JP2013101168A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming apparatus that adjusts connection of a steering device and a steering roller so as to prevent skew movement of a belt member at a mechanical original position of the steering device, and thereby perform skew control of the belt member during image formation in a stable and precise manner.SOLUTION: A steering roller 35 rotates while supporting an intermediate transfer belt 10, and can be set in an automatic core alignment mode for autonomously moving in an inclining manner by being driven by the rotation of the intermediate transfer belt 10. A steering device 3 drives the steering roller 35 from the outside to forcibly move in an inclining manner so as to perform skew control of the intermediate transfer belt 10. A control unit 4 sets the steering device 3 at the center of a drivable range according to the inclination movement of the steering roller 35 and causes the steering device 3 to be waited, and connects the steering roller 35 in the automatic core alignment mode to the steering device 3.

Description

  The present invention relates to an image forming apparatus that controls the shifting of a belt member by forcibly tilting the steering roller from the outside during image formation, and more specifically, driving the steering roller while stopping the shifting of the belt member during non-image formation. It relates to the control to set the origin position.

  A toner image is formed on an image carrier and transferred to a recording material directly or via an intermediate transfer member, and the recording material onto which the toner image has been transferred is heated and pressed in a heating nip of a fixing device to form an image on the recording material. An image forming apparatus for fixing is widely used. In the image forming apparatus, endless belt members such as an intermediate transfer belt, a recording material conveyance belt, a transfer belt, and a fixing belt are mounted, and the deviation is controlled using a steering system. In the steering system, the amount of tilting is adjusted in real time so that one or two steering rollers rotating while supporting the inner surface of the belt member cancel the shifting of the belt member generated in the direction of the rotation axis of the steering roller. It is controlled (Patent Document 1).

  Patent Document 2 discloses a steering device that tilts a steering roller by raising and lowering a lever that supports the end of a steering roller so as to be swingable by an eccentric cam. Here, the origin position of the tilting of the steering roller is mechanically aligned with the center of the lifting stroke of the eccentric cam.

  In Patent Document 3, in a self-alignment state in which the steering roller is tilted by being driven by the rotation of the belt member, the belt conveyance in which the shift control is autonomously performed so as to cancel the shift of the belt member. The device is shown.

JP 2000-34031 A JP 11-292338 A JP 2010-281963 A

  With reference to FIG. 2, the problem of the steering apparatus disclosed in Patent Document 2 will be described. In the steering device (3), even if the steering roller (35) is positioned at the center (Q0) of the drivable range of the eccentric cam (103), usually, when the belt member (10) is rotated, the mechanical of the member Due to the mounting accuracy, the belt member is displaced. For this reason, the control origin position at which no shift is generated in the belt member (10) is a position (Q1) deviated from the center (Q0) of the drivable range by the eccentric cam (103) of the steering device.

  That is, the deviation of the belt member (10) generated by the direction in which the belt member (10) is moved closer to the control amount from the center (Q0) of the drive range of the eccentric cam (direction in which the eccentric cam 103 is rotated). The speed of movement becomes asymmetric. As a result, the belt member (10) does not have a sufficient shifting speed (front side control range in FIG. 6 (b)), or the non-linear region where the steering roller (35) and the belt member (10) slip. There is a possibility that control will be performed at (back side control range in FIG. 6B).

  Alternatively, if the direction in which the eccentric cam 103 is rotated is different with respect to the same rotation amount of the cam (103) from the control origin position (Q1) that converges the initial shift of the belt member (10), The absolute value of the moving speed of the generated belt member (10) is different. As a result, the accuracy of PID control and the like based on the absolute value of the same shifting speed is impaired.

  In the steering device disclosed in Patent Document 3, a tilt amount is automatically set in which the steering roller tilts autonomously and does not move toward the belt member. However, since the steering roller is not driven from the outside, if an unexpected disturbance occurs along with the conveyance of the recording material and the formation / transfer of the toner image, the tilting state of the steering roller may become unstable.

  The present invention adjusts the connection between the steering device and the steering roller so that the belt member is not displaced at the mechanical origin position of the steering device, so that the belt member can be stably and precisely controlled during image formation. The object is to provide a device.

  The image forming apparatus of the present invention includes an endless belt member, a steering roller that tilts and controls the belt member so that the belt member is tilted by driving the steering roller from outside. A steering device that can be controlled, an automatic alignment device that supports the steering roller so as to be tiltable, and is capable of autonomously tilting when the steering roller is driven by the rotation of the belt member; A switching device capable of switching a steering roller from being driven by the steering device and switching to a tiltable state by the automatic aligning device, and controlling the switching device so that the belt member is autonomous by the automatic aligning device. From forced shift control to forced shift control of the belt member by the steering device In which a control means for the line.

  In the image forming apparatus according to the present invention, the steering roller is connected to the steering device in a state where the self-alignment state of the steering roller is set and the shifting of the belt member is autonomously eliminated, and the steering device is forced. Shift to shift control.

  Therefore, it is possible to connect the steering roller in a state in which the shift of the belt member is eliminated to the steering device that is kept waiting at the mechanical origin position. Thereby, the shift movement of the belt member at the mechanical origin position of the steering device can be eliminated, and thereafter, the belt member can be stably and precisely controlled by the steering device.

1 is an explanatory diagram of a configuration of an image forming apparatus. It is explanatory drawing of a structure of the steering device of Example 1. FIG. It is explanatory drawing of a belt edge sensor. It is explanatory drawing of the relationship between the inclination of a steering roller, and a belt shift speed. It is explanatory drawing of shift control by an automatic aligning roller. It is explanatory drawing of the relationship between the amount of tilting of a steering roller, and deviation correction speed. It is explanatory drawing of the switching mechanism of an automatic centering roller and steering control. 3 is a flowchart of home position setting control according to the first embodiment. FIG. 10 is an explanatory diagram of a configuration of an image forming apparatus in Embodiment 4. FIG. 6 is an explanatory diagram of an inclination of an intermediate transfer belt in a traveling direction.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. According to the present invention, as long as the image forming is performed by shifting the steering roller from the self-aligning state to the shift control by the steering device, a part or all of the configuration of the embodiment is replaced with the alternative configuration. It can also be implemented in the embodiment.

  Therefore, the present invention can be implemented not only by the intermediate transfer belt but also by a belt conveyance mechanism mounted on the image forming apparatus, such as a recording material conveyance belt, a transfer belt, and a fixing belt. The image forming apparatus can be implemented without distinction between a tandem type / 1 drum type, an intermediate transfer type / a recording material conveyance type, a charging method, an electrostatic image forming method, a developing method, a transfer method, and a fixing method. In the present embodiment, only main parts related to toner image formation / transfer will be described. However, the present invention includes a printer, various printing machines, a copier, a fax machine, a composite machine, in addition to necessary equipment, equipment, and a housing structure. It can be implemented in various applications such as a machine.

<Image forming apparatus>
FIG. 1 is an explanatory diagram of the configuration of the image forming apparatus. As shown in FIG. 1, the image forming apparatus 1 is a tandem intermediate transfer type full-color printer in which yellow, magenta, cyan, and black image forming units 22, 23, 24, and 25 are arranged along an intermediate transfer belt 10. is there.

  In the image forming unit 22, a yellow toner image is formed on the photosensitive drum 30 and transferred to the intermediate transfer belt 10. In the image forming unit 23, a magenta toner image is formed in the same procedure as the image forming unit 22, and transferred onto the yellow toner image on the intermediate transfer belt 10. In the image forming units 24 and 25, a cyan toner image and a black toner image are formed in the same procedure as the image forming unit 22, and are sequentially transferred onto the intermediate transfer belt 10.

  The secondary transfer roller 37 abuts on the intermediate transfer belt 10 whose inner surface is supported by the counter roller 36 to form a secondary transfer portion T2. The recording material P drawn from the recording material cassette 51 is separated one by one by the separation roller 52 and sent to the registration roller 53. The registration roller 53 sends the recording material P to the secondary transfer portion T2 in time with the toner image on the intermediate transfer belt 10.

  The four color toner images carried on the intermediate transfer belt 10 are conveyed to the secondary transfer portion T2 and are collectively secondary transferred to the recording material P. A voltage is applied to the secondary transfer roller 37 in the process in which the recording material P is nipped and conveyed over the secondary transfer portion T2 while being superimposed on the toner image, so that the full color toner image is transferred from the intermediate transfer belt 10 to the recording material P. Next is transferred. The untransferred toner remaining on the intermediate transfer belt 10 without being transferred is collected by the belt cleaning device 39.

  The recording material P on which the four-color toner images are secondarily transferred is separated from the intermediate transfer belt 10 by the curvature and sent to the fixing device 50. The fixing device 50 heats and presses the recording material P to melt the toner and fix the image on the surface. Thereafter, the recording material P is discharged out of the machine body.

  The image forming units 22, 23, 24, and 25 are configured substantially the same except that the color of the toner used in each developing device is different from yellow, magenta, cyan, and black. In the following, the toner image forming process for the yellow image forming unit 22 will be described, and redundant description for the other image forming units 23, 24, and 25 will be omitted.

  In the image forming unit 22, a corona charger 26, an exposure device 29, a developing device 28, a transfer roller 33, and a drum cleaning device 27 are disposed around the photosensitive drum 30. The photosensitive drum 30 is formed with a negatively charged photosensitive layer on the surface, and rotates in the direction of the arrow R1 at a predetermined process speed. The corona charger 26 irradiates charged particles accompanying corona discharge to charge the surface of the photosensitive drum 30 to the negative dark potential VD. The exposure device 29 scans the scanning line image data obtained by developing the yellow separation color image with a rotating mirror, and writes an electrostatic image of the image on the surface of the photosensitive drum 30.

  The developing device 28 charges a two-component developer containing non-magnetic toner and a magnetic carrier, carries the developer on the developing sleeve 28 s, and conveys it to a portion facing the photosensitive drum 30. By applying an oscillating voltage obtained by superimposing an AC voltage on a DC voltage to the developing sleeve 28s, the negatively charged nonmagnetic toner is transferred to the exposed portion of the photosensitive drum 30 having a relatively positive polarity, and an electrostatic image is obtained. Is reversely developed.

  The transfer roller 33 presses the inner surface of the intermediate transfer belt 10 to form a transfer portion T <b> 1 between the photosensitive drum 30 and the intermediate transfer belt 10. By applying a positive voltage to the transfer roller 33, the toner image carried on the photosensitive drum 30 is transferred to the intermediate transfer belt 10. The drum cleaning device 27 rubs the photosensitive drum 30 with a cleaning blade to recover the transfer residual toner remaining on the photosensitive drum 30 while escaping from the transfer to the intermediate transfer belt 10.

<Belt drive mechanism>
The belt driving mechanism 2 is rotatable by the intermediate transfer belt 10 being stretched around driven rollers 31 and 32, a transfer roller 33, a drive roller 34, a steering roller 35, and a counter roller 36. The driven rollers 31 and 32 support the transfer surface of the photosensitive drum 30 and keep the contact state between the photosensitive drum 30 and the intermediate transfer belt 10 constant. The drive roller 34 is rotationally driven to rotate the intermediate transfer belt 10. The steering roller 35 also serves as a tension roller for the intermediate transfer belt 10. The steering roller 35 is attached so as to be movable in the horizontal direction, and is pressurized from the inside to the outside of the intermediate transfer belt 10 to apply a certain tension to the intermediate transfer belt 10.

  In the image forming apparatus 1 that employs the belt drive mechanism 2, many functions can be improved. However, the intermediate transfer belt 10 during operation is shifted or meandered, which is a phenomenon unique to the endless belt mechanism. To do. The intermediate transfer belt 10 is shifted or meandered by the belt drive mechanism 2, the mechanical accuracy of the intermediate transfer belt 10 itself, the characteristic change of the intermediate transfer belt 10, and the recording material P coming into contact with the intermediate transfer belt 10. It is caused by impact, vibration, torsional force, etc.

  For this reason, in the image forming apparatus 1, the steering device 3 is provided to suppress the shifting and meandering of the intermediate transfer belt 10. When the intermediate transfer belt 10 is moved or meandered, the steering device 3 detects the position of the intermediate transfer belt 10 and controls the amount of tilt of the steering roller 35 according to the detected position. The shift and meandering of the intermediate transfer belt 10 are corrected. The steering roller 35 can perform the deviation control of the intermediate transfer belt 10 by arbitrarily changing the tilt amount in the direction of the arrow R35.

<Steering device>
FIG. 2 is an explanatory diagram of the configuration of the steering apparatus according to the first embodiment. FIG. 3 is an explanatory diagram of the belt edge sensor. FIG. 4 is an explanatory diagram of the relationship between the inclination of the steering roller and the belt shift speed. FIG. 2 is an enlarged view of the vicinity of the steering roller of FIG.

  As shown in FIG. 2, the steering device 3 can control the side of the intermediate transfer belt 10, which is an example of an endless belt member, by driving the steering roller 35 from the outside and forcibly tilting the steering roller 35. is there. Steering arms 105 and 106 as an example of a driving mechanism drive the end portion of the steering roller 35 in the tilting direction of the steering roller 35.

  The steering arm 105 on the front side is fixed to the arm support member 101 via a slide rail (not shown), and the steering arm 105 can slide in the X direction with respect to the arm support member 101. The steering arm 105 is provided with a long hole 105a. The end portion 35a of the steering roller 35 passed through the elongated hole 105a is biased in the + X direction by the spring 42 via the steering arm 105.

  The rear steering arm 106 is also provided with a mechanism similar to that of the steering arm 105, and the steering roller 105 is urged in the + X direction by the steering arms 105 and 106, thereby applying tension to the intermediate transfer belt 10. . In the first embodiment, both end portions of the steering roller 35 are urged outward by the spring 42 to apply a certain tension to the intermediate transfer belt 10. However, the steering function and the tension applying function are separated from each other. It does not matter as a configuration.

  An arm support member 101 is supported on the front side plate 121 so as to be rotatable about an arm shaft 104. On the arm support member 101, a follower 102 driven by an eccentric cam 103 is attached to a rotating end portion on the opposite side to the steering roller 35 with respect to the arm shaft 104. An eccentric cam 103 is provided so as to contact the follower 102, and the eccentric cam 103 is configured to be rotatable by the steering motor 41.

  Between the bearing holder 107 and the steering arm 105, a pressure contact member 109 that can attach and detach the bearing holder 107 with respect to the steering arm 105 is disposed. When the pressure contact member 109 is operated to fix the bearing holder 107 to the steering arm 105, the steering motor 41 can be controlled to tilt the steering roller 35 to correct the belt shift. A bearing 110 is provided at a contact portion between the steering arm 105 and the end portion 35a of the steering roller 35 to reduce friction between both members.

  The control unit 4 detects the shift position of the intermediate transfer belt 10 by the belt edge sensor 38. The control unit 4 controls the amount of rotation of the eccentric cam 103 so that the output value of the belt edge sensor 38 is constant, generates an arbitrary shift correction speed in the intermediate transfer belt 10, and moves the intermediate transfer belt 10. Rotate stably.

  As shown in FIG. 3, in the belt edge sensor 38, an actuator 381 that can rotate about a rotation shaft 386 is urged by a torsion spring 385, and a sliding portion 382 is placed on the belt edge 10 a of the intermediate transfer belt 10. It is in contact. The optical distance sensor 383 detects the distance to the reflecting mirror on the lower surface of the actuator 381. The actuator 381 rotates in response to the movement of the belt edge 10a of the intermediate transfer belt 10 to change the output of the optical distance sensor 383.

  As shown in FIG. 4, the shifting direction of the intermediate transfer belt 10 changes according to the tilting direction of the steering roller 35. As shown in FIG. 4A, when the driven roller 32, the steering roller 35, and the opposing roller 36 are arranged in parallel, the intermediate transfer belt 10 does not move in the rotational axis direction of the steering roller 35.

  As shown in FIG. 2, when the steering motor 41 rotates the eccentric cam 103 and pushes down the follower 102, the arm support member 101 rotates about the arm shaft 104 in the arrow + θ direction, and the steering roller 35 rotates. It rotates in the direction of arrow -φ. As a result, the steering roller 35 tilts so that the front side is higher than the back side of the steering roller 35, and the intermediate transfer belt 10 moves in the + Y direction as it rotates.

  As shown in FIG. 4C, when the steering roller 35 is tilted so as to raise the end 35a on the back side, the intermediate transfer belt 10 moving in the arrow R2 direction moves closer to the + Y direction.

  As shown in FIG. 2, when the steering motor 41 rotates the eccentric cam 103 and pushes up the follower 102, the arm support member 101 rotates about the arm shaft 104 in the −θ direction, and the steering roller 35 It rotates in the + φ direction. As a result, the steering roller 35 tilts so that the back side is higher than the near side of the steering roller 35, and the intermediate transfer belt 10 moves in the -Y direction as it rotates.

  As shown in FIG. 4B, when the steering roller 35 is tilted so as to lower the end portion 35a on the near side, the intermediate transfer belt 10 moving in the arrow R2 direction moves closer to the -Y direction.

  Incidentally, the method of correcting the shift of the intermediate transfer belt 10 based on such a principle can be realized in addition to forcibly tilting the steering roller 35 from the outside by the steering motor 41. In the belt driving mechanism 2, when the pressure contact member 109 is released, the steering roller 35 is tilted by being driven by the rotation of the intermediate transfer belt 10, and functions as a so-called self-aligning roller so that the intermediate transfer belt 10 is autonomously offset and corrected. .

<Automatic alignment roller>
FIG. 5 is an explanatory diagram of the shift control by the automatic alignment roller. FIG. 5 schematically shows a state where the steering roller 35 operating as an automatic alignment roller is viewed from the X direction side in FIG.

  As shown in FIG. 2, the steering roller 35 is disposed so as to be able to set an automatic alignment state that rotates while supporting the intermediate transfer belt 10 and is autonomously tilted by the rotation of the intermediate transfer belt 10. . When the pressure contact member 109 is released and the bearing holder 107 is separated from the steering arm 105, the steering roller 35 supported by the bearing holder 107 becomes rotatable, and deviation control as an automatic alignment roller is started.

  Both ends of the steering roller 35 are rotatably supported by the bearing holder 107. A holder shaft 111 is provided at the center in the longitudinal direction of the bearing holder 107. The holder shaft 111 is configured to be telescopically extended in the X direction so as to move the bearing holder 107 in the horizontal direction so as not to impede the application of tension to the steering roller 35 described above.

  Since the holder shaft 111 is rotatable with respect to the beam 123 fixed between the side plates 121 and 122, the bearing holder 107 rotates about the holder shaft 111 in a state where the pressure contact member 109 is released. Is possible. As the bearing holder 107 freely rotates about the holder shaft 111, the steering roller 35 tilts autonomously so as to cancel the shifting of the intermediate transfer belt 10.

  Consider the case where the center of the intermediate transfer belt 10 is displaced in the + Y direction with respect to the holder shaft 111 as shown in FIG. At this time, a frictional force is generated between the intermediate transfer belt 10 and the steering roller 35, and the resultant frictional force of the entire steering roller 35 is generated as a force F at the center of the intermediate transfer belt 10.

  Here, if the distance between the center of the intermediate transfer belt 10 where the force F is generated and the holder shaft 111 that is the rotation center of the steering roller 35 is L, the steering roller 35 is moved to the intermediate transfer belt 10. Receives a moment of M = F × L. Then, the steering roller 35 receiving the moment of M = F × L tilts in the M direction and causes the intermediate transfer belt 10 to shift in the −Y direction as shown in FIG. 4B.

  In other words, due to the effect that the center of the intermediate transfer belt 10 is displaced with respect to the holder shaft 111, the steering roller 35 is tilted in the M direction when the intermediate transfer belt 10 is driven in the R2 direction. As a result, the intermediate transfer belt 10 moves in the −Y direction based on the principle of correcting the tilt of the steering roller 35 and the shift of the intermediate transfer belt 10.

  Similarly, when the center of the intermediate transfer belt 10 is deviated in the −Y direction with respect to the holder shaft 111, the steering roller 35 is inclined in the −M direction so as to move the intermediate transfer belt 10 in the + Y direction.

  Due to the effect of such an automatic alignment roller, the intermediate transfer belt 10 continues to rotate so that the Y coordinate of the center of the intermediate transfer belt 10 substantially matches the Y coordinate of the holder shaft 111. In this state, the steering roller 35 is in a posture in which the shifting speed does not occur.

<Home position setting>
FIG. 6 is an explanatory diagram of the relationship between the tilt amount of the steering roller and the shift correction speed. In FIG. 6, (a) shows a case where a shifting speed is not generated at the home position, and (b) is a case where a shifting speed is generated at the home position.

  As shown in FIG. 2, color misregistration of each color at the time of printing due to the shifting or meandering of the intermediate transfer belt 10 occurs particularly in the ± Y direction. The color misregistration of each color is caused by the intermediate transfer belt 10 moving in the Y direction when moving between the image forming units 22 to 25 of each color shown in FIG. If the speed of the shift of the intermediate transfer belt 10 due to disturbance is high, or if the speed of the shift of the intermediate transfer belt 10 generated by the steering roller 35 to cancel the shift is fast, the color shift of each color is large. Become.

  In the steering device 3, it is necessary to set a reference (home position) for tilting the steering roller 35 and to control the amount of tilt from the home position. At the home position, it is preferable to determine the tilting amount of the steering roller 35 so that the intermediate transfer belt 10 does not generate a shifting speed in the rotation axis direction at the steering roller 35. This is because if the home position of the steering roller 35 is not set appropriately, the intermediate transfer belt 10 is moved even at the home position, and the performance of the steering control is deteriorated.

  As shown in FIG. 4A with reference to FIG. 2, it is assumed that the shifting speed does not occur when the inclination of the steering roller 35 is at the home position. Further, when the tilting amount α, which is an angle from the home position, is set to the steering roller 35, a shift correction speed p at which the intermediate transfer belt 10 moves in the direction of the rotation axis of the steering roller 35 is generated. At this time, the relationship between the tilt amount α and the shift correction speed p is symmetrical on the left and right sides with α = 0 as shown in FIG.

  As shown in FIG. 6A, the control unit 4 causes the steering roller 35 to generate a shift speed generated in the intermediate transfer belt 10 and a shift correction speed p that cancels the meandering. Thereby, the shifting speed and meandering of the intermediate transfer belt 10 caused by various external forces acting on the intermediate transfer belt 10 are suppressed.

  However, as shown in FIG. 4A, the shifting speed does not always occur when the steering roller 35 is at the reference position.

  As shown in FIG. 6B, when a shift speed is generated at the home position of the steering roller 35, the left and right are asymmetric with respect to α = 0. Unless the tilt amount deviating from the home position is set, the shifting speed is not offset, and the relationship between the generated shifting speed and the generated shifting correction speed p is broken.

  Therefore, when starting the shift control for tilting the steering roller 35 by the steering motor 41, the attitude of the steering roller 35 at which the shift speed becomes zero is set to the home position in order to accurately determine the shift correction speed. There is a need. If the home position of the steering roller 35 is not properly set, the control quality of the steering control may be deteriorated.

  Also, even if the shifting speed is zero when the steering roller 35 is set to the home position in the initial state, the mechanical accuracy and belt characteristics of the belt drive mechanism change depending on the situation and the shifting speed occurs. There is. It is also impossible to reset the home position of the steering roller 35 in accordance with these situations.

  Therefore, in the following embodiments, the steering roller 35 is operated as an automatic alignment roller during non-image formation, thereby creating a posture of the steering roller 35 in which the shifting speed becomes zero. The home position at which the shifting speed becomes zero is set by connecting the steering roller 35 with the steering device 3 waiting at a predetermined origin position. The home position of the steering roller is set according to the mechanical accuracy of the belt driving mechanism and the belt characteristics, so that the control performance of belt deviation correction by the steering roller 35 is improved.

<Example 1>
FIG. 7 is an explanatory diagram of an automatic alignment roller and a steering control switching mechanism. FIG. 8 is a flowchart of home position setting control according to the first embodiment. FIG. 7 shows a state of a cross section of the YZ plane passing through the central axis of the steering roller 35 in FIG.

  As shown in FIG. 2, the steering device 3 can forcibly control the intermediate transfer belt 10 by driving and tilting the steering roller 35 from the outside. The bearing holder 107, which is an example of an automatic alignment device, supports the steering roller 35 so as to be tiltable, and can realize an automatic alignment state in which the steering roller 35 is autonomously tilted by being driven by the rotation of the intermediate transfer belt 10. It is.

  The pressure contact member 109, which is an example of a switching device, can switch the steering roller 35 from being driven by the steering device 3 to a tiltable state by the bearing holder 107. Steering arms 105 and 106, which are examples of moving members, move the end of the steering roller 35 in the tilting direction of the steering roller 35. A pressure contact member 109, which is an example of a connecting means, connects the end portion of the steering roller 35 to the steering arms 105 and 106 so as to be connected and released. The steering roller 35 can be freely tilted by releasing the pressure contact member 109.

  The control unit 4, which is an example of a control unit, controls the pressure contact member 109 to shift from autonomous shift control of the intermediate transfer belt 10 by the bearing holder 107 to forced shift control of the intermediate transfer belt 10 by the steering device 3. Let In the origin adjustment, which is an example of the setting mode, the steering device 3 stands by at the center position of the driving range related to the tilting of the steering roller 35, and the steering roller 35 during the autonomous shift control of the intermediate transfer belt 10 by automatic alignment. It is feasible to connect

  The control unit 4 performs autonomous shift control of the intermediate transfer belt 10 by the steering roller 35 in an automatic alignment state during non-image formation, and performs forced shift control of the intermediate transfer belt 10 by the steering device 3 during image formation. Let it run. The control unit 4 starts the rotation of the intermediate transfer belt 10 in a state of autonomous shift control of the intermediate transfer belt 10, and after the intermediate transfer belt 10 reaches a predetermined rotation speed, the steering device 3 moves the intermediate transfer belt 10. Start forced shift control.

  The steering device 3 and the steering roller 35 can be switched between connection and release by a pressure contact member 109. When the pressure contact member 109 is released, the end portion 35a of the steering roller 35 is movable along the elongated hole 105a, and the steering roller 35 functions as an automatic alignment roller. When the pressure contact member 109 is connected, the end portion 35a of the steering roller 35 is fixed to one point on the elongated hole 105a, and the steering roller 35 is tilted by being driven by the steering device 3.

  As shown in FIG. 7, a pressure contact member 109 is disposed between the bearing holder 107 and the steering arm 105. The pressure contact member 109 is a clutch mechanism including a fixed portion 109 a and a movable portion 109 b, and the fixed portion 109 a is fixed to the inner side surface of the steering arm 105. The movable portion 109b can be relatively moved in the contact / separation direction by a solenoid incorporated in the fixed portion 109a, and the movable portion 109b can be arbitrarily pressed against and separated from the bearing holder 107.

  As shown in FIG. 7A, the steering roller 35 can freely rotate together with the bearing holder 107 in a state where the movable portion 109 b is separated from the bearing holder 107.

  As shown in FIG. 7B, in a state where the movable portion 109b is in pressure contact with the bearing holder 107, the bearing holder 107 is fixed to the steering arm 105, and the attitude of the steering roller 35 is determined by the position of the steering arm 105. .

  In the first embodiment, as shown in FIG. 7A, the movable portion 109b is separated from the bearing holder 107, and the steering roller 35 functions as an automatic alignment roller. At this time, as described above, the steering roller 35 is in a posture in which the shift correction speed does not occur. In this state, the pressure contact member 109 is operated, and the bearing holder 107 is fixed to the steering arm 105 as shown in FIG. 7B, whereby the attitude of the steering roller 35 functioning as an automatic centering roller. Is taken in as the home position for shift control.

  As shown in FIG. 8 with reference to FIG. 2, the control unit 4 releases the press contact member 109 and separates the steering arm 105 and the bearing holder 107 (S1), and then activates the belt drive mechanism 2. The intermediate transfer belt 10 is started to rotate (S2).

  As a result, the steering roller 35 starts to operate as an automatic alignment roller, and the steering roller 35 is rotated by the force received from the intermediate transfer belt 10 to autonomously control the intermediate transfer belt 10 to be shifted.

  The control unit 4 takes in the output of the belt edge sensor 38 and determines that the intermediate transfer belt 10 does not move or meander and is rotating stably (S3).

  When the output of the belt edge sensor 38 is stabilized (Yes in S3), the control unit 4 operates the pressure contact member 109 to fix the bearing holder 107 to the steering arm 105 (S4).

  The home position setting of the steering roller 35 is completed by the process as described above. With the above operation, it is possible to set a posture in which the deviation correction speed does not occur in the steering roller 35 as a home position for tilting the steering roller 35.

  Since the steering device 3 forcibly changes the tilting amount of the steering roller 35, the setting of the home position of the steering roller 35 is important. Therefore, in the first embodiment, the home position is detected by operating the steering roller 35 as an automatic alignment roller. However, after the home position is set, by performing forced shift movement control by the steering roller 35, it is possible to reduce color misregistration of each color during image formation.

  That is, it is possible to operate the steering roller 35 as an automatic alignment roller even during image formation. However, if the steering roller 35 is operated as an automatic centering roller during image formation, the steering roller tilts as soon as the shift occurs, so fine control cannot be performed, resulting in large color misregistration of each color. There is sex. If a large disturbance occurs when the recording material enters the secondary transfer portion T2, an excessive response may occur and the steering roller 35 may be temporarily in a vibrating state.

  On the other hand, since the steering device 3 forcibly determines the amount of tilt of the steering roller 35, the steering response speed and response gain can be optimized, and the response timing can be shifted. The steering device 3 can also moderately correct the positional deviation in the Y direction of the intermediate transfer belt 10 caused by disturbance by providing a time difference. The steering device 3 can also temporarily fix the tilt amount when the toner image passes through the image forming units 22, 23, 24, and 25, and the steering device 3 moves in a state that does not affect the image transfer. It is also possible to reduce the influence on the image by increasing the correction speed. The steering device 3 can predict the disturbance generated with the transfer of the toner image and the feeding of the recording material, and can suppress the shift of the intermediate transfer belt 10 in advance and can perform integral control. is there.

  In the first embodiment, when the steering roller 35 operates as an automatic alignment roller, the steering roller 35 rotates to automatically find a position where the center of the intermediate transfer belt 10 coincides with the holder shaft 111. When the center of the intermediate transfer belt 10 coincides with the holder shaft 111, the steering roller 35 maintains a posture in which a deviation correction speed is not generated by the force received from the intermediate transfer belt 10. Then, by setting the posture as the home position of the steering roller 35 and controlling the amount of tilt with reference to the home position, the control performance of belt deviation correction is improved.

  In the first embodiment, the home position of the steering roller 35 is optimized in accordance with the mechanical accuracy of the belt driving mechanism 2 and the characteristics of the intermediate transfer belt 10, so that the control performance of belt deviation correction by the steering roller 35 is improved.

  In the first embodiment, installing a photo sensor that determines the center of the drivable range of the eccentric cam 103 so that a signal is output when the steering roller 35 is in an appropriate posture can improve the performance and mounting accuracy of the photo sensor. It is easy regardless.

  In the first embodiment, even when the center of the driveable range of the eccentric cam 103 is detected by a mechanical configuration, the steering roller 35 is not deviated from an appropriate posture regardless of the assembly accuracy of the parts.

  In the first embodiment, the mechanical accuracy and belt characteristics of the belt driving mechanism 2 change according to the situation, but can be reset to the home position of the steering roller 35 according to the situation.

  In the first embodiment, as a method of fixing the bearing holder 107 to the steering arm 105, the press contact member 109 that mechanically presses is used. However, the present invention is not limited to this, and any structure that can be fixed and separated, such as an air cylinder, an electromagnetic clutch, and screw fastening, can be replaced.

<Example 2>
In the first embodiment, the home position of the steering roller 35 in the steering device 3 is set by operating the steering roller 35 as an automatic alignment roller. On the other hand, in the second embodiment, not only the home position setting but also the control unit 4 executes autonomous shift control of the intermediate transfer belt 10 by the steering roller 35 in the automatic alignment state at the time of non-image formation. Then, forced shift control of the intermediate transfer belt 10 by the steering device 3 is executed during image formation.

  In the second embodiment, the same mechanism as that of the first embodiment is used, and when the non-image is formed, the pressing member 109 is always released and the steering roller 35 is operated as an automatic alignment roller. The press contact member 109 is connected immediately before an image forming job is input and the first image is formed by the image forming units 22, 23, 24, and 25. When the last image is transferred onto the recording material, the press contact member 109 is connected. Is released. While the pressure contact member 109 is released, the steering device 3 stands by at the center of the drivable range (the state where the eccentric cam 103 is rotated to the ± 0 center position of the cam curve).

<Example 3>
In the third embodiment, the timing for setting the home position of the steering roller 35 will be described. In the third embodiment, the control unit 4 starts the rotation of the intermediate transfer belt 10 in an autonomous shift control state of the intermediate transfer belt 10 by the steering roller 35 in the automatic alignment state. Then, after the intermediate transfer belt 10 reaches a predetermined rotational speed, the forced shift control of the intermediate transfer belt 10 by the steering device 3 is started.

  When the image forming apparatus 1 is turned on, first, initial operations such as cleaning of the intermediate transfer belt 10 and detection of a color misregistration amount by an optical sensor (not shown) are performed. The home position of the steering roller 35 can be set in parallel with these initial operations.

  When the steering roller 35 is fixed to the steering device 3 and rotation of the intermediate transfer belt 10 is started, it is necessary to set the home position of the steering roller 35 before performing the initial operation. This is because if the home position is not set, there is a possibility that the intermediate transfer belt 10 will be cut off, or that the intermediate transfer belt 10 may become unstable and affect the initial operation.

  On the other hand, as described above, when the rotation of the intermediate transfer belt 10 is started using the steering roller 35 as an automatic alignment roller, the intermediate transfer belt 10 approaches even in a transient state where the speed rises due to the effect of the automatic alignment roller. There is nothing. Therefore, the home position can be set in parallel with the initial operation such as cleaning of the intermediate transfer belt 10, and the startup loss time of the image forming apparatus 1 can be reduced.

  Further, the mechanical accuracy and belt characteristics of the belt driving mechanism 2 may change due to a temperature rise in the image forming apparatus 1 or the like. Also in such a case, when the image forming job is interrupted, the home position can be reset by temporarily separating the steering roller 35 from the steering device 3.

<Example 4>
FIG. 9 is an explanatory diagram of a configuration of the image forming apparatus according to the fourth embodiment. FIG. 10 is an explanatory diagram of the inclination of the intermediate transfer belt in the traveling direction. In the first embodiment, a belt conveyance mechanism using one steering roller is shown. In the fourth embodiment, a belt conveyance mechanism using two steering rollers is shown.

  In the case of a belt conveying mechanism using two steering rollers separated from each other, the effect of releasing the stress of the intermediate transfer belt 10 is obtained by operating both of the two steering rollers simultaneously as an automatic alignment roller. It is done.

  As shown in FIG. 9, the steering device 3, which is an example of the first steering device, controls the intermediate transfer belt 10 by forcibly tilting the steering roller 35, which is an example of the first steering roller. The steering device 7 as an example of the second steering device controls the intermediate transfer belt 10 by forcibly tilting the steering roller 45 as an example of the second steering roller.

  The first automatic alignment device and the second automatic alignment device are constituted by bearing holders (107: FIG. 2) incorporated in the steering devices 3 and 7, respectively, and support the steering roller 35 and the steering roller 45 in a tiltable manner. To do. The first switching device and the second switching device are configured by pressure contact members (109: FIG. 2) incorporated in the steering devices 3 and 7, respectively, and the steering roller 35 and the steering roller 45 are separated from driving by the steering devices 3 and 7. Is possible.

  The control unit 4, which is an example of a control unit, rotates the intermediate transfer belt 10 to connect the steering rollers 35 and 45 to the steering devices 3 and 7, respectively, in a state where the steering rollers 35 and 45 are set in an automatic alignment state. Thereby, the intermediate transfer belt 10 shifts from the autonomous shift control by the steering rollers 35 and 45 in the automatic alignment state to the forced shift control by the steering devices 3 and 7.

  In the image forming apparatus 6 according to the fourth exemplary embodiment, a steering device 7 having the same configuration as that of the steering device 3 is disposed between the driving roller 34 and the driven roller 31 of the image forming apparatus 1 illustrated in FIG. 1. In addition, a belt edge sensor 48 having the same configuration as the belt edge sensor 38 is disposed between the driven roller 31 and the transfer roller 33 in order to detect the shift amount of the intermediate transfer belt 10 controlled by the steering device 7. Yes. Further, since the tension to the intermediate transfer belt 10 is applied by the steering roller 35 of the steering device 3, the urging member corresponding to the spring 42 is not attached to the steering device 7. However, other than this, the image forming apparatus 6 is configured in the same manner as in the first embodiment, and the steering devices 3 and 7 are controlled in the same manner as in the first embodiment. Therefore, in FIG. 9, the same components as those in FIG.

  The steering device 7 tilts and controls the intermediate transfer belt 10 by tilting a steering roller 45 having the same function as the steering roller 35. The belt edge sensor 48 has the same function as the belt edge sensor 38 shown in FIG. The steering roller 45 is supported by a bearing holder (not shown) (107: FIG. 2) so that an automatic alignment state can be set.

  The control unit 4 operates the steering motor 41 based on the belt shift amount detected by the belt edge sensor 48 to control the rotation angle of the eccentric cam 103 to change the tilt angle of the steering arm 105. As a result, a tilt amount corresponding to the tilt angle of the steering arm 105 is set in the steering roller 45.

  The control unit 4 operates the pressure contact member 109 to fix the bearing holder (107) to the steering arm 105, thereby connecting the steering roller 45 to the steering device 7 so that the steering control is possible. The controller 4 sets the automatic alignment state for the steering roller 45 by releasing the pressure contact member 109.

  As shown in FIG. 10, the controller 4 simultaneously controls the shift of the intermediate transfer belt 10 by the two steering rollers 35 and 45. As shown in FIG. 8 with reference to FIG. 9, the control unit 4 sets the home positions of the steering rollers 35 and 45 using the same procedure as in the first embodiment.

  As shown in FIG. 2, the control unit 4 operates the pressure contact member 109 so that the steering roller 35 is separated from the steering arm 105. A function similar to this is also provided in the steering roller 45, and the control unit 4 moves the steering roller 45 away from the steering arm 105 (S1).

  When the control unit 4 separates the steering rollers 35 and 45 from the steering devices 3 and 7 and starts to rotate the intermediate transfer belt 10, both the steering rollers 35 and 45 operate as automatic alignment rollers (S2). Due to the effect of the self-aligning roller, the intermediate transfer belt 10 continues to rotate so that the center of the intermediate transfer belt 10 substantially coincides with the rotation center of the steering rollers 35 and 45 in the rotational axis direction of the steering rollers 35 and 45. . In this state, the steering rollers 35 and 45 are automatically tilted so that no shifting speed is automatically generated.

  The control unit 4 determines from the values of the belt edge sensors 38 and 48 that the intermediate transfer belt 10 does not have a shifting speed or meandering (S3).

  The controller 4 operates the pressure contact member 109 to fix the postures of the steering rollers 35 and 45, and sets this posture as a home position for steering control of the steering rollers 35 and 45 (S4). Thereby, in the steering rollers 35 and 45, it is possible to set a posture in which the shifting speed does not occur as a home position for each steering control.

  The control unit 4 starts image formation. Thereafter, the steering roller 35 controls the position of the intermediate transfer belt 10 in the shift direction based on the detection result of the belt edge sensor 38 and the steering roller 45 based on the detection result of the belt edge sensor 48.

  As shown in FIG. 6B, when the home position of the steering rollers 35 and 45 is simply set to the center position of the stroke of the eccentric cam 103, the intermediate transfer is performed even if the steering rollers 35 and 45 are set to the home position. A deviation speed is generated in the belt 10.

  In order to set the home positions of the steering rollers 35 and 45 so that the shifting speed does not occur in the intermediate transfer belt 10, it is necessary to set the target values of the belt edge sensors 38 and 48 in advance. At this time, if the target value is not properly set, a force that may be forcibly twisted in the direction toward the intermediate transfer belt 10 may act, and the control may not be stable. As shown in FIG. 10, there is a possibility that a shearing force acts on the intermediate transfer belt 10 due to a shift movement generated in the steering roller 35 and a reverse shift movement generated in the steering roller 45, thereby generating a wave. There is.

  On the other hand, in the configuration of the fourth embodiment, when setting the home positions of the steering rollers 35 and 45, a position where the intermediate transfer belt 10 can be stably rotated without being completely moved is searched. The shift movement generated in the steering roller 35 and the shift movement in the reverse direction generated in the steering roller 45 are eliminated.

  In the fourth embodiment, the detection results of the belt edge sensors 38 and 48 when the home positions of the steering rollers 35 and 45 are set are reflected in the target value, so that the intermediate transfer belt 10 does not become unstable. Can be corrected.

  In the fourth embodiment, since the intermediate transfer belt 10 is rotated in a state where both the steering rollers 35 and 45 operate as automatic alignment rollers, it is possible to simultaneously search for postures in which the shifting speed does not occur in each of the steering rollers 35 and 45. . At this time, since appropriate target values of the belt edge sensors 38 and 48 are also searched, the control performance of belt deviation correction by the alignment of the steering rollers 35 and 45 is improved.

DESCRIPTION OF SYMBOLS 1 Image forming apparatus, 2 Belt drive mechanism, 3, 7 Steering device 4 Control part, 10 Intermediate transfer belt, 34 Belt drive roller 35, 45 Steering roller, 38, 48 Belt edge sensor 40 Belt drive motor, 41 Steering motor, 42 Spring 101 Arm support plate, 102 follower, 103 Eccentric cam 104 Arm shaft, 105, 106 Steering arm, 107 Bearing holder 109 Pressure contact member, 110 Bearing, 111 Holder shaft

Claims (7)

An endless belt member;
A steering roller that tilts and controls the belt member to be shifted;
A steering device capable of forcing and controlling the belt member by driving and tilting the steering roller from the outside;
An automatic alignment device that supports the steering roller in a tiltable manner, and the steering roller can be autonomously tilted by being driven by the rotation of the belt member;
A switching device capable of switching the steering roller from being driven by the steering device and switching to a tiltable state by the automatic alignment device;
Control means for controlling the switching device to shift from the autonomous shift control of the belt member by the automatic alignment device to the forced shift control of the belt member by the steering device, Image forming apparatus.   The controller is configured to execute autonomous shift control of the belt member by the automatic alignment device during non-image formation and execute forced shift control of the belt member by the steering device during image formation. The image forming apparatus according to claim 1.   The control means starts rotation of the belt member in a state of autonomous shift control of the belt member by the automatic alignment device, and after the belt member reaches a predetermined rotational speed, the belt by the steering device 3. The image forming apparatus according to claim 2, wherein forced shift control of the member is started.   The control means sets the steering device to stand by at the center position of the driving range related to the tilting of the steering roller, and connects the steering roller during autonomous shift control of the belt member by the automatic alignment device The image forming apparatus according to claim 1, wherein the mode can be executed. The steering device has a moving member that moves an end portion of the steering roller in a tilting direction of the steering roller;
The switching device has a connecting means for connecting the end portion of the steering roller to the moving member so as to be connectable and disengageable.
5. The image forming apparatus according to claim 1, wherein the steering roller is tiltable by releasing the connecting unit. 6. An endless belt member;
A first steering roller and a second steering roller that are tilted at positions away from each other to control the belt members to be shifted, respectively;
A first steering device and a second steering device capable of forcibly shifting the belt member by driving and tilting the first steering roller and the second steering roller, respectively;
The first steering roller and the second steering roller are tiltably supported, and the first steering roller and the second steering roller can be tilted autonomously driven by the rotation of the belt member. A first automatic alignment device and a second automatic alignment device;
A first switching device capable of switching the first steering roller and the second steering roller from being driven by the first steering device and the second steering device, respectively, to a tiltable state by the automatic alignment device; A second switching device;
The first steering device and the second switching device are controlled by controlling the first switching device and the second switching device so that the belt member is autonomously shifted by the first automatic alignment device and the second automatic alignment device. An image forming apparatus comprising: a control unit configured to shift to forced shift control of the belt member by a two-steering device. An endless belt member;
A steering roller that tilts and controls the belt member to be shifted;
It has a moving member that moves the end portion of the steering roller in the tilting direction of the steering roller, and the belt member can be forcibly controlled by driving and tilting the steering roller by the moving member. Steering device,
An automatic alignment device that supports the steering roller in a tiltable manner, and the steering roller can be autonomously tilted by being driven by the rotation of the belt member;
Connecting means for connecting the end of the steering roller to the moving member so as to be connectable and disengageable,
An image forming apparatus capable of separating the steering roller from being driven by the steering device and switching to a tiltable state by the automatic alignment device by releasing the connecting means.

Images