JP7622380B2 - Heating device and image forming apparatus - Google Patents

Description

The present invention relates to a heating device and an image forming device.

Known heating devices installed in image forming devices such as copiers and printers include fixing devices that fix toner on paper using heat and drying devices that dry ink on paper.

For example, the following Patent Document 1 discloses a fixing device that includes a heating element (heater) on a longitudinal substrate, the heating element including a resistive heating element, an electrode portion, and a conductor that electrically connects the two.

In a heating element in which such a conductor is provided on a substrate, when the resistive heating element is made to generate heat, the conductor also generates a small amount of heat when electricity is passed through it. Therefore, strictly speaking, the heat distribution of the entire heating element is affected by the heat generated by the conductor.

Therefore, depending on the heat generation distribution of the conductor, there is a risk that this may cause variations in the temperature distribution of the heating element. Therefore, in heating devices equipped with such heating elements, measures are required to suppress problems caused by variations in the temperature of the heating element due to heat generation by the conductor.

There was an issue of delayed detection of temperature rise within the heating device due to temperature deviation between one side and the other side of the heating element in the longitudinal direction.

In order to solve the above-mentioned problems, the present invention provides a heating device including a heating body and a plurality of temperature detection means, wherein the heating body includes a first heating section including at least two resistive heating elements, a second heating section including at least two resistive heating elements located on both ends of the heating body in a longitudinal direction relative to the first heating section, a plurality of conductors, a first electrode section connected to the first heating section via the conductors, a second electrode section connected to the first heating section and the second heating section via the conductors, and a third electrode section connected to the second heating section via the conductors, wherein, in the longitudinal direction, a region from a resistive heating element located on one side to a resistive heating element located on the other side among all the resistive heating elements included in the heating body is defined as a heating region, and in the longitudinal direction, the first electrode section is disposed on one side of a central position of the heating region. The present invention is characterized in that, in the longitudinal direction, the first temperature detection means as the temperature detection means is a resistive heating element included in the first heating portion, and is arranged at a position corresponding to the resistive heating element arranged on one side of the central position of the heating area, the second temperature detection means as the temperature detection means is a resistive heating element included in the second heating portion, and is arranged at a position corresponding to the resistive heating element arranged on the other side of the central position of the heating area, and the second electrode portion is connected via the conductor to each of the resistive heating elements of the first heating portion and the second heating portion in order from the resistive heating element furthest on the other side of the longitudinal direction to one side in the longitudinal direction, and the arrangement of all the temperature detection means provided in the thermal device is asymmetric on one side and the other side of the longitudinal direction with respect to the central position of the heating area .

The present invention allows for earlier detection of temperature increases within the heating device.

1 is a schematic diagram illustrating a configuration of an image forming apparatus according to an embodiment of the present invention. FIG. 2 is a schematic diagram of a fixing device. FIG. FIG. FIG. FIG. FIG. FIG. FIG. 4 is a perspective view showing a state in which a connector is connected to the heater. FIG. 4 is a diagram showing power supply to a heater. FIG. 11 is a diagram showing a normal current path in the heater of FIG. 10 . 11 is a diagram showing a current path when unintended current shunting occurs in the heater of FIG. 10. FIG. FIG. 11 is a diagram showing the amount of heat generated in the power supply lines for each block when unintended current shunting occurs in the heater of FIG. 10 . 11 is a diagram showing the amount of heat generated by the power supply lines for each block when electricity is supplied to all heat generating parts in the heater of FIG. 10. FIG. 4 is a diagram showing the longitudinal arrangement of thermistors. 11 is a side view of the fixing device in the case where a temperature detection unit is provided on the outer circumferential side of the fixing belt. 11 is a diagram showing a heater having a different configuration from that shown in FIG. 10 and power supply to the heater. FIG. 18 is a diagram showing the amount of heat generated in the power supply lines for each block when unintended current shunting occurs in the heater of FIG. 17. 18 is a diagram showing the amount of heat generated by the power supply lines for each block when electricity is supplied to all heat generating parts in the heater of FIG. 17. FIG. 2 is a plan view showing the short-side dimension of a heater and the short-side dimension of a resistance heating element. 1A and 1B are plan views showing modified examples of the heater. FIG. 13 is a diagram showing the configuration of another fixing device. FIG. 13 is a diagram showing the configuration of another fixing device. FIG. 13 is a diagram showing the configuration of still another fixing device. 13 is a diagram showing a heater in which a third electrode portion is disposed on the other side in the longitudinal direction. FIG. 1 shows a heater in which the first heating portion is composed of two resistive heating elements.

The following describes embodiments of the present invention with reference to the drawings. In each drawing, the same or corresponding parts are given the same reference numerals, and duplicated descriptions are appropriately simplified or omitted. In the following description of each embodiment, the heating device is described as a fixing device that fixes toner by heat.

The monochrome image forming device 1 shown in FIG. 1 is provided with a photoconductor drum 10. The photoconductor drum 10 is a drum-shaped rotating body capable of carrying toner as a developer on its surface, and rotates in the direction of the arrow in the figure. Around the photoconductor drum 10 are a charging roller 11 that uniformly charges the surface of the photoconductor drum 10, a developing device 12 equipped with a developing roller 7 that supplies toner to the surface of the photoconductor drum 10, and a cleaning blade 13 for cleaning the surface of the photoconductor drum 10.

An exposure unit is disposed above the photoconductor drum 10. Laser light Lb emitted by the exposure unit based on image data is irradiated onto the surface of the photoconductor drum 10 via the mirror 14.

In addition, a transfer means 15 equipped with a transfer charger is disposed opposite the photosensitive drum 10. The transfer means 15 transfers the image on the surface of the photosensitive drum 10 onto the paper P.

The paper feed section 4 is located at the bottom of the image forming device 1 and is made up of a paper feed cassette 16 that contains paper P as a recording medium, a paper feed roller 17 that conveys the paper P from the paper feed cassette 16 to the conveying path 5, and the like. A registration roller 18 is disposed downstream of the paper feed roller 17 in the conveying direction.

The fixing device 9 includes a fixing belt 20 that is heated by a heating element, which will be described later, and a pressure roller 21 that can apply pressure to the fixing belt 20.

The basic operation of the image forming device 1 will be described below with reference to FIG. 1.

When the printing operation (image forming operation) starts, the surface of the photoconductor drum 10 is first charged by the charging roller 11. Then, a laser beam Lb is irradiated from the exposure section based on image data, and the potential of the irradiated area is reduced to form an electrostatic latent image. Toner is supplied from the developing device 12 to the surface of the photoconductor drum 10 on which the electrostatic latent image has been formed, and the image is made visible as a toner image (developer image). Any toner remaining on the photoconductor drum 10 after transfer is removed by the cleaning blade 13.

When the printing operation is started, the paper feed roller 17 of the paper feed section 4 rotates at the bottom of the image forming device 1, sending the paper P stored in the paper feed cassette 16 to the transport path 5.

The paper P sent to the transport path 5 is timed by the registration roller 18 and transported to the transfer section, which is the opposing part between the transfer means 15 and the photosensitive drum 10, at a timing that faces the toner image on the surface of the photosensitive drum 10, and the toner image is transferred by applying a transfer bias by the transfer means 15.

The paper P with the transferred toner image is transported to the fixing device 9, where it is heated and pressurized by the heated fixing belt 20 and pressure roller 21, fixing the toner image to the paper P. The paper P with the fixed toner image is then separated from the fixing belt 20, transported by a pair of transport rollers provided downstream of the fixing device 9, and discharged to a paper output tray provided outside the device.

Next, we will explain the configuration of the fixing device 9 in more detail.

2, the fixing device 9 according to the present embodiment includes a fixing belt 20 as a belt member or fixing member, a pressure roller 21 as an opposing member or pressure member that contacts the outer peripheral surface of the fixing belt 20 to form a nip portion N, and a heating unit 19 that heats the fixing belt 20. The heating unit 19 also includes a planar heater 22 as a heating body, a heater holder 23 as a holding member that holds the heater 22, a stay 24 as a support member that supports the heater holder 23, and a thermistor 35 as a temperature detection means. The fixing belt 20, the pressure roller 21, the heater 22, the heater holder 23, and the stay 24 extend in a direction perpendicular to the paper surface of FIG. 2 (see the direction of the double-headed arrow B in FIG. 3), and hereinafter, this direction is referred to as the longitudinal direction of each member (however, it is also the axial direction of the pressure roller 21), or the longitudinal direction of the heating unit 19 or the fixing device 9. This longitudinal direction is also the width direction of the paper passed through the fixing device 9.

The fixing belt 20 is composed of an endless belt member, and has a cylindrical substrate made of polyimide (PI) with an outer diameter of 25 mm and a thickness of 40 to 120 μm. A release layer made of fluororesin such as PFA or PTFE with a thickness of 5 to 50 μm is formed on the outermost surface of the fixing belt 20 to enhance durability and ensure releasability. An elastic layer made of rubber or the like with a thickness of 50 to 500 μm may be provided between the substrate and the release layer. The substrate of the fixing belt 20 is not limited to polyimide, and may be a heat-resistant resin such as PEEK or a metal substrate such as nickel (Ni) or SUS. The inner peripheral surface of the fixing belt 20 may be coated with polyimide, PTFE, or the like as a sliding layer.

The pressure roller 21 has an outer diameter of, for example, 25 mm and is composed of a solid iron core 21a, an elastic layer 21b formed on the surface of the core 21a, and a release layer 21c formed on the outside of the elastic layer 21b. The elastic layer 21b is made of silicone rubber and has a thickness of, for example, 3.5 mm. To improve the release properties of the surface of the elastic layer 21b, it is desirable to form a release layer 21c made of a fluororesin layer having a thickness of, for example, about 40 μm.

The fixing belt 20 is pressed against the pressure roller 21 by the pressure mechanism, and is pressed against the pressure roller 21. This forms a nip N between the fixing belt 20 and the pressure roller 21. The pressure roller 21 also functions as a drive roller that is rotated by a driving force transmitted from a drive means provided in the image forming apparatus body. Meanwhile, the fixing belt 20 is configured to rotate in response to the rotation of the pressure roller 21. When the fixing belt 20 rotates, the fixing belt 20 slides against the heater 22, so a lubricant such as oil or grease may be interposed between the heater 22 and the fixing belt 20 to improve the sliding properties of the fixing belt 20.

The heater 22 is provided longitudinally along the rotation axis or longitudinal direction of the fixing belt 20, and is in contact with the inner peripheral surface of the fixing belt 20 at a position corresponding to the pressure roller 21. The heater 22 is a member for heating the fixing belt 20 as a heated member, and for heating the fixing belt 20 to a predetermined fixing temperature.

Unlike this embodiment, the heat generating section 60 may be provided on the opposite side of the substrate 50 from the fixing belt 20 side (the heater holder 23 side). In that case, since the heat from the heat generating section 60 is transferred to the fixing belt 20 via the substrate 50, it is desirable that the substrate 50 be made of a material with high thermal conductivity such as aluminum nitride. Furthermore, in the configuration of the heater 22 according to this embodiment, an insulating layer may be further provided on the surface of the substrate 50 opposite the fixing belt 20 (the heater holder 23 side).

The heater 22 may be in non-contact with the fixing belt 20 or indirectly contact with the fixing belt 20 via a low-friction sheet or the like, but in order to increase the efficiency of heat transfer to the fixing belt 20, it is preferable to have the heater 22 in direct contact with the fixing belt 20 as in this embodiment. The heater 22 can also be in contact with the outer peripheral surface of the fixing belt 20, but since there is a risk that the fixing quality will decrease if the outer peripheral surface of the fixing belt 20 is damaged by contact with the heater 22, it is preferable that the surface with which the heater 22 contacts is the inner peripheral surface of the fixing belt 20.

The heater holder 23 and the stay 24 are disposed inside the fixing belt 20. The stay 24 is made of a metal channel material, and both ends are supported by both side walls of the fixing device 9. The stay 24 supports the surface of the heater holder 23 opposite the heater 22 side, so that the heater 22 and the heater holder 23 are maintained without being significantly deflected by the pressure force of the pressure roller 21, and a fixing nip N is formed as a nip portion between the fixing belt 20 and the pressure roller 21.

The heater holder 23 is desirably made of a heat-resistant material because it is prone to becoming hot due to the heat of the heater 22. For example, if the heater holder 23 is made of a heat-resistant resin with low thermal conductivity such as LCP, the transfer of heat from the heater 22 to the heater holder 23 is suppressed, and the fixing belt 20 can be heated efficiently.

The thermistor 35 is provided on the rear surface of the substrate 50 at a position facing the heat generating section 60. Based on the temperature detected by the thermistor 35, the temperature of the fixing belt 20 is controlled to the desired temperature by controlling the power supplied to the heater 22 by the heating control means. The heating control means refers to a microcomputer including a CPU, ROM, RAM, an I/O interface, etc. However, when paper is being passed through, etc., the temperature of the fixing belt 20 is controlled to the desired temperature by appropriately supplying additional power in addition to the detected temperature, taking into account the amount of heat dissipated by the paper passing through.

When the printing operation starts, power is supplied to the heater 22, which causes the heat generating section 60 to generate heat and heat the fixing belt 20. The pressure roller 21 is also rotated and the fixing belt 20 starts to rotate. Then, when the temperature of the fixing belt 20 reaches a predetermined target temperature (fixing temperature), as shown in FIG. 2, the paper P carrying the unfixed toner image is transported between the fixing belt 20 and the pressure roller 21 (fixing nip N) (see the direction of arrow A in FIG. 2), and the unfixed toner image is heated and pressurized to be fixed to the paper P.

Figure 3 is a perspective view of the fixing device, and Figure 4 is an exploded perspective view of the fixing device.

As shown in Figures 3 and 4, the device frame 40 of the fixing device 9 includes a first device frame 25 consisting of a pair of side walls 28 and a front wall 27, and a second device frame 26 consisting of a rear wall 29. The pair of side walls 28 are arranged at one end side and the other end side in the longitudinal direction, and both end sides of the fixing belt 20, the pressure roller 21, and the heating unit 19 are supported by the side walls 28. Each side wall 28 is provided with a plurality of engagement protrusions 28a, and the first device frame 25 and the second device frame 26 are assembled by each engagement protrusion 28a engaging with an engagement hole 29a provided in the rear wall 29.

Each side wall portion 28 is provided with an insertion groove 28b for inserting the rotating shaft of the pressure roller 21. The insertion groove 28b opens on the rear wall portion 29 side and is a butt portion that does not open on the opposite side. A bearing 30 that supports the rotating shaft of the pressure roller 21 is provided at the end on the butt portion side. The pressure roller 21 is rotatably supported by the side wall portions 28 by mounting both ends of the rotating shaft to the bearings 30.

A drive transmission gear 31 is provided as a drive transmission member on one end of the rotation shaft of the pressure roller 21. The drive transmission gear 31 is arranged in a state where it is exposed outside the side wall portions 28 when the pressure roller 21 is supported by the side wall portions 28. As a result, when the fixing device 9 is mounted on the image forming apparatus main body, the drive transmission gear 31 is connected to a gear provided on the image forming apparatus main body, and is in a state where it can transmit drive force from the drive source. Note that the drive transmission member that transmits drive force to the pressure roller 21 may be, in addition to the drive transmission gear 31, a pulley that stretches a drive transmission belt or a coupling mechanism.

A pair of flanges 32 are provided at both longitudinal ends of the heating unit 19 to support the fixing belt 20, heater holder 23, stay 24, etc. Each flange 32 is provided with a guide groove 32a. The flanges 32 are assembled to the side wall portion 28 by inserting the guide grooves 32a along the edge of the insertion groove 28b of the side wall portion 28.

A pair of springs 33 acting as urging members contact each flange 32. Each spring 33 urges the stay 24 and the flange 32 toward the pressure roller 21, so that the fixing belt 20 is pressed against the pressure roller 21, forming a fixing nip between the fixing belt 20 and the pressure roller 21.

As shown in FIG. 4, one end of the rear wall 29 constituting the second device frame 26 in the longitudinal direction is provided with a hole 29b as a positioning portion for positioning the fixing device body relative to the image forming device body. On the other hand, the image forming device body is provided with a protrusion 101 as a positioning portion. When the protrusion 101 is inserted into the hole 29b of the fixing device 9, the protrusion 101 and the hole 29b fit together, and the fixing device body is positioned in the longitudinal direction relative to the image forming device body. Note that no positioning portion is provided on the end side opposite the end side where the hole 29b of the rear wall 29 is provided. This prevents the longitudinal expansion and contraction of the fixing device body due to temperature changes from being restricted.

Figure 5 is a perspective view of the heating unit 19, and Figure 6 is an exploded perspective view of the heating unit 19.

As shown in Figs. 5 and 6, the heater holder 23 has a rectangular storage recess 23a on the fixing belt side (the surface on the front side in Figs. 5 and 6) for storing the heater 22. The storage recess 23a is formed to have approximately the same shape and size as the heater 22, but the longitudinal dimension L2 of the storage recess 23a is set to be slightly longer than the longitudinal dimension L1 of the heater 22. In this way, the storage recess 23a is formed to be slightly longer than the heater 22, so that the heater 22 and the storage recess 23a do not interfere with each other even if the heater 22 expands in its longitudinal direction due to thermal expansion. In addition, the heater 22 is held in the storage recess 23a by being sandwiched together with the heater holder 23 by a connector, which will be described later, as a power supply member.

The pair of flanges 32 have a C-shaped belt support portion 32b that is inserted inside the fixing belt 20 to support the fixing belt 20, a flange-shaped belt regulation portion 32c that contacts the end face of the fixing belt 20 to regulate longitudinal movement (deviation), and support recesses 32d into which both end sides of the heater holder 23 and the stay 24 are inserted to support them. With the belt support portions 32b inserted into both end sides, the fixing belt 20 is supported in a so-called free belt manner in which no tension is generated in the circumferential direction (belt rotation direction) when the belt is not rotating.

As shown in Figures 5 and 6, a positioning recess 23e is provided as a positioning portion at one end of the heater holder 23 in the longitudinal direction. The fitting portion 32e of the flange 32 shown on the left side of Figures 5 and 6 fits into this positioning recess 23e, thereby positioning the heater holder 23 and the flange 32 in the longitudinal direction. On the other hand, the flange 32 shown on the right side of Figures 5 and 6 does not have a fitting portion 32e, and is not positioned in the longitudinal direction relative to the heater holder 23. In this way, by positioning the heater holder 23 relative to the flange 32 only on one side in the longitudinal direction, even if the heater holder 23 expands and contracts in the longitudinal direction due to temperature changes, the expansion and contraction is not restricted.

As shown in FIG. 6, steps 24a are provided on both longitudinal ends of the stay 24 to restrict movement of the stay 24 relative to each flange 32. Each step 24a abuts against the flange 32 to restrict longitudinal movement of the stay 24 relative to the flange 32. However, at least one of these step portions 24a is disposed with a gap (backlash) between it and the flange 32. In this way, by disposing at least one step portion 24a with a gap between it and the flange 32, even if the stay 24 expands and contracts in the longitudinal direction due to temperature changes, the expansion and contraction is not restricted.

Figure 7 is a plan view of the heater 22, and Figure 8 is an exploded perspective view of the heater 22.

As shown in FIG. 8, the heater 22 has a substrate 50, a first insulating layer 51 provided on the substrate 50, a conductor layer 52 having a heat generating portion 60 and the like provided on the first insulating layer 51, and a second insulating layer 53 covering the conductor layer 52. In this embodiment, the substrate 50, the first insulating layer 51, the conductor layer 52 (heat generating portion 60), and the second insulating layer 53 are laminated in this order toward the fixing belt 20 side (fixing nip N side), and the heat generated from the heat generating portion 60 is transferred to the fixing belt 20 via the second insulating layer 53 (see FIG. 2).

The substrate 50 is a longitudinal plate made of a metal material such as stainless steel (SUS), iron, or aluminum. In addition to metal materials, ceramics, glass, etc. can also be used as the material for the substrate 50. When an insulating material such as ceramics is used for the substrate 50, the first insulating layer 51 between the substrate 50 and the conductor layer 52 can be omitted. On the other hand, metal materials are excellent in durability against rapid heating and are easy to process, making them suitable for reducing costs. Among metal materials, aluminum and copper are particularly preferred because they have high thermal conductivity and are less likely to cause temperature unevenness. Stainless steel also has the advantage of being cheaper to manufacture than these.

Each insulating layer 51, 53 is made of an insulating material such as heat-resistant glass. Alternatively, ceramic or polyimide (PI) may be used as the material.

The conductor layer 52 is composed of a heating section 60 having multiple resistive heating elements 59, multiple electrode sections 61, and multiple power supply lines 62 as conductors that electrically connect these. Each resistive heating element 59 is electrically connected in parallel to any two of the three electrode sections 61 via multiple power supply lines 62 provided on the substrate 50. In this embodiment, the arrangement direction of the multiple resistive heating elements 59 is the same as the longitudinal direction of the heater 22.

The resistance heating element 59 is formed, for example, by applying a paste made of silver palladium (AgPd) and glass powder to the substrate 50 by screen printing or the like, and then firing the substrate 50. In addition to these, the material of the resistance heating element 59 may be a resistance material such as a silver alloy (AgPt) or ruthenium oxide (RuO ₂ ).

The power supply line 62 is made of a conductor with a resistance value smaller than that of the resistive heating element 59. The power supply line 62 and the electrode portion 61 can be made of a material such as silver (Ag) or silver palladium (AgPd), and the power supply line 62 and the electrode portion 61 are formed by screen printing or the like of such a material.

Figure 9 is an oblique view showing the connector 70 connected to the heater 22.

As shown in FIG. 9, the connector 70 has a resin housing 71 and a number of contact terminals 72 provided on the housing 71. Each contact terminal 72 is made of a leaf spring and is connected to a power supply harness 73.

As shown in FIG. 9, the connector 70 is attached so as to sandwich the heater 22 and heater holder 23 together from the front and back sides. In this state, the contact portions 72a provided at the tip of each contact terminal 72 elastically contact (pressure weld) with the corresponding electrode portions 61, electrically connecting the heat generating portion 60 to the power source provided in the image forming device via the connector 70. This makes it possible to supply power from the power source to the heat generating portion 60. Note that in order to ensure connection with the connector 70, at least a portion of each electrode portion 61 is not covered by the second insulating layer 53 and is exposed (see FIG. 7).

10, in this embodiment, among the multiple resistive heating elements 59 arranged in the longitudinal direction of the substrate 50, the first heating section 60A composed of the resistive heating elements 59 other than those at both ends and the second heating section 60B composed of the resistive heating elements 59 at both ends are configured to be able to control heat generation independently. Specifically, each resistive heating element 59 other than those at both ends constituting the first heating section 60A is connected to a first electrode portion 61A provided on one end side of the longitudinal direction of the substrate 50 via a first power supply line 62A. In addition, each resistive heating element 59 constituting the first heating section 60A is connected to a second electrode portion 61B provided on the end side opposite to the first electrode portion 61A via a second power supply line 62B. On the other hand, each of the resistive heating elements 59 at both ends constituting the second heating section 60B is connected to a third electrode section 61C (separate from the first electrode section 61A) provided at one end of the longitudinal direction of the substrate 50 via a third power supply line 62C or a fourth power supply line 62D. Also, each of the resistive heating elements 59 at both ends is connected to the second electrode section 61B via a second power supply line 62B, similar to each of the resistive heating elements 59 of the first heating section 60A. In other words, the second electrode section 61B is connected by merging the power supply lines (second power supply line 62B) extending from all of the resistive heating elements 59.

Each of the electrode units 61A to 61C is connected to a power source 64 via the connector 70 described above, and receives power from the power source 64. A switch 65A is provided between the electrode unit 61A and the power source 64 as a switching unit, and the ON/OFF state of the switch 65A can be switched between applying and not applying a voltage. Similarly, a switch 65C is provided between the electrode unit 61C and the power source 64 as a switching unit, and the ON/OFF state of the switch 65C can be switched between applying and not applying a voltage. Furthermore, the ON/OFF state of the switches 65A and 65C and the timing of the power supply to the heater 22 are controlled by a control circuit 66 as a control unit. The control circuit 66 also performs these controls based on the detection results of various sensors in the image forming apparatus. For example, the timing of passing paper can be determined based on the detection results of sensors provided at the entrance and exit of the fixing nip N, and the supply of power to the heater 22 and the switching of the switches 65A and 65C can be performed.

When a voltage is applied to the first electrode portion 61A and the second electrode portion 61B, the resistive heating elements 59 other than those at both ends are energized, and only the first heating portion 60A is heated. On the other hand, when a voltage is applied to the second electrode portion 61B and the third electrode portion 61C, the resistive heating elements 59 at both ends are energized, and only the second heating portion 60B is heated. In addition, if a voltage is applied to all the electrodes 61A to 61C, both (all) of the resistive heating elements 59 of the first heating portion 60A and the second heating portion 60B can be heated. For example, when a relatively small width paper of A4 size (paper passing width: 210 mm) or less is passed through, only the first heating portion 60A is heated, and when a relatively large width paper of more than A4 size (paper passing width: 210 mm) is passed through, the second heating portion 60B is also heated in addition to the first heating portion 60A, so that a heating area according to the paper width can be obtained.

Incidentally, in order to further reduce the size of image forming devices and fixing devices, it is important to reduce the size of the heater, which is one of the components arranged inside the fixing belt. That is, by reducing the size of the heater in its short-side direction (the direction of arrow Y in FIG. 10: the direction intersecting the longitudinal direction B along the surface on which the heat generating parts 60A and 60B of the heater 22 are provided, or the direction perpendicular to the longitudinal direction B of the heater 22 and different from the thickness direction of the heater 22, which is the direction perpendicular to the paper surface of FIG. 10), the diameter of the fixing belt can be reduced, which in turn makes it possible to reduce the size of the fixing device and image forming device. Specifically, the following three methods can be given as examples of methods for reducing the size of the heater in the short-side direction.

One method is to reduce the size of the heat generating section (resistance heating element) in the short direction. However, when the heat generating section is reduced in the short direction, the width of the heating area in which the fixing belt is heated is reduced, which causes a problem that the peak temperature rise value becomes higher when attempting to ensure the same amount of heat to be given to the fixing belt. If the peak temperature rise value becomes higher, there is a risk that the temperature of the overheating detection device, such as a thermostat or fuse provided on the back surface of the heater, will exceed its heat resistance temperature or that the overheating detection device will malfunction. Furthermore, if the peak temperature rise value becomes higher, the efficiency of heat transfer from the heater to the fixing belt will also decrease, which is undesirable from the standpoint of energy efficiency. As such, there are circumstances that make it difficult to adopt the method of reducing the heat generating section in the short direction.

The second method is to reduce the size of the parts in the short direction where the heating part, electrode part, and power supply line are not provided. However, this method reduces the gap between the heating part and the power supply line and between the electrode part and the power supply line, which may make it difficult to ensure insulation. Considering the current heater structure, it is difficult to further reduce the gap between the heating part and the power supply line and between the electrode part and the power supply line.

The remaining third method is to reduce the size of the power supply line in the short direction. This method is more feasible than the above two methods. However, when the power supply line is reduced in the short direction, the resistance value of the power supply line increases, which may cause unintended current shunting on the conductive path of the heater. In particular, when the resistance value of the heating unit is reduced in order to increase the heat generation amount of the heating unit in response to the high speed of the image forming device, the resistance value of the power supply line and the resistance value of the heating unit become relatively close to each other, which makes it easier for unintended current shunting to occur. As a method for avoiding such unintended current shunting, it is possible to ensure the cross-sectional area and suppress the increase in the resistance value of the power supply line by increasing the thickness direction (the direction intersecting the long direction and short direction) by the amount of reduction in the power supply line in the short direction. However, in that case, it becomes difficult to screen print the power supply line, which forces a change in the method of forming the power supply line. For this reason, it is difficult to adopt a solution of making the power supply line thicker. Therefore, to achieve a smaller heater size in the short direction, it is necessary to reduce the size of the power supply line in the short direction while anticipating an increase in resistance, and to take separate measures against unintended current shunting that may occur as a result.

Below, we will explain unintended current diversion and the resulting problems using a heater with the same layout as heater 22 described above as an example.

In the heater 22 shown in FIG. 11, when a voltage is applied to the first electrode portion 61A and the second electrode portion 61B to heat only the resistive heating elements 59 of the first heating portion 60A, a current normally flows through the first power supply line 62A, passes through each resistive heating element 59 other than the two ends, and flows into the second power supply line 62B.

However, when the difference between the resistance of the power supply line and the heating part becomes small due to the increase in resistance of the power supply line associated with the above-mentioned miniaturization, or the decrease in resistance of the heating part associated with the increase in the amount of heat generated, an unintended branching of the current occurs, as shown in FIG. 12. That is, part of the current that passed through the second resistive heating element 59 from the left in FIG. 12 flows in the opposite direction to the second electrode part 61B at the branch part X of the second power supply line 62A. The branched current then passes through the resistive heating element 59 at the left end in FIG. 12, and further passes through the third power supply line 62C, the third electrode part 61C, the fourth power supply line 62D, and the resistive heating element 59 at the right end in this order, before joining the second power supply line 62B.

In this way, in the heater 22 shown in FIG. 12, the portion of the second power supply line 62B extending from the branch portion X to the left side of the figure, the resistive heating elements 59 at both ends constituting the second heating portion 60B, the third electrode portion 61C, and the portion including the third power supply line 62C and the fourth power supply line 62D constitute a branched conductive path E3 that allows current to flow through an unintended path.

In addition, such unintended branching can occur when electricity is applied to the first heating portion 60A if the conductive path of the heater 22 has at least a first conductive portion E1 connecting the first heating portion 60A and the third electrode portion 61C, a second conductive portion E2 extending from the first heating portion 60A in a first direction S1 (right side in Figure 12) of the longitudinal direction of the heater 22 and connected to the second electrode portion 61B, and a branch conductive path E3 branching from the second conductive portion E2 in a second direction S2 (left side in Figure 12) opposite to the first direction S1 and connected to the second conductive portion E2 or the second electrode portion 61B without passing through the first conductive portion E1. In other words, the above-mentioned shunting can occur when electricity is applied to the first heat generating part 60A under three conditions: "the first electrode part (first electrode part 61A) is connected to the resistive heating element 59 at the center of the longitudinal direction," "the second electrode part (third electrode part 61C) is connected to the resistive heating elements 59 at both ends of the longitudinal direction," and "the power supply lines extending from each resistive heating element 59 join and are connected to the third electrode part (second electrode part 61B)." In this embodiment, the second heat generating part 60B and the first electrode part 61A are provided on the branched conductive path E3, but even in a conductive path that does not have the second heat generating part 60B and the first electrode part 61A or a conductive path that has a conductive member other than these, unintended shunting can occur.

When unintended current shunting occurs, the current flows through a previously unanticipated path, causing variations in the temperature distribution of the heater 22 due to heat generation from the power supply line. For example, in the heater 22 shown in FIG. 13, if 20% of the current flows evenly from the first electrode portion 61A to each resistive heating element 59 of the first heating portion 60A, and if 5% of the current passing through the second resistive heating element 59 from the left in the figure is shunted at the branch point X beyond that, the amount of heat generated in the power supply line within each block divided by the resistive heating elements 59 will be as shown in the table in the figure.

Here, the portion of each power supply line that extends in the short direction of the heater 22 is short, and the amount of heat generated in this portion is small, so this amount of heat is ignored, and only the amount of heat generated in the portion of each power supply line that extends in the longitudinal direction of the heater 22 is calculated. Specifically, the amount of heat generated in the portion of the first power supply line 62A, the second power supply line 62B, and the fourth power supply line 62D that extends in the longitudinal direction of each heater 22 is calculated. In addition, since the amount of heat generated (W) is expressed by the following formula (1), the amount of heat generated shown in the table of FIG. 13 is calculated as the square of the current (I) flowing through each power supply line for convenience. Therefore, the numerical values of the amount of heat generated shown in the table of FIG. 13 are merely simply calculated values and differ from the actual amount of heat generated.

The method of calculating the amount of heat generated will be specifically described with reference to FIG. 13. In the first block, the current flowing through the first power supply line 62A is 100%, and the current flowing through the fourth power supply line 62D is 5%, so the sum of the squares of these, 10025 (10000+25), is the total amount of heat generated by the power supply lines in the first block. In the second block, the current flowing through the first power supply line 62A is 80%, the current flowing through the second power supply line 62B is 5%, and the current flowing through the fourth power supply line 62D is 5%, so the sum of the squares of these, 6450 (6400+25+25), is the total amount of heat generated by the power supply lines in the second block. In the other blocks, the amount of heat generated is calculated in a similar manner.

As shown in the table and graph at the bottom of Figure 13, the total heat generation amount of each block is asymmetrical with respect to the fourth block in the center of the heat generation area due to the unintended current diversion described above, with the heat generation amount on one side in the longitudinal direction being greater than the other side. However, the first block and the seventh block are non-paper passing areas through which paper does not pass.

Even when electricity is applied to all heat generating parts, the amount of heat generated in the longitudinal direction of the heater 22 becomes asymmetrical due to the difference in the magnitude of the current flowing through the conductive parts. In other words, when trying to miniaturize the heater 22 as described above, it becomes difficult to make the amount of heat generated in the longitudinal direction of the heater 22 symmetrical because the arrangement of the electrode parts and conductive parts is also restricted. Also, when trying to increase the speed of the device as described above, the value of the current flowing through the conductive parts increases, and the difference between the left and right becomes large, so that the difference cannot be ignored. Below, we will explain the case where electricity is applied to all heat generating parts.

As shown in Figure 14, when electricity is applied to all the heating parts, 20% of the current also flows through the resistive heating elements 59 at both the left and right ends, and through the power supply lines 62C and 62D connected to them, which is different from the previous case. In contrast, the value of the current flowing through power supply line 62A is the same as before. In this case, in the first block, the current flowing through the first power supply line 62A is 100%, and the current flowing through the fourth power supply line 62D is 20%, so the sum of the squares of these, 10,400 (10,000 + 400), is the total heat generation of the power supply lines in the first block. In the second block, the current flowing through the first power supply line 62A is 80%, the current flowing through the second power supply line 62B is 20%, and the current flowing through the fourth power supply line 62D is 20%, so the sum of these squares, 7200 (6400 + 400 + 400), is the total heat generation amount of the power supply lines in the second block. The heat generation amount is also calculated in the other blocks in the same way.

As shown in the table and graph at the bottom of Figure 14, the total heat generation amount of each block is asymmetrical with respect to the fourth block in the center of the heat generation area. In particular, the current value of the second power supply line 62B connected to all the resistive heating elements 59 increases to 120% downstream, i.e., in the seventh block, and the heat generation amount on the other side in the longitudinal direction is greater than on the one side. Note that in this embodiment, each block is set to the same length so that small and large size paper can be heated evenly.

When the second power supply line 62B is partially or fully energized as described above, the amount of current increases from one side in the longitudinal direction to the other side. Also, when current flows from the second electrode portion 61B to the first electrode portion 61A or the third electrode portion 61C, the resistive heating element 59 on the other side in the longitudinal direction is positioned upstream in the current direction, and the resistive heating element 59 on one side is positioned downstream.

As described above, in the heater 22 of this embodiment, one longitudinal side (left side in FIG. 10) is the side where the amount of heat generated by the heater 22 is large when electricity is applied to the first heat generating portion 60A and unintended current division occurs (as in FIG. 13). Also, the other longitudinal side (right side in FIG. 10) is the side where the amount of heat generated is large when electricity is applied to the first heat generating portion 60A and the second heat generating portion 60B (as in FIG. 14).

Such asymmetric variation in the heat generation amount of the power supply lines causes temperature variation along the length of the heater 22. If the temperature of the heater 22 varies along the length, the temperature detection means provided in the fixing device 9 will give different detection results depending on which position in the length direction it detects. Therefore, an arrangement that takes into account the above-mentioned temperature deviation is required. In the following explanation, the arrangement of the thermistor 35 mentioned above will be explained as one of the temperature detection means provided in the fixing device.

As shown in FIG. 15, the fixing device of this embodiment has a first thermistor 35A, a second thermistor 35B, and a third thermistor 35C. The longitudinal arrangement of each thermistor 35 will be described below. Region C in FIG. 15 is the longitudinal heat generation region of all the resistive heating elements 59 provided in the heater 22, and is hereinafter also simply referred to as the heat generation region C of the heater 22. The heat generation region C of the heater 22 refers to the region from the resistive heating element 59 (at one end of the longitudinal direction) located at the most one side in the longitudinal direction among all the resistive heating elements 59 provided in the heater 22 to the resistive heating element 59 (at the other end of the longitudinal direction) located at the most other side in the longitudinal direction. In addition, line C0 is a line indicating the center position of the heat generation region C, and is hereinafter also simply referred to as the center position C0.

The first thermistor 35A is disposed within the range of the area CA, which is the range facing the resistance heating element 59 of the first heating section 60A, on one side of the central position C0 in the longitudinal direction. In other words, the first thermistor 35A is disposed facing (at a corresponding position) the resistance heating element 59 on the side of the first heating section 60A that generates a large amount of heat when partial current is applied and unintended shunt current flows (as in FIG. 13). In this embodiment, as an example, the first thermistor 35A is disposed facing the resistance heating element 59 of the first heating section 60 that is disposed at one end of the longitudinal direction of the area CA. Note that the above-mentioned thermistor 35 being disposed at a position corresponding to the resistance heating element 59 means that the temperature detection portion of the thermistor 35 and at least a part of the resistance heating element 59 overlap in the longitudinal direction.

The second thermistor 35B is disposed opposite the resistive heating element 59 of the second heating portion 60B on the other longitudinal side of the center position C0. In other words, the second thermistor 35B is disposed opposite the resistive heating element 59 of the second heating portion 60B that generates a larger amount of heat when fully energized (as in the case of FIG. 14).

The third thermistor 35C is positioned toward the center in the longitudinal direction. In other words, the third thermistor 35C is positioned opposite the resistive heating element 59 that is closer to the center position C0 than the other thermistors 35, and in this embodiment, in particular, the third thermistor 35C is positioned opposite the resistive heating element 59 at the center position C0.

When the amount of heat generated on one longitudinal side of the heater 22 is greater than on the other side, for example, as shown in FIG. 13, when the first heat generating section 60A is energized in the heater configuration of FIG. 10 and unintended current division occurs, the first thermistor 35A can detect the temperature of the one longitudinal side where the amount of heat generated by the heater 22 is greater. The output of the heater 22 is controlled using the detection result of the first thermistor 35A. This makes it possible to detect a rise in temperature of the heater 22 at an earlier timing and reduce the output of the heater 22, or to detect an abnormal rise in temperature of the heater 22 and cut off the power supply to the heater 22, thereby improving the safety of the fixing device.

When the fixing device performs a fixing operation on a small-sized paper, the temperature of the non-paper passing area, which is the end side of the heater 22 or the fixing belt 20 in the longitudinal direction, becomes higher than that of the center side, which is a so-called end temperature rise. For example, when a fixing operation is performed on a paper with a width of range H2, if the first heat generating unit 60A is energized and range H1 is set as the heating area of the heater 22, ranges H3 on both sides of range H1 become non-paper passing areas. In the non-paper passing areas, the heat of the fixing belt 20 is not taken by the paper, and the temperature of the fixing belt 20 and the heater 22 rises at this position in the longitudinal direction. In this embodiment, in order to prevent an excessive temperature rise in the non-paper passing area on the end side of the longitudinal direction, the output of the heater 22 is reduced to reduce the productivity of the fixing device. The control circuit also uses the detection result of the third thermistor 35C on the longitudinal center side to determine the end temperature rise. In addition, the third thermistor 35C can measure the temperature of the paper passing area with the lowest temperature whether the current is fully or partially applied, so it is possible to control the temperature using the third temperature detection means to ensure fixing performance, while preventing problems caused by temperature rise by detecting the temperature using the first or second temperature detection means.

Even if the above-mentioned end temperature rise occurs, the end temperature rise can be detected earlier by providing the first thermistor 35A on the side where the heat generation in the longitudinal direction is large, particularly in the area that becomes a non-paper passing area when small-sized paper is passed through. Then, the control circuit 66 (see FIG. 10) controls the output of the heater 22 based on the detection result of the first thermistor 35A, enabling more accurate temperature control.

When the heat generation amount of the other longitudinal side of the heater 22 is greater than that of the other side, for example, as shown in FIG. 14, when all heat generating parts are energized in the heater configuration of FIG. 10, the second thermistor 35B arranged opposite the second heat generating part 60B can detect the temperature of the other longitudinal side of the heater 22, which is the side where the heat generation amount of the heater 22 is greater. Then, the output of the heater 22 is controlled using the detection result of the second thermistor 35B. This makes it possible to detect a rise in temperature of the heater 22 at an earlier timing and reduce the output of the heater 22, or to detect an abnormal rise in temperature of the heater 22 and cut off the power supply to the heater 22, thereby improving the safety of the fixing device.

In the above embodiment, the third electrode portion 61C is disposed on one side in the longitudinal direction, which is the same side as the first electrode portion 61A, but this is not limited thereto. For example, as shown in FIG. 25, the third electrode portion 61C may be disposed on the other side in the longitudinal direction, which is the opposite side to the first electrode portion 61A. In this embodiment, too, the thermistors are disposed in the same manner as in the above embodiment.

Also, as in FIG. 13 of the embodiment described above, in this embodiment, when the first heat generating portion 60A is energized and unintended current division occurs, the amount of heat generated on one side of the heater 22 in the longitudinal direction increases. Therefore, the first thermistor 35A can detect the temperature of the side of the heater 22 where the amount of heat generated is large. Also, as in FIG. 14 of the embodiment described above, when all heat generating portions are energized, the amount of heat generated on the other side of the heater 22 in the longitudinal direction increases. Therefore, the second thermistor 35B can detect the temperature of the side of the heater 22 where the amount of heat generated is large. As a result, in each case, the temperature rise of the heater 22 can be detected at an earlier timing to reduce the output of the heater 22, or the abnormal temperature rise of the heater 22 can be detected to cut off the power supply to the heater 22, thereby improving the safety of the fixing device. Also, the third thermistor 35C can measure the temperature of the paper passing area where the amount of heat generated is the smallest when fully energized and when partially energized, so that the fixing performance can be guaranteed.

In the above embodiment, the first heating section 60A has five resistive heating elements 59, but the present invention is not limited to this. For example, as shown in FIG. 26, the first heating section 60A may be composed of two resistive heating elements 59 arranged on one side and the other side of the center position C0 in the longitudinal direction. In this case, among the resistive heating elements 59 constituting the first heating section 60A, the first thermistor 35A is arranged at a position corresponding to the resistive heating element 59 on one side of the center position C0 in the longitudinal direction. In addition, among the resistive heating elements 59 constituting the second heating section 60B, the second thermistor 35B is arranged at a position corresponding to the resistive heating element 59 on the other side of the center position C0 in the longitudinal direction. As in the above embodiment, when the first heating section 60A is energized and an unintended shunt occurs, the first thermistor 35A can detect the temperature of the side of the heater 22 that generates a larger amount of heat, and when all heating sections are energized, the second thermistor 35B can detect the temperature of the side of the heater 22 that generates a larger amount of heat. Therefore, in each case, the temperature rise of the heater 22 can be detected at an earlier timing to reduce the output of the heater 22, or an abnormal temperature rise of the heater 22 can be detected to cut off the power supply to the heater 22, thereby improving the safety of the fixing device.

In addition, the above describes an example of a temperature detection means in which the present invention is applied to the thermistor 35 for temperature control, but the present invention may also be applied to a thermostat that detects the temperature of the heater 22 or the fixing belt 20 when the temperature rises abnormally and cuts off the power supply to the heater 22. In other words, by arranging the thermostat in the same manner as the first thermistor 35A and the second thermistor 35B described above, it is possible to detect an abnormal rise in temperature of the heater 22 early in each case and cut off the power supply to the heater 22.

In the above embodiment, the present invention has been exemplified by a temperature detection means that faces the heater 22 and detects its temperature. By providing a temperature detection means facing the heater 22, the fixing device 9 can be made smaller. However, this is not limited to this, and a temperature detection means that detects its temperature facing the fixing belt 20 as a belt member may also be provided.

For example, as shown in FIG. 16, a non-contact temperature detection means 36 is provided on the fixing belt 20 facing the outer peripheral surface of the fixing belt 20. The temperature detection means 36 may be, for example, a non-contact thermistor or a thermopile.

The temperature detection means 36 of this embodiment can also be arranged in the longitudinal direction in the same manner as the first thermistor 35A and the second thermistor 35B of the previously described embodiment, and can be arranged at positions corresponding to each of the previously described resistive heating elements 59.

When the temperature detection means 36 is provided in the same arrangement as the first thermistor 35A, as in the above-mentioned embodiment, when the first heat generating portion 60A is energized in the heater configuration of FIG. 10 and an unintended shunt occurs, the temperature detection means 36 can detect the temperature of the fixing belt 20 on one side in the longitudinal direction, which is the side where the heater 22 generates a large amount of heat, as in the heater configuration of FIG. 10. Then, by controlling the output of the heater 22 using the detection result of the temperature detection means 36, it is possible to detect a rise in temperature of the fixing belt 20 at an earlier timing and reduce the output of the heater 22, or to detect an abnormal rise in temperature of the fixing belt 20 and cut off the power supply to the heater 22, thereby improving the safety of the fixing device. Also, as mentioned above, an increase in the end temperature can be detected earlier.

When the temperature detection means 36 is provided in the same arrangement as the second thermistor 35B, as in the above-mentioned embodiment, when all heat generating parts in the heater configuration of FIG. 10 are energized, the temperature detection means 36 can detect the temperature of the fixing belt 20 on the other side in the longitudinal direction, which is the side where the heater 22 generates more heat. By controlling the output of the heater 22 using the detection result of the temperature detection means 36, it is possible to detect a rise in temperature of the fixing belt 20 at an earlier timing and reduce the output of the heater 22, or to detect an abnormal rise in temperature of the fixing belt 20 and cut off the power supply to the heater 22, thereby improving the safety of the fixing device. Of course, it is possible to provide the temperature detection means 36 facing the outer circumferential surface of the fixing belt 20 at each position in the longitudinal direction, as in the first to third thermistors 35A to 35C in FIG. 15.

The layout of the heater 22 is not limited to the configuration shown in FIG. 10. The present invention can be applied to a heater 22 in which a temperature deviation occurs in the heater 22 or the fixing belt 20 between one side and the other side in the longitudinal direction.

For example, as another example of a heater to which the present invention is applicable, the heater 22 shown in FIG. 17 differs from the above-mentioned embodiment in that all electrode portions are provided on one side in the longitudinal direction. In other words, compared to the heater 22 in FIG. 10 etc., it differs in that the second electrode portion 61B is provided on one side in the longitudinal direction. Also, as shown in FIG. 17, since the second electrode portion 61B is provided on one side in the longitudinal direction, the power supply line directly connected to the second electrode portion 61B extends to the other side in the longitudinal direction, bends back, and is connected to each resistive heating element 59.

In this embodiment, of the power supply lines connecting these second electrode portions 61B and each resistive heating element 59, the portion from the portion connected to each resistive heating element 59 to the folded portion on the other side in the longitudinal direction is referred to as the second power supply line 62B, and the portion from the portion extending to one side in the longitudinal direction continuous with the folded portion to the second electrode portion 61B is referred to as the fifth power supply line (conductor) 62E.

Even in such a heater 22, when electricity is applied only to the first heat generating element 60A, and when electricity is applied to both the first heat generating element 60A and the second heat generating element 60B, the temperature deviation in the longitudinal direction as described above occurs.

First, when electricity is applied only to the first heat generating section 60A, as shown in FIG. 18, an unintended shunt current occurs toward the third power supply line 62C. Therefore, the total heat generation amount of each block is asymmetrical with respect to the fourth block in the center of the heat generating area, and the heat generation amount on one side in the longitudinal direction is greater than that on the other side. However, the first block and the seventh block are non-paper passing areas through which paper does not pass. Also, when electricity is applied to the first heat generating section 60A and the second heat generating section 60B, as shown in FIG. 19, the total heat generation amount is asymmetrical with respect to the fourth block, and the heat generation amount on the other side in the longitudinal direction is greater than that on one side.

When the second power supply line 62B is partially or fully energized as described above, the amount of current increases from one side in the longitudinal direction to the other side. Also, when current flows from the second electrode portion 61B to the first electrode portion 61A or the third electrode portion 61C, the resistive heating element 59 on the other side in the longitudinal direction is positioned upstream in the current direction, and the resistive heating element 59 on one side is positioned downstream.

In the heater 22, the same effect as in the above embodiment can be obtained by arranging a temperature detection means at a position corresponding to the first thermistor 35A or the second thermistor 35B in the longitudinal direction. That is, in the case of FIG. 18, the output of the heater 22 can be controlled using the detection result of the first thermistor 35A, so that the temperature rise of the heater 22 can be detected at an earlier timing to reduce the output of the heater 22, or the abnormal temperature rise of the heater 22 can be detected to cut off the power supply to the heater 22, thereby improving the safety of the fixing device. Also, as described above, the end temperature rise can be detected at an earlier timing. Furthermore, in the case of FIG. 19, the output of the heater 22 can be controlled using the detection result of the second thermistor 35B, so that the temperature rise of the heater 22 can be detected at an earlier timing to reduce the output of the heater 22, or the abnormal temperature rise of the heater 22 can be detected to cut off the power supply to the heater 22, thereby improving the safety of the fixing device.

The present invention is particularly suitable for heaters that are small in size in the short side direction. In other words, as described above, if the short side dimension of the heater 22 is to be reduced, the short side dimension of the power supply line must be reduced, and the amount of heat generated from the power supply line becomes relatively large, which increases the impact. Specifically, it is preferable to apply the present invention to a heater 22 in which the ratio (R/Q) of the short side dimension R of the resistance heating element 59 to the short side dimension Q of the heater 22 (substrate 50) shown in FIG. 20 is 25% or more. Furthermore, it is more preferable to apply the present invention to a heater 22 in which the short side dimension ratio (R/Q) is 40% or more. By applying the present invention to such a small heater 22, greater effects can be expected.

Next, the experimental results of the temperature deviation occurring between the center side and the end side of the heater 22 in the longitudinal direction when the ratio of the short side dimensions (R/Q) is changed will be described. In the experiment, heaters 22 having the above-mentioned configuration were prepared with the above-mentioned short side dimension ratios (R/Q) of 20% or more and less than 25%, 25% or more and less than 40%, 40% or more and less than 70%, and 70% or more and less than 80%, and a predetermined voltage was applied to all the resistance heating elements of the heater under the condition of the heater alone, and the surface temperatures of the center side and the end side of the heater in the longitudinal direction were measured using an infrared thermography FLIR T620 manufactured by FLIR Systems. The above experimental results are shown in Table 1. In the results of Table 1, the temperature difference between the center side and the end side was less than 2°C as ○, the temperature difference between 2°C or more and less than 5°C as △, and the temperature difference of 5°C or more as ×. In addition, if the ratio of short side dimensions (R/Q) is 80% or more, there will be no space to place the power supply wires unless the short side dimension of the heater is made extremely large, so this was not included in the experiment.

As shown in Table 1, the temperature difference between the center and ends of the heater increased as the ratio of the short-side dimensions (R/Q) increased. Specifically, a ratio of 20% or more and less than 25% was rated as ◯, whereas a ratio of 25% or more and less than 40% changed to △, and a ratio of 40% or more and less than 70%, and a ratio of 70% or more and less than 80% changed to ×. As can be seen from these results, the temperature unevenness in the heater's longitudinal direction becomes noticeable when the ratio of the short-side dimensions (R/Q) is 25% or more, and is particularly noticeable when it is 40% or more. Therefore, it is preferable to apply the above-described configuration of this embodiment to heaters with such dimensional ratios to suppress the temperature deviation.

In addition, to suppress the temperature variation of the heater 22 described above, a resistive heating element having PTC characteristics may be used. PTC characteristics are characteristics in which the resistance value increases as the temperature increases (when a constant voltage is applied, the heater output decreases). By using a heating element with PTC characteristics, it is possible to achieve high output at low temperatures for rapid heating, and low output at high temperatures to suppress overheating. For example, if the TCR coefficient of the PTC characteristics is set to about 300 to 4000 ppm/degree, it is possible to reduce costs while ensuring the resistance value required for the heater. It is more preferable to set the TCR coefficient to 500 to 2000 ppm/degree.

The temperature coefficient of resistance (TCR) can be calculated using the following formula (2). In formula (2), T0 is the reference temperature, T1 is an arbitrary temperature, R0 is the resistance value at reference temperature T0, and R1 is the resistance value at arbitrary temperature T1. For example, in the heater 22 described above and shown in FIG. 7, if the resistance value between the first electrode portion 61A and the second electrode portion 61B is 10Ω (resistance value R0) at 25°C (reference temperature T0) and 12Ω (resistance value R1) at 125°C (arbitrary temperature T1), the temperature coefficient of resistance is 2000 ppm/°C according to formula (2).

The heater to which the present invention is applied is not limited to the heater 22 having a block-shaped (square-shaped) resistance heating element 59 as shown in FIG. 7, but can also be applied to heaters 22 having a resistance heating element 59 shaped like a folded straight line as shown in FIG. 21(a) or FIG. 21(b), or heaters having resistance heating elements of other shapes. In the figure, the colored parts indicate the resistance heating element 59. FIG. 21(a) shows an example in which the power supply lines 62A and 62D formed along the longitudinal direction of the heater 22 extend in a direction intersecting the longitudinal direction. On the other hand, FIG. 21(b) shows an example in which the resistance heating element 59 is formed including the area bent from the power supply lines 62A and 62D formed along the longitudinal direction of the heater 22 in a direction intersecting the longitudinal direction.

In addition to the fixing devices described above, the present invention can also be applied to fixing devices such as those shown in Figures 22 to 24. The configuration of each fixing device shown in Figures 22 to 24 will be briefly described below.

First, the fixing device 9 shown in FIG. 22 has a pressure roller 90 disposed on the opposite side of the fixing belt 20 from the pressure roller 21 side, and is configured so that the fixing belt 20 is sandwiched and heated by this pressure roller 90 and heater 22. On the other hand, on the pressure roller 21 side, a nip forming member 91 is disposed on the inner circumference of the fixing belt 20. The nip forming member 91 is supported by a stay 24, and the fixing belt 20 is sandwiched between the nip forming member 91 and the pressure roller 21 to form a fixing nip N.

Next, in the fixing device 9 shown in FIG. 23, the pressure roller 90 described above is omitted, and the heater 22 is formed in an arc shape to match the curvature of the fixing belt 20 in order to ensure the circumferential contact length between the fixing belt 20 and the heater 22. The rest of the configuration is the same as that of the fixing device 9 shown in FIG. 22.

Finally, the fixing device 9 shown in FIG. 24 will be described. The fixing device 9 is composed of a heating assembly 92, a fixing roller 93 as a fixing member, and a pressure assembly 94 as an opposing member. The heating assembly 92 has the heater 22 and heating unit 19 described in the previous embodiment, and a heating belt 120 as a belt member. The fixing roller 93 is composed of a solid iron core 93a, an elastic layer 93b formed on the surface of the core 93a, and a release layer 93c formed on the outside of the elastic layer 93b. A pressure assembly 94 is provided on the opposite side of the fixing roller 93 from the heating assembly 92 side. The pressure assembly 94 has a nip forming member 95 and a stay 96 arranged therein, and a pressure belt 97 rotatably arranged so as to enclose the nip forming member 95 and the stay 96. Then, a paper P is passed through the fixing nip N2 between the pressure belt 97 and the fixing roller 93, and the image is fixed by heating and pressing it.

In the fixing device 9 shown in FIG. 24, the heating assembly 92 heats the fixing roller 93, so if there is a difference in the amount of heat generated between one side and the other side of the heater 22 in the longitudinal direction (depth direction in the figure) as described above, there will also be a difference in temperature between one side and the other side in the longitudinal direction of the fixing roller 93.

Even in the fixing device of Figures 22 to 24, by providing a temperature detection means at a position facing the heater 22 or fixing belt 20 (heating belt 120) and in the longitudinal direction corresponding to the first thermistor 35A and second thermistor 35B described above, it is possible to detect a rise in temperature of the heater 22 or fixing belt 20 (heating belt 120) at an earlier timing and reduce the output of the heater 22, or to detect an abnormal rise in temperature of the heater 22 or fixing belt 20 (heating belt 120) and cut off the power supply to the heater 22, thereby improving the safety of the fixing device. Also, an increase in the end temperature can be detected earlier.

The present invention is not limited to the fixing device described in the above embodiment, but can also be applied to heating devices such as drying devices that dry ink applied to paper, and further heating devices such as laminators that thermocompress the surface of a sheet such as paper with a film as a covering member, and heat sealers that thermocompress the seal portion of a packaging material. By applying the present invention to such devices, it is possible to detect an abnormal temperature rise in the heating element or heated element at an earlier timing and cut off the power supply to the heating element, thereby improving the safety of the heating device.

Recording media include paper P (plain paper), as well as cardboard, postcards, envelopes, thin paper, coated paper (coated paper, art paper, etc.), tracing paper, overhead projector sheets, plastic film, prepreg, copper foil, etc.

1 Image forming apparatus 9 Fixing device (heating device)
19 Heating unit 20 Fixing belt (heated member or belt member or fixing member)
21 Pressure roller (opposing member or pressure member)
22 Heater (heating body)
35 Thermistor (temperature detection means)
36 Temperature detection means 59 Resistance heating element (heating element)
60 Heat generating portion 61 Electrode portion 62 Power supply line (conductor)
66 Control circuit (control unit)
A: Paper feed direction C: Heating area generated by all resistance heating elements C0: Center position of the heating area N: Fixing nip (nip portion)
P Paper (recording medium or heated object)
Q: Short side dimension of heater R: Short side dimension of resistance heating element
Y: Short side of heater

JP 2016-62024 A

Claims (17)

A heating body;
A heating device equipped with a plurality of temperature detection means,
The heating body is
A first heating portion including at least two resistive heating elements;
a second heating section including at least two resistive heating elements each located closer to both ends of the heating body in the longitudinal direction than the first heating section;
A plurality of conductors;
a first electrode portion connected to the first heat generating portion via the conductor;
a second electrode portion connected to the first heat generating portion and the second heat generating portion via the conductor;
a third electrode portion connected to the second heat generating portion via the conductor;
In the longitudinal direction, when a region from the resistive heating element arranged on the most one side to the resistive heating element arranged on the most other side among all the resistive heating elements included in the heating element is defined as a heat generating region,
In the longitudinal direction, the first electrode portion is disposed on one side with respect to a center position of the heat generating region,
In the longitudinal direction, the first temperature detection means as the temperature detection means is a resistive heating element included in the first heating portion, and is disposed at a position corresponding to the resistive heating element disposed on one side of the center position of the heating area, and the second temperature detection means as the temperature detection means is a resistive heating element included in the second heating portion, and is disposed at a position corresponding to the resistive heating element disposed on the other side of the center position of the heating area ,
the second electrode portion is connected to each of the resistance heating elements of the first heating portion and the second heating portion via the conductor in order from the resistance heating element closest to the other side in the longitudinal direction to the one side in the longitudinal direction,
A heating device, characterized in that all of the temperature detection means provided in the heating device are arranged asymmetrically on one side and the other side in the longitudinal direction with respect to a central position of the heat generation region . 2. The heating device according to claim 1,
The temperature detection means is a heating device arranged at a position corresponding to the endmost resistive heating element on the one side among the resistive heating elements of the first heating portion. In the heating device according to claim 1 or 2 ,
The temperature detection means is a heating device arranged at a position corresponding to the endmost resistive heating element on the other side among the resistive heating elements of the second heating portion. The heating device according to claim 1 , wherein the first heat generating portion has a plurality of resistive heating elements electrically connected in parallel. In the heating device according to any one of claims 1 to 4 ,
The heating device further comprises a temperature detection means provided at a position corresponding to the centralmost resistance heating element in the longitudinal direction among the resistance heating elements. The heating device according to any one of claims 1 to 5, wherein the conductor connecting the first heat generating portion or the second heat generating portion to the second electrode portion includes a portion in which the amount of current increases from one side to the other side in the longitudinal direction. 7. The heating device according to claim 1, wherein the heater heats a rotatable endless belt member. 8. The heating device according to claim 7 , wherein said temperature detection means detects the temperature of said belt member. 9. The heating device according to claim 8 , wherein the temperature detection means is disposed opposite to and in non-contact with the belt member. 10. The heating device according to claim 9 , wherein the temperature detection means is a non-contact thermistor. 10. The heating device according to claim 9 , wherein said temperature sensing means is a thermopile. The heating device according to claim 1 , wherein the temperature detection means is disposed opposite the heating body. If a direction perpendicular to the longitudinal direction of the heating body and different from the thickness direction of the heating body is defined as a short direction,
13. The heating device according to claim 1, wherein a ratio of a short-side dimension of the resistance heating element to a short-side dimension of the heating element is 25% or more. If a direction perpendicular to the longitudinal direction of the heating body and different from the thickness direction of the heating body is defined as a short direction,
13. The heating device according to claim 1, wherein a ratio of a short-side dimension of the resistance heating element to a short-side dimension of the heating element is 40% or more. 15. The heating device according to claim 1, which is a fixing device for fixing an image on a recording medium. An image forming apparatus comprising the heating device according to claim 1 . The heating device according to claim 1 ;
An image forming apparatus including a control unit for controlling power supply to the heating body,
When the first heat generating portion is energized, the first temperature detecting means detects the temperature and the control unit controls the heating body;
an image forming apparatus, wherein when the first heat generating portion and the second heat generating portion are energized, the second temperature detecting means detects the temperature and the control portion controls the heater;

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