This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2006-222183 filed Aug. 17, 2006.
1. Technical Field
The present invention relates to a drive switching mechanism and an image forming apparatus including such mechanism.
2. Related Art
An image forming apparatus such as a printer, copier, or facsimile machine provided with a sheet turnover unit, including a drive switching unit for reversing the paper driving direction is known.
An aspect of the present invention resides in a drive switching mechanism including a first gear, a second gear, a support member for movably supporting the first gear and the second gear, and a switching unit that moves the support member to reverse an output direction of the first gear and the second gear.
Exemplary embodiments of the present invention will be described in detail based on the following figures, wherein:
Then, exemplary embodiments of the present invention are described based on the drawings.
The image forming unit 14 is, for example, of an electrophotographic type, and composed of the following: an image carrying body 26 made of a photoreceptor; a charging device 28 that charges the image carrying body 26 evenly, wherein the charging device 28 is formed of, for example, a charging roller; an optical projection device 30 that, by light irradiation, projects a latent image onto the image carrying body 26 charged by the charging member 28; a development device 32 that applies a developer to a latent image formed on the image carrying body 26 by the optical projection device 30, thus making the latent image visible; a transfer device 34 that transfers a developer image created by the development device 32 onto a sheet, wherein the transfer device 34 is formed of, for example, a transfer roller; a cleaning device 36 that clears remaining developer particles from the image carrying body 26, wherein the cleaning device 36 is formed of, for example, a blade; and a fixing device 38 that fuses and fixes the developer image on the sheet, transferred by the transfer device 34, to the sheet, wherein the fixing device 38 is formed of, for example, a pressure roller and a heating roller. The optical projection device 30 is formed of, for example, a scan-type laser illumination device. This device is placed in parallel with a paper cassette 20 in the paper feeder 18 and nearer to the front (right side in
A process cartridge 40 is a cartridge in which the image carrying body 26, the charging device 28, the development device 32, and the cleaning device 36 are integrated. The process cartridge 40 is positioned directly under the output tray 16 and this cartridge is removably installed in the apparatus main body 12.
In the apparatus main body 12, for example, registration rollers 44 are placed upstream of the transfer device 34 (beneath the transfer device 34 in
In the case of both-side printing, however, the sheet gets back to the reverse path 50. Specifically, there is a two-way divergence just before the output rollers 46 and a switching pawl (not shown) is provided at the divergence. The reverse path 50 is formed for going back from the divergence to the registration rollers 44. Transport rollers 52a to 52c are provided along the reverse path 50. In the case of both-side printing, the switching pawl (not shown) is placed to a position to open the reverse path 50 and the output rollers 46 rotate reversely when a part of the sheet has been outputted out of the apparatus main body 12. The sheet is reversed and guided to the reverse path 50 in the opposite direction to the output tray 16. The sheet is transported again to pass the registration rollers 44, a nip between the transfer device and the image carrying body 26, and to the fixing device 38, and then outputted to the output tray 16.
The paper feeder 18 includes the paper cassette 20, a pickup roller 54, a feed roller 56, and a retard roller 58. The pickup roller 54 abuts on a top one of sheets stacked in the paper cassette 20 and picks up the sheet. The feed roller 56 and the retard roller 58 are positioned to contact with each other, downstream of the pickup roller 54, and work together for sheet by sheet feeding to feed only the top sheet picked up by the pickup roller 54.
Then, an example of a drive switching mechanism 60 is explained based on
As shown in
The first idler gear 66 is provided on the drive side of the sway gear train 76 and positioned to interlock with a part of the sway gear train 76 when the sway gear train 76 is in a predefined position. The first connecting gear 68 is positioned to interlock with the second connecting gear 70 and the feed gear 72 provided coaxially with the feed roller 56. The second connecting gear 70 is positioned to interlock with the transport gear 74 provided coaxially with one of the transport rollers 52c. Thus, the forward rotary motor 62 is arranged to rotate the feed roller 56 in a forward direction (as indicated by arrow B in
The output gear 86 is provided coaxially with one of the output rollers 46. The output gear 86 is provided on the load side of the sway gear train 76 and positioned to interlock with a part of the sway gear train 76 when the sway gear train 76 is in a predefined position.
In the sheet turnover unit main body 24, a forward/reverse rotary motor 88 as a drive unit, a forward/reverse rotary motor gear 90, and a second idler gear 92 are installed. The forward/reverse rotary motor 88 is a motor running in two directions; i.e., it is rotatable in both forward and reverse directions (as indicated by arrows D and E in
In the sheet turnover unit main body 24, a forward rotary motor running only in one direction may be installed and a drive direction reversing unit may be provided so that the direction of the drive interlocked with the forward rotary motor can be reversed. An additional gear train may be provided that interlocks with the forward rotary motor 62 when the sheet turnover unit is attached to the image forming apparatus main body 12 and the drive direction reversing unit may be provided in the sheet turnover unit main body 24 so that the direction of the drive interlocked with the additional gear train can be reversed.
On the inner side (right side in
Also as shown in
The sway gear train supporting member 84 is formed in a substantially triangle shape with round vertices and a pinion gear 84a is provided in the vicinity of one vertex. The pinion gear 84a is formed in a partially cut circle like a D shape and provided integrally with the sway gear train supporting member 84. The sway gear train supporting member 84 is provided with a support axis 78a and a support axis 80a. The first sway idler gear 78 and the second sway idler gear 80 are rotatably supported on the support axis 78a and the support axis 80a, respectively.
The sway fulcrum gear 82 is positioned to engage with the first sway idler gear 78 and the second sway idler gear 80 and rotatably supported on a support axis 82a provided in the sway gear train supporting member 84. The support axis 82a is provided in the center of rotation of the pinion gear 84a and coaxially supports the pinion gear 84a and the sway fulcrum gear 82. One end of the support axis 82a is rotatably provided in the image forming apparatus main body 12.
Thus, the sway gear train supporting member 84 movably supports the first sway idler gear 78 and the second sway idler gear 80.
The switching unit 94 includes the above pinion gear 84a and the rack 96 that is engaged with the pinion gear 84a. By the engagement of the pinion gear 84a and the rack 96, translatory movement of the rack 96 is converted into rotary motion of the pinion gear 84a and, thereby, the sway gear train supporting member 84 turns.
When the sheet turnover unit 22 is detached from the image forming apparatus main body 12, as shown in
As shown in
In this way, switching of the drive that drives the output rollers 46 can be performed by attaching/detaching the sheet turnover unit 22 to/from the image forming apparatus main body 12. Specifically, by the engagement of the rack 96 of the sheet turnover unit 22 and the pinion gear 84a, the sway gear train supporting member 84 turns. This turning moves the first sway idler gear 78 and the second sway idler gear 80 to reverse the output direction of the drive switching mechanism 60. In this way, the input and output gears in the drive switching mechanism 60 are used to transmit the drive. This avoids useless idle running of at least the input and output gears and can suppress vibration and noise.
By use of the rack 96 and the pinion gear 84a as the switching unit, the first sway idler gear 78 and the second sway idler gear 80 can be moved to a greater extent than the amount of movement of the sheet turnover unit 22. This makes it easy to lay out gear trains in various ways. Moreover, by changing the gear ratio between the rack 96 and the pinion gear 84a, the amount of movement of the sheet turnover unit main body 24 and the amount of rotation of the sway gear train supporting member 84 can be adjusted easily.
When the sheet turnover unit 22 is attached to the image forming apparatus main body 12, the output rollers 46 can be rotated in both forward and reverse directions by the forward/reverse rotary motor 88 within the sheet turnover unit main body 24. Accordingly, the structure inside the image forming apparatus main body 12 can be simplified, as compared with the image forming apparatus main body 12 incorporating the switching unit. When the sheet turnover unit 22 is not in use, noise and power consumption can be suppressed, as compared with the image forming apparatus main body 12 incorporating another motor for reversing the rotation of the output rollers 46.
Next, a second exemplary embodiment is described based on
The sheet turnover unit main body 24 configured according to the second exemplary embodiment includes the following: a forward/reverse rotary motor 88, as a drive unit, which is rotatable in both forward and reverse directions (as indicated by arrows D and E in
In this way, by providing the second connecting gear 70 and the transport gear 74 in the sheet turnover unit main body 24, useless rotation of the transport rollers 52c can be prevented when the sheet turnover unit 22 is detached. When the sheet turnover unit 22 is detached, the image forming apparatus main body 12 can be more compact.
As described hereinbefore, the present invention can be applied to a drive switching device and an image forming apparatus including such device for which vibration and noise have to be suppressed.
The present invention may be embodied in other specific forms without departing from its spirit or characteristics. The described exemplary embodiments are to be considered in all respects only as illustrated and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
Number | Date | Country | Kind |
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2006-222183 | Aug 2006 | JP | national |
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Number | Date | Country | |
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20080044212 A1 | Feb 2008 | US |