This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2009-111916 filed on May 1, 2009.
1. Technical Field
The present invention relates to an image forming apparatus.
2. Related Art
In an image forming apparatus such as a copying machine or a printer according to the related art, a so-called openable cover which is an openable member capable of revealing the inside of the image forming apparatus is provided so that a paper jam of a medium conveyed to form an image thereon can be solved or an exhausted part can be replaced.
According to an aspect of the invention, an image forming apparatus includes: an image forming apparatus body; an openable member that is supported movably between an opening position where the openable member is opened to reveal an inside of the image forming apparatus body and a closing position where the openable member is closed to hide the inside of the image forming apparatus body; a positioning portion that is provided in the image forming apparatus body; a positioned portion that is supported on the openable member and that is brought into contact with the positioning portion to be positioned when the openable member is in the closing position; a rotary member that is supported on the image forming apparatus body; and an opposed member that is supported on the openable member. When the openable member moves to the closing position, the opposed member moves in a direction crossing an opening/closing direction of the openable member and then moves in a reverse direction to the moving direction. The opposed member is opposed to the rotary member rotatably when the openable member is in the closing position.
Exemplary embodiment(s) of the present invention will be described in detail based on the following figures, wherein:
Although specific examples of modes for carrying out the invention (hereinafter referred to as “exemplary embodiments”) will be described below with reference to the drawings, the invention is not limited to the following exemplary embodiments.
In order to facilitate understanding of the following description, in the drawings, the front/rear direction is indicated as an X-axis direction, the left/right direction is indicated as a Y-axis direction and the up/down direction is indicated as a Z-axis direction, and directions or sides designated by the arrows X, −X, Y, −Y, Z and −Z are indicated as the front direction, the rear direction, the right direction, the left direction, the upper direction and the lower direction, or the front side, the rear side, the right side, the left side, the upper side and the lower side respectively.
In the drawings, each arrow with “•” written in “o” means an arrow directed from the back side of the sheet to the front side thereof and each arrow with “x” written in “o” means an arrow directed from the front side of the sheet to the back side thereof.
In the following description using the drawings, any other member than members required for description is omitted from the drawings suitably for the purpose of facilitating understanding.
In
The printer U according the first exemplary embodiment has a controller C as an example of a control portion, an image processing portion IPS, a laser drive circuit DL as an example of a latent image forming circuit, a power supply unit E, etc. The operations of the image processing portion IPS, the laser drive circuit DL and the power supply unit E are controlled by the controller C. The power supply unit E applies voltages to a charging roll CR as an example of a charger, a developing roll Ga as an example of a developing member, a transfer roll Tr as an example of a transfer member, etc., which will be described later.
The image processing portion IPS converts print information into image information for forming a latent image. The print information is inputted from a host computer or the like as an example of an external information transmitting apparatus. The image processing portion IPS outputs the image information to the laser drive circuit DL at a predetermined timing. The laser drive circuit DL is an example of an image writing circuit. The laser drive circuit DL outputs a driving signal to a latent image forming unit LH in accordance with the inputted image information. The latent image forming unit LH according to the first exemplary embodiment is composed of a so-called LED head, which is a unit of LEDs (Light Emitting Diodes) arranged linearly in the left/right direction at predetermined intervals. Each LED is an example of a latent image writing element.
A photoconductor PR as an example of an image retainer, which is driven to rotate, is supported in a rear portion of the printer U. A charging roll CR, a latent image forming unit LH, a developing unit G, a transfer roll Tr and a photoconductor cleaner CL are disposed around the photoconductor PR and along the rotating direction of the photoconductor PR. The photoconductor PR is an example of a rotary member. The transfer roll Tr is an example of a transfer member. The photoconductor cleaner CL is an example of a cleaner for the image retainer.
In
In addition, the developing unit G has a developing vessel V which stores a developer internally. A developing roll Ga, a pair of circulating conveyance members Gb and Gc, a supply member Gd and a layer thickness limiting member Ge are disposed in the developing vessel V. The developing roll Ga is an example of a developer retainer, which is disposed in opposition to the photoconductor PR. The circulating conveyance members Gb and Gc circulate and convey the developer while agitating the developer. The supply member Gd conveys, to the developing roll Ga, the developer agitated by the circulating conveyance members. The layer thickness limiting member Ge limits the layer thickness of the developer on the surface of the developing roll Ga.
A developer supply port V1 as an example of a supply portion is formed in the front upper surface of the developing vessel V. A developer supply path V3 as an example of a developer conveyance path, which extends frontally, is connected to the developer supply port V1. A supply auger V4 as an example of a developer conveyance member is rotatably supported inside the developer supply path V3. A cartridge holder KH as an example of an attachment/detachment portion, to/from which a toner cartridge TC can be attached/detached, is connected to the front end of the developer supply path V3. Thus, a developer from the toner cartridge TC can flow into the developer supply path V3. Accordingly, when the supply auger V4 is driven, a developer is supplied from the toner cartridge TC to the developing unit G in accordance with consumption of a developer in the developing unit G.
The surface of the photoconductor PR which is rotating is charged by the charging roll CR in a charging area Q1. In a latent image forming position Q2, an electrostatic latent image is formed in the surface of the photoconductor PR by latent image forming light emitted from the latent image forming unit LH. The electrostatic latent image is developed into a toner image in a developing area Q3 by the developing roll Ga. The toner image is an example of a visible image. In a transfer area Q4 which is formed out of an area where the photoconductor PR as an example of a rotary member is opposed to the transfer roll Tr as an example of an opposed member, the toner image on the surface of the photoconductor PR is transferred to a sheet S as an example of a medium by the transfer roll Tr. The transfer roll Tr according to the first exemplary embodiment is made of an elastic material so that the transfer roll Tr can be elastically deformed by contact with the photoconductor PR.
Residual toner on the surface of the photoconductor PR is removed by a cleaning blade CB in a cleaning area Q5 which is an example of a cleaning area set on the downstream side of the transfer area Q4. The cleaning blade CB is an example of a cleaning member. The removed toner is recovered into the photoconductor cleaner CL.
A film seal FS is provided oppositely to the cleaning blade CB. The film seal FS is an example of a scatter prevention member. The film seal FS prevents the toner recovered in the photoconductor cleaner CL from spilling out therefrom.
In
A transfer voltage is applied to the transfer roll Tr from the power supply unit E whose operation is controlled by the controller C. The transfer roll Tr transfers the toner image on the photoconductor PR to the recording sheet S which is passing through the transfer area Q4.
The recording sheet S to which the toner image has been transferred in the transfer area Q4 is conveyed to a fixing unit F in the state where the toner image has not yet been fixed. The fixing unit F has a pair of fixing rolls Fh and Fp as examples of fixing members. A fixing area Q6 is formed out of a pressure contact area between the pair of fixing rolls Fh and Fp. The toner image on the recording sheet S conveyed to the fixing unit F is fixed by the pair of fixing rolls Fh and Fp in the fixing area Q6. The recording sheet S where the fixed toner image has been formed is guided by sheet guides SG1 and SG2 and discharged to the discharge tray TRh on the top of the printer body U1 through discharge rolls R1. The sheet guides SG1 and SG2 are examples of medium guide members. Each discharge roll R1 is an example of a medium discharge member.
(Description of Rear Cover)
In
Above the shaft portions 2, a pair of right and left lower holders 3 and 4 are formed into plates extending frontally. Each lower holder 3, 4 is an example of a lower holding portion. A lower guide groove 3a, 4a as an example of a lower guide portion, which extends in the up/down direction, is formed in each lower holder 3, 4. The lower guide groove 3a, 4a according to the first exemplary embodiment is formed into an inverted U-shape so that the lower guide groove 3a, 4a can prevent a transfer slider 21 from being detached upward. That is, the lower guide groove 3a, 4a also has a function as a stopper.
Above the lower holders 3 and 4 and outside the lower holders 3 and 4 in the left/right direction, a pair of right and left upper holders 6 and 7 are formed into plates extending frontally. Each upper holder 6, 7 is an example of an upper holding portion. An upper guide groove 6a, 7a as an example of an upper guide portion, which extends in the up/down direction, is formed in each upper holder 6, 7. The upper guide groove 6a, 7a according to the first exemplary embodiment is formed into a U-shape directed reversely to the lower guide groove 3a, 4a. Thus, the upper guide groove 6a, 7a can prevent the transfer slider 21 from being detached downward. In addition, a spring hook portion 6b, 7b as an example of an urging support portion is formed in the front end upper portion of the upper holder 6, 7.
Above the upper holders 6 and 7, a pair of right and left lock claw holders 8 and 9 are formed to protrude frontally. Each lock claw holder 8, 9 is an example of a fixed holding portion. In each lock claw holder 8, 9, a protruding claw bearing 8a, 9a as an example of a claw receiving portion is formed to protrude outward in the left/right direction.
In
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Under the operating recess portion 16b, a guide recess portion 16c as an example of a guided portion is formed so that the handle guides 12 can be fitted to the guide recess portion 16c and guided in the up/down direction thereby.
In
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In FIGS. 3 and 5-8, under the lock interlocking protrusions 28 and 29 and at the oblique rear of the lock interlocking protrusions 28 and 29, upper guide protrusions 31 are formed correspondingly to the upper guide grooves 6a and 7a to protrude outward in the left/right direction. Each upper guide protrusion 31 is an example of a guided portion. In the drawings, the left upper guide protrusion 31 is not shown, but only the right upper guide protrusion 31 is shown. The left upper guide protrusion is arranged in the same manner as the right upper guide protrusion, except they are symmetrical. Thus, detailed description of the left upper guide protrusion will be omitted. In the following description, in the same manner, right members will be explained, but illustration and detailed description of left members will be omitted appropriately.
Each upper guide protrusion 31 according to the first exemplary embodiment is formed into a column with an outer diameter corresponding to and substantially equal to the width of the upper guide groove 6a, 7a. The upper guide protrusion 31 fitted to the upper guide groove 6a, 7a without much looseness is supported movably in the up/down direction.
In
In addition, in the laterally outer end portions of the lower guide protrusions 32, spring hook portions are formed correspondingly to the spring hook portions 6b and 7b. Each spring hook portion is an example of an urging support portion.
A pair of right and left coil springs 34 are mounted between the spring hook portions 6b and 7b of the upper holders 6 and 7 and the spring hook portions 32a of the lower guide protrusions 32 respectively. Each coil spring 34 is an example of an urging member. Each coil spring 34 according to the first exemplary embodiment applies a force to the lower guide protrusion 32 to pull the lower guide protrusion 32 toward the spring hook portion 6b, 7b, that is, obliquely frontally and upward. Thus, the lower guide protrusion 32 with looseness between the lower guide protrusion 32 and the lower guide groove 3a, 4a is retained to be pressed onto the front surface of the lower guide groove 3a, 4a.
As a result, the guide protrusions 31 and 32 are guided by the guide grooves 3a, 4a, 6a and 7a respectively so that the transfer slider 21 according to the first exemplary embodiment can be supported on the rear cover U1b movably in the up/down direction.
A semi-cylindrical transfer holder 36 extending in the left/right direction is supported as an example of a transfer holding portion on a lower portion of the transfer slider body 22. The transfer roll Tr is received in the transfer holder 36. A rotary shaft 37 of the transfer roll Tr is rotatably supported on the transfer holder 36 with its opposite end portions supported on bearing members 38. According to the first exemplary embodiment, the rotary shaft 37 of the transfer roll Tr is supported with its outer ends protruding outside the bearing members 38 in the left/right direction respectively. Each outer end of the rotary shaft 37 serves as an example of a positioned portion.
In a front surface of the transfer slider body 22, a pretransfer guide 41 as an example of a medium guide member is formed under the transfer holder 36 so as to guide the sheet S to the transfer area Q4, while a post-transfer guide 42 as an example of a medium guide member is formed above the transfer holder 36. By the post-transfer guide 42, the sheet S having passed through the transfer area Q4 is guided to the fixing unit F.
In
In the front end portion of each arm portion 46b, 47b, an interlocking long hole 46f, 47f extending in the front/back direction is formed correspondingly to the lock interlocking protrusion 28, 29. The interlocking long hole 46f, 47f is an example of an interlocked portion. The lock interlocking protrusion 28, 29 is fitted into the interlocking long hole 46f, 47f. The lock member 46, 47 interlocks with the vertical movement of the transfer slider 21 and is supported rotatably around the rotation center portion 46a, 47a.
In
In
In a lower surface of the upper positioning portion 52a, an upper positioning face 52c is formed as an example of a moving-direction positioning portion. The upper positioning face 52c comes in contact with an upper outer circumferential surface of the rotation shaft 37 of the transfer roll Tr so as to position the transfer roll Tr in the up/down direction, that is, in the moving direction of the transfer slider 21. In addition, a rear positioning face 52d as an example of an opposite-direction positioning portion is formed in the left surface of the rear positioning portion 52b. The rear positioning face 52d comes in contact with a rear outer circumferential surface of the rotation shaft 37 of the transfer roll Tr so as to position the transfer roll Tr in the left/right direction, that is, on the opposite side to the photoconductor PR in the opposite direction in which the transfer roll Tr and the photoconductor PR are opposed to each other.
A transfer guide face 52e as an example of an insertion guide portion is formed in a rear lower surface of the rear positioning portion 52b. The transfer guide face 52e is inclined upward toward the rear.
In the printer U configured thus according to the first exemplary embodiment, assume that the operator opens the rear cover U1b, for example, in order to remove the sheet S jammed in a sheet conveyance path SH. When the operating recess portion 16b is pushed down with a finger having passed through the operating opening 11 in such a case, the handle 16 is guided by the guides 12, 13a and 14a to move down. Thus, the handle 16 moves from the contactable position shown in
As the handle 16 moves down, the transfer slider 21 is pressed onto the sliding interlocking protrusion 16d of the handle 16. As a result, the guide protrusions 31 and 32 of the transfer slider 21 are guided by the guide grooves 6a, 7a and 3a, 4a so as to move down against the elastic force of the coil springs 34. Thus, the transfer slider 21 is moved from the positioning position shown in
As the transfer slider 21 moves down, the lock interlocking protrusions 28 and 29 of the transfer slider 21 move down to rotate the lock members 46 and 47 downward through the interlocking long holes 46f and 47f into which the lock interlocking protrusions 28 and 29 are fitted respectively. Accordingly, the lock members 46 and 47 move from the opening/closing fixing positions where the lock members 46 and 47 have been hooked on the lock protrusions 48 and 49 as shown in
Released from locking with the lock members 46 and 47, the rear cover U1b is made openable and closable. Thus, the rear cover U1b can move from the closing position shown by the solid line in
When the operator makes his/her finger leave the handle 16 after the handle 16 moves to the releasable position, the elastic restoring force of the coil springs 34 acts on the transfer slider 21 to return the transfer slider 21 from the leaving position to the positioning position. As a result, the sliding interlocking protrusion 16d is pushed by the transfer slider 21. Thus, the handle 16 also returns from the releasable position to the contactable position, and the lock members 46 and 47 also return from the fixing releasing position to the opening/closing fixing position.
That is, in the rear cover U1b according to the first exemplary embodiment, when the rear cover U1b moves toward the opening position, the transfer roll Tr once moves down in a moving direction crossing the opening/closing direction of the rear cover U1b and then returns upward.
Assume that the rear cover U1b having moved to the opening position is returned to the closing position. In this case, when the rear cover U1b is returned to the closing position by the operator who is pushing down the handle 16, the state shown in
In addition, according to the first exemplary embodiment, the transfer positioning portion 52 is supported integrally with the process frame 51 which retains the photoconductor PR. In comparison with the case where the transfer positioning portion 52 is formed separately from the process frame 51, an accumulated error of parts etc. is reduced and the accuracy of position between the photoconductor PR and the transfer roll Tr supported on the rear cover U1b to be opened and closed can be improved.
Further, according to the first exemplary embodiment, the rotation shaft 37 of the transfer roll Tr is positioned by contact with the upper positioning face 52c and the rear positioning face 52d. Thus, the rotation shaft 37 is positioned from the two directions. Therefore, the accuracy of position can be improved, in comparison with the case where the rotation shaft 37 is positioned from only one direction. Particularly on the opposite side of the transfer roll Tr to the photoconductor PR, that is, on the rear side of the transfer roll Tr which is elastically deformed to leave the photoconductor PR by its elastic restoring force, the transfer roll Tr is positioned by the rear positioning face 52d. Thus, the transfer roll Tr can be positioned more accurately, in comparison with the case where the transfer roll Tr is not positioned by the rear positioning face 52d.
In addition, according to the first exemplary embodiment, allowance is provided between each lower guide groove 3a, 4a and each lower guide protrusion 32. Even if the transfer slider 21 is caught when the transfer slider 21 moves up or down, the transfer slider 21 can move slightly or rotate around the upper guide protrusion 31 side. Thus, operation can be performed stably and easily to suspend the transfer roll Tr on the transfer positioning portion 52 easily, in comparison with the case where no allowance is provided between each lower guide groove 3a, 4a and each lower guide protrusion 32.
The lower guide protrusions 32 are pulled obliquely upward by the coil springs 34. When the rear cover U1b has moved to the closing position, looseness can be suppressed to retain the rear cover U1b in a stable position. At that time, due to the elastic force of the coil springs 34, a component of the force to rotate the transfer slider 21 around the upper guide protrusions 31 acts on the transfer slider 21 so that a force can be applied to press the transfer roll Tr onto the photoconductor PR. Thus, the photoconductor PR and the transfer roll Tr can be brought into contact with each other surely, and the accuracy of position can be improved.
In addition, according to the first exemplary embodiment, there is not provided urging members such as springs or the like for pressing the transfer roll Tr onto the photoconductor PR. When the transfer roll Tr is pressed onto the photoconductor PR in the background-art configuration where spring bearings are disposed on the rear cover U1b side, the reaction force of springs act on the rear cover U1b in the state where the transfer roll Tr is in contact with the photoconductor PR. It is therefore necessary to enhance the rigidity of the rear cover U1b to make the cover high in cost and large in size. On the contrary, according to the first exemplary embodiment, there is not provided members with which the rear cover U1b may suffer a reaction force from the printer body U1 side in the state where the transfer roll Tr is in contact with the photoconductor PR, such as the springs for pressing the transfer roll Tr onto the photoconductor PR. In addition, the rotation shaft 37 of the transfer roll Tr which is pressed onto the photoconductor PR and elastically deformed to produce a reaction force is received by the transfer positioning portion 52 on the printer body U1 side. Thus, the reaction force is received not by the rear cover U1b but by the printer body U1 side. Accordingly, the force acting on the rear cover U1b in the closing position is reduced as compared with that in the background-art configuration. The rigidity of the rear cover U1b can be suppressed in comparison with that in the background-art configuration so that the rear cover U1b can be made small in size and low in cost.
When the rear cover U1b having moved to the opening position is returned to the closing position, the operator may return the rear cover U1b to the closing position with his/her finger apart from the handle 16. In this case, due to the elastic force of the coil springs 34, the transfer slider 21, the handle 16 and the lock members 46 and 47 are kept in the state shown in
On this occasion, in the same manner, the rotation shaft 37 of the transfer roll Tr also touches the transfer guide face 52e of the transfer positioning portion 52. The transfer roll Tr is guided downward to once move the transfer slider 21 down toward the leaving position. After that, when the transfer roll Tr passes through the transfer guide face 52e, the transfer slider 21 returns to the positioning position due to the elastic force of the coil springs 34. Thus, the transfer slider 21 is brought into the state shown in
That is, according to the rear cover U1b in the first exemplary embodiment, also when the rear cover U1b moves toward the closing position, the transfer roll Tr once moves down in the moving direction crossing the opening/closing direction of the rear cover U1b, and then moves up back.
Next, the second exemplary embodiment will be described. In the description of the second exemplary embodiment, constituent elements corresponding to those of the first exemplary embodiment are referred to by the same numerals, and detailed description thereof will be omitted.
This exemplary embodiment is configured in the same manner as the first exemplary embodiment, except the following points.
In the first exemplary embodiment, the bearing member 38 is fixedly supported on the transfer holder 36. Instead, in
In the printer U configured thus according to the second exemplary embodiment, the transfer positioning portion 52′ performs positioning by contact with the position corresponding to the transfer pressure spring 61 in the state where the transfer slider 21 has moved to the positioning position shown in
The rear cover U1b according to the second exemplary embodiment operates in the same manner as the rear cover U1b according to the first exemplary embodiment, so that detailed description of the operation will be omitted.
Next, the third exemplary embodiment will be described. In the description of the third exemplary embodiment, constituent elements corresponding to those of the first exemplary embodiment are referred to by the same numerals, and detailed description thereof will be omitted.
This exemplary embodiment is configured in the same manner as the first exemplary embodiment, except the following points.
In
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In the transfer slider 21 according to the third exemplary embodiment, the lock interlocking protrusions 28 and 29 according to the first exemplary embodiment are replaced by interlocking support protrusions 28′ and 29′ formed in the same manner as the lock interlocking protrusions 28 and 29. Each interlocking support protrusion 28′, 29′ is an example of an interlocking support member. According to the third exemplary embodiment, the lock members 46 and 47 according to the first exemplary embodiment are replaced by inside interlocking hooks 103 and 104 fixedly supported on the interlocking support protrusions 28′ and 29′. Each inside interlocking hook 103, 104 is an example of an inside interlocking member. Each inside interlocking hook 103, 104 includes an inside hook body 103a, 104a and an inside claw portion 103b, 104b. The inside hook body 103a, 104a extends upward from the interlocking support protrusions 28′, 29′ and then extends backward. The inside claw portion 103b, 104b protrudes upward from a rear end of the inside hook body 103a, 104a. In an upper surface of the inside claw portion 103b, 104b, an inside guide face 103c, 104c is formed to be inclined downward toward the rear.
In
Shaft support flanges 108 and 109 protruding backward are supported on opposite (right and left) end portions of a rear surface of the inside cover U2. Each shaft support flange 108, 109 is an example of a shaft support portion. An inversion driving shaft 111 extending in the left/right direction is supported rotatably between the shaft support flanges 108 and 109. An inversion driving roller 112 as an example of an inversion driving member is supported on the inversion driving shaft 111 and disposed in opposition to each inversion driven roller 107 and in contact therewith. An inversion driving gear 113 for transmitting a driving force to the inversion driving shaft 111 is supported on a left surface of the left shaft support flange 109. The inversion driving gear 113 is an example of a driving force transmitting member. A driving force is transmitted from a not-shown driving source of the printer body U1 to the inversion driving gear 113.
Thus, a conveyance roller 107+112 for the inversion path according to the third exemplary embodiment is constituted by the inversion driven roller 107 and the inversion driving roller 112. The sheet S conveyed to the inversion path SH2 is conveyed toward the registration rolls Rr by the conveyance roller 107+112.
Under the shaft support flanges 108 and 109, erect protrusions 116 and 117 are formed to protrude backward. Each erect protrusion 116, 117 is an example of an erect contact member.
In
In addition, a most downstream guide 119 as an example of a guide member of a downstream end of the inversion path SH2 is formed in the front surface lower portion of the inside cover body 101 so as to be opposed to the upper side of the lower end guide 118.
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On the opposite right and left sides under the inversion guide face 123, erect guides 126 and 127 are formed to protrude frontally so that the erect protrusions 116 and 117 can touch the erect guides 126 and 127. Each erect guide 126, 127 is an example of an erect portion to be touched. Each erect guide 126, 127 is formed into a shape whose vertically central portion swells to be convex frontally.
In the upper end portion of the outside cover body 121, a concave handle receiving portion 128 as an example of an operating receiving portion is formed behind the inversion guide face 123. As shown in
A prismatic handle 16′ extending in the left/right direction is received in the handle receiving portion 128 movably in the up/down direction. The handle 16′ is an example of an operating portion. That is, the handle 16′ is formed with a vertical length shorter than the vertical depth of the handle receiving portion 128. In
On the opposite right and left sides of the inversion guide face 123 of the outside cover body 121, hook holding ribs 13′ and 14′ arranged in the same manner as the handle holding ribs 13 and 14 according to the first exemplary embodiment are formed under the open portions 128a. Each hook holding rib 13′, 14′ is an example of an interlocking holding portion. A hook lateral guide 13a′, 14a′ shaped like a long hole extending in the up/down direction and arranged in the same manner as the handle lateral guide 13a, 14a according to the first exemplary embodiment is formed in the hook holding rib 13′, 14′.
In
Guided protrusions 131b and 132b are formed in the lower portions of the handle fixing portions 131a and 132a. Each guided protrusion 131b, 132b is an example of a guided portion. The guided protrusions 131b and 132b are fitted to and supported on the hook lateral guides 13a′ and 14a′ movably in the up/down direction. Thus, according to the third exemplary embodiment, the handle 16′ is supported movably in the up/down direction along the hook lateral guides 13a′ and 14a′ by the guided protrusions 131b and 132b of the outside interlocking hooks 131 and 132 which are fixed and coupled with the handle 16′.
In the front end portions of the outside interlocking hooks 131 and 132, outside claw portions 131c and 132c protruding downward are formed correspondingly to the inside interlocking hooks 103 and 104.
A rear cover U1b′ as an openable member according to the third exemplary embodiment is constituted by the inside cover U2 and the outside cover U3.
In the printer U configured thus according to the third exemplary embodiment, when the operator pushes down the operating recess portion 16b of the handle 16′ against the coil springs 129 in order to reveal the inside of the printer U to solve a paper jam or the like occurring in the sheet conveyance path SH or the inversion path SH2, the handle 16′ moves down from the contactable position shown in
In
As shown in
Thus, also according to the third exemplary embodiment, when the rear cover U1b′ moves toward the opening position, the transfer roll Tr once moves down in a moving direction crossing the opening/closing direction of the rear cover U1b and then returns upward.
When the outside cover U3 is rotated toward the opening position in the state shown in
In
Thus, the sheet conveyance path SH is opened in the state shown in
In order to remove the sheet S jammed in the inversion path SH2, the inversion path SH2 can be opened if only the inside cover U2 is grasped and moved toward the closing position. On this occasion, when only the inside cover U2 is moved toward the closing position, in the same manner as in the first exemplary embodiment the transfer slider 21 once moves down toward the leaving position due to the contact between the transfer guide face 52e of the transfer positioning portion 52 and the rotation shaft 37 of the transfer roll Tr. The transfer slider 21 can be then retained in the positioning position due to the elastic force of the coil springs 34. That is, removal of the sheet S or the like can be carried out easily in the state where the inside cover U2 has been retained in the closing position shown in
Assume that the outside cover U3 is returned to the closing position in the state where the inversion path SH2 has been opened. In this case, when the outside interlocking hooks 131 and 132 of the outside cover U3 come into contact with the inside guide faces 103c and 104c of the inside interlocking hooks 103 and 104 of the inside cover U2. Thus, the transfer slider 21 once moves down toward the leaving position. Then, the transfer slider 21 returns to the positioning position due to the elastic force of the coil springs 34. The outside interlocking hooks 131 and 132 engage with the inside interlocking hooks 103 and 104 so as to retain the outside cover U3 on the inside cover U2. As a result, the rear cover U1b′ moves to the closing position.
In order to move the rear cover U1b′ to the closing position in the state shown in
When the rear cover U1b′ has moved to the closing position, similar operation to that of the first exemplary embodiment is provided due to the rotation shaft 37 of the transfer roll Tr positioned by the transfer positioning portion 52 in the same manner as in the first exemplary embodiment. That is, also according to the third exemplary embodiment, when the rear cover U1b′ moves toward the closing position, the transfer roll Tr once moves downward in the moving direction crossing the opening/closing direction of the rear cover U1b′ and then moves back upward.
(Modifications)
The exemplary embodiments of the invention have been described above in detail. However, the invention is not limited to the exemplary embodiments, but various changes can be made within the gist of the invention stated in the scope of claims. Modifications (H01) to (H07) of the invention will be shown below.
(H01) In the aforementioned exemplary embodiments, a printer was shown as an example of an image forming apparatus. The invention is not limited to the printer but can be also applied to a copying machine, a fax machine, a composite machine having a plurality or all of functions of those, or the like.
(H02) In the aforementioned exemplary embodiments, the printer U was designed to use a monochromatic developer by way of example. The invention is not limited to such a configuration, but can be also applied to a multi-color image forming apparatus for two or more colors.
(H03) In the aforementioned exemplary embodiments, the shape of the transfer positioning portion 52 is not limited to the illustrated shape, but can be formed into any shape. The upper positioning portion 52a passing above the transfer roll Tr may be changes suitably in accordance with design. For example, the configuration of the upper positioning portion 52a may be replaced by a configuration where the upper positioning portion 52a passes below the transfer roll Tr. Accordingly, the moving direction of the transfer slider 21 is not limited to the configuration where the transfer slider 21 once moves downward with respective to the transfer positioning portion 52 and then moves upward when the cover is opened or closed. The transfer slider 21 may be designed to once move upward and then move downward.
(H04) In the aforementioned exemplary embodiments, it is desired to form the transfer positioning portion 52 integrally with the process frame 51. The invention is not limited to such a configuration, but can have any configuration where the transfer positioning portion 52 is fixedly supported on the image forming apparatus body.
(H05) In the aforementioned exemplary embodiments, the configuration by which the photoconductor PR and the transfer roll Tr are positioned was illustrated by way of example. The invention is not limited to the configuration. For example, the invention can be applied to the configuration where a driving roller supported on the image forming apparatus body and a driven roller supported on the cover are positioned. In addition, the configuration by which the drum-like photoconductor PR as an example of an image retainer and the transfer roll Tr are positioned was illustrated by way of example. The invention is not limited to the configuration, but can be applied to the configuration by which an endless belt-like image retainer and a roller are positioned. For example, the invention can be applied to a multi-color image forming apparatus in which an intermediate transfer belt as an example of an image retainer and a secondary transfer roll as an example of a transfer member are positioned.
(H06) In the aforementioned exemplary embodiments, the configuration where positioning is performed in two places, that is, in the upper positioning face 52c and the rear positioning face 52d was illustrated by way of example. Although it is desired to use the configuration where positioning is performed in two or more places, positioning may be performed in only one place. For example, it is possible to use the configuration where the upper positioning face 52c is not brought into contact with the rotation shaft 37 of the transfer roll Tr but only the rear positioning face 52d is brought into contact therewith.
(H07) In the aforementioned exemplary embodiments, the configuration where the rear positioning face 52d is formed along the up/down direction was illustrated by way of example. The invention is not limited to the configuration. The rear positioning face 52d may be formed in any direction. It is, however, desired that the rear position face 52d is formed in a direction perpendicular to the line connecting the photoconductor PR and the center of the transfer roll.
The foregoing description of the exemplary embodiments of the present invention has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, thereby enabling others skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2009-111916 | May 2009 | JP | national |
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Entry |
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Japanese Office Action dated Apr. 17, 2012 issued in counterpart Japanese Application No. 2009111916. |
Translation of Japanese Office Action issued in Japanese Application No. 2012-135476 dated Jul. 24, 2012. |
Number | Date | Country | |
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20100278557 A1 | Nov 2010 | US |