JP2007307710A - Conductive bearing mechanism and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely carry out electric connection while supporting a conductive shaft by a low-cost and small-sized configuration. <P>SOLUTION: The conductive bearing mechanism is equipped with a bearing member (2) and a conductive member (9) shaped like a leaf spring. The bearing member (2) includes a bearing part (3) which supports the conductive shaft (T2a1), a conductive member accommodating part (4+8) in which the conductive member (7) for making the conductive shaft (T2a1) electrically conductive is accommodated, and a shaft contact terminal attachment opening (7a) which connects the conductive member accommodation part (4+8) and the bearing part (3) with each other and to which a shaft contact terminal (7) to be in contact with the conductive shaft (T2a1) is attached. The conductive member (9) includes a shaft contact terminal pressing part (9d) which presses the shaft contact terminal (7) to the conductive shaft (T2a1), and an external terminal pressing part (9b) which is pressed to an external terminal (1) by a predetermined pressing force. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a conductive bearing mechanism that supports a conductive shaft, and an image forming apparatus such as a printer, a FAX, a copying machine having the conductive bearing mechanism, or a multifunction peripheral having all or a plurality of functions. The present invention relates to a conductive bearing mechanism having a conductive member that conducts between the shaft and an external terminal, and an image forming apparatus including the conductive bearing mechanism.

  An electronic apparatus such as an image forming apparatus often includes a member having a rotation shaft such as a motor or a roller. When the shaft itself or the roller supported by the shaft rotates, static electricity may accumulate due to frictional charging, etc., which may cause electric discharge, fire, and radio noise. In order to prevent this, a configuration is adopted in which the shaft is constituted by a conductive shaft and is connected to the ground (external terminal) to release static electricity. In addition, when it is desired to apply a predetermined voltage to the shaft or roller, the shaft is also connected to a connection terminal of a power source.

The following conventional techniques (J01) to (J03) are conventionally known as techniques for conducting the shaft.
(J01) Patent Document 1 (Utility Model Registration No. 3093539), Patent Document 2 (Utility Model Registration No. 3093726), Patent Document 3 (Utility Model Registration No. 3093890), Patent Document 4 (Utility Model Registration No. In the rotating magnetic head device, the stator (25) disposed outside the shaft end of the rotating shaft (8) is connected to the shaft by a spring (27). A technique is described in which a grounding brush (26) pressed at the shaft end of (8) or a grounding member (26) composed of a leaf spring is provided, and the shaft (8) is connected to the ground.
(J02) Technology described in Patent Document 5 (Japanese Patent Laid-Open No. 2000-98682) In Patent Document 5, a damper spring (29) is attached to a conductive bearing (30) that receives a shaft (32) of a secondary transfer roller (7). A technique is described in which a contact (23) of a high voltage generating unit is brought into contact with a relay plate (28) connected via a contact spring (24) while being pressed.

FIG. 10 is an explanatory view of a conventional conductive member.
(J03) Technology shown in FIG. 10 In FIG. 10, in the transfer unit 01 of the conventional image forming apparatus, the tip of a leaf spring 03 made of a conductive material (metal or the like) is formed on the shaft end of the shaft 02a of the transfer roll 02. A contact (contact terminal) 04 of a highly slidable resin (fluorine resin or the like) press-fitted or adhered to the contact is made. The leaf spring 03 is screwed to the frame 06 of the transfer unit 01. Therefore, the shaft 02a of the transfer roll 02 is conducted through the contact 04 and the leaf spring 03.

Utility Model Registration No. 3093539 (FIG. 1) Utility Model Registration No. 3093726 (FIG. 1) Utility Model Registration No. 3093890 (FIG. 1) Utility Model Registration No. 3094287 (FIG. 1) JP 2000-98682 A (“0027” to “0034”, FIG. 2)

(Problems of conventional technology)
In the prior arts (J01) and (J02), the bearing for receiving the shaft and the conductive mechanism for electrically connecting to the ground or the high-voltage power source are configured separately, and the component for electrically connecting In many cases, the structure is complicated, and there is a problem that the cost of parts and assembly (manufacturing) increases. In addition, since the configuration is complicated, there is a problem that it is not easy to replace parts at the time of failure.
In the prior art (J03), since the contact 04 is press-fitted or bonded to the leaf spring 03 and the leaf spring 03 is screwed to the frame 06, there is a problem that the assemblability is not good and the cost is high. In particular, in the prior art (J03), since the conductive members of the leaf spring 03 and the contact 04 are exposed, there is a possibility that the conductive member may be deformed by touching with a hand or just contacting another member, so that conduction cannot be obtained. Although it is conceivable to attach a cover to protect the leaf spring 03 and the contact 04, in this case, the unit 01 may be increased in size.

In view of the above circumstances, the present invention has the following description (O01) as a technical problem.
(O01) To ensure electrical connection while supporting the conductive shaft with a low-cost and compact configuration.

Next, the present invention that solves the above problems will be described. In order to facilitate correspondence with the constituent elements of the embodiments described later, the constituent elements of the present invention are enclosed in parentheses. I will add that.
The reason why the present invention is described in correspondence with the reference numerals of the embodiments described later is to facilitate the understanding of the present invention, and not to limit the scope of the present invention to the embodiments.

(First invention)
In order to solve the technical problem, the conductive bearing mechanism of the first invention is:
Bearing portions (3, 23, BB + 42a) for supporting the conductive shaft (T2a1) and conductive members (7, 9, 9 ′, 13, 14, 16, 27, 29, 33, 33) for conducting the conductive shaft (T2a1) 34, 35, 37) for accommodating the conductive member accommodating portion (4 + 8, 11 + 12, 28, 38), the conductive member accommodating portion (4 + 8, 11 + 12, 28, 38) and the bearing portion (3, 23, BB + 42a). And a shaft contact terminal mounting port (7a, 27a, 37a) on which a shaft contact terminal (7, 27, 37) that contacts the conductive shaft (T2a1) is mounted. ', 15, 22, 32, 42),
The shaft contact terminal pressing portion (9d, 16b, 29d, 35b) that presses the shaft contact terminal (7, 27, 37) against the conductive shaft (T2a1) and the external terminal (1) are pressed with a predetermined pressing force. A plate spring-like conductive member (9, 9 ', 13, 14, 16, 29, 33, 34, 35) having external terminal pressing portions (9b, 14a, 29b);
It is provided with.

(Operation of the first invention)
In the conductive bearing mechanism of the first invention having the above-described configuration, the shaft contact terminal mounting port (7a, 27a, 37a) of the bearing member (2, 2 ', 15, 22, 32, 42) is a conductive shaft (T2a1). Bearing portions (3, 23, BB + 42a) for supporting the conductive members (7, 9, 9 ', 13, 14, 16, 27, 29, 33, 34, 35, 37) that conduct the conductive shaft (T2a1). ) Is connected to the conductive member accommodating portion (4 + 8, 11 + 12, 28, 38). The shaft contact terminal mounting ports (7a, 27a, 37a) have shaft contact terminals (7, 27, 37) that contact the conductive shaft (T2a1) of the bearing member (2, 2 ', 9', 22, 32, 42). 37) is mounted.
The shaft contact terminal pressing portion (9d, 16b, 29d, 35b) of the conductive member (9, 9 ', 13, 14, 16, 29, 33, 34, 35) in the form of a leaf spring is connected to the shaft contact terminal (7 , 27, 37) are pressed against the conductive shaft (T2a1). The external terminal pressing portions (9b, 14a, 29b) of the leaf spring-like conductive members (9, 13, 14, 16, 29, 33, 34, 35) press the external terminals (1) with a predetermined pressing force. Is done.
Therefore, in the conductive bearing mechanism of the first invention, the shaft contact terminals (7, 27, 37) are formed by the plate spring-like conductive members (9, 9 ', 13, 14, 16, 29, 33, 34, 35). Is pressed by the conductive shaft (T2a1) and the external terminal pressing portions (9b, 14a, 29b) are pressed by the external terminal (1), so that the conductive shaft (T2a1) is supported while supporting the conductive shaft (T2a1). And the external terminal (1) can be reliably connected electrically.
The conductive bearing mechanism according to the first aspect of the present invention includes the bearing member (2, 2 ', 9', 22, 32, 42), the shaft contact terminal (7, 27, 37), and the leaf spring-shaped conductive member (9 , 9 ', 13, 14, 16, 29, 33, 34, 35) are unitized, so that the configuration can be simplified and replacement work at the time of assembly or failure can be easily performed.

(First Embodiment 1)
The conductive bearing mechanism according to the first aspect of the first invention is the first invention,
The conductive member (9, 9 ', 29) configured by a leaf spring in which the shaft contact terminal pressing portion (9d, 29d) and the external terminal pressing portion (9b, 29b) are integrally formed;
It is provided with.

(Operation of Form 1 of the First Invention)
In the conductive bearing mechanism according to the first aspect of the first invention having the above configuration, the conductive member (9, 9 ', 29) includes the shaft contact terminal pressing portion (9d, 29d) and the external terminal pressing portion (9b, Since 29b) is constituted by a leaf spring formed integrally, the number of parts can be reduced and the construction can be simplified.

(First Embodiment 2)
The conductive shaft (T2a1) receiving mechanism according to the second aspect of the present invention is the first leaf spring member (14, 34) having the shaft contact terminal pressing portion (16b, 29d) and the external terminal pressing portion in the first invention. The second leaf spring member (16, 35) having (14a), the first leaf spring member (14, 34) and the second leaf spring member (16, 35) are fixedly supported and the conductive member accommodating portion A plate spring fixing member (13, 33) supported by (11 + 12, 38), and the conductive member (13, 14, 16, 33, 34, 35),
It is provided with.

(Operation of the second aspect of the first invention)
In the conductive bearing mechanism according to the second aspect of the first invention having the above-described configuration, the leaf spring fixing member (13, 33) supported by the conductive member accommodating portion (11 + 12, 38) is the shaft contact terminal pressing portion (16b). , 35b) and the second leaf spring member (16, 35) having the external terminal pressing portions (9b, 14a, 29b) are fixedly supported.
Accordingly, the vibration generated by the rotation of the conductive shaft (T2a1) is absorbed by the leaf spring fixing members (13, 33), so that the conductive shaft (T2a1) and the conductive shaft (T2a1) are supported. The electrical connection with the external terminal (1) can be performed stably.

(Embodiment 3 of the first invention)
The conductive bearing mechanism according to the third aspect of the first invention is the first invention or the first and second aspects of the first invention.
The shaft contact terminal (7) in contact with the axial end of the conductive shaft (T2a1);
It is provided with.

(Operation of the third aspect of the first invention)
In the conductive bearing mechanism according to the third aspect of the first invention having the above-described configuration, the shaft contact terminal (7) contacts the axial end of the conductive shaft (T2a1). For this reason, the said shaft contact terminal (7) can contact the said conductive shaft (T2a1), without receiving the load of the said conductive shaft (T2a1).

(First aspect 4)
The conductive bearing mechanism of the fourth aspect of the first invention is the first invention or the first and second aspects of the first invention,
The shaft contact terminals (27, 37) in contact with the outer peripheral surface of the conductive shaft (T2a1);
It is provided with.

(Operation of the fourth aspect of the first invention)
In the conductive bearing mechanism according to the fourth aspect of the first invention having the above-described configuration, the shaft contact terminals (27, 37) are in contact with the outer peripheral surface of the conductive shaft (T2a1). For this reason, the conductive axis (T2a1) can be received at a portion other than the shaft end. Therefore, for example, the gear can be supported on the shaft end of the conductive shaft (T2a1).

(First embodiment 5)
The conductive bearing mechanism of the fifth aspect of the first invention is the first invention or the first to fourth aspects of the first invention.
The bearing member (42) having the bearing portion (BB + 42a) constituted by a bearing (BB) that rotatably supports the conductive shaft (T2a1) and a bearing support portion (42a) that supports the bearing (BB);
It is provided with.

(Operation of the fifth aspect of the first invention)
In the conductive bearing mechanism according to the fifth aspect of the first invention having the above-described configuration, the conductive shaft (T2a1) can be rotatably supported by the bearing (BB).

(First Embodiment 6)
The conductive bearing mechanism of the sixth aspect of the first invention is the first invention or the first to fourth aspects of the first invention.
The bearing part (2, 2 ', 15, 22, 32) constituted by a sliding bearing (3, 23);
It is provided with.

(Operation of the sixth aspect of the first invention)
In the conductive bearing mechanism according to the sixth aspect of the first invention having the above-described configuration, the bearing portion (2, 2 ', 15, 22, 32) is formed by a slide bearing (3, 23). The rotation of (T2a1) is stably held.

(First embodiment 7)
The conductive bearing mechanism of the seventh aspect of the first invention is the first invention or the first to sixth aspects of the first invention.
The external terminal (1) constituted by a grounded frame;
It is provided with.

(Operation of the first aspect 7)
In the conductive bearing mechanism according to the seventh aspect of the first invention having the above-described configuration, since the external terminal (1) is configured by a grounded frame, the conductive shaft (T2a1) can be reliably grounded.

(Second invention)
The image forming apparatus (U) of the second invention is
The electroconductive bearing mechanism according to the first invention or the first to seventh aspects of the invention is provided.

(Operation of the second invention)
Since the image forming apparatus (U) of the second invention having the above-described configuration includes the conductive bearing mechanism according to the first invention or the first to seventh aspects of the invention, the plate spring-like conductive member (9, 9) is provided. 9 ', 13, 14, 16, 29, 33, 34, 35), the electrical connection can be ensured, the configuration is simplified, the size can be reduced, and the space can be used efficiently. .

The above-described present invention has the following effect (E01).
(E01) It is possible to reliably perform electrical connection while supporting the conductive shaft with a low cost and small configuration.

Next, examples (examples) of the embodiments of the present invention will be described with reference to the drawings, but the present invention is not limited to the following examples.
In order to facilitate understanding of the following description, in the drawings, the front-rear direction is the X-axis direction, the left-right direction is the Y-axis direction, the up-down direction is the Z-axis direction, and arrows X, -X, Y, -Y, The direction indicated by Z and -Z or the indicated side is defined as the front side, the rear side, the right side, the left side, the upper side, the lower side, or the front side, the rear side, the right side, the left side, the upper side, and the lower side, respectively.
In the figure, “•” in “○” means an arrow heading from the back of the page to the front, and “×” in “○” is the front of the page. It means an arrow pointing from the back to the back.

Example 1
FIG. 1 is an overall explanatory view of an image forming apparatus including a fixing device according to a first embodiment of the present invention.
In FIG. 1, an image forming apparatus (digital copying machine) U according to the first embodiment includes a printer (image forming apparatus main body) U1, an image scanner U2, and an automatic document feeder U3.
The automatic document feeder U3 is supported on a platen glass PG on the upper surface of the image scanner U2.

The automatic document feeder U3 has a document feed tray TG1 on which a plurality of documents Gi to be copied are stacked. Each of the plurality of documents Gi placed on the document feed tray TG1 sequentially passes through the copy position on the platen glass PG (the press contact position of the platen roll GR1) and is discharged from the document discharge roll GR2 to the document discharge tray TG2. It is comprised so that.
The automatic document feeder U3 is rotatable with respect to the upper surface of the platen glass PG by a hinge shaft (not shown) provided in the rear end portion (−X end portion) extending in the left-right direction (Y-axis direction). When the operator places the document Gi on the platen glass PG by hand, the document Gi is rotated upward.

The image scanner U2 has a UI (user interface) (see FIGS. 1 and 5) through which a user inputs an operation command signal such as copy start.
An exposure optical system A for reading a document image is disposed below the transparent platen glass PG.
Reflected light from a document which is transported to the upper surface of the platen glass PG by the automatic document feeder U3 and passes through the copy position or a document (not shown) manually placed on the platen glass PG is reflected by the exposure optical system A. Then, it is converted into an electrical signal by a CCD (solid-state imaging device).
The IPS (image processing system) converts R, G, B (red, green, blue) electrical signals input from the CCD into Y, M, C, K (yellow, magenta, cyan, black) image data (digital). Data) and temporarily stored, and the image data is output to the laser drive circuit DL as image data for forming a latent image at a predetermined timing.
The laser drive circuit DL outputs a laser drive signal to a laser diode (not shown) of a ROS (latent image forming apparatus) in accordance with the input image data. The operations of the UI (user interface), IPS and laser drive circuit DL, and the power supply circuit E for applying a bias voltage to the developing roll R0, the transfer roll T1, the secondary transfer roll (sheet transfer member) T2b, which will be described later, etc. Is controlled by the controller C.

  The laser drive circuit DL to which the four-color image data (laser drive data) of YMCK output from the IPS is input, the laser drive signal of each color corresponding to the input image data of each color at a predetermined timing for each color. Output to a ROS (latent image forming apparatus).

  The surface of each rotatable image bearing member (photosensitive member) Py, Pm, Pc, Pk is uniformly charged by each charging roll (charging member) CR when passing through the charged region during the rotation, and then the latent image is transferred to the latent image. When passing through the image forming position, an electrostatic latent image is formed on the surface by the light beam L output from the ROS (latent image forming device) of each color. The electrostatic latent images on the surface of the image carriers Py, Pm, Pc, and Pk are respectively developed into toner images of each color YMCK in the developing areas facing the developing units (developing devices) Gy, Gm, Gc, and Gk. Each of the developing units Gy, Gm, Gc, and Gk includes a developing container that stores toner of each color, an electrostatic image on the surface of the image carrier Py, Pm, Pc, and Pk that is rotatably supported by the developing container. A developing roll R0 is provided for conveying toner to the latent image and developing the toner image. The developing containers Gy, Gm, Gc, and Gk for the respective colors are configured to be supplied with toner of each color from the toner cartridges TY to TK.

  The developed toner image of each color YMCK is conveyed to a primary transfer region Q3 where each of the image carriers Py, Pm, Pc, Pk and an endless intermediate transfer belt (image carrier) B are in contact. The primary transfer roll T1 disposed on the back side of the intermediate transfer belt B in each primary transfer region Q3 has a polarity opposite to the developer charging polarity at a predetermined timing from the power supply circuit E controlled by the controller C. A primary transfer voltage is applied. The toner images on the image carriers Py to Pk are primary-transferred on the intermediate transfer belt B in a primary transfer region Q3 facing the primary transfer rolls T1. Residual toner on the surface of the image carrier Py, Pm, Pc, Pk after the primary transfer is removed by the image carrier cleaner CLp.

  Each color toner image is formed on each image carrier Py to Pk by each image carrier Py to Pk, each color ROS (latent image forming device), and each color developer Gy to Gk. The apparatus UY (Py + ROS + Gy), UM (Pm + ROS + Gm), UC (Pc + ROS + Gc), and UK (Pk + ROS + Gk) are configured.

Below the image carriers Py, Pm, Pc, and Pk of the respective colors, a slide frame F1 is slidable in the front-rear direction (direction perpendicular to the paper surface, that is, the X-axis direction) by a pair of left and right slide rails SR, SR. It is supported. The slide frame F1 includes an operating position where the belt frame F2 of the belt module BM is raised (a position where the belt frame F2 is in contact with the image carriers Py to Pk) and a maintenance position where the belt frame BM is moved downward (a position away from the image carriers Py to Pk). It is supported so that it can move up and down. In a state where the belt module BM is lowered to the belt maintenance position, the slide frame F1 and the belt module BM supported by the slide frame F1 are brought into contact with the image carrier Py to Pk without being brought into frictional contact with the image forming apparatus body U1. It is comprised so that it can be made to go in / out.
The configuration for moving the slide frame F1 back and forth and the configuration for moving the belt module BM up and down are conventionally known (see, for example, JP-A-8-171248), and various conventionally known configurations can be employed. .

  The belt module BM includes a belt support roll (Rd, Rt, Rw) including the intermediate transfer belt B, a belt drive roll Rd, a tension roll Rt, a walking roll Rw, a plurality of idler rolls (free rolls) Rf, and a backup roll T2a. , Rf, T2a) and the four primary transfer rolls T1. The intermediate transfer belt B is supported by the belt support rolls (Rd, Rt, Rw, Rf, T2a) so as to be rotatable in the arrow Ya direction.

A secondary transfer roll (sheet transfer member) T2b is disposed opposite to the surface of the intermediate transfer belt B in contact with the backup roll T2a, and the secondary transfer roll B2 and the secondary transfer roll T2b are opposed to the secondary transfer roll T2b. A transfer region (sheet transfer region) Q4 is formed. A secondary transfer voltage having a polarity opposite to the charging polarity of the developer is applied to the secondary transfer roll T2b from the power supply circuit E controlled by the controller C at a predetermined timing. The backup roll T2a disposed facing the secondary transfer roll T2b is grounded, and when a secondary transfer voltage is applied to the secondary transfer roll T2b, the secondary transfer roll T2b and A secondary transfer electric field is formed between the backup rolls T2a. The backup roll T2a and the secondary transfer roll T2b constitute a secondary transfer device T2.
Surfaces of image carriers Py to Pk of toner image forming apparatuses (UY, UM, UC, UK) by a belt module BM including the four primary transfer rolls T1 and the intermediate transfer belt B, a secondary transfer unit T2, and the like. The transfer device (BM + T2) for transferring the toner image formed on the recording sheet S is configured.

Under the printer (image forming apparatus main body) U1, paper feed trays TR1 to TR3 accommodating sheets S and a paper feed transport path SH1 are provided. Further, the sheet feeding conveyance path SH1 is configured to be fed from the manual feed tray TR4. The sheets S accommodated in the sheet feeding trays TR1 to TR3 are taken out by the pickup roll Rp at a predetermined timing, separated one by one by the separating roll Rs, and conveyed to the registration roll Rr by the conveying roll Ra. Further, the sheet fed from the manual feed tray TR4 is conveyed to the registration roll Rr by the conveyance roll Ra. The recording sheet S transported to the registration roll Rr is aligned with the secondary transfer region at the timing when the multiple toner image or the single color toner image primarily transferred to the intermediate transfer belt B moves to the secondary transfer region Q4. It is conveyed to Q4.
When the recording sheet S passes through the secondary transfer region Q4, the secondary transfer voltage is applied to the secondary transfer roll T2b, so that the color toner image primarily transferred over the intermediate transfer belt B is Secondary transfer is performed on the recording sheet S at once in the secondary transfer region Q4.
The residual toner is removed from the intermediate transfer belt B after the secondary transfer by the belt cleaner CLb.

The recording sheet S on which the toner image is secondarily transferred is conveyed to the fixing area Q5 by the post-transfer sheet guide SG and the sheet conveying belt HB, and when passing through the fixing area Q5, the heating roll Fh and the pressure roll Fp The image is fixed by heating by the fixing device F configured as described above. The recording sheet S on which the toner image is fixed is conveyed to the sheet discharge path SH2 or the duplex recording conveyance path SH3. The sheet conveyed to the sheet discharge path SH2 is discharged to the sheet discharge tray TRh, and the sheet conveyed to the sheet reversing path SH3 is reversed upside down and then retransmitted from the sheet circulation path SH4 to the registration roll Rr.
A sheet conveying device SH is constituted by the elements indicated by the symbols Rp, Rs, Rr, SG, BH, SH1, SH2, SH3, SH4 and the like.

FIG. 2 is an enlarged view of a main part of the conductive bearing mechanism of the first embodiment.
FIG. 3 is a rear view of the bearing member according to the first embodiment.
4A and 4B are explanatory views of the leaf spring according to the first embodiment. FIG. 4A is a top view of the leaf spring, and FIG.
2 and 3, a roll support frame 1 is disposed at the rear of the image forming apparatus U. A bearing mounting hole 1 a is formed in the roll support frame 1. A bearing member 2 made of resin is mounted in the bearing mounting hole 1a. A flange portion FL that is locked to the front surface of the frame 1 is formed on the outer periphery of the front end portion of the bearing member 2.
A cylindrical bearing-shaped sliding bearing portion 3 is formed on the front surface of the bearing member 2. The sliding bearing portion 3 rotatably supports the axial rear end portion of the shaft T2a1 of the backup roll T2a.

2 and 3, a rectangular parallelepiped contact accommodating recess 4 is formed on the rear surface of the bearing member 2. A contact conductive member through hole 6 is formed in the front wall 4a of the contact housing recess 4 so as to correspond to the center of the slide bearing portion 3 having a cylindrical recess shape and penetrate the slide bearing portion 3. The contact conductive through hole 6 has a shaft corresponding to the center of the shaft of the contact conductive member through hole 6 and has a contact portion 7a that contacts the rear surface of the shaft RTa of the transfer roll (contact conductive terminal). ) 7 is installed.
A rectangular parallelepiped leaf spring mounting recess 8 that is formed continuously with the contact receiving recess 4 and longer in the front-rear direction (X-axis direction) than the contact receiving recess 4 is formed in the upper portion of the contact receiving recess 4. ing. A pair of guide grooves 8 b extending in the front-rear direction (X-axis direction) is formed in the side wall 8 a of the leaf spring mounting recess 8. A leaf spring through-hole 8c that penetrates the upper wall 2a of the bearing member 2 is formed on the upper surface of the front end portion of the leaf spring mounting recess 8. The contact housing recess 4 and the leaf spring mounting recess 8 constitute a conductive member housing (4 + 8).

In FIG. 4, a conductive leaf spring 9 is supported on the conductive member housing portion (4 + 8). The leaf spring 9 has a central portion 9a in which guided portions 9a1 and 9a1 projecting in the left-right direction (Y-axis direction) are formed. An arcuate frame contact portion 9 b is formed at the front side (X side) end of the central portion 9 a of the leaf spring 9. A bent portion 9c bent downward is formed at the tip of the leaf spring 9 opposite to the frame contact portion 9b, and an arc-shaped contact support portion 9d is formed at the lower end of the bent portion 9c. Is formed.
When the leaf spring 9 is inserted into the leaf spring mounting recess 8, the guided portions 9a1 and 9a1 are guided and supported by the guide groove 8b.
At this time, the frame contact portion 9 b penetrates the leaf spring through hole 8 c and protrudes upward, and contacts the surface of the bearing mounting hole 1 a of the roll support frame 1. The contact support portion 9 c comes into contact with the rear surface (−X surface) of the contact 7 and presses the contact 7 forward by the elastic force of the leaf spring 9.
The frame, flange portion, bearing member, bearing portion, contact receiving recess, contact conductive through hole, contact, leaf spring mounting recess, and leaf spring constitute the conductive bearing mechanism of the first embodiment.

(Operation of Example 1)
In Embodiment 1 of the present invention having the above-described configuration, the leaf spring 9 is inserted in the front direction (X direction) from the rear surface of the bearing member 2 while being supported by the guide groove 8b. At this time, the arc-shaped frame contact portion 9b of the leaf spring 9 passes through the leaf spring through hole 8c formed in the upper surface of the front end portion of the leaf spring mounting recess 8, and is caught by the leaf spring through hole 8b. Accordingly, the leaf spring 9 is positioned, and the contact support portion 9d of the leaf spring 9 presses the rear surface of the contact (contact conductive terminal) 7 forward.
For this reason, the arc-shaped contact support portion 9d of the leaf spring 9 surely pushes the contact 7 forward, so that the contact 7 comes into contact with the rear end face of the shaft T2a1 of the backup roll T2a supported by the slide bearing portion 3. Is retained.
Therefore, the contact 7 and the leaf spring 9 enable the conductive bearing mechanism of the first embodiment to reliably connect the backup roll T2a and the frame 1 of the image forming apparatus U and ground them.

In the conductive bearing mechanism of the first embodiment, the bearing member 2 and the contact 7 and the leaf spring 9 which are conductive mechanisms for electrically connecting to the image forming apparatus U as a member capable of grounding are unitized. . Therefore, the configuration is simplified, and replacement work at the time of failure can be easily performed.
Further, since the structure is simplified, the conductive bearing mechanism can be miniaturized, and space can be used efficiently, so that component costs and assembly costs can be kept low.

The leaf spring 9 is guided by the guide groove 8b and positioned by the leaf spring through hole 8c. For this reason, in this invention, the bearing member 2 can be easily assembled, without performing the operation | work which requires tools, such as adhesion | attachment, etc., using a screw and crimping. Therefore, the component cost and assembly cost can be kept low.
Furthermore, in the conductive bearing mechanism of the first embodiment, the leaf spring 9 that is a conductive member is disposed inside the bearing member 2. For this reason, since the said leaf | plate spring 9 is not exposed outside the said bearing member 2, the interruption | blocking of conduction | electrical_connection by the deformation | transformation of the said leaf | plate spring 9 which arises in contact with an operator's hand and another member can be prevented.
Further, in the conductive bearing mechanism of the first embodiment, the contact 7 is in contact with the shaft end of the shaft T2a1, so that the contact 7 can contact without receiving the load of the backup roll T2a, and wear compared to the case where the load acts. And damage can be reduced.

(Example 2)
FIG. 5 is an enlarged view of a main part of the conductive bearing mechanism of the second embodiment, FIG. 5A is an enlarged view of the conductive bearing mechanism, and FIG. 5B is a top view of the leaf spring.
In the description of the second embodiment of the present invention, components corresponding to those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
The second embodiment is different from the first embodiment in the following points, but is configured in the same manner as the first embodiment in other points.
In FIG. 5, a guide groove 8b1 'is formed in the side wall 8a of the leaf spring mounting recess 8 of the bearing member 2' of the second embodiment. A pair of left and right retaining grooves 8b2 'extending in the rear lower direction (-X side -Z direction) is formed on the lower surface (-Z surface) of the central portion of the guide groove 8b1'. The retaining groove 8b2 'is formed narrower toward the tip.

In the second embodiment, the leaf spring 9 'is supported by the conductive member accommodating portion (4 + 8) as in the first embodiment. A pair of symmetrical L-shaped guided portions 9a1 'and 9a1' are formed in the central portion 9a 'of the leaf spring 9' of the second embodiment. The guided portions 9a1 ′ and 9a1 ′ are configured in a leaf spring shape, and the tip end portion extends rearwardly downward (−X side−Z direction) with respect to the central portion 9a ′ (FIG. 5A). reference).
In FIG. 5, when the leaf spring 9 'is inserted into the leaf spring mounting recess 8, the guided portions 9a1' and 9a1 'are guided and supported by the guide groove 8b'1. At this time, the tip portions of the guided portions 9a1 ′ and 9a1 ′ having a leaf spring shape are fitted into the retaining groove 8b2 ′ by the elastic restoring force of the leaf spring, so that the leaf spring 9 ′ is prevented from coming off.

(Operation of Example 2)
In the second embodiment of the present invention having the above-described configuration, the rear end of the guided portions 9a1 ′ and 9a1 ′ formed in the central portion 9a ′ of the leaf spring 9 ′ when the leaf spring mounting recess 8 ′ is mounted. Since the portion (−X side end portion) is fitted into the retaining portion 8b2 ′, the leaf spring 9 ′ is prevented from being detached and positioned reliably. Therefore, in the second embodiment, the backup roll T2a and the frame 1 of the image forming apparatus U can be more reliably connected and grounded (grounded) than the first embodiment.
Further, since the second embodiment has the same configuration as that of the first embodiment except for the configuration of the leaf spring guide groove 8b1 'and the leaf spring 9', the same operation as the first embodiment is achieved.

(Example 3)
FIG. 6 is an enlarged view of a main part of the conductive bearing mechanism according to the third embodiment.
In the description of the third embodiment of the present invention, components corresponding to those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
The third embodiment is different from the first embodiment in the following points, but is configured in the same manner as the first embodiment in other points.
In FIG. 6, a bearing member 15 made of resin is mounted in the mounting hole 1a of the frame bearing. A plate spring fixing member accommodating portion 11 having an open upper surface is formed at the upper portion of the bearing member 15. A rear lower portion of the leaf spring fixing member accommodating portion 11 is formed continuously with the leaf spring fixing member accommodating portion 11 and extends downward in the front-rear direction (X side direction) than the leaf spring fixing member accommodating portion 11. A short rectangular parallelepiped contact accommodating portion 12 is formed. A contact conductive member through hole 6 similar to that of the first embodiment is formed in the front wall of the contact housing portion 12.
The leaf spring fixing member accommodating portion 11 and the contact accommodating portion 12 form a conductive member accommodating portion (11 + 12).

A metal leaf spring fixing member 13 is fixed and supported by the side wall 11 a of the leaf spring fixing housing portion 11 inside the leaf spring fixing member housing portion 11. The fixing member 13 has a first leaf spring member support surface 13a on the upper surface side and a second leaf spring member support surface 13b. A first leaf spring member 14 is fixedly supported on the upper surface portion 13a by screws.
The arc-shaped external terminal pressing portion 14 a of the first leaf spring member 14 protrudes upward and contacts the bearing mounting hole 1 a surface of the roll support frame 1.

In FIG. 6, a second leaf spring member 16 is fixedly supported on a second leaf spring member support surface 13 b on the lower surface of the leaf spring fixing member 13. The second leaf spring member 16 has a bent portion 16a bent downward behind the second leaf spring member support surface 13b, and an arc-shaped contact support portion ( A shaft contact terminal pressing portion) 16b is formed.
The contact support portion 16b is formed in the same manner as the contact support portion 9d of the first embodiment. The contact support portion 16b is in contact with the rear surface of the contact (contact conductive terminal) 7 mounted in the contact conductive portion through hole 6 so that the contact 7 is Press forward.
The leaf spring fixing member 13, the first leaf spring member 14, and the second leaf spring member 16 constitute the leaf spring-like conductive member (13 + 14 + 16) of the second embodiment.

(Operation of Example 3)
In the third embodiment of the present invention having the above-described configuration, the contact support portion 16b of the plate spring-like conductive member (13 + 14 + 16) presses the rear surface of the contact (contact conductive terminal) 7 forward. For this reason, since the arc-shaped contact support portion 16b of the second leaf spring portion 16 reliably pushes the contact 7 forward, the contact 7 is the rear end surface of the shaft T2a1 of the backup roll T2a supported by the sliding bearing portion 3. Held in contact with.
The arc-shaped external terminal pressing portion 14 a of the first leaf spring member 14 protrudes upward and contacts the bearing mounting hole 1 a surface of the roll support frame 1.
Therefore, with the contact 7 and the leaf spring-like conductive member (13 + 14 + 16), the conductive bearing mechanism of Embodiment 2 can reliably connect the backup roll T2a and the frame 1 of the image forming apparatus U and ground them. is there.

In the conductive bearing mechanism of the third embodiment, the bearing member 2, the contact 7 which is a conductive mechanism for electrically connecting to the image forming apparatus U as a groundable member, and a leaf spring-like conductive member (13 + 14 + 16), Is unitized. Therefore, it is possible to easily perform replacement work at the time of failure or the like.
Further, the conductive bearing mechanism can be reduced in size, and space can be used efficiently. Further, according to the configuration, the plate spring-like conductive member (13 + 14 + 16), which is a conductive member, is supported by the bearing member 15. Placed inside. For this reason, since the leaf spring-like conductive member (13 + 14 + 16) of Example 3 is not exposed to the outside of the bearing member 15, the leaf spring-like conductive member (which is produced in contact with an operator's hand or another member) 13 + 14 + 16) can be prevented from being interrupted by deformation.

  Furthermore, in the conductive bearing mechanism of the third embodiment, the conductive member (13 + 14 + 16) has the first plate spring 14 and the second plate spring 16 supported by the fixed member 13, so that the vibration during rotation of the backup roll T2a is not caused. Even if it is transmitted to the second leaf spring 16, it can be absorbed by the fixing member 13. Therefore, the adverse effect of vibration is reduced, and the backup roll T2a and the frame 1 can be stably electrically connected.

Example 4
FIG. 7 is an explanatory view of the conductive bearing mechanism of Example 4, FIG. 7A is an enlarged view of the conductive bearing mechanism, and FIG. 7B is a top view of the leaf spring.
In the description of the fourth embodiment of the present invention, components corresponding to those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
The fourth embodiment is different from the first embodiment in the following points, but is configured in the same manner as the first embodiment in other points.
In FIG. 7, the sliding bearing portion 23 of the bearing member 22 of the fourth embodiment is configured so that the shaft T2a1 can penetrate in the front-rear direction (X-axis direction), unlike the sliding bearing portion 3 of the first embodiment. The shaft T2a1 of the backup roll T2a penetrating the sliding bearing portion 23 has a rear outer peripheral surface rotatably supported by the shaft through hole 23, and a rear end protruding to the rear portion (−X portion).

  The bearing member 22 of the fourth embodiment has only the rectangular plate spring housing recess 28 extending in the front-rear direction (X-axis direction), with the contact housing recess 4 omitted in the bearing member 22 of the first embodiment. A guide groove 28b extending in the front-rear direction (X-axis direction) is formed in the side wall 28a of the leaf spring mounting recess 28. A leaf spring through hole 28c is formed in the upper surface of the front end portion of the leaf spring mounting recess 28 so as to penetrate the upper wall 22a of the bearing member 22. A contact conductive through hole 26 penetrating in the vertical direction (Z-axis direction) is formed in the lower surface of the front end portion of the leaf spring mounting recess 28. A conductive contact (contact conductive terminal) 27 having a contact portion 27a whose lower surface is in contact with the outer peripheral surface of the axis T2a1 of the backup roll is mounted in the contact conductive through hole 26.

In FIG. 7, a leaf spring 29 bent in a U shape in the forward direction is attached to the leaf spring accommodating recess 28 of the second embodiment.
The leaf spring 29 has a central portion 29a in which guided portions 29a1 and 29a1 projecting in the left and right sides (Y-axis direction) are formed. An arcuate frame contact portion 29 b is formed at the upper end (Z side end) of the central portion 29 a of the leaf spring 29. An arc-shaped contact support portion 29d is formed at the lower end of the leaf spring 29 opposite to the frame contact portion 29b.
When the leaf spring 29 is inserted into the leaf spring mounting recess 28, the guided portions 29a1 and 29a1 are guided and supported by the guide groove 28b.
At this time, the frame contact portion 29b protrudes upward through the leaf spring through hole 28c and contacts the surface of the bearing mounting hole 1a of the roll support frame 1. The contact support portion 29 c comes into contact with the upper surface (Z surface) of the contact 27 and presses the contact 27 downward by the elastic force of the leaf spring 29.

(Operation of Example 4)
In Embodiment 3 of the present invention having the above-described configuration, the sliding bearing portion 23 has a shaft T2a1 of a backup roll T2a protruding from the rear portion (−X portion) of the shaft through hole 23, and into the roll through hole 23a. The outer peripheral surface is rotatably supported while being supported. For this reason, other members, such as a gear, can be attached to the rear end portion (−X end portion) of the shaft T2a1 of the backup roll T2a.
The leaf spring 29 is inserted and attached to the front (X direction) from the rear surface of the bearing member 22 while being supported by the guide groove 28b, and the frame contact portion 29b is attached to the frame 1 in the same manner as the leaf spring of the first embodiment. The contact support portion 29d presses the upper surface of the contact (contact conductive terminal) 27 downward.

  Therefore, the contact 27 is held in contact with the outer peripheral surface of the shaft T2a1 of the backup roll T2a supported by the slide bearing portion 23, and the frame contact portion 29b reliably contacts the frame 1. Therefore, similarly to the first embodiment, the conductive bearing mechanism of the third embodiment can also reliably connect the backup roll T2a and the frame 1 and can be reduced in size and simplified in configuration. In the conductive bearing mechanism of Example 3, the contact 27 is in contact with the outer peripheral surface of the shaft T2a1 from above, so that the load of the shaft T2a1 does not act. Therefore, it is possible to reduce the wear and damage of the contact 27 accompanying the rotation of the shaft T2a1.

(Example 5)
FIG. 8 is an enlarged view of a main part of the conductive bearing mechanism of the fifth embodiment.
In the description of the fifth embodiment of the present invention, components corresponding to those of the fourth embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
The fifth embodiment is different from the third and fourth embodiments in the following points, but is configured in the same manner as the third and fourth embodiments in other points.
In FIG. 8, the sliding bearing member 32 of the fifth embodiment has a sliding bearing portion 23 configured in the same manner as the sliding bearing portion 23 of the fourth embodiment.
The bearing member 32 has a rectangular parallelepiped leaf spring accommodating recess 38 formed in the same manner as in the fourth embodiment and extending in the front-rear direction (X-axis direction).

  In FIG. 8, a metal leaf spring fixing member 33 configured similarly to the leaf spring fixing member of Example 3 is fixedly supported inside the leaf spring accommodating recess 38 of Example 5. A first leaf spring member 34 is fixedly supported by screws on the upper surface portion 33a of the first leaf spring member support surface 33a on the upper surface side of the leaf spring fixing member 33.

In FIG. 8, a second leaf spring member 35 is fixedly supported on a second leaf spring member support surface 33 b on the lower surface of the leaf spring fixing member 33. An arcuate contact support portion (shaft contact terminal pressing portion) 35 b is formed at the front end portion of the second leaf spring member 35.
The contact support portion 35b is formed in the same manner as the contact support portion 29d of the fourth embodiment, contacts the upper surface of a contact (contact conductive terminal) 37 mounted in the contact conductive portion through hole 36, and the contact 37 is Press down.
The leaf spring fixing member 33, the first leaf spring member 34, and the second leaf spring member 35 constitute the leaf spring-like conductive member (33 + 34 + 35) of the fifth embodiment.

(Operation of Example 5)
In the fifth embodiment of the present invention having the above-described configuration, the contact support portion 35b of the plate spring-like conductive member (33 + 34 + 35) presses the upper surface of the contact (contact conductive terminal) 37 downward. For this reason, since the arc-shaped contact support portion 35b of the second leaf spring portion 35 reliably pushes the contact 37 downward, the contact 37 is an outer peripheral surface of the shaft T2a1 of the backup roll T2a supported by the slide bearing portion 3. Held in contact with. Further, the front end portion of the first plate spring member 34 protrudes upward through the plate spring through hole 28 c and contacts the surface of the bearing mounting hole 1 a of the roll support frame 1.
Therefore, the fifth embodiment can reliably conduct the backup roll T2a and the frame 1 as in the fourth embodiment. Similarly to the third embodiment, the conductive member having the fixing member 33 can reduce adverse effects due to vibration and can conduct stably.

(Example 6)
FIG. 9 is an enlarged view of a main part of the conductive bearing mechanism of the sixth embodiment.
In the description of the sixth embodiment of the present invention, components corresponding to those of the fourth embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
The sixth embodiment is different from the fourth embodiment in the following points, but is configured in the same manner as the fourth embodiment in other points.
In FIG. 9, the bearing member 42 of the sixth embodiment is replaced with the plain bearing portion 23 of the fourth embodiment, a bearing support portion 42a formed on the front side, a rear side of the bearing support portion 42a, and the backup roll T2a. And a cylindrical shaft penetration part 42b through which the shaft T2a1 passes. The bearing support portion 42a supports a ball bearing (rolling bearing) BB that supports the outer peripheral surface of the shaft T2a1 of the backup roll T2a. Therefore, in Example 6, the axis T2a1 of the backup roll T2a is rotatably supported by the ball bearing BB, and the ball bearing BB and the bearing support portion 42a constitute a bearing portion (BB + 42a).

Further, in the bearing member 42 of the sixth embodiment, the flange portion FL is omitted, and the bearing member 42 is mounted by fitting the frame 1 into the portion of the through plate spring through hole 8c ′ of the upper wall 42a. It is configured as follows. Therefore, first, after the bearing member 42 is mounted on the frame 1, the shaft T2a1 is inserted into the ball bearing BB and the shaft T2a1 from the front side, and the ball bearing BB is fixed by the bearing fixing member 44, whereby the shaft T2a1 is electrically connected to the frame 1. Can be fixed in a connected state. In the bearing portion 42 of the sixth embodiment, after the shaft T2a1 of the backup roll T2a is press-fitted into the ball bearing BB, the shaft T2a1 of the backup roll T2a and the ball bearing BB are integrally inserted into the bearing member 42 and attached. is doing.
The bearing member 42 of the sixth embodiment is provided with the same contact (contact conductive terminal) 27 and leaf spring 29 as those of the third embodiment. The bearing member 42, the contact (contact conductive terminal) 27 and the leaf spring 29 are provided. Further, the conductive bearing mechanism (27 + 29 + 42 + BB) of the sixth embodiment is configured by the ball bearing BB.

(Operation of Example 6)
In the sixth embodiment of the present invention having the above-described configuration, the leaf spring 29 is supported from the rear surface of the bearing member 42 in the front direction (X direction) while being supported by the guide groove 28b, like the leaf spring of the first embodiment. Inserted and mounted, the frame contact portion 29b is pressed against the frame 1, and the contact support portion 29d presses the upper surface of the contact (contact conductive terminal) 27 downward.
For this reason, the contact 27 is held in contact with the outer peripheral surface of the shaft T2a1 of the backup roll T2a supported by the ball bearing BB, and the frame contact portion 29b reliably contacts the frame 1.
Therefore, in the sixth embodiment, the backup roll T2a and the frame 1 can be reliably conducted as in the fourth embodiment.
Further, the ball bearing BB and the bearing member 42 can be unitized, and the bearing mounting hole 1a can be made common as compared with the case where the ball bearing BB and the bearing member 42 are separately mounted on the frame 1.

(Example of change)
As mentioned above, although the Example of this invention was explained in full detail, this invention is not limited to the said Example, A various change is performed within the range of the summary of this invention described in the claim. It is possible. Examples of modifications of the present invention are illustrated below.
(H01) In the above-described embodiment, the copying machine as the image forming apparatus has been illustrated. However, the present invention is not limited to this, and a FAX, a printer, or a multifunction machine having all or a plurality of functions may be used. Further, the image forming apparatus is not limited to a color image forming apparatus, and may be configured by a monochrome image forming apparatus. The present invention is not limited to a so-called rotary image forming apparatus, and can be applied to an image forming apparatus such as a tandem type. is there.

(H02) In the above-described embodiment, the conductive bearing mechanism of the backup roll T2a has been exemplified. However, the present invention is not limited to this, and the backup roll T2a can be incorporated in a bearing portion that requires electrical connection. Therefore, it can be used as a bearing for a grounded photosensitive member Py, Pm, Pc, Pk or a rotating roll (for example, a driving roll Rd) that may accumulate static electricity.
(H03) In the above embodiment, the grounded frame 1 is exemplified as the external terminal. However, the present invention is not limited to this, and when used as a bearing of a rotating roll to which a bias is applied, a power supply terminal as an external terminal It is also possible to connect to. For example, it can be used as a conductive bearing mechanism such as a transfer roll T1, T2b or a developing roll.
(H04) In the above embodiment, it is sufficient to provide the conductive bearing mechanism at one end of the shaft, but it is also possible to provide it at both ends.
(H05) In the above embodiment, the shaft is not limited to the rotating shaft T2a1, and a fixed shaft can be supported.
(H06) In the sixth embodiment, when the conduction bearing mechanism is assembled, the shaft T2a1 of the backup roll T2a is first press-fitted into the ball bearing BB and then inserted into the bearing member 42. It is also possible to mount the axis T2a1 of the backup roll T2a after mounting the bearing BB.
(H07) In the above embodiment, the conductive bearing mechanism is provided on the shaft T2a1 of the backup roll T2a fixedly supported inside the image forming apparatus main body. However, the present invention is not limited to this, and the open position relative to the image forming apparatus main body. It is also possible to provide a conductive bearing mechanism on a sheet conveying roll or the like supported by an opening / closing cover that can be opened and closed between the position and the closing position. In the image forming apparatus having the conductive bearing mechanism provided on the sheet conveying roll of the opening / closing cover, the static electricity charged on the shaft of the sheet conveying roll can be removed even when the opening / closing cover is moved to the open position. It is desirable that the frame 1 of the conductive bearing mechanism is electrically connected to a grounded frame disposed inside the image forming apparatus main body (H08). In the second embodiment, the leaf spring 9 ' L-shaped leaf spring-shaped guided portions 9a1 'and 9a1' whose front end portion is formed in the center portion 9a 'and extends in the rear lower direction (-X side -Z direction) with respect to the center portion 9a'. However, it is also possible to use the leaf spring 9 'in the conductive bearing mechanism of the first embodiment. In this case, the guided portions 9a1 ′ and 9a1 ′ are brought into contact with the lower surface of the plate spring mounting recess 8 in a state where the plate spring 9 ′ is inserted and mounted in the plate spring mounting recess 8 of the conductive bearing mechanism of the first embodiment. Since the frictional force is generated, the leaf spring 9 'can be supported more stably than the first embodiment.

FIG. 1 is an overall explanatory view of an image forming apparatus including a fixing device according to a first embodiment of the present invention. FIG. 2 is an enlarged view of a main part of the conductive bearing mechanism according to the first embodiment. FIG. 3 is a rear view of the bearing member according to the first embodiment. 4A and 4B are explanatory views of the leaf spring of the first embodiment, FIG. 4A is a top view of the leaf spring, and FIG. 4B is a view seen from an arrow IVB in FIG. 4A. FIG. 5 is an enlarged view of a main part of the conductive bearing mechanism of the second embodiment, FIG. 5A is an enlarged view of the conductive bearing mechanism, and FIG. 5B is a top view of the leaf spring. FIG. 6 is an enlarged view of a main part of the conductive bearing mechanism according to the third embodiment. FIG. 7 is an explanatory view of the fourth embodiment, FIG. 7A is an enlarged view of a conductive bearing mechanism, and FIG. 7B is a top view of a leaf spring. FIG. 8 is an enlarged view of a main part of the conductive bearing mechanism according to the fifth embodiment. FIG. 9 is an enlarged view of a main part of the conductive bearing mechanism of the sixth embodiment. FIG. 10 is an explanatory view of a conventional conductive member.

Explanation of symbols

1 ... external terminal,
2, 2 ', 22, 32, 42 ... bearing members,
3, 23 ... slide bearing,
3, 23, BB + 42a ... bearing part,
7, 9, 13, 14, 16, 27, 29, 33, 34, 35, 37 ... conductive members,
4 + 8, 11 + 12, 28, 38 ... conductive member housing,
42a ... bearing support,
7, 9, 13, 14, 16, 27, 29, 33, 34, 35, 37 ... conductive members,
7, 27, 37 ... shaft contact terminals,
7a, 27a, 37a ... shaft contact terminal mounting port,
9, 13, 14, 16, 29, 33, 34, 35 ... leaf spring-like conductive members,
9b, 14a, 29b ... external terminal pressing part,
9d, 16b, 29d, 35b ... shaft contact terminal pressing part,
14, 34 ... first leaf spring member,
16, 35 ... second leaf spring member,
BB ... Bearing
T2a1... Conductive axis.

Claims (9)

A bearing portion that supports a conductive shaft, a conductive member housing portion that houses a conductive member that conducts the conductive shaft, and a shaft contact terminal that connects the conductive member housing portion and the bearing portion and contacts the conductive shaft A shaft contact terminal mounting port on which is mounted, and a bearing member having
The plate spring-shaped conductive member having a shaft contact terminal pressing portion that presses the shaft contact terminal against the conductive shaft, and an external terminal pressing portion that is pressed against the external terminal with a predetermined pressing force,
A conductive bearing mechanism characterized by comprising: The conductive member constituted by a leaf spring in which the shaft contact terminal pressing portion and the external terminal pressing portion are integrally formed;
The conductive bearing mechanism according to claim 1, further comprising: The first leaf spring member having the shaft contact terminal pressing portion, the second leaf spring member having the external terminal pressing portion, the first leaf spring member and the second leaf spring member are fixedly supported, and the conductive member A plate spring fixing member supported by the housing portion, the conductive member,
The conductive bearing mechanism according to claim 1, further comprising: The shaft contact terminal in contact with the axial end of the conductive shaft;
The conductive bearing mechanism according to any one of claims 1 to 3, further comprising: The shaft contact terminal in contact with the outer peripheral surface of the conductive shaft;
The conductive bearing mechanism according to any one of claims 1 to 3, further comprising: The bearing member having the bearing portion configured by a bearing that rotatably supports the conductive shaft and a bearing support portion that supports the bearing;
The conductive bearing mechanism according to any one of claims 1 to 5, further comprising: The bearing part constituted by a sliding bearing;
The conductive bearing mechanism according to any one of claims 1 to 5, further comprising: The external terminal constituted by a grounded frame;
The conductive bearing mechanism according to any one of claims 1 to 7, further comprising:   An image forming apparatus comprising the conductive bearing mechanism according to claim 1.

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