JP7095319B2 - Image forming device - Google Patents

Description

The present invention relates to an image forming apparatus having a function of irradiating two places of a photoconductor with static elimination light.

The electrophotographic image forming apparatus includes a static elimination unit that eliminates static electricity by irradiating the surface of a photoconductor that carries a toner image while rotating. In the following description, the light that eliminates static electricity on the surface of the photoconductor is referred to as static elimination light.

The static elimination unit may include a long light guide member along the axial direction of the photoconductor and a light source that emits the static elimination light at one end of the light guide member. The light guide member has a reflecting portion that reflects the static elimination light in a direction toward the surface of the photoconductor. For example, the reflective portion is composed of a plurality of recesses arranged in the axial direction.

Further, in the tandem image forming apparatus, the two reflecting portions formed on the light guide member reflect the static elimination light toward the surfaces of the two adjacent photoconductors in the traveling direction of the lower surface of the intermediate transfer belt. (For example, see Patent Document 1).

In the above case, three of the four photoconductors other than the one located at the uppermost stream in the traveling direction of the lower surface of the intermediate transfer belt are the region before the transfer of the toner image and the region after the transfer of the toner image. It is irradiated with the static elimination light at two places with the area.

Japanese Unexamined Patent Publication No. 2013-11301

By the way, in the tandem image forming apparatus, it is desirable that the static elimination light is applied to two places of the pre-transfer region and the post-transfer region in all four photoconductors.

Further, also in the monochrome image forming apparatus, it is desirable that the static elimination light is applied to two places of the photoconductor, the pre-transfer region and the post-transfer region.

On the other hand, it is not preferable to provide two light sources for each photoconductor in order to irradiate the two places of the photoconductor with the static elimination light.

An object of the present invention is to provide an image forming apparatus capable of irradiating two places of the photoconductor with static elimination light without providing a plurality of light sources for one photoconductor.

The image forming apparatus according to one aspect of the present invention includes a photoconductor, a transfer device, a light source, and a branched light guide. The photoconductor carries a toner image on the outer peripheral surface while rotating in a predetermined rotation direction. The transfer device transfers the toner image on the photoconductor to a transfer material at a predetermined transfer position. The branched light guide uses the static elimination light emitted from the light source in a pre-transfer region and a post-transfer region located on the upstream side and the downstream side in the predetermined rotation direction with respect to the transfer position on the outer peripheral surface of the photoconductor, respectively. Lead to.

According to the present invention, it is possible to provide an image forming apparatus capable of irradiating two places of the photoconductor with static elimination light without providing a plurality of light sources for one photoconductor.

FIG. 1 is a configuration diagram of an image forming apparatus according to an embodiment. FIG. 2 is a block diagram of an image forming unit in the image forming apparatus according to the embodiment. FIG. 3 is a configuration diagram of a static elimination device in the image forming apparatus according to the embodiment. FIG. 4 is a plan view of a downstream light guide member in the static elimination device of the image forming apparatus according to the embodiment. FIG. 5 is a cross-sectional view of a part of the reflecting portion of the light guide member in the image forming apparatus according to the embodiment. FIG. 6 is a diagram of a connection portion between the base of the downstream light guide member and the relay light guide member in the static elimination device of the image forming apparatus according to the embodiment. FIG. 7 is a cross-sectional view of a facing portion of the downstream light guide member in the static elimination device of the image forming apparatus according to the embodiment. FIG. 8 is a cross-sectional view of an upstream light guide member in the static elimination device of the image forming apparatus according to the embodiment. FIG. 9 is a perspective view of the support mechanism of the downstream light guide member in the static elimination device of the image forming apparatus according to the embodiment. FIG. 10 is a block diagram of the static elimination device according to the first application example. FIG. 11 is a block diagram of the static elimination device according to the second application example. FIG. 12 is a cross-sectional view of a facing portion of the downstream light guide member in the static eliminator according to the third application example.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are examples that embody the present invention, and do not limit the technical scope of the present invention.

[Structure of image forming apparatus 10]
The image forming apparatus 10 according to the embodiment is an apparatus that executes a printing process for forming an image on a sheet. The sheet is a sheet-like image forming medium such as paper or an envelope.

As shown in FIG. 1, the image forming apparatus 10 includes a sheet supply mechanism 2, a sheet conveying mechanism 3, an image forming unit 40, a control device 8, and the like in the main body 1.

The image forming unit 40 is a device that executes the printing process by an electrophotographic method. Therefore, the image forming unit 40 includes an image forming device 4, an optical scanning device 47, a transfer device 44, and a fixing device 48.

The image-forming device 4 includes a photoconductor 41, a charging device 42, a developing device 43, a photoconductor cleaning device 45, a static elimination device 46, and the like.

The image forming apparatus 10 shown in FIG. 1 is a color image forming apparatus having a tandem type image forming unit 40. Therefore, the image forming apparatus 10 includes four image forming apparatus 4 corresponding to the toners of four colors of cyan, magenta, yellow, and black. That is, the four image forming devices 4 include a photoconductor 41 and a developing device 43 corresponding to toners of different colors.

Further, the transfer device 44 includes an endless intermediate transfer belt 44a, four primary transfer devices 44b corresponding to the four image forming devices 4, a secondary transfer device 44c, and a belt cleaning device 44d.

The drum-shaped photoconductor 41 in each of the intermediate transfer belt 44a and the image forming apparatus 4 is rotationally driven by a drive mechanism (not shown). The four image forming devices 4 are arranged along a portion of the intermediate transfer belt 44a that moves in a predetermined moving direction. In this embodiment, the four image forming devices 4 are arranged along the lower surface portion of the intermediate transfer belt 44a.

Hereinafter, the predetermined moving direction of the portion of the intermediate transfer belt 44a along which the four image forming devices 4 are aligned is referred to as a first direction D1. Further, the axial direction of the photoconductor 41 is referred to as a second direction D2 (see FIG. 2). The second direction D2 is also the longitudinal direction of the photoconductor 41.

The second direction D2 is the so-called main scanning direction, and the first direction D1 is the so-called sub-scanning direction. The second direction D2 is a direction orthogonal to the first direction D1.

The sheet supply mechanism 2 feeds the sheet to the transport path 30. The sheet transport mechanism 3 transports the sheet along the transport path 30.

The charging device 42 uniformly charges the surface of the photoconductor 41 that rotates in a predetermined direction. The optical scanning device 47 writes an electrostatic latent image on the surface of the photoconductor 41. In the following description, the predetermined rotation direction of the photoconductor 41 is referred to as a drum rotation direction R0 (see FIG. 2).

The developing device 43 develops the electrostatic latent image on the surface of the photoconductor 41 into a toner image. As a result, the photoconductor 41 carries the toner image on the outer peripheral surface while rotating in the drum rotation direction R0.

As shown in FIG. 2, the primary transfer device 44b transfers the toner image on the photoconductor 41 to the intermediate transfer belt 44a at a predetermined transfer position P0. As a result, the toner images of four colors are formed so as to overlap the intermediate transfer belt 44a as a color image.

The control device 8 causes the image forming unit 40 to execute the color printing process by operating all four image forming devices 4. On the other hand, the control device 8 causes the image forming unit 40 to execute the monochrome printing process by operating only one image forming device 4 located at the most downstream of the first direction D1.

That is, one image forming apparatus 4 located at the most downstream of the first direction D1 forms the black toner image on the photoconductor 41.

The photoconductor cleaning device 45 removes the toner remaining on the surface of the photoconductor 41. In the tandem image forming unit 40, the intermediate transfer belt 44a is a transfer material to which the toner image is transferred from the photoconductor 41.

The secondary transfer device 44c transfers the toner image on the intermediate transfer belt 44a to the sheet conveyed along the transfer path 30. The fixing device 48 fixes the toner image on the sheet by heating the toner image transferred to the sheet. The belt cleaning device 44d removes the toner remaining on the intermediate transfer belt 44a.

The control device 8 controls the electric device in the image forming device 10. For example, the control device 8 includes a processor such as a CPU (Central Processing Unit) (not shown), a main storage device such as a RAM (Random Access Memory), and a secondary storage device such as a flash memory.

The processor executes various data processing and control of the electric device by executing a program stored in the secondary storage device in advance. At that time, the processor temporarily stores the program being executed and the data being processed in the RAM.

The processor inputs signals of various sensors and switches and outputs control signals to the device to be controlled.

The static elimination device 46 irradiates the outer peripheral surface of the photoconductor 41 with static elimination light to eliminate static electricity on the outer peripheral surface of the photoconductor 41. As shown in FIG. 2, the static elimination device 46 irradiates the static elimination light at two locations, the pre-transfer region 41b and the post-transfer region 41a, on the outer peripheral surface of the photoconductor 41.

As shown in FIG. 3, each of the static elimination devices 46 includes one light source 461 that emits the static elimination light. Therefore, the image forming apparatus 10 includes four light sources 461 corresponding to the four photoconductors 41. The light source 461 is, for example, an LED (Light Emitting Diode).

The pre-transfer region 41b is a region located upstream of the drum rotation direction R0 with respect to the transfer position P0 on the outer peripheral surface of the photoconductor 41. The pre-transfer region 41b is a region on the outer peripheral surface of the photoconductor 41 between the position facing the developing device 43 and the transfer position P0.

The post-transcriptional region 41a is a region on the outer peripheral surface of the photoconductor 41 on the downstream side of the drum rotation direction R0 with respect to the transfer position P0. The post-transcriptional region 41a is a region between the transfer position P0 on the outer peripheral surface of the photoconductor 41 and the position facing the photoconductor cleaning device 45.

By the way, in the tandem type image forming apparatus 10, it is desirable that the static elimination light is applied to two places of the pre-transfer region 41b and the post-transfer region 41a in all four photoconductors 41.

Further, even in the monochrome image forming apparatus, it is desirable that the static elimination light is applied to two places of the pre-transfer region 41b and the post-transfer region 41a of the photoconductor 41.

On the other hand, it is not preferable to provide two light sources 461 for each photoconductor 41 in order to irradiate the two places of the photoconductor 41 with the static elimination light.

In the image forming apparatus 10, the four static elimination devices 46 can irradiate the two places of the photosensitive member 41 with the static elimination light without providing a plurality of light sources 461 for one photosensitive member 41.

[Static elimination device 46]
In the present embodiment, the four static elimination devices 46 include one first static elimination device 46a and three second static elimination devices 46b. The first static eliminator 46a has a different configuration from the second static eliminator 46b.

The first static elimination device 46a is included in one of the four image forming devices 4 located at the uppermost stream in the first direction D1. The second static elimination device 46b is included in each of the other three image forming devices 4.

[First static elimination device 46a]
As shown in FIG. 3, the first static eliminator 46a includes one light source 461, a downstream light guide member 463, a first mirror 462, a second mirror 464, a relay light guide member 465, and a third mirror. It includes a 466, an upstream light guide member 467, and a fourth mirror 468.

The downstream light guide member 463, the relay light guide member 465, and the upstream light guide member 467 are supported by the housing 450 of the unit including the photoconductor cleaning device 45 in the corresponding image forming device 4.

In the present embodiment, the photoconductor 41, the charging device 42, and the photoconductor cleaning device 45 form one drum unit for each image forming device 4. The downstream light guide member 463, the relay light guide member 465, and the upstream light guide member 467 are supported by a housing 450 that includes the charging device 42 and the photoconductor cleaning device 45 in the drum unit.

In the example shown in FIG. 3, four light sources 461 in four static elimination devices 46 are mounted on one electronic board 4610. However, it is also conceivable that the four light sources 461 are each mounted on a separate electronic board 4610.

It is also conceivable that the light source 461 of the first static eliminator 46a is mounted on one electronic board 4610, and the three light sources 461 of the three second static eliminators 46b are mounted on the other electronic board 4610.

The downstream light guide member 463, the relay light guide member 465, and the upstream light guide member 467 are transparent members. For example, the downstream light guide member 463, the relay light guide member 465, and the upstream light guide member 467 are transparent synthetic resin members.

The downstream light guide member 463 is a rod-shaped member along the second direction D2. The downstream light guide member 463 is arranged on the downstream side of the drum rotation direction R0 with respect to the photoconductor 41. In other words, the downstream light guide member 463 is arranged on the downstream side of the first direction D1 with respect to the photoconductor 41.

As shown in FIG. 4, the downstream light guide member 463 has a base portion 463x on which the static elimination light is incident from the light source 461 and a downstream facing portion 463y facing the post-transcriptional region 41a. In the present embodiment, the static elimination light emitted from the light source 461 is incident on the end face of the base 463x.

The second mirror 464 is arranged to face the end face opposite to the light source 461 in the downstream light guide member 463. For example, it is conceivable that the second mirror 464 is a sheet-shaped mirror. In this case, the second mirror 464 is attached to the end face opposite to the light source 461 in the downstream light guide member 463.

The static elimination light incident on the base portion 463x passes through the base portion 463x along the second direction D2 and travels in the downstream facing portion 463y along the second direction D2. The second mirror 464 prevents the static elimination light from leaking from the end face opposite to the light source 461 in the downstream light guide member 463.

Due to the action of the second mirror 464, the static elimination light travels in the downstream light guide member 463 in the direction from the first end on the light source 461 side to the second end on the opposite side along the second direction D2, and further. It also progresses in the opposite direction.

The base portion 463x of the downstream light guide member 463 has a branch reflection portion 463a. The branch reflecting portion 463a reflects a part of the static elimination light traveling inside the base portion 463x along the second direction D2 toward the base end 465a of the relay light guide member 465.

The branched reflection portion 463a is formed on a portion of the side surface of the base portion 463x opposite to the photoconductor 41.

As shown in FIG. 5, the branch reflection portion 463a is a portion formed by a plurality of recesses 460 arranged at intervals in the second direction D2. Each of the recesses 460 is a groove along a direction intersecting the second direction D2.

In the example shown in FIG. 5, each of the recesses 460 is a groove having a triangular cross section along a direction orthogonal to the second direction D2. The static elimination light traveling along the second direction D2 is reflected and transmitted at the interface of the plurality of recesses 460. Further, the static elimination light reflected at the interface of the plurality of recesses 460 goes to the opposite side of the portion where the branch reflection portion 463a is formed on the outer peripheral surface of the base portion 463x.

Therefore, as shown in FIG. 6, the static elimination light reflected by the branch reflection portion 463a is radiated from the portion of the outer peripheral surface of the base portion 463x opposite to the portion where the branch reflection portion 463a is formed. As a result, the static elimination light incident on the base portion 463x is branched into light directed to the downstream facing portion 463y along the second direction D2 and light emitted from the portion opposite to the branch reflection portion 463a in the base portion 463x. ..

The other part of the static elimination light traveling along the second direction D2 passes through the interface of the plurality of recesses 460. Depending on the angle of the inner surface of the plurality of recesses 460 and the depth of the plurality of recesses 460, the ratio of the static elimination light reflected at the interface of the plurality of recesses 460 to the transmitted static elimination light varies. The shape of the plurality of recesses 460 in the branch reflection portion 463a is designed so that the ratio of the static elimination light transmitted through the branch reflection portion 463a is smaller.

In the present embodiment, the first mirror 462 is arranged outside the branch reflection portion 463a in the base 463x. The first mirror 462 reflects the static elimination light transmitted through the branch reflection portion 463a into the base portion 463x.

For example, it is conceivable that the first mirror 462 is a sheet-shaped mirror. In this case, the first mirror 462 is attached to the outer surface of the branch reflection portion 463a in the base portion 463x.

In the following description, the portion of the outer peripheral surface of the base portion 463x opposite to the portion where the branch reflection portion 463a is formed is referred to as a branch surface 463c. The base portion 463x branches the static elimination light into light traveling along the second direction D2 and light emitted from the branch surface 463c of the base portion 463x.

The branch surface 463c of the base portion 463x faces the base end 465a of the relay light guide member 465. Therefore, the static elimination light reflected by the branch reflection unit 463a is incident on the surface of the base end 465a of the relay light guide member 465.

The downstream facing portion 463y of the downstream light guide member 463 has a light distribution portion 463b. The light distribution unit 463b reflects a part of the static elimination light traveling inside the downstream facing portion 463y along the second direction D2 toward the post-transcriptional region 41a of the photoconductor 41, and the other static elimination light. A part is transmitted to the downstream side of the first direction D1.

Similar to the branch reflection unit 463a, the light distribution unit 463b is also a portion in which a plurality of recesses 460 arranged at intervals in the second direction D2 are formed (see FIG. 5). For example, it is conceivable that the ratio of the static elimination light transmitted through the light distribution unit 463b is larger than the ratio of the static elimination light transmitted through the branch reflection unit 463a. The shape of the plurality of recesses 460 in the light distribution unit 463b is designed so that the static elimination light transmits the light distribution unit 463b by a desired amount.

As shown in FIG. 7, the light distribution unit 463b is formed in a range on the downstream side of the first direction D1 on the outer peripheral surface of the downstream facing portion 463y.

As shown in FIG. 7, the static elimination light reflected by the light distribution unit 463b is radiated from the upstream curved surface 463g on the outer peripheral surface of the downstream facing portion 463y on the opposite side of the light distribution unit 463b.

The static elimination light emitted from the upstream curved surface 463 g is applied to the post-transcriptional region 41a of the corresponding photoconductor 41 as shown in FIGS. 2 and 3. That is, the static elimination light reflected by the light distribution unit 463b toward the upstream side of the first direction D1 is applied to the post-transcriptional region 41a of the corresponding photoconductor 41.

On the other hand, as shown in FIGS. 2 and 3, the static elimination light transmitted through the light distribution unit 463b irradiates the pre-transfer region 41b of the adjacent photoconductor 41 on the downstream side of the first direction D1. That is, the static elimination light transmitted by the light distribution unit 463b to the downstream side of the first direction D1 is applied to the pre-transfer region 41b of the adjacent photoconductor 41.

That is, the light distribution unit 463b directs the static elimination light traveling inside the downstream facing portion 463y along the second direction D2 toward the upstream side of the first direction D1 and toward the downstream side of the first direction D1. Distribute to.

As shown above, the downstream light guide member 463 guides the static elimination light emitted from the light source 461 along the second direction D2. Further, the downstream light guide member 463 is a post-transcriptional region 41a of the photoconductor 41 located on the upstream side of the first direction D1 over the entire second direction D2 and a photoconductor 41 located on the downstream side of the first direction D1. The static elimination light is irradiated to the pre-transcriptional region 41b over the entire second direction D2.

The relay light guide member 465 is a member formed so as to extend from the base end 465a facing the side surface of the base portion 463x of the downstream light guide member 463 toward the upstream position of the drum rotation direction R0 in the photoconductor 41.

In the relay light guide member 465, the portion from the base end 465a to the intermediate corner portion 465c is formed along the first direction D1, and the portion from the corner portion 465c to the end 465b is formed along the second direction D2. It is formed.

As shown in FIG. 6, the surface of the base end 465a of the relay light guide member 465 is in surface contact with the branch surface 463c of the base portion 463x. As a result, the static elimination light reflected by the branch reflection portion 463a of the base portion 463x efficiently advances from the base portion 463x to the relay light guide member 465.

In the example shown in FIG. 6, the branch surface 463c is a convex curved surface, and the surface of the base end 465a of the relay light guide member 465 is a concave curved surface along the branch surface 463c. It is also conceivable that the surface of the branch surface 463c and the base end 465a is a flat surface.

The third mirror 466 is arranged so as to face the outer surface of the corner portion 465c of the relay light guide member 465. The third mirror 466 prevents the static elimination light from leaking from the corner portion 465c to the outside of the relay light guide member 465.

For example, it is conceivable that the third mirror 466 is a sheet-shaped mirror. In this case, the third mirror 466 is attached to the outer surface of the corner portion 465c of the relay light guide member 465.

The upstream light guide member 467 is a rod-shaped member along the second direction D2. The upstream light guide member 467 is arranged at a position on an extension line of the relay light guide member 465 on the upstream side of the drum rotation direction R0 with respect to the photoconductor 41.

The end surface of the upstream light guide member 467 is in surface contact with the surface of the end 465b of the relay light guide member 465. For example, the end surface of the upstream light guide member 467 and the surface of the end 465b of the relay light guide member 465 are flat surfaces.

The fourth mirror 468 is arranged so as to face the end face opposite to the relay light guide member 465 in the upstream light guide member 467. For example, it is conceivable that the fourth mirror 468 is a sheet-shaped mirror. In this case, the fourth mirror 468 is attached to the end face opposite to the relay light guide member 465 in the upstream light guide member 467.

The static elimination light incident on the upstream light guide member 467 from the terminal 465b of the relay light guide member 465 travels in the upstream light guide member 467 along the second direction D2 along the second direction D2. The fourth mirror 468 prevents the static elimination light from leaking from the end face opposite to the relay light guide member 465 in the upstream light guide member 467.

As shown in FIGS. 3 and 8, the upstream light guide member 467 has an upstream reflecting portion 467a that reflects the static elimination light traveling inside along the second direction D2 toward the pre-transfer region 41b.

The upstream reflective portion 467a is also a portion in which a plurality of recesses 460 arranged at intervals in the second direction D2 are formed, similarly to the branched reflective portion 463a (see FIG. 5). The shape of the plurality of recesses 460 in the upstream reflecting portion 467a is designed so that the ratio of the static elimination light transmitted through the upstream reflecting portion 467a is smaller.

As shown in FIG. 8, the static elimination light reflected by the upstream reflecting portion 467a is radiated from the downstream curved surface 467b on the outer peripheral surface of the upstream light guide member 467 opposite to the upstream reflecting portion 467a.

As shown in FIGS. 2 and 3, the static elimination light emitted from the downstream curved surface 467b irradiates the pre-transfer region 41b of the corresponding photoconductor 41. That is, the static elimination light reflected by the upstream reflecting portion 467a toward the downstream side of the first direction D1 is applied to the pre-transfer region 41b of the corresponding photoconductor 41.

The upstream light guide member 467 guides the static elimination light branched by the branch reflection unit 463a and then guided by the relay light guide member 465 along the second direction D2. Further, the upstream light guide member 467 irradiates the pre-transfer region 41b over the entire second direction D2 in the photoconductor 41 located next to the downstream side of the first direction D1 with the static elimination light.

The downstream light guide member 463, the second mirror 464, the relay light guide member 465, the third mirror 466, the upstream light guide member 467, and the fourth mirror 468 in the first static elimination device 46a are examples of the branch light guide.

The branch light guide transfers the static elimination light emitted from the light source 461 to the pre-transfer region 41b and the transfer pre-transfer region 41b located on the upstream side and the downstream side of the drum rotation direction R0 with respect to the transfer position P0 on the outer peripheral surface of the photoconductor 41, respectively. It is a group of optical components leading to the rear region 41a.

[Second static elimination device 46b]
As shown in FIG. 3, each of the second static elimination devices 46b includes one light source 461, a downstream light guide member 463, a second mirror 464, and a fifth mirror 469.

That is, the light source 461, the downstream light guide member 463, and the second mirror 464 of each of the second static elimination device 46b are the same as the light source 461, the downstream light guide member 463, and the second mirror 464 of the first static elimination device 46a.

The fifth mirror 469 is arranged so as to face the branch reflection portion 463a of the downstream light guide member 463 via the base portion 463x. For example, it is conceivable that the fifth mirror 469 is a sheet-shaped mirror. In this case, the fifth mirror 469 is attached to the branch surface 463c of the downstream light guide member 463.

The fifth mirror 469 prevents the static elimination light reflected by the branch reflection unit 463a from leaking from the branch surface 463c to the outside of the downstream light guide member 463.

It is also conceivable that the sixth mirror (not shown) is arranged to face the branch reflection portion 463a of the downstream light guide member 463 from the outside. The sixth mirror prevents the static elimination light reflected by the fifth mirror 469 from leaking from the branch reflecting portion 463a to the outside of the downstream light guide member 463.

In each of the second static elimination devices 46b, the downstream light guide member 463 guides the static elimination light emitted from the light source 461 along the second direction D2. Further, the downstream light guide member 463 covers the post-transcriptional region 41a over the entire second direction D2 in the corresponding photoconductor 41 and the entire second direction D2 in the photoconductor 41 located next to the downstream side of the first direction D1. The pre-transfer region 41b is irradiated with the static elimination light.

However, in the second static elimination device 46b provided in the image forming device 4 located on the most downstream side of the first direction D1, the photoconductor 41 located next to the downstream side of the first direction D1 exists with respect to the downstream light guide member 463. do not do.

In the image forming apparatus 10, the downstream light guide member 463 of the first static elimination device 46a and the downstream light guide member 463 of the three second static elimination devices 46b are common parts. Similarly, the light source 461 of the first static elimination device 46a and the light source 461 of the three second static elimination devices 46b are common parts.

When the color printing process is executed, the control device 8 turns on all four light sources 461. On the other hand, when the monochrome printing process is executed, the control device 8 lights only one light source 461 included in the second static elimination device 46b located at the most downstream side of the first direction D1 among the four light sources 461.

Therefore, the image forming apparatus 10 collectively supplies the first power supply line for supplying electric power to one light source 461 included in the second static elimination device 46b located at the most downstream of the first direction D1 and the other three light sources 461. It is conceivable to include a second power supply line for supplying electric power.

When three light sources 461 of the same specifications are electrically connected in series by the second feeding line, the amount of light emitted by the three light sources 461 is almost the same.

On the other hand, in the first static elimination device 46a, the static elimination light is branched into the downstream light guide member 463 and the upstream light guide member 467, but in the three second static elimination devices 46b, the static elimination light is the fifth mirror 469. Is guided only into the downstream light guide member 463 by the action of.

Therefore, when the light amounts of the static elimination light emitted by the four light sources 461 are substantially the same, the light amount of the static elimination light emitted from the downstream light guide member 463 of the first static elimination device 46a and the three second static elimination devices 46b. The amount of light emitted from the downstream light guide member 463 is different from that of the static elimination light.

Therefore, in the three second static elimination devices 46b, it is conceivable that the downstream light guide member 463 is rotatably supported around the second direction D2.

For example, as shown in FIG. 9, each of the three second static elimination devices 46b directly supports the downstream light guide member 463 and includes a support member 4600 supported by the housing 450. The downstream light guide member 463 is fitted into a non-circular hole formed in the support member 4600.

The support member 4600 is rotatably supported around the second direction D2 by the housing 450. Then, the support member 4600 is fixed to the housing 450 by a screw or the like at an arbitrary angle in the rotation direction.

By fixing the support member 4600 in an arbitrary direction, the support member 4600 is held in an arbitrary direction in the rotational direction. Thereby, the radiation direction of the static elimination light from the downstream light guide member 463 can be arbitrarily adjusted.

By adjusting the radiation direction of the static elimination light from the downstream light guide member 463, the amount of light of the static elimination light irradiated to the photoconductor 41 can be adjusted. As a result, the irradiation amount of the static elimination light can be adjusted to be the same in all the photoconductors 41.

According to the present embodiment, it is possible to irradiate the pre-transfer region 41b and the post-transfer region 41a of the photoconductor 41 with the static elimination light without providing a plurality of light sources 461 for one photoconductor 41.

[First application example]
Next, the static elimination device 46P according to the first application example applicable to the image forming apparatus 10 will be described with reference to FIG.

In this application example, each of the four image forming devices 4 includes the same static elimination device 46P. In FIG. 10, the same components as those shown in FIGS. 1 to 9 are designated by the same reference numerals.

Similar to the first static eliminator 46a described above, the static eliminator 46P includes one light source 461, a downstream light guide member 463P, a second mirror 464, a relay light guide member 465, a third mirror 466, and an upstream guide. It includes an optical member 467 and a fourth mirror 468.

That is, the static elimination device 46P has a configuration in which the downstream light guide member 463 is replaced with a similar downstream light guide member 463P in the first static elimination device 46a. The downstream light guide member 463P is also a transparent rod-shaped member like the downstream light guide member 463P.

The downstream light guide member 463P of the static elimination device 46P has a configuration in which the light distribution unit 463b in the downstream light guide member 463 of the first static elimination device 46a is replaced with the downstream reflection unit 463h.

That is, the downstream light guide member 463P has a base portion 463x and a downstream facing portion 463y. Further, the base portion 463x has a branch reflection portion 463a, and the downstream facing portion 463y has a downstream reflection portion 463h.

The downstream reflecting portion 463h reflects the static elimination light traveling inside the downstream facing portion 463y along the second direction D2 in the direction toward the post-transcriptional region 41a of the photoconductor 41.

Similar to the branch reflection portion 463a, the downstream reflection portion 463h is also a portion in which a plurality of recesses 460 arranged at intervals in the second direction D2 are formed (see FIG. 5). The shape of the plurality of recesses 460 in the downstream reflecting portion 463h is designed so that the ratio of the static elimination light transmitted through the downstream reflecting portion 463h is smaller.

In this application example, the downstream light guide member 463P, the second mirror 464, the relay light guide member 465, the third mirror 466, the upstream light guide member 467, and the fourth mirror 468 are examples of the branch light guide. When the static eliminator 46P is adopted, the same effect as when the static eliminator 46 is adopted can be obtained.

[Second application example]
Next, the static elimination device 46Q according to the second application example applicable to the image forming apparatus 10 will be described with reference to FIG. The static elimination device 46Q is an application example of the static elimination device 46P.

In this application example, each of the four image forming devices 4 includes the same static elimination device 46Q. In FIG. 11, the same components as those shown in FIGS. 1 to 10 are designated by the same reference numerals.

The static elimination device 46Q includes a light source 461, a downstream light guide member 463Q, a second mirror 464, an optical branch member 465Q, two third mirrors 466, an upstream light guide member 467, a fourth mirror 468, and a first. It is provided with 6 mirrors 466a.

The optical branch member 465Q is a transparent member that guides the static elimination light emitted from the light source 461. The optical branch member 465Q has a trunk portion 465d, a downstream branch portion 465e, and an upstream branch portion 465f.

The trunk portion 465d is a portion to which the static elimination light emitted from the light source 461 is incident. The downstream branch portion 465e is a portion branched from the trunk portion 465d to the downstream side in the drum rotation direction R0 in the photoconductor 41. The upstream branch portion 465f is a portion branched from the trunk portion 465d to the upstream side in the drum rotation direction R0 in the photoconductor 41.

The surface of the end 465 g of the downstream branch portion 465e faces the position on the downstream side in the drum rotation direction R0 with respect to the photoconductor 41. Similarly, the surface of the end 465i of the upstream branch portion 465f faces the position on the upstream side of the drum rotation direction R0 with respect to the photoconductor 41.

A part of the static elimination light incident on the trunk portion 465d propagates to the downstream branch portion 465e, and the other part propagates to the upstream branch portion 465f. That is, the static elimination light incident on the trunk portion 465d is bifurcated into a downstream branch portion 465e and an upstream branch portion 465f.

One of the two branches of the static elimination light is incident on the downstream light guide member 463Q from the downstream branch portion 465e, and the other is incident on the upstream light guide member 467 from the upstream branch portion 465f.

For example, a concave portion 465k having a triangular cross section is formed on the surface of the trunk portion 465d opposite to the incident surface of the static elimination light. Further, the sixth mirror 466a is arranged along two planes forming the inner surface of the recess 465k.

Further, it is conceivable that the sixth mirror 466a is a sheet-shaped mirror attached to two planes forming the inner surface of the recess 465k.

One of the two inclined interfaces formed by the recess 465k reflects the static elimination light to the downstream branch portion 465e, and the other reflects the static elimination light to the upstream branch portion 465f.

In the example shown in FIG. 11, the recess 465k is formed at a position shifted to the upstream side in the drum rotation direction R0 with respect to the optical axis of the static elimination light incident on the trunk portion 465d. In this case, the light amount of the static elimination light branched to the downstream branch portion 465e is larger than the light amount of the static elimination light branching to the upstream branch portion 465f.

The portion of the downstream branch portion 465e connected to the trunk portion 465d to the intermediate downstream side corner portion 465h is formed along the first direction D1, and the portion from the downstream side corner portion 465h to the end 465g is formed in the second direction D2. It is formed along.

Similarly, the portion of the upstream branch portion 465f connected to the trunk portion 465d to the intermediate upstream side corner portion 465j is formed along the first direction D1, and the portion from the upstream side corner portion 465j to the terminal 465i is the second. It is formed along the direction D2.

The two third mirrors 466 are arranged to face the outer surfaces of the downstream corner portion 465h and the upstream corner portion 465j of the optical branching member 465Q. The two third mirrors 466 prevent the static elimination light from leaking from the downstream corner portion 465h and the upstream corner portion 465j to the outside of the optical branch member 465Q.

For example, it is conceivable that the two third mirrors 466 are sheet-shaped mirrors. In this case, the two third mirrors 466 are attached to the outer surfaces of the downstream corner portion 465h and the upstream corner portion 465j.

The downstream light guide member 463Q is a rod-shaped transparent member along the second direction D2. The downstream light guide member 463Q is arranged at a position on an extension line of the downstream branch portion 465e on the downstream side of the drum rotation direction R0 with respect to the photoconductor 41.

One end surface of the downstream light guide member 463Q is in surface contact with the end 465 g of the downstream branch portion 465e.

The second mirror 464 is arranged to face the end face opposite to the downstream branch portion 465e in the downstream light guide member 463Q. For example, the second mirror 464 is a sheet-shaped mirror attached to the end face opposite to the downstream branch portion 465e in the downstream light guide member 463.

The static elimination light that has passed through the downstream branch portion 465e travels in the downstream light guide member 463Q along the second direction D2. The second mirror 464 prevents the static elimination light from leaking from the end face of the downstream light guide member 463Q.

The downstream light guide member 463Q has a downstream reflecting portion 463h that reflects the static elimination light traveling inside along the second direction D2 toward the post-transcriptional region 41a. The downstream reflecting portion 463h has a structure similar to that of the upstream reflecting portion 467a shown in FIGS. 5 and 8.

However, the downstream reflecting portion 463h is formed on the surface on the downstream side of the drum rotation direction R0 in the downstream light guide member 463Q, that is, on the surface on the downstream side of the first direction D1 in the downstream light guide member 463Q.

The downstream light guide member 463Q is the same member as the upstream light guide member 467 shown in FIG. 8, and is arranged in a different direction from the upstream light guide member 467. That is, the downstream light guide member 463Q and the upstream light guide member 467 are common parts.

The upstream light guide member 467 of the static elimination device 46Q is the same member as the upstream light guide member 467 of the first static elimination device 46a (see FIGS. 3 and 8). That is, the upstream light guide member 467 has an upstream reflecting portion 467a as shown in FIG.

The upstream light guide member 467 of the static elimination device 46Q is arranged at a position on an extension line of the upstream branch portion 465f on the upstream side of the drum rotation direction R0 with respect to the photoconductor 41. One end surface of the upstream light guide member 467 is in surface contact with the end 465i of the upstream branch portion 465f.

The fourth mirror 468 is arranged so as to face the end surface opposite to the upstream branch portion 465f in the upstream light guide member 467. For example, the fourth mirror 468 is a sheet-shaped mirror attached to the end face opposite to the upstream branch portion 465f in the upstream light guide member 467.

The static elimination light that has passed through the upstream branch portion 465f travels in the upstream light guide member 467 along the second direction D2. The fourth mirror 468 prevents the static elimination light from leaking from the end face of the upstream light guide member 467.

In this application example, the downstream light guide member 463Q, the second mirror 464, the optical branch member 465Q, the two third mirrors 466, the upstream light guide member 467, the fourth mirror 468 and the sixth mirror 466a are the branch light guides. This is an example. When the static eliminator 46Q is adopted, the same effect as when the static eliminator 46 is adopted can be obtained.

[Third application example]
Next, the static elimination device 46R according to the third application example applicable to the image forming apparatus 10 will be described with reference to FIG. 12. The static eliminator 46R is an application example of the static eliminator 46 shown in FIGS. 3 to 9.

The static elimination device 46R has a configuration in which the light distribution section 463b of the downstream light guide member 463 in the first static elimination device 46a of the static elimination device 46 is replaced with the first downstream reflection section 463d and the second downstream reflection section 463e.

In the static elimination device 46R, the downstream facing portion 463y of the downstream light guide member 463 has a first downstream reflecting portion 463d and a second downstream reflecting portion 463e. The first downstream reflecting portion 463d and the second downstream reflecting portion 463e direct the static elimination light traveling inside the downstream facing portion 463y along the second direction D2 toward the post-transcriptional region 41a of the photoconductor 41 and the first direction. It reflects to the downstream side of D1.

Specifically, the first downstream reflecting portion 463d reflects the static elimination light traveling inside the downstream facing portion 463y along the second direction D2 in the direction toward the post-transcriptional region 41a of the photoconductor 41.

Further, the second downstream reflecting portion 463e reflects the static elimination light traveling inside the downstream facing portion 463y along the second direction D2 to the downstream side of the first direction D1.

Similar to the branch reflection unit 463a, the first downstream reflection unit 463d and the second downstream reflection unit 463e are also portions in which a plurality of recesses 460 arranged at intervals in the second direction D2 are formed (see FIG. 5).

The shapes of the plurality of recesses 460 in the first downstream reflecting portion 463d and the second downstream reflecting portion 463e are designed so that the ratio of the static elimination light transmitted through the first downstream reflecting portion 463d and the second downstream reflecting portion 463e is smaller. Will be done.

As shown in FIG. 12, the first downstream reflecting portion 463d is formed in a range on the downstream side of the first direction D1 on the outer peripheral surface of the downstream facing portion 463y. On the other hand, the second downstream reflecting portion 463e is formed in the range on the upstream side of the first direction D1 on the outer peripheral surface of the downstream facing portion 463y.

As shown in FIG. 12, the static elimination light reflected by the first downstream reflecting portion 463d is radiated from the upstream curved surface 463g on the outer peripheral surface of the downstream facing portion 463y opposite to the first downstream reflecting portion 463d.

The static elimination light emitted from the upstream curved surface 463 g is applied to the post-transcriptional region 41a of the corresponding photoconductor 41 (see FIGS. 2 and 3). That is, the static elimination light reflected by the first downstream reflecting portion 463d toward the upstream side in the first direction D1 is applied to the post-transcriptional region 41a of the corresponding photoconductor 41.

On the other hand, as shown in FIG. 12, the static elimination light reflected by the second downstream reflecting portion 463e is radiated from the downstream curved surface 463f on the outer peripheral surface of the downstream facing portion 463y on the opposite side of the second downstream reflecting portion 463e. To.

The static elimination light emitted from the downstream curved surface 463f is applied to the pre-transfer region 41b of the adjacent photoconductor 41 on the downstream side in the first direction D1 (see FIGS. 2 and 3). That is, the static elimination light reflected by the second downstream reflecting portion 463e toward the downstream side in the first direction D1 is applied to the pre-transfer region 41b of the adjacent photoconductor 41.

When the static eliminator 46R is adopted, the same effect as when the static eliminator 46 is adopted can be obtained.

[Other application examples]
In the first static eliminator 46a shown in FIG. 3 and the static eliminator 46P shown in FIG. 10, it is also conceivable that the relay light guide member 465 and the upstream light guide member 467 are formed of one member.

Further, the static eliminator 46P or the static eliminator 46Q may be applied to a monochrome image forming apparatus including one image forming apparatus 4 for black toner. In this case, the primary transfer device 44b transfers the toner image on the photoconductor 41 to a sheet which is an example of the material to be transferred.

1: Main body 2: Sheet supply mechanism 3: Sheet transfer mechanism 4: Image drawing device 8: Control device 10: Image forming device 30: Transfer path 40: Image forming unit 41: Photoreceptor 41a: Post-transfer area 41b: Pre-transfer area 42: Charging device 43: Developing device 44: Transfer device 44a: Intermediate transfer belt 44b: Primary transfer device 44c: Secondary transfer device 44d: Belt cleaning device 45: Photoreceptor cleaning device 46: Static elimination device 46P: Static elimination device 46Q: Static elimination device Device 46a: First static elimination device 46b: Second static elimination device 47: Optical scanning device 48: Fixing device 450: Housing 460: Recessed portion 461: Light source 462: First mirror 463: Downstream light guide member 463P: Downstream light guide member 463Q: Downstream light guide member 463a: Branch reflection part 463b: Light distribution part 463c: Branch surface 463d: First downstream reflection part 463e: Second downstream reflection part 463f: Downstream curved surface 463g: Upstream curved surface 463h: Downstream reflecting part 463x : Base 463y: Downstream facing portion 464: Second mirror 465: Relay light guide member 465Q: Optical branch member 465a: Base end of relay light guide member 465b: End of relay light guide member 465c: Corner portion of relay light guide member 465d : Trunk 465e: Downstream branch 465f: Upstream branch 465g: Downstream branch end 465h: Downstream corner 465i: Upstream branch end 465j: Upstream corner 465k: Recess 466: Third mirror 466a: 6th Mirror 467: Upstream light guide member 467a: Upstream reflecting portion 467b: Downstream curved surface 468: Fourth mirror 469: Fifth mirror 4600: Support member 4610: Electronic substrate D1: First direction (default movement direction)
D2: Second direction (axial direction)
P0: Transfer position R0: Drum rotation direction (default rotation direction)

Claims (5)

A photoconductor that carries a toner image on the outer peripheral surface while rotating in a predetermined rotation direction,
A transfer device that transfers the toner image on the photoconductor to a transfer material at a predetermined transfer position, and a transfer device.
Light source and
A branch light guide that guides the static elimination light emitted from the light source to the pre-transfer region and the post-transfer region located on the upstream side and the downstream side in the predetermined rotation direction with respect to the transfer position on the outer peripheral surface of the photoconductor. ,
An intermediate transfer belt, which is the rotating endless material to be transferred,
It comprises four image forming devices, each comprising the photoconductor corresponding to a different color toner and arranged along a portion of the intermediate transfer belt moving in a predetermined moving direction.
One of the four image-forming devices located at the uppermost stream in the predetermined moving direction includes the light source and the branch light guide.
The branch light guide is
A transparent rod-shaped body arranged downstream of the photoconductor in the predetermined rotation direction and along the axial direction of the photoconductor, and having a base portion to which the static elimination light is incident and a downstream facing portion facing the post-transfer region. Downstream light guide member and
A transparent relay light guide member formed by extending from a base end facing the side surface of the base toward a position on the upstream side of the photoconductor in the predetermined rotation direction.
A rod-shaped transparent upstream light guide member arranged at a position on an extension line of the relay light guide member on the upstream side in the predetermined rotation direction with respect to the photoconductor, and provided with a rod-shaped transparent upstream light guide member along the axial direction.
The base portion of the downstream light guide member has a branch reflection portion that reflects a part of the static elimination light traveling inside along the axial direction toward the base end of the relay light guide member.
The downstream facing portion of the downstream light guide member reflects a part of the static elimination light traveling inside along the axial direction toward the post-transcriptional region and the other part of the static elimination light. It has a light distribution unit that transmits light to the downstream side in the default movement direction.
The upstream light guide member has an upstream reflecting portion that reflects the static elimination light traveling inside along the axial direction toward the pre-transfer region.
Each of the other three of the four image forming devices includes the light source, the downstream light guide member, and a mirror facing the branch reflecting portion via the base portion. The first aspect of the present invention, wherein the downstream light guide member is rotatably supported around the axial direction in three of the four image forming devices that are not located in the uppermost stream in the predetermined moving direction. Image forming device. A photoconductor that carries a toner image on the outer peripheral surface while rotating in a predetermined rotation direction,
A transfer device that transfers the toner image on the photoconductor to a transfer material at a predetermined transfer position, and a transfer device.
Light source and
A branch light guide that guides the static elimination light emitted from the light source to the pre-transfer region and the post-transfer region located on the upstream side and the downstream side in the predetermined rotation direction with respect to the transfer position on the outer peripheral surface of the photoconductor. , Equipped with
The branch light guide is
A transparent rod-shaped body arranged downstream of the photoconductor in the predetermined rotation direction and along the axial direction of the photoconductor, and having a base portion to which the static elimination light is incident and a downstream facing portion facing the post-transfer region. Downstream light guide member and
A transparent relay light guide member formed by extending from a base end facing the side surface of the base toward a position on the upstream side of the photoconductor in the predetermined rotation direction.
A rod-shaped transparent upstream light guide member arranged at a position on an extension line of the relay light guide member on the upstream side in the predetermined rotation direction with respect to the photoconductor, and provided with a rod-shaped transparent upstream light guide member along the axial direction.
The base portion of the downstream light guide member has a branch reflection portion that reflects a part of the static elimination light traveling inside along the axial direction toward the base end of the relay light guide member.
The downstream facing portion of the downstream light guide member has a downstream reflecting portion that reflects the static elimination light traveling inside along the axial direction toward the post-transcriptional region.
The upstream light guide member is an image forming apparatus having an upstream reflecting portion that reflects the static elimination light traveling inside along the axial direction toward the pre-transfer region. The image forming apparatus according to any one of claims 1 to 3 , wherein the relay light guide member and the upstream light guide member are formed of one member. A photoconductor that carries a toner image on the outer peripheral surface while rotating in a predetermined rotation direction,
A transfer device that transfers the toner image on the photoconductor to a transfer material at a predetermined transfer position, and a transfer device.
Light source and
A branch light guide that guides the static elimination light emitted from the light source to the pre-transfer region and the post-transfer region located on the upstream side and the downstream side in the predetermined rotation direction with respect to the transfer position on the outer peripheral surface of the photoconductor. , Equipped with
The branch light guide is
A trunk portion on which the static elimination light is incident, a downstream branch portion branching from the trunk portion to the downstream side in the predetermined rotation direction of the photoconductor and propagating a part of the static elimination light, and a trunk portion in the predetermined rotation direction of the photoconductor. A transparent optical branching member having an upstream branch portion that branches to the upstream side and propagates the other part of the static elimination light.
A rod-shaped transparent downstream light guide member arranged at a position on an extension line of the downstream branch portion on the downstream side in the predetermined rotation direction with respect to the photoconductor and along the axial direction of the photoconductor.
A rod-shaped transparent upstream light guide member arranged at a position on an extension line of the upstream branch portion on the upstream side in the predetermined rotation direction with respect to the photoconductor, and provided with a rod-shaped transparent upstream light guide member along the axial direction.
The downstream light guide member has a downstream reflecting portion that reflects the static elimination light traveling inside along the axial direction toward the post-transcriptional region.
The upstream light guide member is an image forming apparatus having an upstream reflecting portion that reflects the static elimination light traveling inside along the axial direction toward the pre-transfer region.

Images