JP2018205641A - Drive device and image formation apparatus - Google Patents

Abstract

To provide a drive device and an image formation apparatus which can suppress a change in an inter-shaft core distance between an output gear of a gear unit and an input gear of a roller unit.SOLUTION: In a drive device, a gear unit 8 includes an output gear 82 and a gear unit frame 81 supporting the output gear 82, and is fixed to a housing frame 21. A discharge roller unit 7 includes: a drive shaft 71a; an input gear 71b which is rotatably provided integrally with the drive shaft 71a and is engaged with an output gear 82; and a roller 71c which is rotatably provided integrally with the drive shaft 71a and rotates with driving force input to the input gear 71b from the output gear 82, and is fixed to a housing frame 21. A bearing 9 includes a cylindrical part 91 to which the drive shaft 71a of the discharge roller unit 7 is inserted. A gear unit frame 81 includes a holding part 83 which holds the bearing 9 in a state where the drive shaft 71a is inserted to the cylindrical part 91.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a drive device including an output gear that outputs a driving force, and a roller unit having an input gear that meshes with the output gear, and an image forming apparatus.

  2. Description of the Related Art Conventionally, a driving device including a gear unit having an output gear that outputs a driving force, an input gear meshing with the output gear, and a roller unit having a roller that rotates when the driving force is input from the output gear to the input gear. Is known.

In such a drive device, a gear unit and a roller unit are attached to a frame member (see Patent Document 1).
In the drive device described in Patent Document 1, the gear unit is supported in a cantilevered manner with respect to the frame member, and is attached so as to be swingable along the axial direction of the output gear with the support portion as a fulcrum.

JP 2013-45026 A

As described above, when the gear unit and the roller unit are attached to the frame member, the relative positions of the gear unit and the roller unit may shift with time. If the relative positions of the gear unit and the roller unit are shifted, the distance between the shaft centers of the output gear of the gear unit and the input gear of the roller unit will change, and the engagement between the output gear and the input gear will shift. .
In this case, transmission of driving force from the output gear to the input gear may be hindered, or noise may be generated when the output gear and input gear are driven.

  Accordingly, the present invention provides a drive device and an image forming apparatus that can suppress a change in the distance between the shaft centers of the output gear of the gear unit and the input gear of the roller unit.

The driving device and the image forming apparatus that solve the above-described problems have the following characteristics.
That is, the driving device includes a housing frame (21), a driving source (4), an output gear (82) that outputs driving force input from the driving source (4), and the output gear (82). A gear unit (8) fixed to the housing frame (21), a drive shaft (71a), and a unit frame (81) to be supported so as to be integrally rotatable with the drive shaft (71a) An input gear (71b) that is provided and meshes with the output gear (82), and is rotatably provided integrally with the drive shaft (71a), and the driving force is transferred from the output gear (82) to the input gear (71b). A roller unit (7) having a roller (71c) that rotates by being input and fixed to the housing frame (21), and the drive shaft (71a) of the roller unit (7) are inserted. A bearing (9) having a cylindrical portion (91), and the unit frame (81) includes the bearing (9) in a state where the drive shaft (71a) is inserted into the cylindrical portion (91). ) Is held.

  ADVANTAGE OF THE INVENTION According to this invention, it can suppress that the distance between shaft centers of the output gear of a gear unit and the input gear of a roller unit changes.

It is a perspective view showing an image forming apparatus provided with a drive device. It is a perspective view which shows the discharge roller unit and gear unit which are supported by the housing frame. It is the perspective view which looked at the drive device from the back side. It is the perspective view which looked at the drive device from diagonally upward. It is rear surface sectional drawing which shows a drive device. It is right side sectional drawing which shows a drive device. It is the perspective view which looked at the bearing from the back side. It is the perspective view which looked at the bearing from the slant front side. It is a top view which shows a mode that the rotation prevention protrusion of a bearing is engaging with the recessed part in a gear unit frame. It is a top view which shows a mode that the boundary part of a 1st arm part and a connection part was bent, when the force of an axial direction was added to the bearing. It is a perspective view which shows the mounting procedure to the gear unit frame of a bearing.

  Next, modes for carrying out the present invention will be described with reference to the accompanying drawings.

[Overall configuration of image forming apparatus]
An image forming apparatus 1 shown in FIG. 1 is an embodiment of an image forming apparatus according to the present invention, and is a color laser printer that forms images of a plurality of colors on a sheet S such as paper or an OHP sheet by an electrophotographic method. .

  In the following description, “left side”, “right side”, “front side of paper”, and “back side of paper” in FIG. 1 are respectively referred to as “rear side”, “front side”, “left side”, And “right”. Further, “upper side” and “lower side” in FIG. 1 are defined as “upper side” and “lower side” of the image forming apparatus 1, respectively.

  The image forming apparatus 1 includes a housing 2, a sheet feeding unit 3 that supplies a sheet S, an image forming unit 5 that forms an image on the sheet S, and discharges the sheet S on which an image is formed to the outside of the housing 2. A discharge roller unit 7 is provided.

The housing 2 is a box formed in a substantially rectangular parallelepiped shape, and houses the paper feeding unit 3, the image forming unit 5, the discharge roller unit 7, and the like.
The upper surface of the housing 2 is covered with an upper surface cover 23. The top cover 23 is formed with a paper discharge tray 23a that is recessed so as to incline downward from the front side toward the rear side.

  The sheet feeding unit 3 includes a sheet cassette 31, a sheet feeding roller 32, a separation roller 33, a separation pad 33a, a pair of conveyance rollers 34a and 34b, and a pair of registration rollers 35a and 35b. In the housing 2, a conveyance path P <b> 1 from the sheet cassette 31 to the paper discharge tray 23 a through the image forming unit 5 is configured.

  The sheet cassette 31 stores a plurality of sheets S in a stacked state. The sheets S accommodated in the sheet cassette 31 are sent out one by one to the transport path P1 by the paper feed roller 32, the separation roller 33, and the separation pad 33a. The sheet S sent to the conveyance path P1 is conveyed toward the image forming unit 5 by the conveyance roller pair 34a and 34b and the registration roller pair 35a and 35b.

  The image forming unit 5 is disposed above the sheet feeding unit 3 and includes four drum units 51 arranged in parallel in the front-rear direction. Each drum unit 51 is provided corresponding to each color of black, yellow, magenta, and cyan. Each drum unit 51 includes a photosensitive drum 51a and a developing roller 51b. The image forming unit 5 includes an exposure LED head 52 corresponding to each color, and a fixing device 6 disposed on the downstream side of the photosensitive drum 51a in the sheet S conveyance direction.

  A transfer belt 40 is disposed below the conveyance path P1 of the image forming unit 5. The transfer belt 40 is stretched between a driving roller 41a and a driven roller 41b disposed behind the driving roller 41a. Transfer rollers 42 are arranged at positions facing the respective photosensitive drums 51a with the transfer belt 40 interposed therebetween.

  In the image forming unit 5, the photosensitive drum 51 a uniformly charged by the charger is selectively exposed by the exposure LED head 52. By this exposure, electric charges are selectively removed from the surface of the photosensitive drum 51a, and an electrostatic latent image is formed on the surface of the photosensitive drum 51a.

  A developing bias is applied to the developing roller 51b. When the electrostatic latent image formed on the photosensitive drum 51a faces the developing roller 51b, the developing roller 51b is caused by a potential difference between the electrostatic latent image and the developing roller 51b. The toner is supplied to the electrostatic latent image. As a result, a toner image is formed on the surface of the photosensitive drum 51a.

  When the sheet S conveyed toward the image forming unit 5 is conveyed onto the transfer belt 40, the sheet S is conveyed by the transfer belt 40 and sequentially passes between the transfer belt 40 and each photosensitive drum 51a. The toner image on the surface of the photosensitive drum 51 a is transferred to the sheet S by the transfer bias applied to the transfer roller 42 when facing the sheet S.

  The sheet S on which the toner image is transferred is conveyed to the fixing device 6. The fixing device 6 includes a heating roller 61 and a pressure roller 62 that is in pressure contact with the heating roller 61. The heating roller 61 is disposed above the pressure roller 62. The toner image is heat-fixed on the sheet S conveyed to the fixing device 6 while passing between the heating roller 61 and the heating roller 61.

In addition, the fixing device 6 includes a heating roller 61 and fixing discharge rollers 63 and 64 disposed downstream of the heating roller 61 in the conveyance direction of the sheet S. The sheet S on which the toner image has been thermally fixed is conveyed downstream while being sandwiched between the fixing discharge rollers 63 and 64.
The sheet S conveyed to the downstream side in the conveyance direction of the sheet S by the fixing discharge rollers 63 and 64 is discharged to the discharge tray 23 a of the upper surface cover 23 by the discharge roller unit 7. The discharge roller unit 7 is an example of a roller unit.

Specifically, the discharge roller unit 7 conveys the sheet S more than the intermediate discharge rollers 71 and 72, and the intermediate discharge rollers 71 and 72 disposed downstream of the fixing discharge rollers 63 and 64 in the sheet S conveyance direction. Discharge rollers 73 and 74 disposed on the downstream side in the direction, intermediate discharge rollers 71 and 72, and a roller unit frame 75 that rotatably supports the discharge rollers 73 and 74 are provided.
Then, the sheet S conveyed to the downstream side in the conveyance direction of the sheet S by the fixing discharge rollers 63 and 64 is conveyed by the intermediate discharge rollers 71 and 72, and further conveyed by the discharge rollers 73 and 74 to the discharge tray 23a. Discharged.

  In the image forming apparatus 1, a re-conveying path P <b> 2 for conveying the sheet S on which one image is formed in the image forming unit 5 and discharged from the fixing device 6 toward the image forming unit 5 again is configured. Has been. The sheet S re-conveyed to the image forming unit 5 along the re-conveying path P <b> 2 forms an image on the other surface by the image forming unit 5, and is then discharged to the paper discharge tray 23 a by the discharge roller unit 7.

  As described above, in the image forming apparatus 1, the sheet S on which the image is formed on one side by the image forming unit 5 is re-conveyed to the image forming unit 5 through the re-conveying path P <b> 2 and is transferred to the other side of the sheet S. It is possible to perform so-called double-sided printing that forms an image.

[Configuration of drive unit]
As shown in FIG. 2, the image forming apparatus 1 has a housing frame 21 in the housing 2. The housing frame 21 has side frames 21 a and 21 b that are arranged on the left and right sides in the housing 2. The discharge roller unit 7 is disposed between the side frame 21a and the side frame 21b at the rear part in the housing 2, and is fixed to the side frames 21a and 21b. The discharge roller unit 7 is detachably attached to the housing 2, and the discharge roller unit 7 is fitted between the side frame 21a and the side frame 21b from above to be attached to the side frames 21a and 21b. The discharge roller unit 7 is attached to the housing 2 by fastening or the like.

  The image forming apparatus 1 includes a motor 4 that is a driving source, and a gear unit 8 that receives a driving force from the motor 4 and outputs the input driving force. The gear unit 8 is fixed to the side frame 21 a of the housing frame 21.

As shown in FIGS. 3 to 6, the gear unit 8 includes an output gear 82 and a gear unit frame 81. The output gear 82 is a gear that outputs the driving force input from the motor 4. The gear unit frame 81 rotatably supports the output gear 82, and is fixed to the outer side surface of the side frame 21a in the left-right direction. The gear unit frame 81 is an example of a unit frame that supports the output gear 82.
A sheet metal frame 22 is disposed on the left and right outer sides of the gear unit 8, and the motor 4 is fixed to an outer surface of the sheet metal frame 22 in the left and right direction.

As shown in FIGS. 2-6, the discharge roller unit 7 includes a drive shaft 71a, an input gear 71b, and a roller 71c. The drive shaft 71 a is a shaft member of the intermediate discharge roller 71. The input gear 71b is a gear that is rotatably provided integrally with the drive shaft 71a and meshes with the output gear 82. The roller 71c is a roller member of the intermediate discharge roller 71, and is rotatably provided integrally with the drive shaft 72a. The roller 71c rotates when the driving force from the motor 4 is input from the output gear 82 to the input gear 71b.
The discharge roller unit 7 includes a roller unit frame 75 that forms a conveyance path P1 of the sheet S in the discharge roller unit 7 and in which intermediate discharge rollers 71 and 72 and discharge rollers 73 and 74 are provided.

The left end portion of the drive shaft 71 a in the intermediate discharge roller 71 is supported by the gear unit frame 81 via the bearing 9.
The housing frame 21, the motor 4, the roller unit 7, the gear unit 8, the bearing 9, and the like constitute a drive device that drives the intermediate discharge roller 71 and the like.

As shown in FIGS. 7 to 9, the bearing 9 includes a cylindrical portion 91, a first arm portion 92, a rotation preventing projection 93, and a second arm portion 94.
The cylindrical part 91 is comprised by the cylindrical member arrange | positioned so that an axial center may become the direction along a left-right direction, and the left end part of the drive shaft 71a is inserted. The drive shaft 71a is supported by the cylindrical portion 91 so as to be rotatable about the axis of the drive shaft 71a. The axial direction of the cylindrical part 91 and the axial direction of the drive shaft 71a inserted in the cylindrical part 91 are the same direction.

  The first arm portion is a plate-like member extending in a direction orthogonal to the axial direction of the drive shaft 71 a and is connected to the cylindrical portion 91 by a connecting portion 95. The connecting portion 95 is a plate-like member that extends in a direction orthogonal to the axial direction of the drive shaft 71a.

The first arm portion 92 has a first region 92a extending in the axial direction of the drive shaft 71a and a second region 92b extending in a direction orthogonal to the axial direction of the drive shaft 71a.
That is, the first arm portion 92 is formed in an L shape by the first region 92a and the second region 92b. A connecting portion 95 is connected to the end of the first region 92a opposite to the end connected to the second region 92b.

  In the second region 92b of the first arm portion 92, a detent projection 93 that protrudes in the axial direction of the drive shaft 71a is formed. The anti-rotation protrusion 93 protrudes leftward from the left side surface of the second region 92b.

The second arm portion 94 is an extending member that extends in a direction orthogonal to the axial direction of the drive shaft, and is provided on the cylindrical portion 91. The second arm portion 94 is provided on the opposite side of the cylindrical portion 91 from the first arm portion 92 side in a direction orthogonal to the axial direction of the drive shaft 71a.
The bearing 9 has a collar portion 96 that extends radially outward from the outer peripheral surface of the cylindrical portion 91.

  The gear unit frame 81 has a holding portion 83 that holds the bearing 9 in a state where the drive shaft 71 a is inserted into the cylindrical portion 91. The bearing 9 in a state where the drive shaft 71 a is inserted into the cylindrical portion 91 is held by the holding portion 83, whereby the intermediate discharge roller 71 is supported by the gear unit frame 81. As a result, the input gear 71b and the output gear 82 are both supported by the gear unit frame 81.

The cylindrical portion 91 of the bearing 9 can be inserted into the holding portion 83 from the left and right outer sides, and the cylindrical portion 91 inserted into the holding portion 83 can be rotated about the axis of the drive shaft 71a. It has become.
The cylindrical portion 91 is inserted into the holding portion 83, and the cylindrical portion 91 in a state where the driving shaft 71 a is inserted is held by the holding portion 83, so that the driving shaft 71 a is connected to the gear unit frame via the bearing 9. 81 is supported.

  The holding portion 83 is formed in a cylindrical shape, and includes a first tube portion 84 and a second tube portion 85 that is disposed at a position shifted in the axial direction of the drive shaft 71a with respect to the first tube portion 84. doing. The first cylinder portion 84 is disposed on the left and right outside of the second cylinder portion 85.

The first cylindrical portion 84 is provided corresponding to the entire outer periphery of the cylindrical portion 91 of the bearing 9. The second cylindrical portion 85 has a cutout portion 85 a in which a portion corresponding to a part of the circumferential direction in the cylindrical portion 91 of the bearing 9 is cut out.
The cutout portion 85 a is disposed in the upper portion of the second cylinder portion 85 in the vertical direction.

Here, when the discharge roller unit 7 is mounted on the housing 2, the end of the drive shaft 71 a is moved while the discharge roller unit 7 is entirely fitted between the side frame 21 a and the side frame 21 b from above. It is inserted into the holding part 83 of the gear unit frame 81.
In this case, since the left end portion of the drive shaft 71a can be inserted into the holding portion 83 from above through the cutout portion 85a by having the cutout portion 85a in the vertical upper portion of the second cylindrical portion 85, It is possible to easily insert the end of the drive shaft 71a into the holding portion 83.

  The gear unit frame 81 has a first engagement portion 86 disposed in front of the cylindrical portion 91 of the bearing 9 held by the holding portion 83. The first engaging portion 86 has a concave portion 86 a that engages with a rotation preventing protrusion 93 formed on the first arm portion 92 of the bearing 9. In the case of this embodiment, the recessed part 86a is formed by the hole which penetrates the 1st engaging part 86 in the left-right direction.

By engaging the concave portion 86a and the rotation prevention projection 93, the bearing 9 held by the holding portion 83 is prevented from rotating about the axis of the drive shaft 71a.
Further, the first engaging portion 86 is disposed on the left and right outside of the first arm portion 92, and the first engaging portion 86 and the first arm portion 92 are engaged in the left-right direction, whereby the bearing 9 is Further movement to the left and right sides is suppressed.

The gear unit frame 81 has a second engagement portion 87 that is arranged behind the cylindrical portion 91 of the bearing 9 held by the holding portion 83. The second engaging portion 87 engages with the second arm portion 94 of the bearing 9 in the left-right direction. The second engaging portion 87 is an example of an engaging portion that engages with the second arm portion 94 of the bearing 9. In the present embodiment, the inner end surface in the left-right direction of the second cylindrical portion 85 is configured as the second engaging portion 87.
The second engaging portion 87 is disposed on the left and right outer sides than the second arm portion 94, and the bearing 9 is further moved to the left and right outer sides by engaging the second engaging portion 87 and the second arm portion 94. The movement is suppressed.

The gear unit frame 81 has a third engagement portion 88 that engages with the flange portion 96 of the bearing 9 in the left-right direction. In the present embodiment, the outer end surface of the first tube portion 84 in the left-right direction is configured as a third engagement portion 88.
The third engaging portion 88 is disposed on the left and right inner sides of the collar portion 96, and the bearing 9 moves further to the left and right inner sides when the third engaging portion 88 and the collar portion 96 are engaged. Is suppressed.

The gear unit frame 81 has a recessed portion 89 through which the second arm portion 94 of the bearing 9 can pass in the axial direction of the drive shaft 71a (see FIG. 6).
The recessed portion 89 is formed by the inner peripheral surfaces of the first cylindrical portion 84 and the second cylindrical portion 85 in the holding portion 83b being recessed outward in the radial direction, and from the outer end surface of the holding portion 83 in the left-right direction. It is formed over the inner end surface of the holding portion 83.

In the circumferential direction of the holding portion 83, the recessed portion 89 is formed at a position out of phase with the position of the second engaging portion 87 with which the second arm portion 94 is engaged.
Therefore, when mounting the bearing 9 on the holding portion 83, first, the cylindrical portion 91 of the bearing 9 is attached to the holding portion 83 in a state where the phases of the recessed portion 89 and the second arm portion 94 are aligned in the circumferential direction. The second arm portion 94 is inserted into the recessed portion 89 by inserting from the left and right outer sides. Then, when the second arm portion 94 moves to the left and right inward from the holding portion 83 and comes out of the recessed portion 89, the bearing 9 is rotated around the axis of the drive shaft 71a, and the second arm portion 94 is rotated. And the second engagement portion 87 are brought into phase with each other so that the second arm portion 94 and the second engagement portion 87 can be engaged in the left-right direction.

  Thus, in the drive device, since the holding portion 83 has the recessed portion 89, the second arm of the bearing 9 is inserted into the recessed portion 89 when the cylindrical portion 91 of the bearing 9 is inserted into the holding portion 83. The cylindrical portion 91 can be inserted into the holding portion 83 while passing the portion 94, and the bearing 9 can be easily assembled to the holding portion 83.

In the drive device, when the cylindrical portion 91 of the bearing 9 is inserted into the holding portion 83 to a position where the third engaging portion 88 and the collar portion 96 are engaged, the second arm portion 94 is moved from the holding portion 83 to the left and right. It is configured to exit inward.
Further, when the bearing 9 is in a rotational position where the rotation preventing projection 93 of the first arm portion 92 and the concave portion 86a of the first engagement portion 86 are engaged, the second arm portion 94 and the second engagement portion are arranged in the circumferential direction. It is comprised so that the phase with the joint part 87 may match.

  In a state where the bearing 9 is mounted on the holding portion 83 of the gear unit frame 81, the rotation preventing projection 93 of the first arm portion 92 and the concave portion 86 a of the first engaging portion 86 are engaged, and the first arm portion 92 is engaged. Is disposed close to the left and right inner sides of the first engaging portion 86. Further, the second arm portion 94 is disposed close to the left and right inner sides of the second engaging portion 87, and the collar portion 96 is disposed close to the left and right outer sides of the third engaging portion 88.

In this manner, the rotation-preventing protrusion 93 of the first arm portion 92 and the concave portion 86a of the first engaging portion 86 engage with each other, so that the bearing 9 attached to the holding portion 83 is accompanied by the rotation of the drive shaft 71a. Thus, the rotation about the axis of the drive shaft 71a is suppressed.
In addition, the first arm portion 92 is disposed close to the left and right inner sides of the first engaging portion 86, and the second arm portion 94 is disposed close to the left and right inner sides of the second engaging portion 87, so that the bearing 9 Displacement to the left and right outer sides of the third engaging portion 88 can be restricted by disposing the collar portion 96 close to the left and right outer sides of the third engagement portion 88.

  In this case, since the first arm portion 92 and the second arm portion 93 are provided on the opposite sides of the cylindrical portion 91 in the direction orthogonal to the axial direction of the drive shaft 71a, the first arm portion is provided. When 92 and the second arm part 93 are engaged with the first engaging part 86 and the second engaging part 87, respectively, a force is applied to both the first arm part 92 side and the second arm part 93 side of the bearing 9. Therefore, the bearing 9 can be prevented from being twisted.

The first arm portion 92 includes a first region 92a extending in the axial direction of the drive shaft 71a, and a second region 92b extending in a direction orthogonal to the axial direction of the drive shaft 71a, and the second region 92b. An anti-rotation projection 93 is provided at the end.
As a result, as shown in FIG. 10, when a force toward the outer side in the left-right direction, which is the outer side in the axial center direction, is applied to the cylindrical portion 91 of the bearing 9, for example, It is possible to absorb the force applied to the bearing 9 due to the bending of the first arm portion 92, for example, the connecting portion is bent, and the bearing 9 can be prevented from being twisted.

  Further, when the cylindrical portion 91 of the bearing 9 is inserted into the holding portion 83 to a position where the third engaging portion 88 and the flange portion 96 are engaged, the notch portion 85a in the second cylindrical portion 85 of the holding portion 83 is It is configured so as to be closed by the cylindrical portion 91. As a result, the drive shaft 71a inserted into the holding portion 83 and supported by the holding portion 83 via the bearing 9 is prevented from unexpectedly coming out through the cutout portion 85a.

  Further, in the holding portion 83, the cylindrical portion 91 of the bearing 9 is supported by the lower part in the vertical direction in both the first cylinder portion 84 and the second cylinder portion 85. It is possible to hold it securely.

[Installation procedure of bearing to gear unit frame]
In the drive device configured as described above, the bearing 9 is attached to the holding portion 83 of the gear unit frame 81 by the following procedure.
As shown in FIG. 11A, when the bearing 9 is attached to the holding portion 83, the left end portion of the drive shaft 71a is inserted into the holding portion 83 through the notch portion 85a in the second cylindrical portion 85 in advance. deep. In this manner, the cylindrical portion 91 of the bearing 9 is inserted into the holding portion 83 from the left and right outer sides while the left end portion of the drive shaft 71a is inserted into the holding portion 83.

  When the cylindrical portion 91 of the bearing 9 is inserted into the holding portion 83, the second recess portion 89 in the holding portion 83 and the second arm portion 94 of the bearing 9 are in phase with each other in the circumferential direction. The cylindrical portion 91 is inserted into the holding portion 83 while passing through the two arm portions 94. When the cylindrical portion 91 is inserted into the holding portion 83, the left end portion of the drive shaft 71 a that is arranged in advance in the cylindrical portion 91 is inserted into the cylindrical portion 91. In a state where the recesses 89 of the holding portion 83 and the second arm portion 94 of the bearing 9 are in phase with each other in the circumferential direction, the first arm portion 92 of the bearing 9 has the anti-rotation protrusion 93 and the first engaging portion 86. It is located at a rotation position where the recess 86a is not engaged.

  As shown in FIG. 11B, after the cylindrical portion 91 of the bearing 9 is inserted into the holding portion 83 to a position where the collar portion 96 engages with the third engaging portion 88, the bearing 9 is inserted into the drive shaft 71a. The rotation preventing projection 93 of the first arm portion 92 is rotated in the direction approaching the recess 86 a of the first engaging portion 86 around the axis.

  As shown in FIG. 11C, when the bearing 9 is rotated to a rotation position where the rotation preventing projection 93 of the first arm portion 92 and the recess 86a of the first engagement portion 86 are in phase in the circumferential direction. Then, the rotation preventing projection 93 and the recess 86a are engaged, and the mounting of the bearing 9 to the holding portion 83 is completed.

  In this case, the first arm portion 92 of the bearing 9 has flexibility, and before the anti-rotation protrusion 93 and the concave portion 86a are engaged, the first arm portion 92 is bent in the bent state. The protrusion 93 is in sliding contact with the left and right inner surfaces of the first engaging portion 86. When the bearing 9 is rotated from the state in which the rotation preventing projection 93 is in sliding contact with the first engaging portion 86 to the rotation position where the phases of the rotation preventing projection 93 and the recessed portion 86a are matched, the bent first arm portion 92 is The original shape is restored, and the anti-rotation protrusion 93 is engaged with the recess 86a.

In this way, by attaching the bearing 9 to the holding portion 83 and supporting the drive shaft 71a by the holding portion 83 via the bearing 9, the input gear 71b provided on the drive shaft 71a of the discharge roller unit 7 and the gear Both the output gear 82 and the output gear 82 of the unit 8 are supported by the gear unit frame 81. Even if the relative positions of the discharge roller unit 7 and the gear unit 8 shift with time, the input gear 71b and the output The distance D between the shaft centers with the gear 82 (see FIG. 5) can be kept substantially constant.
Thereby, it is possible to suppress the change in the distance D between the shaft centers of the input gear 71b and the output gear 82, and the transmission efficiency of the driving force between the output gear 82a and the input gear 71b is reduced, or the output gear 82 is reduced. In addition, it is possible to suppress the generation of noise when the input gear 71b is driven.

[Effects of this embodiment]
In the present embodiment, the image forming apparatus 1 includes the following driving device.
That is, the drive device includes the housing frame 21, the motor 4, the gear unit 8, the discharge roller unit 7, and the bearing 9. The gear unit 8 includes an output gear 82 that outputs a driving force input from the motor 4 and a gear unit frame 81 that supports the output gear 82, and is fixed to the housing frame 21. The discharge roller unit 7 is provided with a drive shaft 71a, an input gear 71b that is integrally rotatable with the drive shaft 71a, and meshes with the output gear 82, and is rotatably provided with the drive shaft 71a so that the driving force is output. A roller 71c that rotates by being input from the gear 82 to the input gear 71b is fixed to the housing frame 21. The bearing 9 has a cylindrical portion 91 into which the drive shaft 71a of the discharge roller unit 7 is inserted. The gear unit frame 81 includes a holding portion 83 that holds the bearing 9 in a state where the drive shaft 71 a is inserted into the cylindrical portion 91.

  As described above, since the holding portion 83 of the bearing 9 is provided on the gear unit frame 81 that supports the output gear 82, the relative position between the discharge roller unit 7 and the gear unit 8 fixed to the housing frame 21. Even when the time shifts over time, the distance between the shaft centers of the input gear 71b and the output gear 82 is suppressed by making the distance between the shaft centers of the input gear 71b and the output gear 82 substantially constant. it can. Thereby, it is possible to prevent the transmission efficiency of the driving force between the output gear 82 and the input gear 71b from being reduced, and noise from being generated when the output gear 82 and the input gear 71a are driven.

Further, the holding portion 83 is displaced in the axial direction of the drive shaft 71 a with respect to the first cylindrical portion 84 provided corresponding to the entire outer periphery of the cylindrical portion 91 of the bearing 9 and the first cylindrical portion 84. And a second cylinder portion 85 having a notch portion 85a in which a portion corresponding to a part in the circumferential direction of the outer periphery of the cylindrical portion 91 of the bearing 9 is notched.
Thus, when the drive shaft 71a is assembled to the gear unit frame 81 of the gear unit 8, the drive shaft 71a can be inserted into the holding portion 83 through the cutout portion 85a, so that the assembly of the drive shaft 71a is facilitated.

Further, the cutout portion 85 a of the second tube portion 85 is disposed in the upper portion of the second tube portion 85 in the vertical direction.
Thus, the notch part 85a is arranged on the upper side, so that the part of the second cylinder part 85 that supports the bearing 9 is arranged on the lower side. This makes it possible to achieve both the support of the bearing 9 by the holding portion 83 and the ease of assembly of the drive shaft 71a.

The bearing 9 has a first arm portion 92 extending in a direction orthogonal to the axial direction of the drive shaft 71a, and the first arm portion 92 has a rotation-preventing protrusion 93 protruding in the axial direction of the drive shaft 72a. The gear unit frame 81 of the gear unit 8 has a recess 86 a that engages with the rotation prevention protrusion 93.
With such a configuration, the rotation prevention projection 93 of the first arm portion 82 is engaged with the recess 86a of the gear unit frame 81, so that the bearing 9 can be prevented from rotating as the drive shaft 71a rotates. Further, the displacement of the bearing 9 in the axial direction of the drive shaft 71a can be suppressed.

The bearing 9 is provided on the opposite side to the first arm portion 92 side in the direction orthogonal to the axial direction of the drive shaft 71a, and extends in the direction orthogonal to the axial direction of the drive shaft 71a. The gear unit frame 81 of the gear unit 8 has a second engagement portion 87 that engages with the second arm portion 94.
Accordingly, the second arm portion 94 is engaged with the second engagement portion 87 of the gear unit frame 81, so that the displacement of the drive shaft 71a of the bearing 9 in the axial direction can be suppressed. In particular, the second arm portion 94 is provided on the opposite side of the first arm portion 92 in the direction orthogonal to the axial direction of the drive shaft 71a, so that the bearing 9 can be prevented from being twisted.

The gear unit frame 81 of the gear unit 8 is formed at a position shifted in the circumferential direction of the holding portion 83 with respect to the second engaging portion 87, and the second arm portion 94 passes in the axial direction of the drive shaft 71a. It has a possible recess 89.
Thus, when the drive shaft 71a is assembled to the gear unit frame 8 of the gear unit 8, the bearing 9 held by the holding portion 83 is moved in the axial direction of the drive shaft 71a, thereby being inserted into the holding portion 83. The drive shaft 71a can be inserted into the cylindrical portion 91 of the bearing 9, and the assembly of the drive shaft 71a can be facilitated.

The first arm portion 92 includes a first region 92a extending in the axial direction of the drive shaft 71a, and a second region 92b extending in a direction orthogonal to the axial direction of the drive shaft 71a, and the second region 92b. The anti-rotation protrusion 93 is provided on the surface.
Thereby, when the force of the axial direction of the drive shaft 71a is applied to the bearing 9, it can suppress that the 1st arm part 92 bends and absorbs the force applied to the bearing 9, and the bearing 9 is twisted.

  In the above-described embodiment, the configuration in which the driving device is applied to the image forming apparatus has been described. However, the driving device according to the present invention is not limited to the image forming apparatus, and for example, may include a driving device. For example, the present invention may be applied to an image reading apparatus.

DESCRIPTION OF SYMBOLS 1 Image forming apparatus 2 Case 4 Motor 7 Discharge roller unit 8 Gear unit 9 Bearing 21 Case frame 21a, 21b Side frame 71 Intermediate discharge roller 71a Drive shaft 71b Input gear 71c Roller 81 Gear unit frame 82 Output gear 83 Holding part 84 1st cylinder part 85 2nd cylinder part 85a Notch part 86 1st engaging part 86a Recessed part 87 2nd engaging part 89 Recessed part 91 Cylindrical part 92 1st arm part 92a 1st area | region 92b 2nd area | region 93 circumference | surroundings Stop projection 94 Second arm 95 Connecting part

Claims (8)

A housing frame;
A driving source;
An output gear that outputs a driving force input from the drive source; a unit frame that supports the output gear; and a gear unit that is fixed to the housing frame;
A drive shaft, an input gear that is integrally rotatable with the drive shaft and meshes with the output gear, and a drive shaft that is integrally rotatable with the drive shaft and the driving force is input from the output gear to the input gear A roller unit that rotates and is fixed to the housing frame;
A bearing having a cylindrical portion into which the drive shaft of the roller unit is inserted;
With
The unit frame includes a holding portion that holds the bearing in a state where the drive shaft is inserted into the cylindrical portion.
A drive device characterized by that. The holding part is
A first cylindrical portion provided corresponding to the entire circumference of the cylindrical portion of the bearing;
A notch in which a portion corresponding to a part in the circumferential direction of the outer periphery of the cylindrical portion of the bearing is cut away from the first cylindrical portion at a position shifted in the axial direction of the drive shaft. A second cylindrical portion having a notch,
The drive device according to claim 1. The notch portion of the second cylindrical portion is disposed in a portion on the upper side in the vertical direction of the second cylindrical portion.
The drive device according to claim 2, wherein: The bearing has a first arm portion extending in a direction orthogonal to the axial direction of the drive shaft,
The first arm portion has a detent protrusion protruding in the axial direction of the drive shaft,
The unit frame of the gear unit has a recess that engages with the detent protrusion.
The drive device according to any one of claims 1 to 3, wherein the drive device is provided. The bearing has a second arm portion provided on a side opposite to the first arm portion side in a direction orthogonal to the axial direction of the drive shaft, and extending in a direction orthogonal to the axial direction of the drive shaft. ,
The unit frame of the gear unit has an engaging portion that engages with the second arm portion.
The drive device according to claim 4. A unit frame of the gear unit is formed at a position shifted in the circumferential direction of the holding portion with respect to the engaging portion, and the second arm portion has a recessed portion that can pass in the axial direction of the drive shaft. ,
The drive device according to claim 5. The first arm portion includes a first region extending in the axial direction of the drive shaft, and a second region extending in a direction orthogonal to the axial direction of the drive shaft,
The rotation stop projection is provided in the second region,
The drive device according to any one of claims 4 to 6, wherein the drive device is characterized. A drive device according to any one of claims 1 to 7, comprising:
An image forming apparatus.

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