JP3814659B2 - Medium transport mechanism, control method therefor, and image forming apparatus including the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a medium transport mechanism that transports a planar medium in a predetermined direction, a control method therefor, and an image forming apparatus including the medium transport mechanism. In particular, the present invention relates to a recording medium such as a cut sheet by a roller. Medium suitable for serial printers and line printers that form a single completed image by continuously forming line-shaped partial images on the surface of the recording medium by the image forming means while quantitatively conveying The present invention relates to a transport mechanism and a control method thereof.
[0002]
[Prior art]
Conventionally, in a serial printer typified by an ink jet printer or the like, a recording sheet is conveyed to an image forming unit such as an ink head mechanism by a sheet conveying mechanism including a roller or the like. The paper transport mechanism transports the recording paper in a predetermined direction, and the image forming unit continuously outputs the partial images in a line shape in a direction (scanning direction) perpendicular to the transport direction with respect to the recording paper. To record. Thus, one completed image (completed image) is formed on the recording paper.
[0003]
The above-mentioned line-shaped partial image is a rectangular partial image when expressed strictly. The maximum length of the long side is the width in the scanning direction of the recording paper, and the short side is the length of the recording paper. The length is equal to the transport amount. Therefore, in other words, in order to form one complete image, the conveyance amount of the recording sheet by the sheet conveyance mechanism needs to match the length of the short side of the line-shaped partial image.
[0004]
If the conveyance amount of the recording paper and the length of the short side of the partial image do not match, a deviation occurs between the partial images, and the quality of the completed image is greatly impaired. Specifically, when the partial images overlap each other, the completed images are crushed (black stripes) due to partial overlap, and when the partial images are opened, white lines (white stripes) appear in the completed images. Occurs). Therefore, the shift of the partial image needs to be avoided as much as possible.
[0005]
Here, for example, in an ink jet printer, in general, a paper transport mechanism often uses a roller or the like that transports a recording paper using frictional force as a transporting unit. In the configuration using the conveying means by such a frictional force, in order to avoid misalignment between the partial images, a paper feed roller unit (recording medium supply means) is arranged on the upstream side in the conveying direction, and the downstream side A configuration in which a paper discharge roller portion (recording medium discharge means) is disposed in the ink head mechanism (image forming portion) is disposed between them is very preferably employed.
[0006]
If the recording paper conveyed during image formation bends, the recording paper rises or sinks from a predetermined position, so that the partial images tend to be misaligned. Therefore, the two feeding means of the paper feed roller unit and the paper discharge roller unit are provided, and the paper feed roller unit has a carrying capacity smaller than the paper discharge roller unit and larger in carrying power. Set to.
[0007]
As a result, the main conveyance of the recording paper is the upstream paper feed roller unit, but the conveyance amount itself is larger in the downstream paper discharge roller unit. Therefore, the recording paper before image formation is pushed out with a large frictional force on the upstream side, and the recording paper is conveyed while being pulled with a light frictional force on the downstream side. As a result, it is possible to convey the recording paper while maintaining the tensioned state, and it is possible to reduce the frictional force of the paper discharge roller portion, and thus it is possible to reduce the influence on the formed image.
[0008]
In addition, since the frictional force of the roller or the like slightly changes depending on the ambient temperature, the conveying ability of the conveying means such as the roller varies depending on the temperature change. Therefore, a technique for measuring the environmental temperature and using it for correcting the conveyance capacity is known.
[0009]
As a specific example of the above technique, for example, there is a printer disclosed in Japanese Patent Laid-Open No. 1-110172. In this printer, the transport amount of the recording paper is determined based on the output obtained from the sensor for detecting the leading edge and the trailing edge of the recording paper, and the temperature measured by the thermistor as the temperature detecting means. Based on this, the control unit corrects the carry amount.
[0010]
More specifically, the temperature change measured based on the temperature-resistance characteristics of the thermistor is converted into a voltage change. Then, this is further A / D converted, and the motor rotation correction amount is added to or subtracted from the motor rotation speed with reference to a table showing the relationship between the temperature (actually voltage) and the conveyance amount prepared in advance. Then, the conveyance amount of the recording paper is corrected. As a result, the printer can print at an accurate position.
[0011]
If a frame line or ruled line is printed in advance on the recording paper, it must be printed after being aligned so as to correspond to the frame line or ruled line. The above-mentioned printer is used for such alignment applications, and is not intended to avoid misalignment between partial images. However, it is a technique that enables finer alignment in a serial printer. Yes.
[0012]
[Problems to be solved by the invention]
However, the conventional serial printer has a problem that the partial images tend to be misaligned at the final stage of image formation, and deterioration in image quality cannot be avoided.
[0013]
In other words, if the recording paper is gradually transported and the recording paper is removed from the paper feed roller section at the final stage, the recording paper is transported in a state where the recording paper is stretched instead of the paper roller section that has been mainly functioning until now. Therefore, it is carried only by the paper discharge roller unit that has been functioning to maintain the above.
[0014]
As described above, the transport amount of the paper discharge roller unit is set to be larger than the transport amount of the paper feed roller unit, and the upstream paper feed roller unit presses the recording paper with a strong frictional force. Conveying. Thereafter, when the recording paper is removed from the upstream side paper supply roller section, the recording paper is transported by a larger transport amount than before. As a result, the conveyance amount of the recording paper does not match the length of the short side of the partial image, and the image deterioration phenomenon such as white streaks is likely to occur.
[0015]
Conventionally, the trailing edge of the recording paper, which is the final stage of image formation, does not form an image as a margin. On the other hand, in recent years, there is a tendency to form an image as large as possible on the entire surface of the recording paper, and it is preferable to make the margin as small as possible. However, if the image deterioration phenomenon is likely to occur at the final stage as described above, the above tendency cannot be dealt with.
[0016]
Further, although the technique disclosed in Japanese Patent Application Laid-Open No. 1-110172 allows finer alignment in consideration of temperature change, it does not assume a change in the conveyance amount at the final stage of image formation. The problem cannot be addressed. That is, the technique disclosed in the above publication is a technique that corrects only the conveyance amount of a conveyance unit (conveyance roller) that is a main component of conveyance of the recording paper. Therefore, no consideration is given to the fact that the main subject of transfer from the paper feed roller portion to the paper discharge roller portion at the final stage.
[0017]
Further, especially in a sheet conveying means using a frictional force such as a roller, the conveyance amount is slightly different depending on the type of recording sheet. For example, the conveyance amount of the recording paper changes slightly according to the thickness thereof, and the conveyance amount also changes because the frictional force varies depending on the surface state of the recording paper. Therefore, the type of recording paper must be taken into consideration for the correction of the carry amount. However, the conventional technique including the technique of the above-mentioned Japanese Patent Application Laid-Open No. 1-110172 does not take that point into consideration.
[0018]
The present invention has been made in view of the above problems, and an object thereof is to provide a medium transport mechanism capable of stably transporting a medium such as recording paper and a control method therefor, and such a medium transport mechanism. And an image forming apparatus that can reliably avoid the occurrence of misalignment between partial images at the final stage of image formation.
[0019]
[Means for Solving the Problems]
  In order to solve the above-described problem, the medium transport mechanism according to the present invention includes a supply unit disposed on the upstream side in the transport direction for transporting a planar medium, and a discharge unit disposed on the downstream side. Further, the medium transport by the supply means is a medium transport mechanism having a small transport amount and a large transport force as compared with the medium transport by the discharge means, and at least a control means for controlling the operation of the discharge means.,
  A medium presence detecting means for detecting the presence or absence of the medium on the upstream side in the medium transport direction as viewed from the supply means;
  The control means performs control to change the medium conveyance amount by the discharge means in accordance with the conveyance amount of the supply means when the main body for conveying the medium is changed from the supply means to the discharge means.Also, based on the detection result of the medium presence detection means and the transport amount of the supply means, the time when the trailing edge of the medium is removed from the supply means is predicted, and the supply means is operated for a predetermined time until this time is reached. Depending on whether or not the main body that transports the medium determines the timing when the supply means replaces the discharge means, and performs control to change the transport amount of the discharge meansIt is characterized by that.
[0020]
If the above-mentioned difference is provided in the conveyance capability between the supply means and the discharge means, the medium can be conveyed in a stretched state so as not to bend between these conveyance means. When the rear end of the medium is removed from the medium, the medium is mainly transported by a transport amount different from the transport amount up to that point, instead of the supply means and the discharge means.
[0021]
Therefore, according to the above configuration, when the main body that transports the medium is changed from the supply unit to the discharge unit, the transport amount of the medium by the discharge unit is changed in accordance with the transport amount of the supply unit. Thereby, while a part of the medium exists between the supply means and the discharge seed end, the medium can always be transported by a substantially constant transport amount. Therefore, the medium supply unit according to the present invention can be suitably used for an application for conveying a medium constantly at a predetermined interval, for example, for a paper conveyance means of a printer.
[0023]
According to the above configuration, by detecting the presence of the medium with the medium presence detection unit, it is possible to substantially detect the remaining amount of the medium with a simple configuration. In addition, since the transport capability of the supply unit is constant, it is possible to accurately determine the timing at which the main body that transports the medium replaces the discharge unit based on the remaining amount of the medium and the transport capability of the supply unit. As a result, the medium can be reliably transported with a substantially constant transport amount.
[0024]
In addition to the above-described configuration, the medium transport mechanism according to the present invention includes an input unit that can input a medium type to the control unit, and the control unit is configured based on the type of the medium. Control for correcting a change in the transport amount of the discharge means is performed.
[0025]
Since the discharge means is set to a transport force smaller than that of the supply means, depending on the type of the medium, the medium cannot always be transported constantly, and the transport amount may be slightly different.
[0026]
Therefore, according to the above configuration, the control unit corrects the degree of change in the conveyance amount by inputting the medium type to the input unit. Therefore, even when the main body of the medium is changed from the supply means to the discharge means, it becomes possible to reduce the influence on the transport amount due to the type of the medium, and the medium can be transported more reliably with a substantially constant transport amount. be able to.
[0027]
The medium transport mechanism according to the present invention is characterized in that, in addition to the above configuration, the medium presence detection unit also serves as the input unit that detects the type of the medium and inputs the detection result to the control unit.
[0028]
According to the above configuration, the medium presence detecting unit also serves as the medium type detecting unit that detects not only the presence of the medium but also the type of the medium. Therefore, both the remaining amount of the medium and the type of the medium are set as one unit. Can be detected and input to the control means. As a result, the manufacturing cost can be reduced and the device configuration can be simplified.
[0029]
  In order to solve the above problems, a control method for a medium transport mechanism according to the present invention includes a supply unit disposed on the upstream side in the transport direction for transporting a planar medium, and a discharge unit disposed on the downstream side. ,Medium presence detecting means for detecting the presence or absence of the medium upstream of the medium conveying direction as viewed from the supply means;In the method for controlling the medium transport mechanism, the transport of the medium by the supply unit is smaller than the transport of the medium by the discharge unit and the transport force is large.The detection result of the medium presence detection meansBased on the remaining amount of the medium upstream of the supply means and the conveying capacity of the supply means,Depending on whether or not the supply means is operated for a predetermined time until the rear end of the medium is deviated from the supply means and this time is reached,A step of determining a timing at which the rear end of the medium is removed from the supply means; and a step of changing a conveyance amount by the discharge means when the rear end of the medium to be conveyed is removed from the supply means. .
[0030]
According to the above method, based on the remaining amount of the medium and the conveying capability of the supply unit, the timing at which the main body conveying the medium replaces the discharge unit is accurately determined, and based on this, the medium conveyance amount by the discharge unit is supplied. It is precisely changed according to the transport amount of the means. Therefore, as long as a part of the medium exists between the supply unit and the discharge seed end, the medium can be always transported by a substantially constant transport amount. Therefore, the control method according to the present invention can be suitably used for controlling a unit that always conveys a medium at a predetermined interval, for example, a sheet conveying unit of a printer.
[0031]
In addition to the above method, the control method for the medium transport mechanism according to the present invention is characterized in that the change in the transport amount of the discharge means is corrected based on the type of the medium.
[0032]
According to the above method, the type of medium that may greatly affect the transport amount of the discharge means is used for control. Even when the main body of the medium is changed from the supply means to the discharge means, it is possible to reduce the influence on the transport amount due to the type of the medium, and the medium can be transported more reliably with a substantially constant transport amount. it can.
[0033]
The control method of the medium transport mechanism according to the present invention is characterized in that, in the above method, the type of the medium is at least one of a thickness of the medium and a surface roughness of the medium.
[0034]
Roller means is generally used as a transport means for transporting a planar medium. In this roller means, frictional force and pressure contact force with the medium surface are important transport conditions. Therefore, in the above method, since at least one of the thickness of the medium and the surface roughness of the medium, which is likely to directly affect the change of the frictional force and the pressure contact force, is used for the control, the transport amount depends on the type of the medium. Can be further reduced, and the medium can be transported more reliably with a substantially constant transport amount.
[0035]
In order to solve the above problems, an image forming apparatus according to the present invention includes a medium transport mechanism having the above-described configuration as a recording medium transport unit, and further includes an image forming unit between a supply unit and a discharge unit. Yes.
[0036]
According to the above configuration, a recording medium such as a sheet can be conveyed in a stable state at the image forming portion. As a result, it is possible to realize higher-quality image formation by applying the present invention to a printer such as an ink jet printer that is required to form a precise image.
[0037]
DETAILED DESCRIPTION OF THE INVENTION
[Embodiment 1]
The first embodiment of the present invention will be described below with reference to FIGS. Note that the present invention is not limited to this.
[0038]
A medium transport mechanism and a control method thereof according to the present invention are provided with transport means for transporting a medium in the order of supply means and discharge means from the upstream side in the transport direction for transporting a planar medium, and at least a part of the medium is provided. During the period existing between the supply means and the discharge means, the transport amount of the medium is kept constant.
[0039]
Usually, among the above transport means, the supply means has a larger transport force than the discharge means, but the transport amount is small. Therefore, if the medium being transported is removed from the supply means and transported only by the discharge means, the result is as follows. The transport amount will increase. Therefore, when the main body that transports the medium is changed from the supply unit to the discharge unit by the control of the control unit, the transport amount of the medium by the discharge unit is changed in accordance with the transport amount of the supply unit.
[0040]
An image forming apparatus according to the present invention includes the medium transport mechanism as a recording medium transport unit, and is particularly preferably applied to a serial printer. In a serial printer, a line-shaped partial image is continuously formed on a recording medium being conveyed. Therefore, it is important to align the partial images. It is possible to obtain a high-quality completed image by avoiding misalignment.
[0041]
In this embodiment, an ink jet printer which is a typical serial printer will be described as an example.
[0042]
As shown in FIGS. 1 and 2, the ink jet printer according to the present embodiment includes an ink head mechanism (image forming unit) 1 disposed with respect to a sheet conveyance path 10, a sheet conveyance mechanism (medium conveyance mechanism / recording medium conveyance). Means) 2 and a paper entry sensor (medium presence detecting means) 3a, and further, as shown in FIG. 1, a control unit (control means) 4 is provided. Of course, the configuration of the ink jet printer is not limited to this, and includes various other members and means such as a paper feed tray and a paper discharge tray. However, in FIG. 1 and FIG. Only the principal part of the ink jet printer is shown as a block diagram or schematic diagram. In addition, the arrangement of each means and member in the block diagram of FIG. 1 substantially corresponds to the actual arrangement.
[0043]
As shown in FIG. 2, the ink head mechanism 1 includes an ink carriage 11 and a platen 12, which are opposed to each other via a paper transport path 10. The ink carriage 11 continuously forms line-shaped partial images on the surface of a sheet (recording sheet) 6. The configuration is generally configured to be movable in a direction (scanning direction) perpendicular to the conveyance direction of the paper 6 by a rail-shaped support member (not shown).
[0044]
As shown in FIGS. 1 and 2, the sheet transport mechanism 2 includes two transport units, a paper feed roller unit (supply unit) 21 and a paper discharge roller unit (discharge unit) 22, and a driving motor unit ( Drive means) 23. When viewed from the ink head mechanism 1, the paper feed roller unit 21 is disposed on the upstream side in the conveyance direction of the paper 6, and the paper discharge roller unit 22 is disposed on the downstream side. That is, since the ink head mechanism 1 is disposed between the paper feed roller unit 21 and the paper discharge roller unit 22, when viewed from the upstream side in the conveyance direction of the paper 6, the paper feed roller unit 21, the ink head mechanism 1, The paper discharge roller unit 22 is arranged so as to face the paper transport path 10 in this order.
[0045]
The conveyance of the paper 6 by the paper feed roller unit 21 is smaller than the conveyance of the paper 6 by the paper discharge roller unit 22, and the conveyance force is large. As a result, the main conveyance of the paper 6 is the upstream paper feed roller unit 21, but the conveyance amount itself is larger in the downstream paper discharge roller unit 22. For this reason, the paper 6 before image formation (printing) is pushed out with a large frictional force on the upstream side, and the paper 6 is conveyed while being pulled with a light frictional force on the downstream side. As a result, the paper 6 can be conveyed in a stretched state so as not to bend before and after the ink head mechanism 1.
[0046]
Specifically, since the paper discharge roller unit 22 is on the downstream side of the ink head mechanism 1, an image is formed with ink on the surface of the paper 6 conveyed by the paper discharge roller unit 22. However, the ink of the image immediately after formation is not completely dried, and the image itself is not fixed on the surface of the paper 6. Therefore, when the paper discharge roller unit 22 strongly presses the paper 6 with a large surface area, the image is disturbed on the paper 6.
[0047]
Therefore, in general, among the two types of transport means, the paper feed roller unit 21 is a main body for transporting the paper 6, while the paper discharge roller unit 22 is stretched so as not to bend the paper 6. In this state, it must be transported lightly enough to be along the paper transport path 10. Accordingly, the paper feed roller unit 21 strongly presses the paper 6 with a large surface area in order to generate a large frictional force between the paper feed roller 21 a and the surface of the paper 6. In contrast, the paper discharge roller unit 22 lightly presses the paper 6 with a small surface area.
[0048]
As a result, at the time of printing by the ink head mechanism 1, the paper 6 can be transported while maintaining the tensioned state without being bent before and after the ink head mechanism 1. Therefore, a situation in which the paper 6 floats up or sinks from a predetermined position at the print site on the platen 12 is avoided.
[0049]
Further, the paper discharge roller unit 22 on the downstream side of the ink head mechanism 1 conveys the paper 6 with a reduced frictional force on the surface of the paper 6 after printing. Therefore, it is possible to reliably prevent an image that has not been fixed on the sheet 6 immediately after formation from being disturbed. As a result, no deviation occurs between the line-shaped partial images continuously formed by the ink carriage 11, and the influence on the image in the unfixed state on the surface of the paper 6 is avoided, so that the high quality is achieved. An image can be formed.
[0050]
The force applied when the paper feed roller unit 21 and the paper discharge roller unit 22 make contact with the surface of the paper 6 while pressing the surface of the paper 6 with an arbitrary surface area in order to generate a frictional force for conveying the paper 6. Is expressed as pressure contact. Further, the force involved in transporting the paper 6 including the frictional force and the pressure contact force applied to the paper 6 by the paper feed roller unit 21 and the paper discharge roller unit 22 is collectively expressed as a transport force.
[0051]
The paper feed roller unit 21 includes a pair of roller members, a paper feed roller 21a serving as a driving roller, and a pinch roller 21b serving as a driven roller disposed so as to face the paper feed path 10 via the paper transport path 10. Both the paper feed roller 21a and the pinch roller 21b have a cylindrical shape. When the paper 6 is sandwiched between these roller members, the paper feed roller 21a conveys the paper 6 with a sufficient pressure contact force. be able to.
[0052]
The paper discharge roller unit 22 also includes a pair of roller members including a paper discharge roller 22a as a driving roller and a spur (or star wheel) 22b as a driven roller disposed opposite to the paper transfer path 10 through the paper conveyance path 10. Contains. The paper discharge roller 22a has a cylindrical shape like the paper feed roller 21a and the pinch roller 21b. On the other hand, the spur 22b has a substantially star shape in cross section, as shown in FIG. For this reason, the paper 6 is contacted primarily (linearly) at the tip of the star-shaped collar portion (portion protruding outward from the center). Therefore, since the spur 22b is lightly touching in a pinpoint manner on the surface of the sheet 6 on which the image is formed, the sheet 6 can be conveyed with a small pressure contact force, and is not fixed. Disturbing the image in the state is avoided.
[0053]
The configuration of each roller member is not particularly limited, but in an ink jet printer, generally, a non-slip ceramic material is sprayed on the surface of a metal shaft (roller) as a paper feed roller 21a by thermal spraying or the like. A coated one is used, and a rubber roller is used as the pinch roller 21b. Further, as the paper discharge roller 22a, a rubber roller is used similarly to the pinch roller 21b. Further, as the spur 22b, an integrally molded product of stainless steel (SUS) and resin is used, and for example, an integrally molded product in which the main part is made of resin and the above-described collar part is made of SUS can be cited.
[0054]
The degree of difference in the transport amount between the paper feed roller unit 21 and the paper discharge roller unit 22 is not particularly limited. Practically, the transport amount of the paper discharge roller unit 22 may be set to be several percent higher than the transport amount of the paper 6 by the paper feed roller unit 21. Further, the transport amount referred to here is the length of the sheet 6 that is transported per unit time in the transport direction of the sheet 6, and is appropriately determined according to the size and structure of the ink jet printer, the print capability per unit time, and the like. It is set and is not particularly limited.
[0055]
In addition, the degree of difference in conveying force between the paper feed roller unit 21 and the paper discharge roller unit 22 is not particularly limited, and may be practically due to a difference in configuration of the driven roller. That is, the difference in the pressure contact force against the paper 6 due to the difference in the shape of the pinch roller 21b and the spur 22b, which are driven rollers, results in the frictional force between the surface of the paper 6 and the paper feed roller unit 21 or the paper discharge roller unit 22. There is also a difference. Therefore, if such a driven roller has the above-described structural difference, the conveying force is not particularly limited numerically.
[0056]
As shown in FIGS. 1 and 2, the drive motor unit 23 drives a paper feed roller 21a and a paper discharge roller 22a, which are drive rollers included in the paper feed roller unit 21 and the paper discharge roller unit 22. The thick line arrows in FIG. In the present embodiment, both the paper feed roller 21a and the paper discharge roller 22a are driven by a single drive motor unit 23, but each drive roller is driven by a separate drive means. It may be like this.
[0057]
Further, as will be described later, the operation of the drive motor unit 23 is controlled by the control of the control unit 4 so as to change at least the conveyance speed of the paper discharge roller unit 22. As the drive motor unit 23, a stepping motor or a DC motor with an encoder can be used, and the conveyance speed can be changed by switching the rotation speed of these motors. Of course, the configuration of the drive motor unit 23 is not limited to this.
[0058]
In FIG. 2, for convenience of explanation, the drive motor unit 23 is schematically illustrated as a block diagram, and the drive system is also schematically illustrated by a bold arrow as in FIG. 1.
[0059]
As shown in FIGS. 1 and 2, the paper entry sensor 3 a is arranged on the upstream side in the transport direction of the paper 6 when viewed from the paper feed roller portion 21, and detects the presence or absence of the paper 6. Yes. The detection result of the paper entry sensor 3a indicates a state in which the paper 6 exists on the upstream side of the paper feed roller unit 21 and printing is possible by the conveyance of the paper feed roller unit 21. The control unit 4 performs control for starting the printing operation by the ink head mechanism 1. As will be described later, the detection result of the paper entry sensor 3a is also used for control of changing the transport amount of the paper discharge roller unit 22 by determining the timing at which the main body that transports the paper 6 replaces the paper discharge roller unit 22. It has become so.
[0060]
The specific configuration of the paper entry sensor 3a is not particularly limited, and can detect whether or not the paper 6 is present in the paper transport path 10 at least upstream of the paper feed roller unit 21. I just need it. In the present embodiment, for example, as shown in FIG. 2, a contact type having a contact member 31 protruding with respect to the paper transport path 10 is used.
[0061]
In the contact-type paper entry sensor 3a, for example, the contact member 31 is normal to the planar paper conveyance path 10 so as to prevent the conveyance of the paper 6 when the paper 6 is not in the paper conveyance path 10. It protrudes from the direction, and the input as a sensor is in an OFF state. In FIG. 2, it is indicated as OFF by a broken line.
[0062]
On the other hand, when the paper 6 is carried into the paper transport path 10, the tip of the contact member 31 comes into contact with the tip of the paper 6, and as the paper 6 is transported as it is, the tip of the contact member 31. Moves to the downstream side so as to be dragged, and continues to contact the surface of the paper 6. In this state, the contact member 31 that was initially upright in the normal direction is inclined so that the tip is on the downstream side, and the input as a sensor is turned on. In FIG. 2, it is indicated as ON by a solid line.
[0063]
After that, when the conveyance of the paper 6 is continued, the rear end of the paper 6 is disengaged from the front end of the contact member 31, so that the contact member 31 returns to the off state protruding in the normal direction from the inclined state.
[0064]
Therefore, if the paper input sensor 3a is in the off state, the detection result is that the paper 6 is not present. If the paper input sensor 3a is in the on state, the paper 6 is present on the upstream side of the paper feed roller unit 21. The detection result. The control unit 4 uses these detection results for control.
[0065]
The control unit 4 controls at least the operation of the paper discharge roller unit 22. Here, in the ink jet printer of the present embodiment, as described above, the drive motor unit 23 drives the drive rollers included in the paper feed roller unit 21 and the paper discharge roller unit 22. For this reason, by controlling the operation of the drive motor unit 23, the operations of both the paper feed roller unit 21 and the paper discharge roller unit 22 are indirectly controlled.
[0066]
Further, in the configuration in which the medium transport mechanism according to the present invention is provided as the paper transport mechanism 2 of the ink jet printer as in this embodiment, the control of the medium transport mechanism and the control of the entire ink jet printer are the same control means. It is preferred that Therefore, the control unit 4 in the present embodiment controls the entire inkjet printer as shown in FIG.
[0067]
Specifically, upon receiving an output (detection result) from the paper entry sensor 3a, the control unit 4 controls the operation of the drive motor unit 23 and the operation of the ink head mechanism 1. . In the present embodiment, as shown in FIG. 1, the paper receiving sensor 3 a not only detects the presence of the paper 6 but also outputs the detection result to the counter 41 included in the control unit 4. The number of prints may be counted. The control unit 4 may also use this number of prints for various controls.
[0068]
In the paper transport mechanism 2, the control unit 4 keeps the transport amount of the paper 6 constant during a period in which at least a part of the paper 6 exists between the paper feed roller unit 21 and the paper discharge roller unit 22. Control is performed so as to change the transport amount of the paper discharge roller unit 22 so as to be maintained. In other words, the control unit 4 determines the conveyance amount of the paper 6 by the paper discharge roller unit 22 when the main body that transports the paper 6 is changed from the paper supply roller unit 21 to the paper discharge roller unit 22. Control to change according to the transport amount.
[0069]
Specifically, as described above, when the partial images are continuously formed, the paper 6 needs to be conveyed in a stretched state so as not to bend between the paper feed roller unit 21 and the paper discharge roller unit 22. There is. Therefore, the peripheral speed of the paper feed roller 21a, that is, the transport speed of the paper 6 is set to V₁And the peripheral speed of the paper discharge roller 22a is V₂Then, as described above, V₁<V₂It is set to become.
[0070]
In addition, at this time, the conveyance force of the paper feed roller 21a is larger than the conveyance force of the paper discharge roller 22a. Therefore, the main component of conveyance of the paper 6 is the paper feed roller 21a (the paper feed roller unit 21). Yes. Therefore, the conveyance speed of the paper 6 is V₁It has become. At this time, the transport amount of the paper discharge roller 22a is larger than that of the paper feed roller 21a. However, during actual transport, the paper discharge roller portion 22 having a small transport force slips on the surface of the paper 6 and is constant. The paper 6 is transported by the transport amount.
[0071]
However, when the trailing edge of the paper 6 is removed from the paper feed roller 21a, the main carrier of the paper 6 is the paper discharge roller 22a, that is, the paper discharge roller unit 22, and thus the transport speed V until now.₁The conveyance of the paper 6 was a larger peripheral speed V than this.₂It becomes the conveyance speed by. Therefore, although the paper 6 is not bent between the paper feed roller unit 21 and the paper discharge roller unit 22, the paper 6 is transported with a larger transport amount than before, and a deviation occurs between the partial images. I will let you.
[0072]
Therefore, in the control unit 4, when the output from the paper input sensor 3a changes from the on state to the off state, the peripheral speed V of the paper feed roller 21a is reached.₁On the basis of the above, after determining the time for the trailing edge of the paper 6 to be removed from the paper feed roller 21a, the paper discharge speed of the paper 6 by the paper discharge roller section 22 (that is, the paper 6 conveyance amount) is reduced. In order to make the conveyance speed (conveyance amount) substantially the same as that of the paper roller unit 21, the peripheral speed of the paper discharge roller 22a is set to V₂Control to decrease from.
[0073]
That is, the change timing of the conveyance amount by the paper discharge roller unit 22 is set at a time point when the trailing edge of the conveyed paper 6 is removed from the paper supply roller unit 21. 21, with reference to the point in time when the sheet receiving sensor 3a on the upstream side of the sheet 21 detects that the sheet 6 is not present, the conveyance capability (circumferential speed V) of the sheet feeding roller unit 21₁).
[0074]
Therefore, in the present invention, the timing at which the trailing edge of the paper 6 is removed from the paper feed roller unit 21 based on the remaining amount of the paper 6 on the upstream side of the paper feed roller unit 21 and the conveyance capability of the paper feed roller unit 21. It comes to judge. Therefore, the remaining amount of the sheet 6 may be detected by a simple method such as the presence or absence of the sheet 6 by the sheet receiving sensor 3a as in the present embodiment, or another sensor unit may be provided, The remaining amount of 6 may be detected as a specific numerical value, and is not particularly limited.
[0075]
The control for changing the transport amount of the paper 6 will be described in detail below with reference to FIGS.
[0076]
First, as shown in the flowchart of FIG. 3, when the paper 6 is fed as a step (hereinafter abbreviated as “S”) 11, driving of the paper feed roller unit 21 and the paper discharge roller unit 22 is started. At this time, as shown in the time chart of the peripheral speed in FIG. 4, the peripheral speed (solid line in the figure) of the paper feed roller unit 21 is V₁The peripheral speed of the paper discharge roller section 22 (the dashed line in the figure) is V₁V several percent larger than₂It has become. In FIG. 4, the vertical axis represents the peripheral speed V, and the horizontal axis represents time T.
[0077]
Next, in S12, as the paper 6 is fed, whether or not the paper 6 has been carried to the upstream side of the paper feed roller portion 21 in the paper transport path 10, that is, whether or not the paper feed sensor 3a is in an on state. Determine. If it is not in the on state (NO in the figure, off state), this step is repeated. If it is in the on state (YES in the figure), the ink head mechanism 1 starts the printing operation.
[0078]
After the paper feed sensor 3a detects the carry-in of the paper 6, the paper 6 is transported to the print site (between the ink carriage 11 and the platen 12) by driving the paper feed roller 21a, and the printing operation is started. In addition, the time when the paper receiving sensor 3a is turned on is set to t₁Then, as shown in FIG. 4, the peripheral speeds of the paper feed roller unit 21 and the paper discharge roller unit 22 at this time are both V₁And V₂Remains.
[0079]
Thereafter, a line-shaped partial image is formed on the surface of the paper 6 by the operation of the ink carriage 11 in the scanning direction and the ejection of ink based on the image data under the control of the control unit 4, and the short side of the partial image The paper 6 is conveyed by an equal length. Therefore, there is no deviation between the partially formed partial images, and a single image is obtained.
[0080]
At this time, as shown in FIG. 5A, the paper input sensor 3 a is in an on state, and it is output to the control unit 4 that the paper 6 exists on the upstream side of the paper feed roller unit 21. . In addition, as shown in FIG.₁Thereafter, the peripheral speeds of the paper feed roller unit 21 and the paper discharge roller unit 22 are both V.₁And V₂It remains unchanged.
[0081]
Thereafter, in S14, it is determined whether or not the paper input sensor 3a is turned off. If it remains in the ON state (NO in the figure), the process proceeds to S18, where the normal transport amount, that is, the peripheral speed V of the paper feed roller unit 21 shown in FIG.₁And the peripheral speed V of the paper discharge roller section 22₂The conveyance of the paper 6 is continued without change.
[0082]
On the other hand, if the paper input sensor 3a is turned off (YES in the figure), the rear end of the paper 6 is detached from the paper input sensor 3a as shown in FIG. The remaining portion of the sheet 6 is reduced on the upstream side. Therefore, the process proceeds to S15, and the time when the trailing edge of the paper 6 is removed from the paper feed roller unit 21 from the transport amount of the paper feed roller unit 21 (t in FIG. 4)._Three) And predict this t_ThreeIt is determined whether or not the paper feed roller unit 21 has been operated for a predetermined time until reaching the value.
[0083]
Here, as shown in FIG. 4, the point in time when the paper input sensor 3a is turned off is indicated by t.₂At this point, the peripheral speeds of the paper feed roller unit 21 and the paper discharge roller unit 22 are still V₁And V₂Remains. And t_ThreeTime to reach_Three-T₂Corresponds to the predetermined time. The predetermined time t_Three-T₂, In advance, the peripheral speed V of the paper feed roller unit 21₁It is preferable to calculate from the above and store it in a storage means (not shown).
[0084]
In S15, the paper feed roller unit 21 is set for a predetermined time (t_Three-T₂) Time t when the paper receiving sensor 3a is not in operation, that is, when the paper receiving sensor 3a is turned off.₂To t_ThreeIf not reached (NO in the figure), the process proceeds to S19, and similarly to S18, the normal transport amount, that is, the peripheral speed V of the paper feed roller unit 21 shown in FIG.₁And the peripheral speed V of the paper discharge roller section 22₂The conveyance of the paper 6 is continued without change.
[0085]
On the other hand, in S15, the paper feed roller unit 21 is set for a predetermined time (t_Three-T₂) Time t during which the sheet receiving sensor 3a is turned off₂To t_ThreeIs reached (YES in the figure), the process proceeds to S16, and the transport amount of the paper discharge roller unit 22 is changed. Specifically, as shown in FIG. 4, the time t when the trailing edge of the paper 6 is removed from the paper feed roller unit 21._Three, The peripheral speed V of the paper discharge roller section 22₂To reduce the peripheral speed V_ThreeAnd The peripheral speed of the paper discharge roller unit 22 is V_ThreeThe conveyance amount of the paper 6 at the time becomes the peripheral speed V of the paper feed roller unit 21.₁It becomes the same value as the conveyance amount of the paper 6 by.
[0086]
In this embodiment, since both the paper feed roller unit 21 and the paper discharge roller unit 22 are driven by a single drive motor unit 23, as shown in FIG._Three, The peripheral speed of the paper discharge roller unit 22 is V_ThreeAt the same time, the peripheral speed of the paper feed roller unit 21 is also V₁To V_FourTo drop. Of course, since it is not necessary to reduce the peripheral speed of the paper feed roller unit 21, the peripheral speed of the paper feed roller unit 21 is V when the driving means is different.₁Should be maintained.
[0087]
In S17, a final partial image is formed on the paper 6, and the printing operation is completed. Thereafter, the printed paper 6 is discharged to a paper discharge tray (not shown). Thereby, a series of printing operations in the present invention is completed.
[0088]
As described above, in this embodiment, printing or printing is performed by a serial recording head (ink head mechanism) while a predetermined amount of a recording medium such as a sheet used as a conveying unit by a frictional force of a roller unit is conveyed. In the serial printer, when the trailing end of the recording medium is removed from the conveying means on the upstream side of the recording head, the conveying amount of the conveying means on the downstream side of the recording head is changed.
[0089]
Therefore, at the final stage of printing or printing, the recording medium is not transported by a larger transport amount than before, so that the recording surface (the surface of the recording medium) deteriorates recording quality such as white streaks. And high quality printing and printing can be realized.
[0090]
Further, the timing at which the trailing edge of the recording medium deviates from the upstream conveying means is assumed by the control means on the basis of the signal from the recording medium presence detection sensor further upstream, so the downstream conveying can be performed more reliably. The conveyance amount of the means can be changed.
[0091]
[Embodiment 2]
The second embodiment of the present invention will be described below with reference to FIGS. Note that the present invention is not limited to this. For convenience of explanation, members having the same functions as those used in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0092]
In the first embodiment, the control for changing the transport amount of the paper discharge roller unit 22 by the control unit 4 uses the presence / absence of the paper 6 output from the paper input sensor 3a. In the form, in addition to this, the type of the paper 6 is also used. That is, in the present embodiment, not only the output of the paper input sensor 3a but also the type of the paper 6 can be input to the control unit 4, which is also used for control.
[0093]
Specifically, as shown in FIG. 6 or FIG. 7, the inkjet printer according to the present embodiment is substantially the same as the configuration described in the first embodiment, but only the configuration of the sensor is different.
[0094]
In FIG. 6, a paper type detection sensor 3 b that detects the type of the paper 6 is separately provided in addition to the paper insertion sensor 3 a, and the detection result is output to the control unit 4. On the other hand, in FIG. 7, a composite sensor 3c configured to serve both as the paper input sensor 3a and the paper type detection sensor 3b is provided instead of the paper input sensor 3a. Each of these functions as an input unit that allows the type of the paper 6 to be input to the control unit 4.
[0095]
The control unit 4 corrects the degree to which the conveyance amount of the paper discharge roller unit 22 is changed based on the type of the paper 6. The type of paper 6 at this time is not particularly limited, but at least one of the thickness (paper thickness) of the paper 6 and the surface roughness (paper surface roughness) of the paper 6 is particularly preferably used.
[0096]
As described above, the paper discharge roller unit 22 has a structure that includes the paper discharge roller 22a and the spur 22b that constitute the paper discharge roller unit 22 and is sufficiently pressed against the paper 6 during conveyance of the paper 6 compared to the paper feed roller unit 21. It is easy to be in a state where force cannot be applied or sufficient frictional force cannot be obtained. For this reason, depending on the type of the paper 6, there is a difference in the frictional force for conveyance by the paper discharge feed roller 22a, and as a result, the conveyance amount is also different.
[0097]
Specifically, the conveyance amount by the paper discharge roller unit 22 (paper discharge feed roller 22a) depends on the magnitude of the frictional force between the paper discharge roller unit 22 and the surface of the paper 6. First, the frictional force varies depending on the pressure applied between the paper discharge roller 22a and the spur 22b facing the paper discharge roller 22a, that is, the pressure contact force on the paper 6.
[0098]
As shown in FIG. 8, in view of the relationship between the carry amount and the paper thickness, a proportional relationship is established between the paper thickness and the carry amount, where the vertical axis is the carry amount and the horizontal axis is the paper thickness. That is, if the paper thickness is small, the pressure contact force is small and the conveyance amount is small. However, if the paper thickness is thick, the pressure contact force is large and the conveyance amount is large.
[0099]
Further, the frictional force varies depending on the surface property (surface state) of the paper 6. As shown in FIG. 8, when the relationship between the carry amount and the paper surface roughness is taken, the vertical axis is the carry amount, and the horizontal axis and the paper surface roughness are the same as the paper thickness between the carry amount and the paper surface roughness. Is also proportional. Therefore, if the paper surface roughness is small, that is, if the surface is smooth, the frictional force itself is small and the conveyance amount is small. However, if the paper surface roughness is large, the surface is rough and the frictional force is also large and the conveyance amount is large. . The paper surface roughness is the roughness of the surface (drive surface) on the side of the discharge feed roller 22a, which is a driving roller, and not the surface on the side of the spur 22b, which is a driven roller.
[0100]
Therefore, in the present embodiment, for the control to change the conveyance amount, at least one of the paper thickness and the paper surface roughness that greatly affects the frictional force is detected or input. Of course, the parameter indicating the type of the paper 6 is not limited to this, and any parameter that can measure the friction force of the paper discharge roller 22b with respect to the paper (recording medium) 6 may be used.
[0101]
When the paper type detection sensor 3b is a paper thickness detection means for detecting the paper thickness, for example, a signal from a head gap switching mechanism can be used. The head gap switching mechanism is a mechanism that changes the distance (head gap) between the ink carriage 11 and the platen 12 in the ink head mechanism 1 according to the paper thickness of the paper 6 to be used. A lever mechanism or the like is used. Therefore, the paper thickness detecting means only needs to detect the switching of the head gap and input it to the control unit 4 as the paper thickness.
[0102]
When the paper type detection sensor 3b is a paper surface roughness detection unit that detects the paper surface roughness, a reflective optical sensor can be used. In the present embodiment, the paper type detection sensor 3b may be provided with both the paper thickness detection means and the surface roughness detection means, or only one of them.
[0103]
Further, as the composite sensor 3c, the same configuration as that of the paper-in sensor 3a described above can be used. That is, if the thickness (paper thickness) of the paper 6 is different, the inclination degree of the contact member 31 is also different, so that the type of the paper 6 can be detected based on the paper thickness.
[0104]
Further, while the paper 6 is carried and conveyed, the contact member 31 continues to contact the surface of the paper 6. At this time, if the surface of the paper 6 is smooth, the inclined state of the contact member 31 is hardly changed. However, if the surface of the paper 6 is rough, a large frictional force is generated between the contact member 31 and the surface. Therefore, it is possible to detect the type of the paper 6 based on the surface state.
[0105]
In this way, if the composite sensor 3c also serves as the paper entry sensor 3a and the paper type detection sensor 3b, it is possible to detect the type of the paper 6 without increasing the number of sensors. The device configuration can be simplified.
[0106]
In the above-described example, the sensor means is used as the input means that enables the type of the paper 6 to be input to the control unit 4, but the present invention is not limited to this. That is, the input of the type of the paper 6 to the control unit 4 may be made by setting the conditions of the paper 6 to the driver of the ink jet printer instead of the paper type detection sensor 3b and the composite sensor 3c.
[0107]
Accordingly, the type of the paper 6 may be input by various input means provided in the ink jet printer and capable of inputting various conditions and data related to printing. Further, the type of the paper 6 may be input from a terminal such as a personal computer externally connected to the ink jet printer. In this case, a connection terminal of an ink jet printer connected to the terminal functions as an input unit.
[0108]
Next, the control for changing the peripheral speed of the paper discharge roller unit 22 in the present embodiment will be described in detail below with reference to FIGS. Although the following description is an example in which the paper thickness is different, it is needless to say that the same control is performed even with the paper surface roughness.
[0109]
First, as shown in the flowchart of FIG. 9, S21 is substantially the same as S11 in the first embodiment (see FIG. 3), but in this embodiment, the paper type is input at this point.
[0110]
Therefore, as shown in the time charts of the peripheral speeds in FIGS. 10A and 10B, the peripheral speed (solid line in the figure) of the paper feed roller section 21 is V regardless of whether the paper thickness is thin or thick.₁However, when the peripheral speed of the paper discharge roller portion 22 (the one-dot chain line in the figure) is thin, as shown in FIG.₁Larger than V₁₂On the other hand, when it is thick, as shown in FIG.₁Slightly larger than V_{twenty two}It has become.
[0111]
The peripheral speed V of the paper discharge roller unit 22 is as follows.₁₂And V_{twenty two}As described in the first embodiment, the peripheral speed V when the paper thickness is standard₂When comparing the magnitude relationship including₁₂Is the largest, standard paper thickness peripheral speed V₂Is the next largest, thick paper thickness peripheral speed V_{twenty two}Becomes the smallest (V₁₂> V₂> V_{twenty two}). Of course, there is no particular limitation on the specific numerical value of the magnitude relationship, for example, what percentage of the speed difference is present, and it varies depending on the configuration of the ink jet printer.
[0112]
Further, the step of inputting the type of the paper 6 is not limited to S21. For example, if the type (paper thickness) of the paper 6 is detected by the composite sensor 3c, the type (paper thickness) of the paper 6 is input when the composite sensor 3c described later is turned on. May be. Therefore, there may be a step in which the paper thickness of the paper 6 is input between S22 and S23.
[0113]
Next, in S22, as in S12, it is determined whether or not the paper input sensor 3a or the composite sensor 3c is in an on state. If it is not on (NO in the figure, off state), this step is repeated. If it is on (YES in the figure), the process proceeds to S23. In addition, the time t when the paper entry sensor 3a or the composite sensor 3c is turned on₁Then, as shown in FIGS. 10A and 10B, the peripheral speeds of the paper feed roller portion 21 and the paper discharge roller portion 22 are both V.₁And V₁₂Or V_{twenty two}Remains.
[0114]
Thereafter, in S23, the printing operation is started by the ink head mechanism 1, and an image based on digital data is printed by the operation of the ink head mechanism 1 and the conveyance of the paper 6 by the paper conveyance mechanism 2 as in the first embodiment. . Even at this time, as shown in FIGS. 10A and 10B, the peripheral speeds of the paper feed roller unit 21 and the paper discharge roller unit 22 are all V.₁And V₁₂Or V_{twenty two}It remains unchanged.
[0115]
Then, in S24, it is determined whether or not the paper entry sensor 3a or the composite sensor 3c has been turned off. If it remains in the ON state (NO in the figure), the process proceeds to S28, where the normal transport amount, that is, the peripheral speed V of the paper feed roller unit 21 shown in FIGS.₁And the peripheral speed V of the paper discharge roller section 22₁₂Or V_{twenty two}The conveyance of the paper 6 is continued without change.
[0116]
On the other hand, if the paper entry sensor 3a or the composite sensor 3c is turned off (YES in the figure), the remaining portion of the paper 6 is reduced on the upstream side of the paper feed roller portion 21. Therefore, the process proceeds to S25, and the time t when the trailing edge of the paper 6 is removed from the paper feed roller unit 21 from the transport amount of the paper feed roller unit 21._ThreeAnd predicts the time t₂To t_ThreeA predetermined time to reach (t_Three-T₂), It is determined whether or not the paper feed roller unit 21 is operated.
[0117]
In S25, the paper feed roller unit 21 is set for a predetermined time (t_Three-T₂) When not operating (NO in the figure), the process proceeds to S29, and similarly to S28, the normal transport amount, that is, the peripheral speed V of the paper feed roller unit 21 shown in FIGS. 10 (a) and 10 (b).₁And the peripheral speed V of the paper discharge roller section 22₁₂Or V_{twenty two}The conveyance of the paper 6 is continued without change.
[0118]
On the other hand, in S25, the paper feed roller unit 21 is set for a predetermined time (t_Three-T₂) When the operation is performed (YES in the figure), the process proceeds to S26, and the conveyance amount of the discharge roller unit 22 is changed. Specifically, when the paper thickness is thin, as shown in FIG._Three, The peripheral speed V of the paper discharge roller section 22₁₂V₁₃To lower. The peripheral speed of the paper discharge roller unit 22 is V₁₃The conveyance amount of the paper 6 at the time becomes the peripheral speed V of the paper feed roller unit 21.₁This is the same as the transport amount of the paper 6 by.
[0119]
Similarly, when the paper thickness is thick, as shown in FIG._Three, The peripheral speed V of the paper discharge roller section 22_{twenty two}V_{twenty three}To lower. The peripheral speed of the paper discharge roller unit 22 is V_{twenty three}The conveyance amount of the paper 6 at the time becomes the peripheral speed V of the paper feed roller unit 21.₁This is the same as the transport amount of the paper 6 by.
[0120]
In the present embodiment, as in the first embodiment, since the drive motor unit 23 drives both the paper supply roller unit 21 and the paper discharge roller unit 22, FIG. As shown in b), the peripheral speed of the paper feed roller unit 21 is also V₁To V_FourTo drop. Of course, when the driving means are different, the peripheral speed of the paper feed roller unit 21 is V.₁Should be maintained.
[0121]
In S27, as in S17, the printing operation is completed and the printed paper 6 is discharged. Thereby, a series of printing operations in the present invention is completed.
[0122]
As described above, in the present embodiment, when the rear end of the recording medium is removed from the conveying unit on the upstream side of the recording head, the recording amount is changed when the conveying amount of the conveying unit on the downstream side of the recording head is changed. The amount of change in the conveyance amount is corrected using the thickness of the medium and the surface roughness on the drive roller side of the recording medium.
[0123]
Therefore, it is possible to appropriately cope with the phenomenon that the conveyance amount in the downstream conveyance unit varies depending on the type of the recording medium. Therefore, it is possible to more reliably prevent the deterioration of the recording quality by changing the transport amount of the downstream transport unit more accurately.
[0124]
The medium transport mechanism and the control method thereof according to the present invention are not limited to the above-described paper transport mechanism of an ink jet printer, and can be applied as a paper transport mechanism for general serial printers. In addition, the present invention is applicable to any application in which a planar medium is conveyed at a constant speed so as not to bend in a certain section, and is not limited to conveyance of paper.
[0125]
In each of the above-described embodiments, the present invention has been described by taking a serial printer as an example. However, even if the present invention is applied to a line printer, the same excellent actions and effects can be exhibited.
[0126]
【The invention's effect】
  As described above, the medium transport mechanism according to the present invention includes at least the control unit that controls the operation of the discharge unit, and the control unit is configured to discharge the medium when the main body that transports the medium changes from the supply unit to the discharge unit. Control to change the transport amount of the medium according to the transport amount of the supply meansAlso, based on the detection result of the medium presence detection means and the transport amount of the supply means, the time when the trailing edge of the medium is removed from the supply means is predicted, and the supply means is operated for a predetermined time until this time is reached. Depending on whether or not the main body that transports the medium determines the timing at which the supply unit replaces the discharge unit, and performs control to change the transport amount of the discharge unitIt is a configuration.
[0127]
Therefore, in the above configuration, when the main body that transports the medium is changed from the supply unit to the discharge unit, the transport amount of the medium by the discharge unit is changed in accordance with the transport amount of the supply unit, so that the transport amount is always substantially constant. The medium can be conveyed. As a result, there is an effect that the medium supply unit according to the present invention can be suitably used for a purpose of always transporting a medium at a predetermined interval, for example, a use of a paper transport unit of a printer.
[0129]
In the above configuration, by detecting the presence of the medium by the medium presence detection unit, the remaining amount of the medium is substantially detected by a simple configuration. Therefore, it is possible to accurately determine the timing at which the main body that transports the medium replaces the discharge means. As a result, there is an effect that the medium can be reliably transported with a substantially constant transport amount.
[0130]
The medium transport mechanism further includes an input unit that enables the medium type to be input to the control unit, and the control unit determines the transport amount of the discharge unit based on the medium type. It is preferable to perform control to correct the change.
[0131]
In the above configuration, since the degree of change in the transport amount is corrected by the control unit by inputting the medium type to the input unit, it is possible to reduce the influence of the medium type on the transport amount. As a result, there is an effect that the medium can be transported more reliably with a substantially constant transport amount.
[0132]
In the medium transport mechanism, it is preferable that the medium presence detection unit also serves as the input unit that detects the type of the medium and inputs the detection result to the control unit.
[0133]
In the above configuration, since the medium presence detection unit and the medium type detection unit are combined as one unit, both the remaining amount of the medium and the type of the medium can be detected by one unit and input to the control unit. it can. As a result, the manufacturing cost can be reduced and the apparatus configuration can be simplified.
[0134]
  As described above, the control method of the medium transport mechanism according to the present invention is as follows.The detection result of the medium presence detection meansBased on the remaining amount of the medium upstream of the supply means and the conveying capacity of the supply means,Depending on whether or not the supply means is operated for a predetermined time until the rear end of the medium is deviated from the supply means and this time is reached,The method includes a step of determining a timing at which the rear end of the medium is removed from the supply unit, and a step of changing a conveyance amount by the discharge unit when the rear end of the medium to be conveyed is removed from the supply unit.
[0135]
Therefore, in the above method, the timing at which the main body that transports the medium replaces the discharge means is accurately determined from the remaining amount of the medium and the transport capability of the supply means, and based on this, the transport amount of the medium by the discharge means is supplied. Change accurately according to the transport amount of the means. Therefore, it is possible to always transport the medium with a substantially constant transport amount, and for example, it is possible to suitably use it for controlling the paper transport means of the printer.
[0136]
In the above control method, it is preferable to correct the change in the transport amount of the discharge means based on the type of medium.
[0137]
In the above method, since the type of medium that may greatly affect the transport amount of the discharging unit is used for control, it is possible to reduce the influence of the medium type on the transport amount. As a result, there is an effect that the medium can be transported more reliably with a substantially constant transport amount.
[0138]
In the control method, the type of the medium is more preferably at least one of the thickness of the medium and the surface roughness of the medium.
[0139]
In the above method, since at least one of the thickness of the medium and the surface roughness of the medium, which easily affects the conveyance force, is used for control, the influence on the conveyance amount due to the type of medium can be further reduced. It becomes possible. As a result, there is an effect that the medium can be transported more reliably with a substantially constant transport amount.
[0140]
As described above, the image forming apparatus according to the present invention includes the medium transport mechanism configured as described above as a recording medium transport unit, and also includes an image forming unit between the supply unit and the discharge unit.
[0141]
Therefore, in the above configuration, a recording medium such as a sheet can be conveyed in a stable state at the image forming portion. As a result, the present invention is applied to a printer such as an ink jet printer that is required to form a precise image, and it is possible to realize a higher quality image formation.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a main part of an ink jet printer according to a first embodiment of the present invention.
FIG. 2 is a schematic diagram showing a more specific configuration of a main part of the ink jet printer shown in FIG. 1;
FIG. 3 is a flowchart showing control of the ink jet printer shown in FIG. 1 and a paper transport mechanism included in the ink jet printer.
4 is a time chart showing a change in the amount of paper transport in a paper transport mechanism included in the ink jet printer shown in FIG. 1. FIG.
FIGS. 5A to 5C are explanatory diagrams illustrating a sheet conveyance state in the ink jet printer illustrated in FIG. 2;
FIG. 6 is a block diagram illustrating a configuration of a main part of an ink jet printer according to a second embodiment of the present invention.
7 is a block diagram showing another configuration of the main part of the ink jet printer shown in FIG. 7;
8 is a graph showing the relationship between the transport amount and the type of paper (paper thickness or paper surface roughness) in the paper transport mechanism provided in the ink jet printer shown in FIG. 6 or FIG.
FIG. 9 is a flowchart showing control of the ink jet printer shown in FIG. 6 or FIG. 7 and a paper transport mechanism provided in the ink jet printer.
FIGS. 10A and 10B are time charts showing changes in the amount of paper transport in the paper transport mechanism provided in the ink jet printer shown in FIG. 6 or FIG. 7, and the time chart in FIG. This is a case where the paper thickness is thin, and the time chart of (b) is a case where the paper thickness of the paper is thick.
[Explanation of symbols]
1 Ink head mechanism (image forming means)
2 Paper transport mechanism (medium transport mechanism / recording medium transport means)
3a Paper entry sensor (medium presence detection means)
3b Paper type detection sensor (medium type detection means)
3c Compound sensor (medium presence detection means / medium type detection means)
4 Control unit (control means)
6 paper (flat media / recording paper)
10 Paper transport path
21 Feeding roller section (supplying means)
21a Paper feed roller
22 Paper discharge roller (discharge means)
22a Paper discharge roller

Claims (9)

A supply means disposed upstream of the conveying direction for conveying a planar medium, and a discharge means disposed downstream, the transport of the medium by the supply means, the pressure contact force with respect to the medium the difference, compared to the transport of the medium by the ejecting means, the transport amount is small and the large media transportation mechanism conveying force,
Further, a control means for controlling the operation of at least said discharge means,
When viewed from the supply means comprises a medium presence detection means for detecting the presence or absence of the medium on the upstream side in the transport direction of the medium,
The supply means is a paper feed roller section; the discharge means is a paper discharge roller section;
Said control means, when the entity carrying the medium was replaced with the discharge means from said supply means, the conveyance amount of the medium by the ejecting means performs the control for changing in accordance with the conveyance amount of the supply means, the In control,
Rear end of the medium to estimate the time to deviate from the supply means on the basis of the conveyance amount detection result and the supply means of the media presence detection means, a predetermined time to reach this time, by operating the supply means by Taka whether, mainly for transporting the medium to determine when to replace the said discharge means from said supply means,
When the rear end of the medium to be transported deviates from the supply means, the transport amount of the discharge means is changed . In this case, the paper discharge after the rear end of the medium deviates from the paper feed roller section. A medium conveying mechanism characterized in that the circumferential speed of the roller section is made larger than the circumferential speed of the sheet feeding roller section before the rear end of the medium is separated from the sheet feeding roller section . Said control means, when the entity carrying the medium was replaced with the discharge means from said supply means, and the carry amount of the medium of said discharge means, the transport volume and the same value of said medium of said feeding means 2. The medium transport mechanism according to claim 1, wherein the operation of the discharge means is controlled so that Furthermore, it has an input means that allows the type of medium to be input to the control means,
The control means, based on the type of the medium, according to claim 1 or 2, wherein the medium conveying mechanism and performs control for correcting the change in the conveyance amount of the discharge means. Furthermore, the medium transport mechanism according to claim 3, characterized in that said medium presence sensor means also serves as said input means for inputting to said control means a detection result by detecting the kinds of the medium. A supply means disposed upstream of the conveying direction for conveying the flat medium, and discharge means disposed downstream, as viewed from the supply means on the upstream side in the transport direction of the medium for the presence of the medium existence and a media presence detection means for detecting a conveyance of the medium by the supply means, the difference in pressure contact force with respect to the medium, as compared with the transport of the medium by the discharge means, small amount of conveying, In the control method of the medium transport mechanism having a large transport force,
The supply means is a paper feed roller section; the discharge means is a paper discharge roller section;
Based on the carrying capacity of the remaining amount and the supply means of the medium on the upstream side of the detection result and the supply means of the media presence detection means, to predict the time the trailing end of the medium deviates from the supply means, the time predetermined time to reach, according to whether to operate the feed unit, a first determining the timing of the trailing edge is outside of said medium from said supply means,
Rear end of the medium to be conveyed saw contains a second step of varying in accordance with the conveyance amount of the supply means the conveyance amount by the discharge means when deviated from said supply means, in the second step The peripheral speed of the paper discharge roller section after the rear end of the medium is removed from the paper feed roller section is greater than the peripheral speed of the paper feed roller section before the rear end of the medium is removed from the paper feed roller section. A control method for a medium transport mechanism. Furthermore, based on the type of the medium, the control method according to claim 5, wherein the medium conveying mechanism, characterized in that to correct the change in the conveyance amount of the discharge means.   7. The method of controlling a medium transport mechanism according to claim 6, wherein the type of the medium is at least one of a thickness of the medium and a surface roughness of the medium. While providing the medium conveyance mechanism of any one of Claims 1 thru | or 4 as a recording medium conveyance means,
An image forming apparatus comprising the image forming means between said supply means and said discharge means. Said supply means is a sheet feeding roller unit, the discharge means is a discharge roller unit, according to claim 1, wherein the driving by the same drive motor unit to the paper feeding roller section and the discharge roller unit Medium transport mechanism.

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