Embodiments described herein relate generally to an image erasing apparatus that erases an image formed on a recording medium.
An image erasing apparatus according to a related art includes a large metal detection apparatus to detect staples or the like attached to a recording medium. Therefore, there is a problem in that the size and cost of the image erasing apparatus is increased. In addition, in order to solve this problem, a method of optically detecting staples instead of performing metal detection is known. However, the optical detecting method has a problem in that an image formed on a recording medium and a staple cannot be distinguished from one another.
An image erasing apparatus according to an embodiment includes: a supply unit that supplies a recording medium; a recovery unit that recovers the recording medium supplied by the supply unit; a carriage path on which the recording medium supplied by the supply unit is carried toward the recovery unit; a foreign matter information acquisition unit that includes a first conductive brush and a second conductive brush of which distal portions respectively come in contact with an upper surface and a lower surface of the recording medium carried on the carriage path; and a heating unit that heats the recording medium at a temperature equal to or higher than a color-erasing temperature of a developer at an erasing position which is on a downstream side of a carriage direction of the carriage path than an acquisition position of the foreign matter information acquisition unit.
The paper feed tray 11 stacks a number of recording media (sheets) S. On the recording medium S, an image is formed by a developer. The pickup roller 12 picks up the recording medium S stacked in the paper feed tray 11 so as to be supplied to a carriage path T of the recording medium. The picking-up operation of the pickup roller 12 is controlled by the controller 30. Here, while there is a case where the recording media S stacked in the paper feed tray 11 are picked up by the pickup roller 12 one by one, there is a case where a plurality of recording media S stacked are integrally picked up. The case where the plurality of recording media S are integrally picked up includes a state where the recording media S are bound by foreign matter made of metal such as staples or clips.
The multiple-feed detection sensor 13 detects a multiple-feed of the recording media S. The multiple-feed detection sensor 13 includes a transmission sensor 13A and a reception sensor 13B. The transmission sensor 13A outputs ultrasonic waves. The reception sensor 13B receives the ultrasonic waves output by the transmission sensor 13A. The ultrasonic waves are attenuated as they pass through the recording media S. The controller 30 determines presence of the multiple-feed on the basis of an output waveform of a signal output by the reception sensor 13B.
The media sensor 14 includes an abutting portion 14A and a swing bar 14B. One end of the swing bar 14B includes the abutting portion 14A, and the other end thereof includes a shaft portion 14C. The swing bar 14B swings in an arrow direction from the shaft portion 14C as a rotation shaft. When the plurality of recording media S in the multiple-feed state reaches a detection position of the media sensor 14, a rotation angle of the swing bar 14B is increased than that when only a single sheet of the recording medium S reaches. The controller 30 determines presence of the multiple-feed on the basis of the rotation angle of the swing bar 14B.
The carriage path T extends in the horizontal direction from a start point in the carriage direction and includes a first carriage path T1 further extending in the horizontal direction from a branched position U and a second carriage path T2 extending downward from the branched position U. A switching device 81 is positioned at the branched position U. The controller 30 controls driving of the switching device 81.
The heating device 15 is positioned on a downstream side of the carriage path T than the media sensor 14. The heating device 15 includes a first heating device 15A and a second heating device 15B. The first and second heating devices 15A and 15B are opposed to each other with the carriage path T interposed therebetween. The heating device 15 heats the recording medium S to a color-erasing temperature which is a temperature at which color of the developer disappears so as to erase the image formed on the recording medium S.
The scanner 16 is positioned on the downstream side of the carriage path T than the heating device 15. The scanner 16 includes a first scanner 16A and a second scanner 16B. The first scanner 16A and the second scanner 16B are opposed to each other with the carriage path T interposed therebetween. The controller 30 determines whether or not erasure of the image of the recording medium S is successful on the basis of an output of the scanner 16.
The image erasing apparatus 1 includes stacking devices 71A, 71B, 71C, and 71D. The stacking device 71D is positioned at an end point of the first carriage path T1. The recording media S from which a staple is detected are stacked in the stacking device 71D. The stacking devices 71A, 71B, and 71C are positioned at an end point of the second carriage path T2. The recording medium heated by the heating device 15 is stacked in any of the stacking devices 71A, 71B, and 71C. Specifically, the controller 30 operates a switching device 82 so that the recording media S for which image erasure is not successful are stacked in the stacking device 71C. The controller 30 operates a switching device 83 so that the recording media S for which image erasure is successful are sorted depending on recording medium sizes so as to be stacked in the stacking device 71A or 71B.
The first pair of rollers 21 are positioned between the multiple-feed detection sensor 13 and the media sensor 14 and rotate while pinching the recording medium S passing through the multiple-feed detection sensor 13 so as to carry the recording medium S toward the media sensor 14. The second pair of rollers 22 are positioned between the media sensor 14 and the heating device 15 on the second carriage path T2 and rotate while pinching the recording medium S passing through the media sensor 14 so as to carry the recording medium S toward the heating device 15.
The third pair of rollers 23 are positioned between the heating device 15 and the scanner 16 on the second carriage path T2 and rotate while pinching the recording medium S passing through the heating device 15 so as to carry the recording medium S toward the fourth pair of rollers 24. The fourth pair of rollers 24 are positioned on the second carriage path T2 and carry the recording medium S passing through the scanner 16 toward any of the stacking devices 71A, 71B, and 71C.
The fifth pair of rollers 25 are positioned on the second carriage path T2 and carry the recording medium S carried from the fourth pair of rollers 24 to the stacking device 71C. The sixth pair of rollers 26 are positioned on the second carriage path T2 and carry the recording medium S carried from the fourth pair of rollers 24 to the stacking device 71A. The seventh pair of rollers 27 are positioned on the second carriage path T2 and carry the recording medium S carried from the fourth pair of rollers 24 to the stacking device 71B.
The eighth pair of rollers 28 are positioned on the first carriage path T1 and rotate while pinching the recording medium S so as to carry the recording medium S to the stacking device 71D.
The first and second conductive brushes 17 and 18 are positioned on an upstream side of the carriage path T than the multiple-feed detection sensor 13. The first conductive brush 17 comes in contact with an upper surface of the recording medium S supplied to the carriage path T. The second conductive brush 18 comes in contact with a lower surface of the recording medium S supplied to the carriage path T. The first conductive brush 17 is formed in a linear shape in which a distal portion is positioned on the downstream side of the carriage direction of the carriage path T than a proximal portion. The second conductive brush 18 is formed in a linear shape in which the distal portion is positioned on the downstream side of the carriage direction of the carriage path T than the proximal portion. Accordingly, contact areas of the first and second conductive brushes 17 and 18 being in contact with the recording media S are increased, so that detection precision is increased and carriage resistance is reduced.
The first and second conductive brushes 17 and 18 are positioned on the carriage path T while not being in contact with each other. Since they are not in contact with each other, a potential is changed when they come in contact with the staple attached to the recording medium S.
The first and second conductive brushes 17 and 18 may also be neutralization brushes.
The controller 30 performs various kinds of control executed by the image erasing apparatus 1. The controller 30 may be a CPU or an MPU. The controller 30 may also be an ASIC circuit that executes at least a part of processing realized by the CPU or the MPU on the circuit. The number of CPUs, MPUs, or ASIC circuits is not limited. Depending on the contents of control, different CPUs may be used for the control. In addition, the controller 30 may include other elements needed for the control.
Next, an example of the configuration for realizing this embodiment is shown by a block diagram of
The supply unit 61 supplies the recording medium S to the carriage path T of the image erasing apparatus 1. Referring to
The first recovery unit 62A recovers the recording medium S from which foreign matter information is acquired by the foreign matter information acquisition unit 64. Referring to
Referring to
The foreign matter information acquisition unit 64 acquires information regarding foreign matter made of metal attached to the recording medium S. The foreign matter made of metal may be a binding member used for binding a plurality of overlapped recording media S. The binding member may be a staple or a clip. The foreign matter information acquisition unit 64 outputs a detection result to the controller 30.
The acquisition circuit 19 includes a comparator 19A. The comparator 19A changes an output signal between a first state in which the first and second conductive brushes 17 and 18 are electrically connected to each other via the staple, and a second state in which the first and second conductive brushes are not electrically connected to each other via the staple. That is, in the second state (a state without foreign matter), the comparator 19A outputs an H (High) signal, and in the first state (a state with foreign matter), the comparator 19A outputs an L (Low) signal. A determination unit 31 receives the signal output by the comparator 19A and determines presence or absence of foreign matter. The determination unit 31 may be the controller 30.
Returning to
A switching unit 68 switches the carriage path T between the first carriage path T1 and the second carriage path T2 at the branched position U of
A storage unit 32 stores programs for performing various kinds of control of the image erasing apparatus 1. The storage unit 32 may be an HDD or a memory. The controller 30 reads out the programs stored in the HDD on the memory. The storage unit 32 may be positioned outside the controller 30.
Next, operations of the image erasing apparatus 1 will be described with reference to a flowchart of
In Act 101, the controller 30 determines whether or not the signal output from the comparator 19A is the L signal fallen from the H signal. When the output signal of the comparator 19A is fallen to the L signal, in Act 102, the controller 30 drives the switching device 81 so as to switch the carriage path T from the second carriage path T2 to the first carriage path T1.
In Act 103, the controller 30 drives a timer (not shown) and then proceeds to Act 104. In Act 104, the controller 30 determines whether or not a set time elapses. Here, the set time corresponds to a time taken until the recording medium S passes through the branched position U from the foreign matter information acquisition position of the foreign matter information acquisition unit 64. Therefore, the recording medium S to which the staple is attached goes straight along the first carriage path T1 to be stacked in the stacking device 71D. Accordingly, the recording medium S to which the staple is attached is prevented from entering the second carriage path T2 and being bent. As a result, concurrence of jams is suppressed.
In Act 105, the controller 30 drives the switching device 81 such that the carriage path T is switched from the first carriage path to the second carriage path, and returns to Act 101.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of invention. Indeed, the novel apparatus described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the apparatus described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
This application is also based upon and claims the benefit of priority from U.S. provisional application 61/318,730, filed on Mar. 29, 2010; the entire contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
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5683189 | Sukigara et al. | Nov 1997 | A |
6152620 | Ozawa et al. | Nov 2000 | A |
6860658 | Tischer | Mar 2005 | B2 |
7324237 | Okada | Jan 2008 | B2 |
Number | Date | Country | |
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20110234736 A1 | Sep 2011 | US |
Number | Date | Country | |
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61318730 | Mar 2010 | US |