This application claims priority under 35 U.S.C. §119 from Japanese Patent Application No. 2007-118278 filed on Apr. 27, 2007. The entire subject matter of the application is incorporated herein by reference.
1. Technical Field
The following description relates to one or more image forming devices such as a copy machine and printer, which are configured to selectively expose an electro-photoconductive body with an exposure unit so as to form a latent image on the electro-photoconductive body, and develop the latent image with developer so as to transfer the latent image onto a recording medium.
2. Related Art
In a conventional image forming device such as a copy machine and a printer, a laser scanning method or below-mentioned LED exposure method has been realized as an image writing method (exposure method). The LED exposure method is a method for forming a latent image on a photoconductive body by exposing a surface of the photoconductive body to light which is emitted by a light emitting unit with a plurality of light emitting elements linearly aligned and converged by a converging unit.
Specifically, there are provided at an end of the LED head 212, a circular hole 221 at a lower portion, and a groove 223 at an upper portion. A lower fitting portion 200b of a pin 200 is fitted into the circular hole 221, and an upper fitting portion 200c of the pin 200 is fitted into along the groove 223. At the other end of the LED head 212, a root portion 232b of a pin 232 is fitted into an oval hole 222 formed as a through-hole.
Meanwhile, the LED head 212 is mounted on two pedestals respectively provided at front and rear sides thereof, and positioned in a height direction (y-axis direction) by adjusting the heights of the pins 200 and 232 with respect to base members 223 and 224, respectively.
In addition, the fitting portion 200b of the pin 200 and the root portion 232b of the pin 232 are fitted into the circular hole 221 and oval hole 222, respectively, and a radial fitting allowance is provided each between the circular hole 221 and fitting portion 200b and between the oval hole 222 and root portion 232b. The fitting allowance is provided for the sake of easy operations of attaching/detaching the LED head 212 and preventing a stress that may be generated in the LED head 212 by restricting spans of the main body and LED head 212 in the device as thermally-expanded (for example, see Japanese Patent Provisional Publication No. 2002-14524).
However, according to the aforementioned conventional mechanism, the fitting allowance provided each between the circular hole 221 and fitting portion 200b and between the oval hole 222 and root portion 232b results in that each of the circular hole 221, oval hole 222, fitting portion 200b, and root portion 232b has to be machined with very high accuracy so as to regulate the amount of backlash that may be caused due to the fitting allowance. Accordingly, it is unfortunate that each of the circular hole 221, oval hole 222, fitting portion 200b, and root portion 232b requires a long manufacturing time and high manufacturing cost.
Aspects of the present invention are advantageous in that there can be provided one or more improved image forming devices in which an LED head can easily be positioned with respect to a photoconductive body without having to provide any fitting allowance.
According to aspects of the present invention, there is provided an image forming device, which includes a first device body having an opening, a second device body attached to the first device body in an openable and closable manner so as to cover the opening of the first device body, a photoconductive body, provided to the first device body, which is configured with a circumferential surface thereof endlessly-movable in a predetermined moving direction, an exposure unit, provided to the second device body, which is configured to scan and expose the circumferential surface of the photoconductive body with light in a predetermined scanning direction such that a latent image is formed on the circumferential surface, the exposure unit including an exposure surface configured to emit therefrom the light for the scanning operation, an opposed surface disposed to face the exposure surface, a first side surface disposed to connect the exposure surface with the opposed surface, and a second side surface disposed to face the first side surface, and a positioning mechanism configured to position the exposure unit with respect to the photoconductive body when the second device body is closed, the positioning mechanism including, a first contact member configured to contact the exposure unit in a first contact point at a side of the first side surface, a second contact member configured to contact the exposure unit in a second contact point at the side of the first side surface, and a third contact member configured to contact the exposure unit in a third contact point at a side of the second side surface, the third contact point being located between the first contact point and the second contact point in a predetermined direction from the exposure surface toward the opposed surface.
In some aspects of the invention, when the second device body provided with the exposure unit is closed with respect to the first device body, the exposure unit is positioned by the first contact member that contacts the exposure unit in the first contact point at the side of the first side surface, the second contact member that contacts the exposure unit in the second contact point at the side of the first side surface, and the third contact member that contacts the exposure unit in the third contact point at the side of the second side surface. The third contact point is located between the first contact point and the second contact point in a predetermined direction from the exposure surface toward the opposed surface. Thus, the exposure unit can easily be positioned with respect to the photoconductive body provided to the first device body by the first to third contact members establishing contact therewith.
According to another aspect of the present invention, there is provided an image forming devices which includes a photoconductive body configured with a circumferential surface thereof endlessly-movable in a predetermined moving direction, an exposure unit configured to scan and expose the circumferential surface of the photoconductive body with light in a predetermined scanning direction such that a latent image is formed on the circumferential surface, the exposure unit including, an exposure surface configured to emit therefrom the light for the scanning operation, an opposed surface disposed to face the exposure surface, a first side surface disposed to connect the exposure surface with the opposed surface, and a second side surface disposed to face the first side surface, and a positioning mechanism configured to position the exposure unit with respect to the photoconductive body, the positioning mechanism including a first contact member configured to contact the exposure unit in a first contact point at a side of the first side surface, a second contact member configured to contact the exposure unit in a second contact point at the side of the first side surface, and a third contact member configured to contact the exposure unit in a third contact point at a side of the second side surface, the third contact point being located between the first contact point and the second contact point in a predetermined direction from the exposure surface toward the opposed surface.
With the image forming device configured as above, the exposure unit is positioned by the first contact member that contacts the exposure unit in the first contact point at the side of the first side surface, the second contact member that contacts the exposure unit in the second contact point at the side of the first side surface, and the third contact member that contacts the exposure unit in the third contact point at the side of the second side surface. The third contact point is located between the first contact point and the second contact point in a predetermined direction from the exposure surface toward the opposed surface. Thus, the exposure unit can easily be positioned with respect to the photoconductive body by the first to third contact members establishing contact therewith.
It is noted that various connections are set forth between elements in the following description. It is noted that these connections in general and, unless specified otherwise, may be direct or indirect and that this specification is not intended to be limiting in this respect.
Hereinafter, embodiments according to aspects of the invention will be described with reference to the accompanying drawings.
In
In the mechanical unit 3, there are detachably arranged in an arrow A direction in which a recording paper is conveyed, four drum units 10K, 10C, 10M, and 10Y which respectively correspond to Black (K), Cyan (C), Magenta (M), Yellow (Y) in sequence from an upstream side.
There are provided to the drum units 10K, 10C, 10M, and 10Y, respective photoconductive bodies 11K, 11C, 11M, and 11Y which are rotatable in an arrow B direction and respective transfer rollers 12K, 12C, 12M, and 12Y which correspond to the photoconductive bodies 11K, 11C, 11M, and 11Y. The recording paper is carried in the arrow
A direction in a state absorbed to a conveying belt 14 owing to collaboration between the photoconductive bodies 11K, 11C, 11M, and 11Y and transfer rollers 12K, 12C, 12M, and 12Y which are rotated in accordance with the photoconductive bodies. Then, images with a predetermined different color each are transferred onto the conveyed recording paper in sequence.
Meanwhile, the upper case 1 has respective four LED units 20K, 20C, 20M, and 20Y provided in positions corresponding to circumferential surfaces of the respective photoconductive bodies 11K, 11C, 11M, and 11Y of the drum units 10K, 10C, 10M, and 10Y.
The supporting body 30 includes a longitudinal supporting body 34 that extends along a right-to-left direction of the image forming device 5 (main scanning direction of the exposure), and side supporting body 35 that is integrally or separately provided at each end of the longitudinal supporting body 34. The LED head 32 is provided beneath the longitudinal supporting body 34. The LED head 32 is configured with an LED array 31 linearly aligned along the main scanning direction and a SELFOC® Lens Array (not shown) as a single unit. An exposure surface 32a, which is directed in a direction in which the light is emitted by the LED head 32, is located so as to face the photoconductive body 11 when the upper case 1 is closed.
The side supporting body 35 is provided with bosses 37a and 37b protruding outward and a circular recess 36. The bosses 37a and 37b are provided with respective screw holes 38a and 38b in which below-mentioned screws 58a and 58b are screwed, respectively.
The LED holder 40 includes oval holes 41a and 41b, a square hole 42 provided between the oval holes 41a and 41b, and a screw hole 43 for fixing with a below-mentioned screw 58c, each of which holes are formed as through holes. Further, the LED holder 40 is provided with a holder side portion 49 at the right side thereof, which includes a holder front portion 49a protruding rightward, a holder rear portion 49b protruding rightward so as to face the holder front portion 49a, and a holder upper portion 49c joining respective upper portions of the holder front portion 49a and holder rear portion 49b (see
Additionally, at an end of the main scanning direction, the LED holder 40 includes a vertically-long projection 47 provided at a lower portion thereof so as to vertically extend, protruded portion 48, and contact face 48a provided to the protruded portion 48. Further, the LED holder 40 includes a roller 55 rotatably provided close to the protruded portion 48 so as to contact the photoconductive body 11.
The holder side portion 49 is provided so as to pinch the side supporting body 35 in a front-to-rear direction (see
The connection member 50 includes a bending hole 51 that bends in a C-shape and a cylindrical projection 54. The cylindrical projection 54 is provided with a first protruded portion 54d protruding outward and a second protruded portion 54b protruding inward. The first protruded portion 54d is formed with a groove 54a around which a below-mentioned stop ring 67 is fitted and a slot 54c into which a flat-blade screwdriver is inserted. The second protruded portion 54b includes an eccentric cam 53.
Firstly, the side supporting body 35 and LED holder 40 are provisionally fixed to each other with the screws 58a and 58b being screwed into the screw holes 38a and 38b through the oval holes 41a and 41b, respectively. Subsequently, the second protruded portion 54b is fitted into the circular recess 36 of the side supporting body 35, and the eccentric cam 53 is fitted into the square hole 42 of the LED holder 40.
It is noted that the first protruded portion 54d and second protruded portion 54b have an identical circular center. Further, as shown in
Next, the screw hole 43 and bending hole 51 are fixed with a screw 58c. Finally, the screws 58a and 58b that have earlier been provisionally fixed are tightly fastened, and the side supporting body 35, LED holder 40, and connection member 50 are fixed to each other. Thereby, even though the components are fixed to each other with some positional errors, the errors can be overcome through final adjustment in assembling. The exposure surface 32a of the LED head 32 has to be strictly controlled on the order of several tens of micrometers. The aforementioned configuration and assembling manner can meet such a strict requirement.
The LED supporting member 60 has a longitudinal supporting portion 61 provided along the main scanning direction of the photoconductive body 11. In addition, a side supporting portion 62 is provided at a side face of the longitudinal supporting portion 61. There is provided at an upper side of the side supporting portion 62, a circular boss 63 to fit into a hole (not shown) provided to the upper case 1. Further, a rectangular hole 64 is provided in the vicinity of a center of the side supporting portion 62.
The first protruded portion 54d of the cylindrical projection 54 provided to the connection member 50 is fitted into the rectangular hole 64 of the side supporting portion 62. The cylindrical projection 54 is configured to have a diameter smaller than a length in a width (short side) direction of the rectangular hole 64. Thus, the cylindrical projection 54 can slightly be shifted in the width direction of the rectangular hole 64. Further, vertical movements of the supporting body 30 and LED holder 40 that are connected via the connection member 50 are restricted by a locking portion 44 extending from the LED holder 40 for the upward movement, and by the cylindrical projection 54 for the downward movement. Furthermore, the locking portion 44 restricts the movement of the supporting body 30 and LED holder 40 along the front-to-rear direction as well.
A stopper ring 67 is fitted around the groove 54a along regulating portions 65 and 66 provided at both sides of the rectangular hole 64, from beneath the side supporting portion 62. Thereby, the supporting body 30 and LED holder 40 that are connected via the connection member 50 are held so as not to be dropped off the LED supporting member 60 with the stopper ring 67 contacting stopper portions 62a and 62b of the side supporting portion 62. Namely, by fitting the stopper ring 67 around the groove 54a, the movement of the LED head 32 along the main scanning direction of the photoconductive body 11 is restricted.
Further, a clearance is provided between the stopper ring 67 and any of the regulating portions 65 and 66. Hence, the first protruded portion 54d of the cylindrical projection 54 can somewhat be shifted within the rectangular hole 64 in any of the front-to-rear, vertical, and right-to-left directions. The regulating portions 65 and 66 are provided such that the stopper ring 67 is not easily dropped off.
On the other hand, a rear mechanical unit 120, which is provided as part of the mechanical unit 3 at a rear side with respect to the guide portion 80, includes a guide surface 121 to guide the LED unit 20, and third contact member 113 formed as a roller. The third contact member 113, which is provided opposite the first contact member 103 with respect to the guide portion 80 so as to face the first contact member 103, is loosely and rotatably fitted into a third contact member bearing 111 of a third contact member supporting portion 110 in the same manner as the first contact member 103.
The third contact member supporting portion 110 is provided at an arm 94 extending from the rear mechanical unit 120. Further, the arm 94 is provided rotatably around an arm shaft 128. The arm 94 includes a contact regulating surface 94b at a side facing the third contact member 113, and a spring biasing surface 94a at the opposite side. On the spring biasing surface 94a, there is provided a cross-shaped spring supporting member 115. Further, another spring supporting member 125 is provided to the rear mechanical unit 120 so as to face the spring supporting member 115. A biasing spring 126 is provided between the spring supporting members 115 and 125. The third contact member 113 is biased by the biasing spring 126 toward the first contact member 103.
It is noted that
The holder front portion 49a and the holder rear portion 49b located to face the holder front portion 49a are guided by the guide surfaces 131 and 121, respectively, inserted into the guide portion 80, and finally guided between the first contact member 103 and third contact member 113 to contact the first contact member 103 and third contact member 113, respectively. As described above, the LED supporting member 60 is fixed to the upper case 1. However, since the supporting body 30 and LED holder 40 integrated as a single unit with the connection member 50 is supported rotatably with respect to the LED supporting member 60, they can be inserted along the guide surfaces 131 and 121.
A cross-shaped spring locking member 45 is provided at a holder upper portion 49c of the LED holder 40, and the spring 46 is fitted around the spring locking member 45 (see
Additionally, the positioning of the LED holder 40 in the right-to-left direction is regulated by the vertically-long projection 47 as shown in
The first and second contact members 103 and 133 are provided at a side of the first side surface 34b. The third contact member 113 is provide at a side of the second side surface 34c. Namely, the first and second contact members 103 and 133 contact the LED unit 20 from the front side of the image forming device 5 (i.e., the side of the first side surface 34b). In addition, the third contact member 113 contacts the LED unit 20 from the rear side of the image forming device 5 (i.e., the side of the second side surface 34c).
In
On the cross-section shown in
A plane, including the third contact point 163, which is parallel to the main scanning direction of the exposure and a direction of a biasing force of the third contact member 113 against the second side surface 34c, is defined as a third standard plane 163a. In addition, a plane, including the first contact point 153, which is parallel to the third standard plane 163a, is defined as a first standard plane 153a. Further, a plane, including the second contact point 183, which is parallel to the third standard plane 163a, is defined as a second standard plane 183a. The third contact point 163 is placed between the first and second standard planes 153a and 183a to contact the second side surface 34c. Thus, by locating the third contact point 163 between the first and second standard planes 153a and 183a, the longitudinal supporting body 34 can maintain a stable posture.
Further, the photoconductive body 11 is rotated (endlessly moved) in the arrow B direction. Therefore, a force is applied to the roller 55 contacting the photoconductive body 11 so as to move forward the roller 55 while the photoconductive body 11 is being rotated. Consequently, such a force as to move forward the longitudinal supporting body 34 is applied thereto. However, the longitudinal supporting body 34 is supported in both of the first and second contact points 153 and 183 provided at the downstream side (front side) in the rotational direction of the photoconductive body 11, and thereby can maintain a stable posture.
Further, as shown in
In the present embodiment, the first and third contact members 103 and 113 contact the first and second side surfaces 34b and 34c, respectively. Further, the contact face 48a of the protruded portion 48, which is provided to the LED holder 40, contacts the contact flat surface 132. However, the present invention is not limited to the aforementioned configuration. Specifically, different contacts may be established from both the side of the first side surface 34b (the front side of the mechanical unit 3) and the side of the second side surface 34c (the rear side of the mechanical unit 3). For example, below-mentioned embodiments may be possible.
A plane, including the third contact point 214, which is parallel to the main scanning direction of the exposure and a direction of a biasing force of the third contact member 114 against the second side surface 34c, is defined as a third standard plane 214a. In addition, a plane, including the first contact point 204, which is parallel to the third standard plane 214a, is defined as a first standard plane 204a. Further, a plane, including the second contact point 234, which is parallel to the third standard plane 214a, is defined as a second standard plane 234a. The third contact point 214 is placed between the first and second standard planes 204a and 234a to contact the second side surface 34c.
A plane, including the third contact point 215, which is parallel to the main scanning direction of the exposure and a direction of a biasing force of the third contact member 115 against the second side surface 34c, is defined as a third standard plane 215a. In addition, a plane, including the first contact point 205, which is parallel to the third standard plane 215a, is defined as a first standard plane 205a. Further, a plane, including the second contact point 235, which is parallel to the third standard plane 215a, is defined as a second standard plane 235a. The third contact point 215 is placed between the first and second standard planes 205a and 235a to contact the second side surface 34c.
A plane, including the third contact point 216, which is parallel to the main scanning direction of the exposure and a direction of a biasing force of the third contact member 116 against the second side surface 34c, is defined as a third standard plane 216a. In addition, a plane, including the first contact point 206, which is parallel to the third standard plane 216a, is defined as a first standard plane 206a. Further, a plane, including the second contact point 236, which is parallel to the third standard plane 216a, is defined as a second standard plane 236a. The third contact point 216 is placed between the first and second standard planes 206a and 236a to contact the second side surface 34c.
A plane, including the third contact point 217, which is parallel to the man scanning direction of the exposure and a direction of a biasing force of the third contact member 117 against the second side surface 34c, is defined as a third standard plane 217a. In addition, a plane, including the first contact point 207, which is parallel to the third standard plane 217a, is defined as a first standard plane 207a. Further, a plane, including the second contact point 237, which is parallel to the third standard plane 217a, is defined as a second standard plane 237a. The third contact point 217 is placed between the first and second standard planes 207a and 237a to contact the second side surface 34c.
A plane, including the third contact point 218, which is parallel to the main scanning direction of the exposure and a direction of a biasing force of the third contact member 118 against the second side surface 34c, is defined as a third standard plane 218a. In addition, a plane, including the first contact point 208, which is parallel to the third standard plane 218a, is defined as a first standard plane 208a. Further, a plane, including the second contact point 238, which is parallel to the third standard plane 218a, is defined as a second standard plane 238a. The third contact point 218 is placed between the first and second standard planes 208a and 238a to contact the second side surface 34c.
A plane, including the third contact point 219, which is parallel to the main scanning direction of the exposure and a direction of a biasing force of the third contact member 119 against the second side surface 34c, is defined as a third standard plane 219a. In addition, a plane, including the first contact point 209, which is parallel to the third standard plane 219a, is defined as a first standard plane 209a. Further, a plane, including the second contact point 239, which is parallel to the third standard plane 219a, is defined as a second standard plane 239a. The third contact point 219 is placed between the first and second standard planes 209a and 239a to contact the second side surface 34c.
In the aforementioned sixth and seventh embodiments,
Hereinabove, the embodiments according to aspects of the present invention have been described. The present invention can be practiced by employing conventional materials, methodology and equipment. Accordingly, the details of such materials, equipment and methodology are not set forth herein in detail. In the previous descriptions, numerous specific details are set forth, such as specific materials, structures, chemicals, processes, etc., in order to provide a thorough understanding of the present invention. However, it should be recognized that the present invention can be practiced without reapportioning to the details specifically set forth. In other instances, well known processing structures have not been described in detail, in order not to unnecessarily obscure the present invention.
Only exemplary embodiments of the present invention and but a few examples of its versatility are shown and described in the present disclosure. It is to be understood that the present invention is capable of use in various other combinations and environments and is capable of changes or modifications within the scope of the inventive concept as expressed herein.
Number | Date | Country | Kind |
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2007-118278 | Apr 2007 | JP | national |