1. Field of the Invention
The present invention relates to an image forming apparatus and to a process unit that is detachably provided to this image forming apparatus.
2. Description of the Related Art
In image forming apparatus, such as a copier, printer, facsimile machine, or apparatus combining these, the process unit system may be adopted, in which cases in which are accommodated process means such as an image carrier, charging unit, developing device or toner accommodating unit are detachably provided with respect to the main body of the image forming apparatus. In this system, the user can easily replace these process units when maintenance of these process units is required.
Consequently, in such a process unit system, a mechanism for mounting/detaching of these process units with respect to the main body of the image forming apparatus is provided. However, there were the problems that ease of mounting/detachment by the conventional mounting/detachment mechanism and/or the precision of positional location thereof with respect to the main body of the image forming apparatus were low.
Technologies relating to the present invention are disclosed in, e.g., Laid-open Japanese Patent Application No. 2001-272838.
It is an object of the present invention to provide an image forming apparatus and process unit with a simple structure whereby positional location thereof with respect to the main body of the image forming apparatus can be reliably performed without impairing ease of mounting/dismounting the process unit.
The gist of the present invention, which solves the aforementioned problems of the prior art, is described below.
(1) According to the present invention, in an image forming apparatus in which a process unit having at least one of an image carrier, a charging unit, a developing device and a toner accommodating unit is detachably mounted, in a direction orthogonal to a width direction of the process unit, to a main apparatus body of the image forming apparatus wherein the improvement comprises: a convex section that projects towards an insertion side provided on the process unit; an engagement section that positions the process unit in the width direction by engaging with the convex section in a condition where the process unit is mounted, provided in the main apparatus body; and a guidance section that guides the convex section towards the engagement section, when the process unit is mounted, provided on at least one of a tip end of the convex section and the main apparatus body.
The “width direction of the process unit” includes for example the longitudinal direction of the process unit or the axial direction of a member accommodated in the process unit, but also includes arbitrarily determined directions other than these. When the process unit is mounted in the main apparatus body, the process unit is inserted into the main apparatus body with the convex section of the process unit directed towards the insertion side. As the process unit is inserted, the convex section comes into contact with the main apparatus body and is guided towards the engagement section by the guidance section. The process unit is therefore located in position in the width direction thereof by engagement of the convex section and the engagement section.
(2) In this image forming apparatus, the guidance section may be inclined in the width direction. The convex section can be guided in the width direction by this guidance section.
(3) In this image forming apparatus, a straight section extending in the insertion direction may be provided on at least one of the locations where the convex section and engagement section come into mutual contact. In this way, reliable engagement of the convex section and engagement section can be achieved, so the process unit can be precisely located in position in the width direction, and subsequent positional offset thereof in the width direction can be prevented.
(4) Likewise, in an image forming apparatus, a pair of side plates facing each other with a gap corresponding to the width direction of the process unit are arranged in the main apparatus body, the process unit being detachably mounted between this pair of side plates, and electrodes that are capable of mutual contact are arranged in one side face of the process unit and in the side plate corresponding to this side face, and a guidance section provided in the main apparatus body is inclined to the side plate side where the electrodes are provided. By means of a guidance section that is inclined in this way, the convex section can be guided towards the side plate side where the electrodes are provided. In this way, the electrodes that are respectively arranged adjacent thereon can be brought into contact by bringing one side face of the process unit adjacent to the corresponding side plate.
(5) In this image forming apparatus, the guidance section may be provided on the convex section and this guidance section may be inclined to the side plate side where the electrodes are provided. By means of a guidance section that is inclined in this way, the convex section can be guided towards the side plate side where the electrodes are provided. In this way, the electrodes that are respectively arranged adjacent thereon can be brought into contact by bringing one side face of the process unit adjacent to the corresponding side plate.
(6) In this image forming apparatus, the electrodes provided on the side plate may be arranged to be capable of resilient biasing in the inwards direction of this side plate. By resiliently biasing the electrodes of the side plate inwards when the respectively provided electrodes come into contact as the process unit approaches the corresponding side plate, mutual contact between the electrodes can be reliably performed.
(7) In this image forming apparatus, a process unit having an image carrier that is exposed to the outside may be erected in a condition placed on a placement surface with the exposed section of this image carrier directed downwards, two or more feet being provided so that the image carrier does not interfere with the placement surface, at least one of these feet serving as the convex section. Consequently, since the feet also play the role of the convex section for positional location of the process unit, there is no need to provide a separate convex section, thereby simplifying the construction and reducing manufacturing costs.
(8) In this image forming apparatus, comprising a plurality of process units that accommodate toners of different colors, an interference section may be provided whereby interference of the process unit and the main apparatus body occurs if an attempt is made to insert the process units in a position other than the prescribed mounting position. In this way, mounting of the process units in the wrong positions can be prevented, so there is no need to provide separate means for preventing wrong mounting, thereby simplifying the construction and reducing manufacturing costs.
(9) In the present invention, in a process unit which has a case that accommodates at least one of an image carrier, a charging unit, a developing device and a toner accommodating unit, and which is capable of detachably mounting this case, in a direction orthogonal to a width direction of the case, to a main apparatus body of an image forming apparatus, a convex section that projects towards an insertion side is provided on the case, an engagement section is provided, in the main apparatus body, that positions the case in the width direction by engaging with the convex section in a condition where the case is mounted, and a guidance section that guides the convex section towards the engagement section when mounting of the case is provided on at least one of a tip end of the convex section and the main apparatus body.
When the process unit is mounted in the main apparatus body, the process unit is inserted in the main apparatus body with the convex section of the process unit facing the insertion side. As the process unit is inserted, it is guided towards the engagement section by the guidance section by contact between the convex section and the main apparatus body. The process unit (case) is then located in position in the width direction thereof by engagement of the convex section and the engagement section.
(10) In this process unit, the guidance section may be inclined in the width direction. Thus the convex section can be guided in the width direction by this guidance section.
(11) In this process unit, a straight section may be provided that extends in the insertion direction in a manner capable of making contact with the engagement section on the convex section. In this way, reliable engagement of the convex section and engagement section can be achieved, so the process unit can be precisely located in position in the width direction, and subsequent positional offset thereof in the width direction can be prevented.
(12) In this process unit, the case may be erected in a condition placed on a placement surface with the exposed image carrier directed downwards from the case and there may be provided two or more feet such that the image carrier does not interfere with the placement surface, at least one of these feet serving as the convex section. Consequently, since the feet also play the role of the convex section for positional location of the process unit, there is no need to provide a separate convex section, thereby simplifying the construction and reducing manufacturing costs.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description taken with the accompanying drawings in which:
First of all, before describing the present invention, prior art relating to the present invention and problems thereof will be described with reference to the drawings.
Also, a plurality of electrodes 25, 26 serving for example for toner information communication or power supply are provided exposed to the outside on both side faces 20R, 20L of the case C of the process units A. Electrodes 27, 28 are also provided on the side plates 19R, 19L of the main apparatus body B, corresponding to these electrodes 25, 26. Thus, in a condition in which the process unit A is located in position in the vertical direction by insertion into the main apparatus body B as described above, the electrodes 25, 26 of the process unit A and the electrodes 27, 28 of the main apparatus body B are in contact.
Also, proposals have been made for positional location by pressing the process unit using a pressing section that is linked with a lever, in order to arrange the developing device in a prescribed position with respect to the image carrier: one such proposal is to be found in Laid-open Japanese Patent Application No. 2001-272838, referred to above.
Typically, a certain degree of movement in the width direction of the process unit is permitted by forming the dimension of the interval between the side plates larger than the width of the process unit, in order to improve ease of mounting/detachment of the process unit.
However, if mounting of the process unit is conducted in a manner that is offset to one side in the width direction, as shown in
In order to prevent such offset mounting of process units, it has been proposed to bring the electrodes into contact by applying pressure to the process unit by the biasing force of a resilient member.
However, since this construction also is not a construction in which the process unit can be reliably located in a prescribed position in the width direction, depending on the manner in which the user performs mounting of the unit, there is a risk that the process unit may not be mounted in the prescribed position.
Also, the mounting/detachment mechanism of the above previous proposals is subject to the problems of being complicated in construction and so inferior in regard to ease of operation and involving an increase in the number of components, which leads to increased costs.
The invention is further described in detail below with reference to the appended drawings.
The chief constituent elements of this image forming unit 1 are: an image carrier 2 (photosensitive body drum); a charging unit 3 that charges up the surface of the image carrier 2; an exposure device 4 that exposes the surface of the image carrier 2; a developing device 5 that forms a toner image on the surface of the image carrier 2; and a transfer device 6 that transfers this toner image to paper.
Of the various members referred to above constituting the image forming unit 1, the image carrier 2, charging unit 3 and developing device 5 are accommodated in a case as an image forming unit, and four process units A (first process unit A1 to fourth process unit A4) that are freely mountable/detachable with respect to the main image forming apparatus body B are provided, corresponding to the colors of the color image. Also, within each process unit A, there are provided for example a toner accommodating unit 7 that accommodates unused toner and used toner, a cleaning blade 8 that removes toner left on the surface of the image carrier 2, and toner conveying means 9 that conveys spent toner that has been removed to the toner accommodating unit 7.
The transfer device 6 comprises four primary transfer rollers 63a, 63b, 63c and 63d facing respective image carriers 2, an intermediate transfer belt 10 that runs in circulating fashion over the primary transfer rollers 63a, 63b, 63c and 63d, drive rollers 61 and following roller 62, and a secondary transfer roller 64 arranged facing the drive roller 61.
At the bottom of the image forming apparatus, there are provided a paper feed cassette 11 that is capable of accommodating a large number of sheets of paper, and a paper feed roller 12 that delivers paper from the paper feed cassette 11. Between the paper feed roller 12 and the secondary transfer roller 64, there are arranged a pair of resist rollers 13a, 13b at which the paper is temporarily halted. A fixing device 14 for heating and fixing the toner image formed on the paper is provided at the image forming unit 1 on the downstream side of the direction of paper feed of the secondary transfer roller 64.
Also, at the paper discharge port 15 formed at the top of the image forming apparatus, there are provided a pair of paper discharge rollers 16a, 16b constituting means for discharging paper. A paper discharge tray 18 constituted by recessing inwardly part of the top cover 17 of the main image forming device body is provided below the paper discharge port 15.
As shown in
A front cover 33 that is provided at the front of the main apparatus body B is constructed so as to be freely opened or closed by pivoting in the direction of the arrow Y about a pivoting axis at the bottom end thereof. When the front cover 33 is opened, the drive roller 61, secondary transfer roller 64, heating roller 14a and pressing roller 14b of the fixing unit 14, and the pair of paper discharge rollers 16a, 16b can easily be separated, making it possible to easily remove paper that has become jammed in the conveying path.
As shown in
On the mutually facing inside faces of the side plates 19R, 19L, there are formed in each case four guide grooves 21 (or guide slits) extending in the vertical direction: a rib 22 and first position locating projection 23 and second position locating projection 24 that are capable of being inserted in these guide grooves 21 are provided on both left and right side faces 20R, 20L of the process cassettes A (i.e. of case C). The width of the guide grooves 21 is set to be larger than the respective widths of the rib 22 and the first position locating projection 23 and second position locating projection 24 (see
An IC chip 29 constituting an information storage circuit and a communication electrode 25 that is electrically connected with this IC chip 29 are provided exposed to the outside on the left side face 20L of the process unit A. Also, a paper feed electrode 26 is arranged exposed to the outside on the right side face 20R of the process unit A.
Also, on the inside face of the left side plate 19L of the main apparatus body B, there are arranged four communication electrodes 27 capable of connection with the communication electrode 25 of each of the process units A; these communication electrodes 27 are electrically connected with a control unit, not shown. Information communication is performed between an IC chip 29 and the above control unit through the respective communication electrodes 25, 27 of the process units A and the main apparatus body B. Also, on the inside face of the right plates 19R, there are arranged four electricity supply electrodes 28 capable of contacting the electricity supply electrodes 26 of each of the process units A. The construction is such that high voltage is applied to the charging unit 3 and developing device 5 in the process units A through the respective electricity supply electrodes 26, 28 of the process units A and the main apparatus body B. The communication electrodes 27 and electricity supply electrodes 28 that are arranged on the two side plates 19R, 19L are formed by for example metal wires or plate springs so as to be capable of being resiliently biased inwardly in the width direction. Also, the communication electrodes 25 and the electricity supply electrodes 26 of the process units A may be constituted so as to be capable of being resiliently biased respectively outwardly in the width direction.
The first positional location projection 23 constitutes a rotary shaft of the image carrier 2 projecting outwardly through the left side face 20L. The first positional location projection 23 is in the vicinity of the bottom end of the left side face 20L and projects to an intermediate position in the thickness direction (forward/rearwards direction) of the case C.
The second positional location projection 24 is on the top side of the left side face 20L and projects to an intermediate position in the thickness direction (forward/rearwards direction) of the case C. Also, the rib 22 is formed in the shape of a rail that extends between the vicinity of the first positional location projection 23 and the vicinity of the second positional location projection 24. Also, regarding the first positional location projection 23, the second positional location projection 24 and the rib 22 that are provided on the right side face 20R, not shown, these are of identical construction with those of the left side face 20L, so further description thereof is dispensed with.
As shown in
Also, on the convex section 30 of the process unit A, there is provided a straight section 30a extending in the vertical direction facing the opposite side to the left side plate 19L; the bottom of this straight section 30a is linked with a guidance section 30b that is inclined on the side of the left side plate 19L facing the opposite side to the left side plate 19L (in other words, approaches the left side plate 19L more closely, going downwards). Also, the bottom end of this guidance section 30b reaches the tip of the convex section 30.
In
In the fourth embodiment of the present invention shown in
Also, a convex section 30 may be provided at both the left and right ends of the process unit A and an engagement section 32a may be provided on both the side plates 19R, 19L engaging with these convex sections 30. The guidance section 30b provided on the convex section 30 and the guidance section 32b provided in the insertion hole 32 may be formed in convex curved face shape or concave curved face shape, apart from being formed in planar shape (straight face shape). Also, the straight section extending in the vertical direction may be provided on at least one of the convex section 30 or main apparatus body B.
As shown in
Specifically, the above width dimensions S and U and the width dimension T of the insertion hole 32 and the width dimension V of the concave section 30 may be set as shown in
By setting the width dimensions as in
Also in order to prevent wrong mounting of the various process units, the cross-sectional shape of the convex section 30 may be made of different shape for each of the process units A1 to A4 and the cross-sectional shape of each of the insertion hole 32 may be formed corresponding to the cross-sectional shape of the convex section 30 that is inserted therein. Also, the cross-sectional shape of the interference section 36 may be made different for each of the process units A1 to A4 and the cross-sectional shapes of the interference sections 35 of the left side plate 19L may be formed corresponding to the cross-sectional shape of these interference sections 36.
It should be noted that the above width dimension S and width dimension U may be adjusted by changing the amount of projection of the respective interference sections 35, 36. It is also possible to adjust the width dimension S and width dimension U by changing the position of arrangement of the insertion hole 32 and the position of arrangement of the convex section 30 in the width direction. Also, the interference sections 35, 36 may be provided on either of the left side plate 19L and the process unit A, or a construction may be adopted in which interference sections 35, 36 are provided on neither of these, but the left side plate 19L and the left side face 20L of the process unit A are arranged to come into direct abutment.
The basic operation of this image forming apparatus is described below.
In
Next, the image formation operation will be described. First of all, the surface of the image carrier 2 is charged up to a uniform high potential by the charging unit 3. Next, the surface of the image carrier 2 is illuminated with a laser beam (L1 to L4) from the exposure device 4 under the control of the image data, thereby forming an electrostatic latent image by lowering of the potential in the illuminated portions. Toner images of the various colors are formed (developed) by transferring toner from the developing device 5 onto surface portions of the image carriers 2 where this electrostatic latent image is formed. The toner images of the various colors on the image carriers 2 are then transferred to the intermediate transfer belt 10 so as to overlap.
Drive of the resist roller pair 13a, 13b and the paper feed roller 12 is then recommenced and paper is fed to the secondary transfer rollers 64 synchronized with the timing of the toner image obtained by overlapping transfer onto the intermediate transfer belt 10. The overlapping transferred toner image is then transferred to the paper that is fed thereto, by means of the secondary transfer roller 64. After this, the paper onto which the toner image has been transferred is conveyed to the fixing device 14, where heat fixing of the toner image onto the paper is effected before the paper is discharged to the paper discharge tray 18 from the paper discharge port 15 which is at the top of the main image forming apparatus body.
Also, toner remaining on the surface of the image carriers 2 after completion of the transfer process is scraped off by a cleaning blade 8 and the used toner that has thus been scraped off is delivered to a used toner recovery section within the toner accommodation section 7 by toner conveying means 9, and stored.
Mounting of the process units in the image forming apparatus will now be described.
First of all, as shown in
With the down-dropping movement of the process unit A, the convex section 30 of the process unit A approaches the insertion hole 32 provided in the main apparatus body B, so that, as shown in
With further down-dropping movement of the process unit A, as shown in
Also, during the process of descent of the process unit A, the power supply electrode 26 on the right side face of the process unit A makes contact (see
After this, as shown in
Also, since the mounting of the process unit of the embodiment of
Embodiments of the present invention have been described above. Although, in the embodiments described above, the description has been given with reference to the example of a process unit comprising an image carrier, charging unit, developing device and toner accommodating unit a process unit comprising at least one of these members could be employed. Alternatively, a process unit could be employed having a member other than these members. Also, although, in the embodiments described above, the process unit was moved towards the left by the guidance section, a construction could be employed in which the process unit is moved towards the right. Also, in
With an image forming apparatus and process unit according to the present invention, the process unit can be reliably located in position in the width direction. In this way, the various members provided in the process unit can be arranged in correct positions with respect to the various members that are provided on the main apparatus body, thereby making it possible to improve the quality of the image that is produced. Also, since the process unit can be located in position in the width direction by a straightforward construction, there is no possibility of ease of mounting/detachment of the process unit being adversely affected. A further merit is that manufacturing costs can be kept low.
Various modifications will become possible for those skilled in the art after receiving the teachings of the present disclosure without departing from the scope thereof.
Number | Date | Country | Kind |
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2007-138365 | May 2007 | JP | national |