a drive source that generates a rotational driving force and a belt drive control device that performs drive control of the belt,
Among the plurality of supporting rotating bodies, the diameters are different from each other, or the degree to which the thickness or pitch line distance of the belt portion wound around the belt affects the relationship between the moving speed of the belt and the rotational angular speed of the belt is different from each other. Detecting means for detecting at least one of a rotational angular displacement or a rotational angular velocity in the two supporting rotating bodies;
A belt device using the belt drive control device according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 as the belt drive control device. The belt device of claim 13,
The belt device according to claim 1, wherein all of the two support rotators are driven support rotators that rotate along with the movement of the belt. The belt device according to claim 14, wherein
The belt device according to claim 1, wherein the driving source includes a feedback control unit that detects its own rotational angular displacement or rotational angular velocity and feeds back the rotational angular displacement or rotational angular velocity. The belt device of claim 13,
The belt device characterized in that the two support rotators include the drive support rotator. The belt device according to claim 13, 14, 15 or 16, wherein the belt drive control device according to claim 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 is used as the belt drive control device.
In order to grasp the reference belt movement position of the belt, it has mark detection means for detecting a mark indicating the reference position on the belt,
The belt device according to claim 1, wherein the control means of the belt drive control device acquires the rotation variation information based on a detection timing by the mark detection means and performs the drive control. The belt device according to claim 13, 14, 15 or 16, wherein the belt drive control device according to claim 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 is used as the belt drive control device.
The control means of the belt drive control device is configured to determine the average time required for the belt to make one turn of the belt or the belt circumference that has been previously grasped in relation to the relationship between the variation of the pitch line distance and the belt moving position. A belt device that performs the above-described drive control after grasping based on the above. In the belt device according to claim 13, 14, 15, 16, 17 or 18, wherein the belt drive control device according to claim 3 is used as the belt drive control device.
A belt device characterized in that a belt circumferential distance between the two supporting rotating bodies is set so that an error generated by the approximation falls within a predetermined allowable range. The belt device according to claim 13, 14, 15, 16, 17, 18 or 19,
The belt device according to claim 1, wherein the belt has a joint at at least one location in the belt circumferential direction. The belt device according to claim 13, 14, 15, 16, 17, 18, 19 or 20,
The belt device according to claim 1, wherein the belt has a plurality of layers in a belt thickness direction. The belt device according to claim 13, 14, 15, 16, 17, 18, 19, 20 or 21,
At least one of the plurality of supporting rotating bodies has a plurality of teeth over the rotation direction,
The belt device according to claim 1, wherein the belt includes a meshing portion that meshes with the plurality of teeth. A latent image carrier comprising a belt stretched over a plurality of support rotating members, a latent image forming unit for forming a latent image on the latent image carrier, and a developing unit for developing a latent image on the latent image carrier And an image forming apparatus provided with a transfer unit that transfers a visible image on the latent image carrier to a recording material.
An image forming apparatus using the belt device according to claim 13, 14, 15, 16, 17, 18, 19, 20, 21, or 22 as a belt device for driving the latent image carrier. A latent image carrier, a latent image forming unit for forming a latent image on the latent image carrier, a developing unit for developing a latent image on the latent image carrier, and a belt stretched around a plurality of support rotating members An intermediate transfer member, a first transfer unit that transfers a developed image on the latent image carrier to the intermediate transfer member, and a second transfer unit that transfers the developed image on the intermediate transfer member to a recording material. An image forming apparatus comprising:
An image forming apparatus using the belt device according to claim 13, 14, 15, 16, 17, 18, 19, 20, 21, or 22 as a belt device for driving the intermediate transfer member. A latent image carrier, a latent image forming unit for forming a latent image on the latent image carrier, a developing unit for developing a latent image on the latent image carrier, and a belt stretched around a plurality of support rotating members The recording material conveying member comprising the above and a visible image on the latent image carrier are directly transferred to the recording material conveyed by the recording material conveying member via the intermediate transfer member or not via the intermediate transfer member. An image forming apparatus comprising transfer means,
An image forming apparatus using the belt device according to claim 13, 14, 15, 16, 17, 18, 19, 20, 21 or 22 as a belt device for driving the recording material conveying member.

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