Exemplary embodiments described herein relate to an image erasing apparatus and an image erasing method to erase color of an image on a sheet which an image forming apparatus has formed.
There is an image erasing apparatus to perform image erasing processing for a sheet with heat to thereby erase color of an image. The image erasing apparatus has an erasure to give heating treatment to a sheet on which an image has been formed with image erasable material to thereby erase the color of the sheet-like image (color material). The image erasing apparatus has a reader to read an image so as to remain image data before image erasing and a reader to read an image so as to discriminate whether or not the image erasing has normally been performed after image erasing. But if the reader to read the image so as to remain the image data and the reader to read the image so as to discriminate whether or not the sheet is reusable after image erasing are separately provided, a problem to cause cost increase occurs. In addition, in case that only the reading processing is performed, if a sheet passes through the erasure, a problem that a long processing time is required occurs.
In general, according to one embodiment, there is provided an image erasing apparatus including: a sheet supply portion to supply a sheet; an ejector to which the sheet is ejected; a first conveying path to form a conveying path from the sheet supply portion toward the ejector; a reader arranged on the first conveying path to read an image on a surface of the sheet; an erasure to erase the image on the sheet formed with image erasable material; a switching portion arranged on the first conveying path at a downstream side of the reader in a sheet conveying direction to switch the sheet conveying direction to a direction of the ejector or a direction of the erasure; and a second conveying path having the erasure which, at a position where the switching portion is arranged, branches from the first conveying path at the downstream side of the reader and merges with the first conveying path at a meeting point between the sheet supply portion and the reader.
Hereinafter, embodiments of an image erasing apparatus will be described with reference to the accompanied drawings.
An image erasing apparatus of a first embodiment reads images by the same reader before and after erasing the image.
The sheet supply portion 10 supplies a sheet P to the inside of the image erasing apparatus 100 so as to erase the color of the image of the sheet P to be reused. The sheet supply portion 10 has a sheet tray 22 and a pickup roller 18. The sheet tray 22 loads the sheet P to be reused. The pickup roller 18 picks up the sheet P one by one from the sheet tray 22 and sends out the sheet P to the first conveying path 11.
The first conveying path 11 and the second conveying path have respectively a plurality of conveying rollers 16. A pair of a drive roller and a driven roller composes the conveying roller 16. The first conveying path 11 has the reader 13. In the present embodiment, the reader 13 has a first reader unit 13A and a second reader unit 13B. Each of the first reader unit 13A and the second reader unit 13B has a two-dimensional CCD scanner. The first reader unit 13A reads out one surface of the sheet conveyed from the sheet supply portion 10. The second reader unit 13B reads out the surface opposite to the surface which is read out by the first reader unit 13A. A RAM (Random Access Memory) 203 (
The images which have been read out by the first reader unit 13A and the second reader unit 13B are stored not exclusively in the RAM 203 of the image erasing apparatus 100 as shown in
In addition, the reader 13 reads out the respective surfaces of the sheet P so as to judge whether or not the sheet P is reusable or whether or not the print of the sheet has been image erased. A controller 200 which will be described later judges whether or not the sheet is image erasable or whether not or the sheet is reusable based on the images which the reader 13 has read out.
The first reader unit 13A and the second reader unit 13B read out the sheet two times, respectively. The controller 200 computerizes the images which have been read by the reader 13 at the first reading and stores the image data in the memory portion. The controller 200 judges whether or not the sheet P is reusable by the second reading by the reader 13 after image erasing.
The image erasing apparatus 100 may store the image by the first reading to judge whether or not the sheet is non-usable due to wrinkle, staple, a memo note which is not image erasable, or the like. If the image erasing apparatus 100 judges that the sheet is in the reusable state by the first reading, for example, performs the erasing processing for the sheet, and judges whether or not the image of the sheet P has been image erased by the second reading. The image erasing apparatus 100 ejects the sheet to the first ejector 19 or the second ejector 20 based on the judging result by the second reading. If the image erasing apparatus 100 judges that the sheet is in the non-reusable state by the first reading, performs the erasing processing, and without performing the second reading, ejects the sheet to the first ejector 19 or the second ejector 20. In addition, if the image erasing apparatus 100 judges that the sheet is in the non-reusable state by the first reading, may eject the sheet to the first ejector 19 or the second ejector 20, without performing the erasing processing and the second reading. These settings can be selected previously and can be set. The first reader unit 13A and the second reader unit 13B are not limited to a pair of two-dimensional CCD scanners, but may be CMOS sensors.
In addition, whether or not the sheet is non-usable due to wrinkle, staple, broken sheet, a memo note which is not image erasable, or the like may be judged based on the image read by the reading after image erasing. If the reading is performed after image erasing, wrinkle, staple, broken sheet, a memo note which is not image erasable, or the like can be easily detected. The CPU 200 judges whether or not the sheet is non-usable due to wrinkle, staple, broken sheet, a memo note which is not image erasable, or the like by the reading after image erasing, and ejects the sheet to the first ejector 19 or the second ejector 20 based on the judging result. These settings can previously be selected and set.
The first conveying path 11 forms a conveying path from the sheet supply portion 10 toward the first ejector 19 or the second ejector 20. The first conveying path 11 conveys the supplied sheet to the reader 13 or the ejector 23. The second conveying path 12 branches from the first conveying path 12 at a branching point BP (Branching Point) at the downstream side of the first reader unit 13A and the second reader unit 13B of the first conveying path 11 in the sheet conveying direction. The path changer 17 (switching portion) is arranged at the branching point BP. The path changer 17 switches the conveying direction of the sheet to be conveyed. The path changer 17 conveys the sheet which has been conveyed on the first conveying path 11 to the second conveying path 12 or the ejector 23.
The second conveying path 12 has the erasure 15 in the conveying path. The conveying rollers 16 of the second conveying path 12 which branches at the branching point convey the sheet P to the erasure 15. In addition, the second conveying path 12 merges with the first conveying path 11 at a meeting point MP (Meeting Point) at the upstream side from the reader 13 in the conveying direction. That is, the second conveying path 12 merges with the first conveying path 11 at the meeting point MP which is located between the sheet supply portion 10 and the reader 13. The erasure 15 has a roller pair 21 and a heater 205 (
The ejector 23 has the first ejector 19 and the second ejector 20. The sheet P to which various processings composed of the reading processing and the image erasing processing have been performed is ejected to the first ejector 19 or the second ejector 20. A user may select such that the sheet P can be ejected to any one of the first ejector 19 or the second ejector 20.
In addition, the CPU 200 is connected to a path changer drive controller 207 to control the path changer 17, a sheet conveying motor drive controller 208 to control a sheet conveying motor 209 for driving the conveying rollers, an operating portion 210, and a display 211.
A program to make the CPU 200 to be operated, a print ratio of the sheet so as to make the guideline of reusability, a density threshold value so as to judge whether or not the image has been erased are stored in the ROM 202. In addition, in case that the depth of the wrinkle is determined at the first image reading, a density threshold value which is utilized for determining the depth of the wrinkle and so on is stored in the ROM 202. The image obtained when the image of the sheet P is read is stored in the RAM 203. The CCD sensor 204 is arranged as an in-line line sensor and detects the contrasting density of the sheet P. Using an IH heater and so on, the heater 205 applies heat to the sheet P through the roller pair 21 while the sheet P passes through the erasure 15, to thereby achromatize the color material.
The operating portion 210 has the display 211 of a touch panel type and various keys, and is arranged at the upper portion of the main body of the image erasing apparatus, for example. The operation keys have a numerical keypad, a stop key, a start key and so on, for example. The display 211 displays setting information including various processing modes of the image erasing apparatus 100, an operation status, log information or a message for a user. A user can instructs to start image erasing or read the image of the sheet P via the operating portion 210. Further, the operation portion 210 of the image erasing apparatus 100 can be select the processing mode. The processing modes will be described later. The display 211 may be of a touch panel type, or may additionally operate as the operating portion. In addition, the operating portion 210 is not limited to one which is arranged in the main body of the image erasing apparatus 100. The operating portion 210 may be a configuration which can be operated from an operating unit of an external device to be connected to the image erasing apparatus 100 via a network, for example. Or the operating portion 210 may be of a type independent from the main body of the image erasing apparatus and a configuration to operate the image erasing apparatus 100 via wire or wireless communication. The operating portion of the present embodiment may be used if it can indicate the processing and browse the information to and from the image erasing apparatus 100. In the following, description will be made assuming that a touch panel is used as the display 211.
The CPU 200 controls the path changer drive controller 207 to thereby cause the path changer 17 to be driven. Thereby, the CPU 200 sorts such that the sheet P is conveyed from the first conveying path 11 to the second conveying path 12, or sorts such that the sheet P is conveyed from the first conveying path 11 to the first ejector 19 or the second ejector 20. In addition, the CPU 200 discriminates whether or not the image erasing has normally been performed after image erasing the image, that is whether or not the sheet P is reusable.
The client PC 101 has a CPU 300, a ROM 301, the RAM 302, an operating portion 303, a display 304, and an I/F 305. The CPU 300, serving as a controller of the client PC 101, is connected to the ROM 301, the RAM 302, the operating portion 303, the display 304, and the I/F 305 through a system bus 306. In addition, the images which have been read out by the first reader unit 13A and the second reader unit 13B of the image erasing apparatus 100 may be stored in the RAM 302 of the client PC 101.
The server 102 has a CPU 400, a ROM 401, the RAM 402, and an I/F 403. The CPU 400, serving as a controller of the server 102, is connected to the ROM 401, the RAM 402, the I/F 403 through a system bus 404. In addition, the images which have been read out by the first reader unit 13A and the second reader unit 13B of the image erasing apparatus 100 may be stored in the RAM 402 of the server 102.
The first ejector 19 is determined as a sheet ejecting destination of the reusable sheet P, and the second ejector 20 is determined as a sheet ejecting destination of the non-reusable sheet P. The CPU 200 judges whether or not the sheet P is reusable from the images which the first reader unit 13A and the second reader unit 13B have read out. The CPU 200 causes the sheet P to be conveyed to the first ejector 19, if reusable. The CPU 200 causes the sheet P to be conveyed to the second ejector 20, if not reusable. Without being limited to this, the CPU 200 may cause the sheet P to be conveyed to the second ejector 20, if reusable, and may cause the sheet P to be conveyed to the first ejector 19, if not reusable.
In case that the CPU 200 performs both the image reading and the discrimination of whether the sheet P is a reusable sheet or a non-reusable sheet after the images have been erased, the sheet P is conveyed to the first reader unit 13A and the second reader unit 13B two times. In case that the sheet P is processed one by one, the first reader unit 13A and the second reader unit 13B perform alternately the image reading so as to remain the image data before image erasing and the image reading so as to discriminate whether or not the image erasing has normally been performed after image erasing the images, respectively.
In addition, the CPU 200 varies the conveying speeds of the sheet P respectively, when the first reader unit 13A and the second reader unit 13B read the respective images and when the erasure 15 erases the color of the images. When the erasure 15 performs the image erasing processing, if the sheet P is conveyed at a conveying speed faster than a prescribed speed, the heater 205 can not apply a sufficient amount of heat to the color material, and thereby the image erasing processing might not normally be performed. On the other hand, though maximum speeds in the reader are different depending on the material, a maximum conveying speed at the time of image reading is faster than a maximum conveying speed at the image erasing processing. For this reason, at the time of image erasing processing, the relation between a conveying speed V1 at the time of image erasing and a conveying speed V2 at the time of reading is determined as V1<V2.
On the other hand, when the reading processing is performed without performing the image erasing processing, since it is not necessary to make the conveying speed V2 at the time of reading equal to the conveying speed V1 pass through the erasure 15 at the time of image erasing processing, the sheet P is conveyed through the erasure 15 at the speed V1≥V2. The conveying speeds of the sheet P are varied at the time of reading the image and at the time of erasing the image, and thereby the processing can be speeded up.
In addition, in case that the images which have been read by the reader 13 are stored in the memory of the image erasing apparatus 100 or the server 102, the images can be accessed through the operating portion 210 of the image erasing apparatus 100, a user terminal, or an operating unit of other external device. In case that the images are stored in association with a user ID, it becomes possible to retrieve the images using the user ID to thereby extract the associated image. The retrieved images can be stored in the moving destination assigned by the user, or can be used for browsing and so on.
In the image erasing apparatus 100 as described above, the reader to read the image so as to remain the image data in the data memory portion, and the reader to read the image so as to discriminate whether or not the image erasing has normally been performed are made a common reader, and thereby the cost can be reduced. In addition, the conveying speeds of the sheet P at the time of reading the image and at the time of erasing the image are made different, and thereby the processing can be speeded up.
An image erasing apparatus of a second embodiment shown in
A first one is a image erasing mode, a second one is a reading mode, and a third one is a discriminating mode. A fourth one is a mode which is combined with the reading and the image erasing, a fifth one is a mode which is combined with the image erasing and the discrimination, and a sixth one is a mode which is combined with the reading, the image erasing and the discrimination.
An image erasing apparatus 100 of the present embodiment comprises a sheet supply portion 10 to supply a sheet, an ejector (a first ejector 19 and a second ejector 20) to which a recording medium is ejected, a first conveying path 11 to form a conveying path from the sheet supply portion 10 toward the ejector, a reader 13 arranged on the first conveying path 11 to read an image on a surface of the sheet, a erasure 15 to erase the image on the sheet formed with image erasable material, a switching portion (a path changer) 17 arranged on the first conveying path 11 at a downstream side of the reader 13 in a sheet conveying direction to switch the sheet conveying direction to a direction of the ejector or a direction of the erasure 15, a second conveying path 12 having the erasure 15 which, at a position where the switching portion 17 is arranged, branches from the first conveying path 11 at the downstream side of the reader 13 and merges with the first conveying path 11 at a meeting point between the sheet supply portion 10 and the reader 13, and a controller (a CPU) 200 to control so as to change the sheet conveying direction by the switching portion 17 depending on a processing mode.
selection by setting items on the display 211. At the time of processing setting, the CPU 200 displays setting items 31, 32, 33, 33, processing selection buttons 40, 41, 42, 43, a determination button 50, a cancel button 51 on the display. In addition, at the time of the processing setting, the CPU 200 displays “TURN ON PROCESSING TO BE EXECUTED”, for example, to thereby urge the processing selection. The CPU 200 displays the setting items 30, 31, 32 in a line in the sequence to be processed. In
The preliminary discrimination is processing to confirm a print ratio by the first reading to thereby perform discrimination. If the print ratio is high, the CPU 200 does not perform the image erasing processing, judges that the sheet is not reusable, and ejects the sheet to the second ejector 20. If a print ratio in the detection range is not less than the threshold value, judges that the print ratio is high. The threshold value of the print ratio to judge whether or not the sheet is reusable may be changed arbitrarily.
The setting items 30, 31, 32 are each displayed by a shape indicating a sequence to be processed. The shapes of the setting items 30, 31 are shown by arrows, respectively, so that the sequence to be processed can be found. In addition, the sequence to be processed is not only displayed by an arrow, but may be described by an alphanumeric character or a character.
The CPU 200 displays the setting item 30 and the processing selection button 40, the setting item 31 and the processing selection button 41, the setting item 32 and the processing selection button 42, and the setting item 33 and the processing selection button 43, in pairs, respectively. ON or OFF can be selected on the processing selection buttons 40, 41, 42, 43 respectively. If ON is selected on the processing selection button 40, a setting to perform data storing processing is made, if ON is selected on the processing selection button 41, a setting to perform the image erasing processing is made, if ON is selected on the processing selection button 42, a setting to perform the discriminating processing is made, and if ON is selected on the processing selection button 43, a setting to perform the preliminarily discriminating processing is made. If OFF is selected on the processing selection button 40, a setting not to perform the data storing processing is made, if OFF is selected on the processing selection button 41, a setting not to perform the image erasing processing is made, if OFF is selected on the processing selection button 42, a setting not to perform the discriminating processing is made, and if OFF is selected on the processing selection button 43, a setting not to perform the preliminarily discriminating processing is made. The display 211 is made of a touch panel, and if the CPU 200 judges that the processing selection buttons 40, 41, 42, 43 have been pushed down, displays selective tabs and thereby displays ON or OFF on them in a selectable manner, respectively.
A user selects ON or OFF on the selection buttons 40, 41, 42, 43, and after finishing the selections, pushes down the determination button 50. If the CPU 200 judges that the determination button 50 has been pushed down, determines a mode. In addition, if the CPU 200 judges that the cancel button 51 has been pushed down, stops processing setting.
If ON is selected on the processing setting button 40 of the setting item 30 of the data storing, OFF is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, OFF is selected on the processing setting button 41 of the setting item 31 of the image erasing, and OFF is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the reading mode. If OFF is selected on the processing setting button 40 of the setting item 30 of the data storing, ON is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, OFF is selected on the processing setting button 41 of the setting item 31 of the image erasing, and OFF is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the preliminarily discriminating mode. If OFF is selected on the processing setting button 40 of the setting item 30 of the data storing, OFF is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, ON is selected on the processing setting button 41 of the setting item 31 of the image erasing, and OFF is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the image erasing mode. If OFF is selected on the processing setting button 40 of the setting item 30 of the data storing, OFF is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, OFF is selected on the processing setting button 41 of the setting item 31 of the image erasing, and ON is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the discriminating mode.
If ON is selected on the processing setting button 40 of the setting item 30 of the data storing, OFF is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, ON is selected on the processing setting button 41 of the setting item 31 of the image erasing, and OFF is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the reading and the image erasing. If OFF is selected on the processing setting button 40 of the setting item 30 of the data storing, OFF is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, ON is selected on the processing setting button 41 of the setting item 31 of the image erasing, and ON is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the image erasing and the discrimination. If ON is selected on the processing setting button 40 of the setting item 30 of the data storing, OFF is selected on the processing setting button 43 of the setting item of the preliminary discrimination, ON is selected on the processing setting button 41 of the setting item 31 of the image erasing, and ON is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the reading, the image erasing and the discrimination. If ON is selected on the processing setting button 40 of the setting item 30 of the data storing, ON is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, OFF is selected on the processing setting button 41 of the setting item 31 of the image erasing, and OFF is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the reading and the preliminary discrimination.
If OFF is selected on the processing setting button 40 of the setting item 30 of the data storing, ON is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, ON is selected on the processing setting button 41 of the setting item 31 of the image erasing, and OFF is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the preliminary discrimination and the image erasing. If ON is selected on the processing setting button 40 of the setting item 30 of the data storing, ON is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, ON is selected on the processing setting button 41 of the setting item 31 of the image erasing, and OFF is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the reading, the preliminary discrimination and the image erasing. If OFF is selected on the processing setting button 40 of the setting item 30 of the data storing, ON is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, ON is selected on the processing setting button 41 of the setting item 31 of the image erasing, and ON is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the preliminary discrimination, the image erasing and the discrimination. If ON is selected on the processing setting button 40 of the setting item 30 of the data storing, ON is selected on the processing setting button 43 of the setting item 33 of the preliminary discrimination, ON is selected on the processing setting button of the setting item 31 of the image erasing, and ON is selected on the processing setting button 42 of the setting item 32 of the discrimination, the CPU 200 judges this to be the mode which is combined with the reading, the preliminary discrimination, the image erasing and the discrimination.
In the above description, ON or OFF is selected on each of the processing setting buttons 40, 41, 42, 43 to thereby perform setting, but without being limited this, ON or OFF may be displayed as “PROCESSED” or “NOT PROCESSED”.
In
The image erasing mode will be described. The image erasing mode does not perform the image reading, but performs the image erasing processing.
The reading mode will be described. The reading mode does not perform the image erasing, but performs the image reading processing.
The discriminating mode will be described. The discriminating mode does not perform the image erasing, but performs the discrimination of whether or not the sheet P is reusable.
The mode which is combined with the reading and the image erasing will be described. The mode which is combined with the reading and the image erasing does not perform the discriminating processing, but after reading the image, performs the image erasing processing.
The mode which is combined with the image erasing and the discrimination will be described. The mode which is combined with the image erasing and the discrimination does not perform the reading processing before image erasing, but after the image erasing processing, performs the discrimination of whether or not the sheet P is reusable.
The mode which is combined with the reading, the image erasing and the discrimination will be described. The mode which is combined with the reading, the image erasing and the discrimination performs the image erasing after reading the image, and then performs the discriminating processing.
Then, in 1005, the conveying rollers 16 convey the sheet P from the second conveying path 12 to the first conveying path 11. In 1006, the first reader unit 13A and the second reader unit 13B read the respective images on the sheet P. In 1007, the CPU 200 judges whether or not the sheet P is reusable. If reusable (Yes in 1007), in 1008, the conveying rollers 16 eject the sheet P to the first ejector 19, and then the operation ends. If not reusable (No in 1007), in 1009, the conveying rollers 16 eject the sheet P to the second ejector 20, and then the operation ends.
The preliminarily discriminating mode will be described. The preliminarily discriminating mode does not perform the image erasing, but performs the judgment of whether or not the sheet P is reusable depending on the print ratio.
If the CPU 200 judges that the preliminarily discriminating mode is selected by the respective processing selection buttons 40, 41, 42, 43 of the setting items 30, 31, 32, 33 of
The mode which is combined with the reading and the preliminary discrimination does not perform the image erasing, but stores the read images in the memory, and performs the judgment of whether or not the sheet P is reusable depending on the print ratio. If the CPU 200 judges that the mode which is combined with the reading and the preliminary discrimination is selected by the respective processing selection buttons 40, 41, 42, 43 of the setting items 30, 31, 32, 33 of
The mode which is combined with the preliminary discrimination and the image erasing will be described. The mode which is combined with the preliminary discrimination and the image erasing performs the judgment of whether or not the sheet P is reusable depending on the print ratio, and performs the image erasing when that the print ratio is not more than the threshold value is judged.
If the CPU 200 judges that the mode which is combined with the preliminary discrimination and the image erasing is selected by the respective processing selection buttons 40, 41, 42, 43 of the setting items 30, 31, 32, 33 of
If the CPU 200 judges that the print ratio is smaller than the threshold value, the path changer drive controller 207 drives the path changer 17, and the conveying rollers 16 convey the sheet P from the first conveying path 11 to the second conveying path 12. The CPU performs the image erasing processing of the images on the sheet P conveyed to the second conveying path 12 by the erasure 15. The CPU 200 conveys the sheet P from the second conveying path 12 to the first conveying path 11 by the conveying rollers 16, ejects the sheet P to the first ejector 19 or the second ejector 20, and then the CPU 200 ends the operation.
The mode which is combined with the reading, the preliminary discrimination and the image erasing stores the read images in the memory, judges whether or not the sheet P is reusable depending on the print ratio, and if the print ratio is smaller than the threshold value, performs the image erasing processing. If the CPU 200 judges that the mode which is combined with the reading, the preliminarily discriminating and the cooler erasing is selected by the respective processing selection buttons 40, 41, 42, 43 of the setting items 30, 31, 32, 33 of
The mode which is combined with the preliminary discrimination, the image erasing and the discrimination will be described. The mode which is combined with the preliminary discrimination, the image erasing and the discrimination performs the judgment of whether or not the sheet P is reusable depending on the print ratio, and when that the print ratio is not more than the threshold value is judged, performs the image erasing, and performs the discrimination of whether or not the sheet P is reusable.
If the CPU 200 judges that the mode which is combined with the preliminary discrimination, the image erasing and the discrimination is selected by the respective processing selection buttons 40, 41, 42, 43 of the setting items 30, 31, 32, 33 of
If the CPU 200 judges that the print ratio is smaller than the threshold value, the path changer drive controller 207 drives the path changer 17, and the conveying rollers 16 convey the sheet P from the first conveying path 11 to the second conveying path 12. The CPU 200 performs the image erasing processing of the images on the sheet P conveyed to the second conveying path 12 by the erasure 15. The CPU 200 conveys the sheet P from the second conveying path 12 to the first conveying path 11 by the conveying rollers 16, and reads again the images of the sheet P by the first reader unit 13A and the second reader unit 13B. The CPU 200 judges whether or not the sheet P is reusable. If the sheet P is reusable, the conveying rollers 16 convey the sheet P to the first ejector 19 and then the CPU 200 ends the operation. If the sheet P is not reusable, the conveying rollers 16 convey the sheet to the second ejector 20, and then the CPU 200 ends the operation.
The mode which is combined with the reading, the preliminary discrimination, the image erasing and the discrimination stores the read images in the memory, and judges whether or not the sheet P is reusable depending on the print ratio, and if the print ratio is smaller than the threshold value, performs the image erasing processing and judges whether or not the sheet P is reusable after the image erasing. If the CPU 200 judges that the mode which is combined with the reading, the preliminary discrimination, the image erasing and the discrimination is selected by the respective processing selection buttons 40, 41, 42, 43 of the setting items 30, 31, 32, 33 of
In case that the mode in which the reading, the image erasing and the discrimination are combined is selected, and the sheet P is processed one by one, the first reader unit 13A and the second reader unit 13B perform alternately the image reading so as to remain the image data before image erasing and the image reading so as to discriminate whether or not the image erasing has normally been performed after erasing the images, respectively.
The operating portion 210 of the image erasing apparatus 100 can select each of the above-described modes, and thereby a user can select a desired mode. Not only the operating portion 210 of the image erasing apparatus 100 can select each mode, but the operating portion 303 of the client PC 101 may select each mode.
The CPU 200 varies the conveying speeds of the sheet P depending on the mode respectively, when the first reader unit 13A and the second reader unit 13B read the respective images and when the erasure 15 erases the color of the images. When the erasure 15 performs the image erasing processing, if the sheet P is conveyed at a conveying speed faster than a prescribed speed, the heater 205 can not apply a sufficient amount of heat to the color material, and thereby the image erasing processing might not normally be performed. On the other hand, though maximum speeds in the reader are different depending on the material, a maximum conveying speed at the time of image reading is faster than a maximum conveying speed at the image erasing processing. For this reason, the relation between the conveying speed V1 at the time of the image erasing processing and the conveying speed V2 at the time of reading is determined as V1<V2.
Accordingly, in each of the four cases of the image erasing mode, the mode which is combined with the reading and the image erasing, the mode which is combined with the image erasing and the discrimination, and the mode which is combined with the reading, the image erasing and the discrimination, the relation between the conveying speed V1 at the time of image erasing and the conveying speed V2 at the time of reading is determined as V1<V2.
In each of the two cases of the reading mode and the discriminating mode, since the sheet P is not conveyed to the erasure 15, the sheet P is conveyed at a prescribed conveying speed which is sufficient for the reader to read the image.
In the image erasing apparatus 100 as described above, the reader to read the image so as to remain the image data in the data memory portion, and the reader to read the image so as to discriminate whether or not the image erasing has been normally performed are made a common reader, and thereby the cost can be reduced.
In addition, the mode can be selected and the conveying speeds of the sheet P are varied depending on the mode, and thereby the processing time can be reduced.
An image erasing apparatus of a third embodiment shown in
In the image erasing processing of a first sheet P, the processings are performed in the following order: the reading processing by the first reader unit 13A and the second reader unit 13B, both serving as the reader, next the image erasing processing by the erasure 15, the reading processing again by the first reader unit 13A and the second reader unit 13B, and then the discriminating processing to judge whether or not the sheet P is reusable. When one sheet P is taken into account, the same processing is performed as in the flow chart shown in
Hereinafter, processings composed of the reading processing, the image erasing processing and the discriminating processing which are performed continuously for three sheets will be described. The preceding sheet P is determined as a first sheet P1, and the sheets conveyed succeeding to the first sheet P1 are determined as a second sheet P2 and a third sheet P3 in sequence. The first sheet P1 is supplied and is conveyed to the first conveying path 11, and then the first reader unit 13A and the second reader unit 13B perform the reading processing (
Subsequently, as shown in
Then, as shown in
In addition, as shown in
And, as shown in
When the above-described processings are repeated, the reading processings are performed in the following order. The reading processing for the first sheet, the reading processing for the second sheet, the discriminating processing for the first sheet, the reading processing for the third sheet, and the discriminating processing for the second sheet are performed. And finally, the discriminating processing for an (N−2)th sheet, the reading processing for an Nth sheet, the discriminating processing for an (N−1)th sheet, and the discriminating processing for the Nth sheet are performed. N is an integer.
While the first sheet P1 is conveyed to the second conveying path 12 in 1102, the second sheet P2 is supplied in 1106, and while the image erasing processing is performed for the first sheet P1 in 1103, the reading processing is performed for the second sheet P2 in 1107. While the discriminating processing is performed for the first sheet P1 in 1104, the second sheet P2 is conveyed to the second conveying path 12 in 1108, and while the first sheet P1 is ejected in 1105, the image erasing processing is performed for the second sheet P2 in 1109. After that time, the discriminating processing is performed for the second sheet P2 in 1110, and then the second sheet P2 is ejected in 1111.
While the discriminating processing is performed for the first sheet P1 in 1104 and the second sheet P2 is conveyed to the second conveying path 12 in 1108, the third sheet P3 is supplied in 1112. While the first sheet P1 is ejected in 1105 and the image erasing processing is performed for the second sheet P2 in 1109, the reading processing is performed for the third sheet P3 in 1113. While the discriminating processing is performed for the second sheet P2 in 1110, the third sheet P3 is conveyed to the second conveying path 12. While the second sheet P2 is ejected in 1111, the image erasing processing is performed for the third sheet P3 in 1115. After that time, the discriminating processing is performed for the third sheet P3 in 1116, and then the third sheet P3 is ejected in 1117.
While the discriminating processing is performed for the second sheet P2 in 1110 and the third sheet P3 is conveyed to the second conveying path 12 in 1114, a fourth sheet P4 is supplied in 1118. While the second sheet P2 is ejected in 1111 and the image erasing processing is performed for the third sheet P3 in 1115, the reading processing is performed for the fourth sheet P4 in 1119. While the discriminating processing is performed for the third sheet P3 in 1116, the fourth sheet P4 is conveyed to the second conveying path 12 in 1120. While the third sheet P3 is ejected in 1117, the image erasing processing is performed for the fourth sheet P4 in 1121. After that time, the discriminating processing is performed for the fourth sheet P4 in 1122, and then the fourth sheet P4 is ejected in 1123.
When the processings for the four sheets are performed, the reading processings are performed in the following order. The reading processing for the first sheet, the reading processing for the second sheet, the discriminating processing for the first sheet, the reading processing for the third sheet, the discriminating processing for the second sheet, the reading processing for the fourth sheet, the discriminating processing for the third sheet, and the discriminating processing for the fourth sheet are performed in this order.
The operating portion 210 of the image erasing apparatus 100 can select each of the above-described modes, and a user can select a desired mode. Not only the operating portion 210 of the image erasing apparatus 100 can select each mode, but the operating portion 303 of the client PC 101 may select each mode.
The CPU 200 controls the first reader unit 13A and the second reader unit 13B, the erasure 15 and the path changer 17 depending on the processing mode. In addition, in case that the processing mode which does not require the erasure 15 is selected, the CPU 200 controls such that the sheet P is ejected without being conveyed to the erasure 15. That is, in the case of the reading mode and the discriminating mode, the CPU 200 controls such that the sheet P is ejected without being conveyed to the second conveying path 12.
The conveying speeds of the sheet P may be varied depending on the mode, when the first reader unit 13A and the second reader unit 13B read the respective images and when the erasure erases the color of the images, respectively. When the erasure 15 performs the image erasing processing, if the sheet P is conveyed at a conveying speed faster than a prescribed speed, the heater 205 can not apply a sufficient amount of heat to the color material, and thereby the image erasing processing might not normally be performed. On the other hand, though maximum speeds in the reader are different depending on the material, a maximum conveying speed at the time of image reading is faster than a maximum conveying speed at the image erasing processing. For this reason, the relation between the conveying speed V1 in the erasure 15 and the conveying speed V2 in the reader is determined as V1<V2.
Accordingly, in each of the four cases of the image erasing mode, the mode which is combined with the reading and the image erasing, the mode which is combined with the image erasing and the discrimination, and the mode which is combined with the reading, the image erasing and the discrimination, the relation between the conveying speed V1 in the erasure 15 and the conveying speed V2 in the reader is determined as V1<V2.
In each of the two cases of the reading mode, and the discriminating mode, since the sheet P is not conveyed to the erasure 15, the sheet P is conveyed at the prescribed conveying speed which is sufficient for the reader to read the image.
In the image erasing apparatus 100 as described above, the reader to read the image so as to remain the image, and the reader to read the image so as to discriminate whether or not the image erasing has normally been performed are made a common reader, and thereby the cost can be reduced. In addition, the mode can be selected, and thereby the processing time can be reduced.
In addition, if the reader processes the second sheet P2 after having processed the first sheet P1, much processing time will be required. But in the above-described image erasing apparatus 100, the processings are shifted for each sheet and the parallel processings are performed, and thereby the processing time can be reduced.
The conveying speeds of the sheet P may be varied, when the reader reads the images and when the erasure 15 erases the color of the images, respectively. When the erasure 15 performs the image erasing processing, if the sheet P is conveyed at a conveying speed faster than a prescribed speed, the heater 205 can not apply a sufficient amount of heat to the color material, and thereby the image erasing processing might not normally be performed. On the other hand, though maximum speeds in the reader are different depending on the material, a maximum conveying speed at the time of image reading is faster than a maximum conveying speed at the image erasing processing. For this reason, the relation between the conveying speed V1 at the time of the image erasing processing and the conveying speed V2 at the time of reading is determined as V1<V2.
On the other hand, when the reading processing is performed without performing the erasing processing, since it is not necessary to make the conveying speed V2 at the time of reading equal to the conveying speed V1 of the erasure 15 at the time of the image erasing processing, the sheet P is conveyed through the erasure 15 at the speed V1≥V2, and thereby the processing can be speeded up.
An image erasing apparatus 100 of a fourth embodiment will be described. In the drawings, the same symbols are given to the same constituent components as in the above-described embodiments.
The CPU 200 varies the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the first reader unit 13A and the second reader unit 13B depending on the mode. In the case of the image erasing mode, and in the case of the mode which is combined with the reading and the image erasing, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the first reader unit 13A and the second reader unit 13B is determined as V1<V2.
In addition, in each of the cases of the reading mode and the discriminating mode where the image erasing processing is not performed, since it is not necessary to make the speed V2 equal to the speed V1 when the sheet P is conveyed through the erasure 15, the sheet P is conveyed through the erasure 15 at the speed V1=V2, and thereby the processing can be speeded up. In addition, if the speed V1 when the sheet P is conveyed through the erasure 15 can be made faster compared with the speed V2 when conveyed through the reader units 13A, 13B, the relation may be determined as V1>V2.
Accordingly, in the case of the reading mode, and in the case of the discriminating mode, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reading units 13A, 13B is determined as V1≥V2. In addition, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reading units 13A, 13B may be varied depending on the temperature of the erasure 15.
In the case of the mode which is combined with the image erasing and the discrimination, and in the case of the mode which is combined with the reading, the image erasing and the discrimination, the sheet P is conveyed from the first conveying path 11 to the second conveying path 12, and then is conveyed from the second conveying path 12 to the first conveying path 11 again. Accordingly, when the sheet P is conveyed on the first conveying path 11 at a first time, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reader units 13A, 13B is determined as V1<V2. In case that the sheet P is conveyed again on the first conveying path 11 via the second conveying path 12, the relation between a speed V3 when the sheet P is conveyed through the erasure 15 and a speed V4 when conveyed through the reader units 13A, 13B is determined as V3≥V4.
In the image erasing apparatus 100 as described above, the reader to read the image so as to remain the image, and the reader to read the image so as to discriminate whether or not the image erasing has normally been performed are made a common reader, and thereby the cost can be reduced.
In addition, the mode is selected and the conveying speeds of the sheet P are made different depending on the mode, and thereby the processing time can be reduced. In addition, since the first conveying path 11 has the erasure 15, in the case of the image erasing mode, and in the case of the mode which is combined with the reading and the image erasing, the sheet P can be processed without being conveyed on the second conveying path 12, and thereby the processing time can be reduced.
In an image erasing apparatus 100 of a fifth embodiment, the first conveying path 11 has the erasure 15 at the upstream side of the first reader unit 13A and the second reader unit 13B. The image erasing apparatus 100 has a plurality of processing modes, and varies the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reader 13 depending on the mode. In the drawings, the same symbols are given to the same constituent components as in the first embodiment.
The CPU 200 varies the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the first reader unit 13A and the second reader unit 13B depending on the mode. In each of the cases of the image erasing mode, the mode which is combined with the reading and the image erasing, the mode which is combined with the image erasing and the discrimination, and the mode which is combined with the reading, the image erasing and the discrimination, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the first reader unit 13A and the second reader unit 13B is determined as V1<V2.
In addition, in each of the cases of the reading mode and the discriminating mode where the image erasing processing is not performed, since it is not necessary to make the speed V2 equal to the speed V1 when the sheet P is conveyed through the erasure 15, the sheet P is conveyed through the erasure 15 at the speed V1=V2, and thereby the processing can be speeded up. In addition, if the speed V1 when the sheet P is conveyed through the erasure 15 can be made faster compared with the speed V2 when conveyed through the first reader unit 13A and the second reader unit 13B, the relation may be determined as V1>V2. Accordingly, in the case of the reading mode, and in the case of the discriminating mode, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reading units 13A, 13B is determined as V1≥V2.
In addition, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reading units 13A, 13B may be varied depending on the temperature of the erasure 15. The erasure 15 applies heat at the time of the image erasing processing, and the temperature thereof does not necessarily drop immediately even if the heat source is made OFF. In case that the sheet P is processed in the reading mode immediately after the sheet P has been image erased in the image erasing mode, for example, there may be a case that the temperature of the erasure 15 has not dropped completely. If the sheet P is conveyed and heat is applied to the color material in such a condition, the print might be image erased.
For this reason, in case that the sheet P is processed in the reading mode, a temperature detecting portion 212 detects the temperature of the heater 205 of the erasure 15, and if the temperature of the erasure 15 is not more than a prescribed value, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reader units 13A, 13B is determined as V1=V2. On the other hand, if the temperature of the erasure 15 is larger than the prescribed value, the relation between the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reader units 13A, 13B is determined as V1>V2.
In the image erasing apparatus 100 as described above, the reader to read the image so as to remain the image and the reader to read the image so as to discriminate whether or not the image erasing has normally been performed are made a common reader, and thereby the cost can be reduced.
In addition, the mode is selected and the conveying speeds of the sheet P are made different depending on the mode, and thereby the processing time can be reduced. In addition, in case that the temperature of the erasure 15 has not dropped completely, the relation of the speed V1 when the sheet P is conveyed through the erasure 15 and the speed V2 when conveyed through the reader units 13A, 13B is determined as V1>V2, and the conveying speed in the erasure 15 is made faster, and thereby the print can be prevented from being image erased.
In the description of the above-described embodiments, “the image erasing processing” has been described so as to mean to erase the color of the image as the image erasing apparatus, but it also has meaning to erase the image. The image erasing apparatus described in the present embodiments is not limited to an apparatus which erases the color of an image with heat. An apparatus to erase the color of an image on a sheet with light irradiation or an apparatus to erase an image formed on a special sheet may be used. Or, an apparatus to remove (eliminate) an image on a sheet may be used, or a configuration to make an image invisible so as to make a sheet reusable may be used.
While certain embodiments have been described, those embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments 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.
Number | Date | Country | Kind |
---|---|---|---|
2011-208903 | Sep 2011 | JP | national |
2011-211811 | Sep 2011 | JP | national |
2011-241977 | Nov 2011 | JP | national |
This application is a continuation of U.S. patent application Ser. No. 15/364,904, filed on Nov. 30, 2016, which is a continuation of and is based upon and claims the benefit of priority from the prior U.S. patent application Ser. No. 15/041,543, filed on Feb. 11, 2016, which is a division of and is based upon and claims the benefit of priority from the prior U.S. patent application Ser. No. 14/292,589, filed on May 30, 2014, which is a division of and is based upon and claims the benefit of priority from the prior U.S. patent application Ser. No. 13/486,769, filed on Jun. 1, 2012, now U.S. Pat. No. 8,743,164, issued on Jun. 3, 2014; U.S. Provisional Application No. 61/492,805, filed on Jun. 2, 2011; U.S. Provisional Application No. 61/494,847, filed on Jun. 8, 2011; U.S. Provisional Application No. 61/494,850, filed on Jun. 8, 2011; U.S. Provisional Application No. 61/494,856, filed on Jun. 8, 2011; and U.S. Provisional Application No. 61/495,274 filed on Jun. 9, 2011, the entire contents of which are incorporated herein by reference. This application is also based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2011-208903, filed on Sep. 26, 2011; Japanese Patent Application No. 2011-211811, filed on Sep. 28, 2011; and Japanese Patent Application No. 2011-241977, filed on Nov. 4, 2011, the entire contents of each of which are incorporated herein by reference.
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Number | Date | Country | |
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Parent | 14292589 | May 2014 | US |
Child | 15041543 | US | |
Parent | 13486769 | Jun 2012 | US |
Child | 14292589 | US |
Number | Date | Country | |
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Parent | 15364904 | Nov 2016 | US |
Child | 16020620 | US | |
Parent | 15041543 | Feb 2016 | US |
Child | 15364904 | US |