1. Technical Field
The present invention relates to a sheet supply device to be provided in an image forming apparatus.
2. Background Arts
Generally, an image forming apparatus such as a stencil printing machine includes a sheet supply device for supplying print sheets to an image forming unit. Such a sheet supply device includes a sheet supply tray on which print sheets are stacked. An entire of a sheet supply tray can be retracted-into and drawn-from a main body of the apparatus. Alternatively, a portion of a sheet supply tray may be extended outward from an opening of a main body of the apparatus.
Such a sheet supply device includes a guide fence(s) for restricting positions of print sheets along a sheet width direction perpendicular to a sheet supply direction. The guide fence(s) can be moved manually along the sheet width direction according to a size of print sheets. In addition, the sheet supply device also includes a guide fence mechanism for locking the guide fence(s).
Various types of lock mechanisms are proposed. For example, Japanese Utility Model Application Laid-Open No. H6-72995 discloses a guide fence mechanism for a pair of guide fences that regulates a width between side edges of print sheets stacked on a sheet supply tray. The guide fences can be moved independently from each other. Each of the guide fences is provided with a lock lever having an eccentric cam. Movement of each of the guide fences is restricted when the lock lever is operated.
When setting large-sized print sheets (e.g. A3 size print sheets) on a sheet supply tray, it may be needed to divide the print sheets into several bundles and then stack the several bundles one by one due to heavy weight of all the print sheets. In such a case, edges of the bundles are more likely to become uneven with respect to each bundle. Therefore, it is required to align the edges of the stacked print sheets (bundles) by guide fences in order to make the edges even.
If a locking (restriction) force of any one of the guide fences is insufficient against an impact force generated by aligning the print sheets, supply positions of the print sheets may become erroneously shifted laterally (in a sheet width direction). In a case of strengthening such a locking force to avoid such an erroneous supply of the print sheets in the prior art as instantiated above, it may be required to increase an eccentric amount of the eccentric cam of the guide fence mechanism in order to increase friction applied to the eccentric cam. Therefore, an operational force of the lock lever may become larger and thereby operability of the guide fence mechanism may become degraded.
An object of the present invention is to provide a sheet supply device that can strengthen a locking force of the guide fence(s) and can improve operability for changing a position(s) of a guide fence(s) on a sheet supply tray.
An aspect of the present invention provides a sheet supply device that includes a sheet supply tray on which sheets are stacked; a guide fence for restricting positions of the sheets along a sheet width direction perpendicular to a sheet supply direction; a slider block that is slidable along the sheet width direction and supports the guide fence in an upright state; a slide shaft that is inserted into a through hole formed in the slider block and guides sliding of the slider block along the sheet width direction; and a guide fence lock mechanism including a restriction member on which a hole is formed and that is attached to the slider block swingably at a position distanced from the guide fence, the slide shaft being inserted into the hole, wherein the guide fence lock mechanism is configured to restrict sliding of the slider block along the sheet width direction by holding the restriction member in a lock state where an inner circumferential edge of the hole is pushed onto an outer circumference of the slide shaft, and to allow sliding of the slider block along the sheet width direction when the restriction member is swung to cancel the lock state.
According to the above aspect, a friction force is generated between the inner circumferential edge of the hole and the outer circumference of the slide shaft when the inner circumferential edge is pushed onto the outer circumference in the lock state. Sliding of the guide fence is locked by the friction force. Therefore, an operational force can be prevented from increasing in comparison with a sheet supply device including a guide fence mechanism using an eccentric cam. In addition, a locking force for the guide fence can be strengthened and operability for changing positions of the guide fence can be also improved.
It is preferable that the guide fence mechanism further includes a fulcrum plate that is fixed with a vertical end of the slider block and engaged with a vertical end of the restriction member so as to function as a fulcrum when the restriction member is swung, an elastic member that is disposed near another vertical end of the slider block and to urge the restriction member toward the guide fence, and a lever that is fixed with another vertical end of the restriction member and configured to swing the restriction member when manually operated to distance the restriction member away from the guide fence against an urging force of the elastic member.
According to this configuration, it become possible by this relatively simple configuration to strengthen the locking force for the guide fence and improve the operability for changing positions of the guide fence. In addition, a pushing force is applied to the guide fence by aligning sheets stacked on the sheet supply tray. The pushing force is transmitted to the restriction member via the fulcrum plate, so that the inner circumferential edge of the hole is further pressed onto the outer circumference of the slide shaft. Therefore, the above-explained friction force is strengthened and thereby the guide fence can be made locked more firmly.
Hereinafter, an embodiment will be explained with reference to the drawings. In the drawings, identical or equivalent components are indicated by identical reference numbers, respectively, and thereby redundant explanations for them are omitted.
As shown in
The sheet supply tray 2 is made of resin, and guide slots 3a and 3b for guiding movements of the guide fences 10 are formed on an upper surface of the sheet supply tray 2 along the sheet width direction b1 and b2. In addition, scales 4 are marked on the upper surface along the guide slots 3a, respectively, and used as reference for setting positions of the guide plates 10. The guide fences 10 include guide fence mechanisms A1a and A1b, respectively, and positions of the guide fences 10 are made fixed at desired positions by the guide fence lock mechanisms A1a and A1b, respectively.
In addition, as shown in
As shown in
As shown in
According to the above-explained configuration, the slider blocks 11 can smoothly slide in the sheet width direction b1 and b2 along the slide shafts 20 inserted into the through holes 11a, respectively. Along with sliding of the slider blocks 11, the guide fences 10 are shifted in the sheet width direction b1 and b2 (see
In addition, the guide fence lock mechanism A1a (A1b) includes a restriction plate (restriction member) 12 on which a hole 12c is formed. The hole 12c has a larger inner diameter than the outer diameter of the slide shaft 20, and the slide shaft 20 can be loosely inserted into the hole 12c. While the stacked print sheets are restricted by the guide fence(s), inner circumferential sharp edges 12d and 12e of the hole 12c is pushed (clenched) onto an outer circumferential surface of the slide shaft 20 by pushing forces F1 and F2 (FF and F2′) to hold the guide fences 10 as shown in
<Configuration of Guide Fence Lock Mechanism>
Next, configurations of the guide fence lock mechanisms A1a and A1b will be explained with reference to
The guide fence lock mechanism A1a includes the restriction plate 12, a fulcrum plate 13, a coil spring (an elastic member) 14, and a lever 16. The restriction plate 12 is made by bending SECC (electrolytic zinc-coated steel plate) or the like. The fulcrum plate 13 is fixed with a vertical end (a lower end in
As shown in
An E-ring (E-shaped stopper ring) 15 is attached to an end of the boss 11b to hold the coil spring 14. The coil spring 14 is disposed between the E-ring 15 and the restriction plate 12 in a half-compressed state so as to urge the restriction plate 12 as explained above. In addition, the pinch plate 17 is formed by bending a sheet metal or the like, and pinched together with the lever 16 by a hand to swing the restriction plate 12 (to unlock the guide fence lock mechanism A1a).
As shown in
<Operations of Guide Fence Lock Mechanism>
Operations of the guide fence lock mechanism A1a (A1b) will be explained with reference to
In
Next, explained will be the other lock state where the pushing force F3 is applied to the restriction plate 12 from sprint sheets via the guide fence 10, the slider block 11 and the fulcrum plate 13 as shown in
A rotating force F10′ is generated by the pushing force F3 and the above-explained urging force of the coil spring 14 so as to swing the restriction plate 12 toward the guide fence 10 while the engagement hole 13a functions as a fulcrum. Therefore, the sharp inner circumferential edges 12d and 12e of the hole 12c are further pushed (clenched) onto the outer circumferential surface of the slide shaft 20. Namely, due to the rotating forces F10′, a pushing force by a vector F2′ shown in
An operation for unlocking the guide fence mechanism A1a (A1b) will be explained with reference to
As shown in
As explained above, according to the guide fence mechanisms A1a and A1b included in the sheet supply device 1 in the present embodiment, an operational force can be prevented from increasing in comparison with a sheet supply device including a guide fence mechanism using an eccentric cam. In addition, locking forces for the guide fences 10 can be strengthened and operability for changing positions of the guide fences 10 can be also improved.
The present invention is not limited to the above-mentioned embodiment, and it is possible to embody the present invention by modifying its components in a range that does not depart from the scope thereof. Further, it is possible to form various kinds of inventions by appropriately combining a plurality of components disclosed in the above-mentioned embodiment. For example, it may be possible to omit several components from all of the components shown in the above-mentioned embodiment. Scope of the present invention is determined in the context of the claims.
For example, the guide fences 10 provided with the guide fence mechanisms A1a and A1b are provided on both sides of the sheet supply direction in the above embodiment as shown in
The guide fences 10 provided with the guide fence mechanisms A1a and A1b are implemented in the sheet supply tray 2 of the sheet supply device 1 as shown in
The friction forces between the inner circumferential edges 12d and 12e and the outer circumferential surface of the slide shaft 20 may be increased by roughening the outer circumferential surface of the slide shaft 20, by engraving grooves on the outer circumferential surface of the slide shaft 20, or the like.
The present application claims the benefit of a priority under 35 U.S.C §119 to Japanese Patent Application No. 2013-2548, filed on Jan. 10, 2013, the entire content of which is incorporated herein by reference.
Number | Date | Country | Kind |
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2013-002548 | Jan 2013 | JP | national |