JP2018163368A - Image erasing apparatus and image erasing method - Google Patents

Abstract

A problem to be solved by an embodiment of the present invention is to provide an image erasing apparatus capable of reducing power consumption. An erasing unit that erases an erasable image formed on a recording medium, a conveying unit that conveys the recording medium, and a recording medium that is conveyed by the conveying unit and erases an image by the erasing unit When determining that the amount of the recording medium detected by the detection unit, the detection unit for detecting the amount of the recording medium temporarily stored in the standby unit, and the amount of the recording medium detected by the detection unit is equal to or greater than a predetermined amount, An image erasing apparatus comprising: a controller configured to sequentially convey the recording medium accommodated in the standby unit to the erasing unit by the conveying unit and to control the erasing unit to erase the image of the conveyed recording medium; Selected figure] Figure 1

Description

  Embodiments described herein relate generally to an image erasing apparatus that erases an image printed on paper and an image erasing method of the image erasing apparatus.

  As an image erasing device, an image is printed on a sheet using a recording material, for example, a decolorable toner, and a toner that forms an image by heating is decolored to erase the image printed on the sheet. A so-called decoloring device is known. This erasing apparatus includes a reading unit that reads an image to leave an image before erasing, a erasing unit that erases toner that forms an image, and whether or not erasing processing has been normally performed after erasing. In order to determine whether or not the image is read again by the above-described reading unit. When erasing the image formed on the paper, a series of operations are performed in which the content of the paper is read and stored by the reading unit and is erased. However, when erasing an image with such an apparatus, a relatively large amount of power consumption is required due to heating, and thus it is necessary to perform an image erasing process efficiently.

JP 2010-113337 A

  The problem to be solved by the embodiments of the present invention is to provide an image erasing apparatus capable of reducing the power consumption associated with the erasing process by performing an efficient image erasing process.

  Therefore, in order to achieve the above-described problem, the following measures are taken in the embodiment of the present invention. An erasing unit for erasing an erasable image formed on the recording medium, a conveying unit for conveying the recording medium, and a standby for temporarily storing the recording medium conveyed by the conveying unit and erasing the image by the erasing unit A detection unit that detects an amount of the recording medium temporarily stored in the standby unit, and a conveyance unit that determines that the amount of the recording medium detected by the detection unit exceeds a predetermined amount. An image erasing apparatus including: a control unit that sequentially transports the recording medium accommodated in the standby unit to the erasing unit and controls the erasing unit to erase the image of the conveyed recording medium.

1 is a schematic cross-sectional view of an image erasing apparatus in the present embodiment. 1 is a block diagram of an image erasing apparatus in the present embodiment. 6 is a flowchart of a reading job of the image erasing apparatus according to the present embodiment. 6 is a flowchart of an erasing job of the image erasing apparatus according to the present embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
(This embodiment)
FIG. 1 is a schematic cross-sectional view of the image erasing apparatus 100. In FIG. 1, the main part excluding the outer casing is shown as the device 100. The image erasing apparatus 100 erases an image on a paper (recording medium) P on which an image has already been formed, and enables the paper P to be reused. In this embodiment, as an example of the erasing process, the recording material is erased by heating and an erasing process for erasing an image is taken as an example. An image erasing apparatus 100 shown in FIG. 1 includes a paper feeding unit 10 that stores paper P, a first transport path 11 and a second transport path 12 that transport the paper P, and a first reading unit that reads an image on the paper P. 13 and the second reading unit 14, the erasing unit 15 for erasing the image on the paper P, the transport roller 16 provided in each transport path, the path changing unit 17 for switching the transport path of the paper P, and the paper P for which processing has been completed. It has a paper discharge unit 30 for storing, and a standby unit 40 for temporarily storing paper P.
The paper feed unit 10 accommodates paper P on which an image has already been formed and is to be reused. Then, in order to erase the image on the paper P, the paper P is fed into the image erasing apparatus 100. The paper P to be reused is, for example, a paper on which an image is formed with a recording material (toner) that can be erased by heating. The paper may be various sizes such as A3, A4, and B5. The paper feed unit 10 includes a paper feed tray 22, a pickup roller 18 that takes out paper in the paper feed tray 22 (hereinafter referred to as a paper feed tray pickup roller), and a paper feed unit sensor 215. The paper feed tray 22 is loaded with paper P for erasing images. The paper feed tray pickup roller 18 takes out the paper P one by one from the paper feed tray 22 and sequentially sends it out to the first transport path 11. The paper feed unit sensor 215 is a sensor that detects whether or not the paper P is present in the paper feed tray 22. The paper feed unit sensor 215 is an infrared sensor, for example. In addition, a sensor using a known microswitch can also be used. The paper feed unit sensor 215 transmits the detection result to a control unit described later.
The 1st conveyance path 11 and the 2nd conveyance path 12 have a plurality of conveyance rollers 16, and conveyance roller 16 comprises a pair of a drive roller and a driven roller.
A first reading unit 13 and a second reading unit 14 are arranged in the first conveyance path 11 along the conveyance path. The first transport path 11 transports the paper P from the paper feed unit 10 to the paper discharge unit 30 via the first reading unit 13 and the second reading unit 14 by the transport roller 16.
In this embodiment, since the paper P is conveyed from the paper supply unit 10 to the paper discharge unit 30, the paper supply unit 10 side is the upstream side with respect to the paper conveyance direction, and the paper discharge unit 30 side is The downstream side with respect to the paper transport direction.
The first reading unit 13 and the second reading unit 14 include, for example, a two-dimensional CCD scanner (the first reading unit 13 and the second reading unit together correspond to a reading unit). The two reading units are provided, for example, at different positions with respect to the first conveyance path 11. With such a configuration, the first reading unit 13 reads one side of the conveyed paper, and the second reading unit 14 reads the surface opposite to the reading side of the first reading unit 13. Images read by the first reading unit 13 and the second reading unit 14 are appropriately stored in, for example, the RAM 203 or the HDD 214 in FIG.
The first transport path 11 is connected to the paper discharge unit 30 via a branch point located downstream of the first reading unit 13 and the second reading unit 14 in the paper transport direction. A route changing unit 17 that switches the route between the first transport path 11 and the second transport path 12 is disposed at the branch point. By default, the path changing unit 17 permits a path for transporting the paper P from the paper feeding unit 10 to the paper discharging unit 30 via the first reading unit 13 and the second reading unit 14, for example. .
The second transport path 12 branches from the first transport path 11 at a branch point (route changing unit 17), and is upstream of the first reading unit 13 and the second reading unit 14 of the first transport path 11. In addition, the first transport path 11 joins at a joining point G located on the downstream side of the paper feeding unit 10. In the transport path of the second transport path 12, a standby unit 40 and an erasing unit 15 are provided in this order. The standby unit 40 includes a standby tray 41, a pickup roller 42 (hereinafter referred to as a standby tray pickup roller) that takes out paper in the standby tray 41, and a measurement sensor 216 (corresponding to a detection unit). The standby unit 40 stacks the paper P on which the image has been read by the first reading unit 13 and the second reading unit 14 in the standby tray 41 and temporarily stores the same. The standby tray pickup roller 42 takes out the paper P one by one from the standby tray 41 and sends it to the erasing unit 15. The measurement sensor 216 detects the amount of paper P stored in the standby tray 41. The measurement sensor 216 is, for example, an infrared sensor. The measurement sensor 216 transmits the detection result to a control unit described later.
As described above, the erasing unit 15 is disposed in the second conveyance path and between the confluence G of the first conveyance path 11 and the second conveyance path 12 and the standby unit 40. The erasing unit 15 includes a roller pair 21, a heater 205 (corresponding to a heat source), and a temperature sensor 217. The heater 205 is provided, for example, in at least one of the rollers constituting the roller pair 21. The roller pair 21 is heated by the heater 205. As a result, the erasing unit 15 erases (discolors) the color material by heating the image of the paper P formed using the image forming material that can be erased by heating to a predetermined temperature (erasing temperature) via the roller. . Further, the heater 205 starts to generate heat in response to a command from the control unit in an erasing mode described later, and preheating control is not performed in the reading mode. The reason is that the sheet P on which the image is read by the reading unit is always temporarily stored in the standby unit, and therefore is not directly conveyed to the erasing unit. The temperature sensor 217 measures the temperature of the roller pair 21. The temperature sensor 217 is disposed in the vicinity of the roller having the heater 205 of the roller pair 21.
The image erasing apparatus 100 performs erasing processing for erasing the color of the image on the paper P on which an image is formed with a color material (recording material) such as erasable toner or erasable ink. Possible colorants include color formers, developers and erasers. Examples of the color developing compound include leuco dyes. Examples of the developer include phenols. Examples of the erasing agent include a substance that is compatible with the color developing compound when heated and does not have an affinity for the developer. The erasable colorant develops color due to the interaction between the color developing compound and the developer, and can be erased because the interaction between the color developing compound and the developer is interrupted by heating above the decoloring temperature. .
FIG. 2 is a block diagram of the image erasing apparatus 100. A CPU (Central Processing Unit) 200 which is a control unit of the image erasing apparatus 100 is connected to a ROM (Read Only Memory) 202, a RAM (Random Access Memory) 203, a reading unit CCD sensor 204, and an erasing unit via a system bus 201. 15 heaters 205, an interface (I / F) 206 for inputting / outputting data to / from an external device such as a client terminal, a path change driving unit 207 for controlling the path changing unit 17, and various rollers. A paper conveyance motor 211, a paper conveyance motor control driving unit 210 for controlling this, an operation unit 212 for inputting various settings, a display unit 213, an HDD 214, a paper feed unit sensor 215, a measurement sensor 216, a temperature sensor 217, a time Timer 218 to keep time It is. The CPU 200, the ROM 202, and the RAM 203 form a control unit.
The ROM 202 stores a program for operating the CPU 200, threshold values (fixed value information), and the like. The paper feed threshold value to be compared with the storage amount of the paper P stored in the paper supply unit 10 measured by the paper supply unit sensor 215, and the storage amount of the paper P stored in the standby tray 41 measured by the measurement sensor 216 The ROM 202 also stores a sheet threshold value to be performed, a temperature threshold value to be compared with the heating temperature of the erasing unit 15, and the like. The temperature threshold is a temperature at which the image on the paper P can be erased by the heat from the roller 21 when the paper P passes through the roller pair 21. The ROM 202 has a time storage area for storing at least one time data. When the time measured by the timer 215 reaches the time stored in this time storage area, the erase mode is automatically selected. The erasing mode is a mode in which the erasing unit 15 erases an image formed on the paper P temporarily stored in the standby tray 41.
Various memory areas such as a work area serving as a work area for data processing by the CPU 200 are dynamically formed in the RAM 203. The RAM 203 has a mode management flag storage area. When the reading mode is selected by the operation unit 212 described later, 0 (zero) is stored in the mode management flag storage area, and 1 is stored when the erasing mode is selected. It is assumed that 0 is stored in the mode management flag storage area by default.
The CCD sensor 204 is an image reading unit (13, 14) and is arranged as a line sensor (two-dimensional scanner), and detects the density of the surface of the paper P. By detecting the density of the surface of the paper P, the image is read or detected. The reading unit is not limited to the CCD sensor, and may be a CMOS sensor.
For example, an induction heating (IH) heater is used as the heater 205. As described above, heat from the heater 205 is indirectly applied to the paper P via the roller pair 21 while the paper P passes through the erasing unit 15 to make the color material colorless. The heater 205 only needs to be temperature-controllable. In addition to the induction heating type heater, for example, a heater lamp such as a halogen lamp may be used.
The operation unit 212 has various setting / instruction keys and is an input unit for inputting various operations. The display unit 213 displays various processing modes of the image erasing apparatus 100. The display unit 213 may be a known touch panel type and may also serve as the operation unit 212. When erasing an image, the operator operates a key of the operation unit 212, for example, presses a selection key provided on the operation unit 212, and selects a reading mode in advance. In the reading mode, after the image of the paper P is read by the first reading unit 13 and the second reading unit 14, the paper P is stored in the standby tray 41. Note that in order to erase the image of the paper P stored in the standby tray 41 at an arbitrary timing, the key of the operation unit 212 may be operated in advance to manually select the erase mode. Further, the operation unit 212 has a start key for starting processing in each mode.
The control unit controls the route change drive unit 207 to drive the route change unit 17 and distribute the paper P from the first transport path 11 to the second transport path 12.
The HDD 214 has a read image storage area for storing an image obtained by reading the paper P before erasure processing. This read image storage area can be accessed from an external terminal through the I / F 206.
Since the paper feed unit sensor 215, the measurement sensor 216, and the temperature sensor 217 have already been described above, a description thereof will be omitted.
In the image erasing apparatus 100 having the above configuration, the control unit executes, for example, a reading job shown in FIG. 3 based on a preset program. It is assumed that the paper P from which the image is erased is already set in the paper feed tray 22. In addition, it is assumed that the operator operates the operation unit 212 and selects the reading mode. In the following processing, it is assumed that the operator presses the start key after operating the operation unit 212 and selecting the reading mode.
First, in ACT1, the control unit determines whether or not the input of the key signal of the start key is detected. When the control unit does not detect the key signal of the start key (ACT1 No), it determines again whether the key signal of the start key has been detected. On the other hand, when the input of the key signal of the start key is detected (Yes in ACT1), the control unit starts conveying the paper P set on the paper feed tray 22 (ACT2). Specifically, the control unit takes out one sheet of paper P set in the paper feed tray 22 using the paper feed tray pickup roller 18. Then, the control unit controls the paper transport motor control driving unit 210 to activate the paper transport motor 211 and drive the transport roller 16 to transport the paper P in the first transport path 11.
The path changing unit 17 allows a path for transporting the paper P from the paper feeding unit 10 to the paper discharging unit 30 as a default position. For this reason, the control unit controls the route change drive unit 207 to drive the route change unit 17 to switch the route so that the sheet P can be conveyed to the second conveyance path 12 via the branch point. As a result, the conveyance path from the second reading unit 14 to the standby unit 40 is connected (ACT 3).
When the conveyance of the sheet P to the first conveyance path 11 is started by the paper feed tray pickup roller 18, the control unit first and second reading units 13 and 2 provided in the first conveyance path 11. 14 is controlled to read the image on the paper P. The control unit stores the read image in the read image storage area of the HDD 214 (ACT 4).
After the first reading unit 13 and the second reading unit 14 read the image of the sheet P, the control unit waits for the sheet P via the branch point between the first conveyance path 11 and the second conveyance path 12. It is conveyed to the standby tray 41 of the section 40 (ACT5).
After storing the paper P in the standby tray 41 of the standby unit 40, the control unit compares the detection result from the paper supply unit sensor 215 with the paper supply threshold value stored in the ROM 202, and the paper supply tray 22 of the paper supply unit 10. It is determined whether or not there is a sheet P (ACT 6). When the control unit determines that there is paper P in the paper supply tray 22 of the paper supply unit 10 (ACT6: Yes), the control unit performs the process of ACT2 again. On the other hand, when the control unit determines that there is no paper P in the paper feed tray 22 of the paper feed unit 10 (ACT 6 No), the path changing unit 17 is driven back to the default position, and the paper is discharged from the paper feed unit 10. A path for conveying the paper P to the section 30 is formed (ACT 7), and the reading job is completed.
Next, the erasing job executed by the control unit based on a preset program will be described. A flowchart of the erase job is shown in FIG. This erasing job is an erasing job for erasing the image on the paper P in the standby tray 41. Further, this erasing job is automatically performed, for example, when a predetermined condition is satisfied when the above-described reading job is not executed. It is assumed that the path changing unit 17 forms a transport path from the paper feeding unit 10 to the paper discharging unit 30 at the default position as described above. Further, it is assumed that when the time measured by the timer 215 reaches the time stored in the time storage area of the ROM 202, the control unit executes the erasing job. As described above, when the control unit selects the erase mode, “1” is stored in the mode management flag storage area of the RAM 203.
First, in ACT 51, the control unit determines whether “1” is stored in the mode management flag storage area of the RAM 203. If it is determined that “1” is not stored in the mode management flag storage area of the RAM 203 (No in ACT 51), the erase job is terminated.
On the other hand, when the control unit determines that “1” is stored in the mode management flag storage area of the RAM 203 (ACT51: Yes), the control unit is accommodated in the standby tray 41 of the standby unit 40 measured by the measurement sensor 216. The amount of the stored paper P is compared with the paper threshold value of the ROM 202, and it is determined whether the stored amount of the standby tray 41 exceeds the paper threshold value as a predetermined condition for starting the erasing process (ACT 52). When the control unit determines that the amount of paper P stored does not exceed the paper threshold (No in ACT 52), the erasing job is terminated. On the other hand, when the control unit determines that the storage amount of the paper P exceeds the paper threshold (ACT 52: Yes), the control unit heats the heater 205 to increase the temperature of the roller pair 21 (ACT 53).
The control unit determines whether the temperature measured by the temperature sensor 217 has reached the temperature threshold (ACT 54). When the control unit determines that the temperature measured by the temperature sensor 217 has not reached the temperature threshold value (No in ACT 54), it waits until the temperature rises to the erasing temperature in ACT 54. In ACT 54, when the control unit determines that the temperature measured by the temperature sensor 217 has reached the temperature threshold value (Yes in ACT 54), the heater 205 is controlled so that the temperature of the roller pair 21 maintains the temperature threshold value (ACT 55).
When the roller pair 21 reaches the erasing temperature, the control unit conveys the paper P stored in the standby tray 41 to the erasing unit 15 (ACT 56). More specifically, the control unit feeds the paper P from the standby tray 41 by the standby tray pickup roller 42, sends it out to the second transport path 12, and transports the paper P to the erasing unit 15. More specifically, the relationship between the erasing temperature of the roller pair 21 and the conveyance of the paper P only needs to be such that the temperature of the roller pair 21 reaches the erasing temperature when the paper P reaches the erasing unit.
The sheet P conveyed to the erasing unit 15 is nipped and conveyed by the roller pair 21 heated by the heater 205. By this conveyance, the image forming material of the paper P reaches a predetermined temperature (erasing temperature) by the heated roller pair 21 and is erased, and as a result, the image is erased (ACT 57).
The control unit further passes through the junction G of the first conveyance path 11 and the second conveyance path 12 upstream of the first reading unit 13 and the second reading unit 14 to the first conveyance path 11. The paper P from which the image has been erased is conveyed. The paper P returned to the first transport path 11 is transported to the paper discharge unit 30 (ACT 58).
When the paper P from which the image has been erased is conveyed to the paper discharge unit 30, the control unit determines whether or not there is the paper P on the standby tray 41 of the standby unit 40 from the detection result of the measurement sensor 216 (ACT 59). When the control unit determines that the sheet P is in the standby tray 41 of the standby unit 40 (ACT 59, Yes), the control unit returns to ACT 53, and the control unit heats the heater 205 to increase the temperature of the roller pair 21. The subsequent processing is as described above. When the control unit determines that there is no paper P in the standby tray 41 of the standby unit 40 (ACT 59: No), the heater 205 is turned off (ACT 60), and the erasing job is terminated.
As described above, in the present embodiment, when erasing an image printed on the paper P, first, the first reading unit 13 and the second reading unit 14 read both sides of the paper P, and then the standby tray 41 reads it. The paper P is accommodated. When the predetermined time has elapsed, the mode automatically shifts to the erasing mode, and if the amount of paper P stored in the standby tray 41 is equal to or greater than the paper threshold stored in the ROM 202, the paper is stored in the standby tray 41. The image P erase process is performed collectively. Conventionally, even when there is only one sheet P on which an image is erased, the image on the sheet P is erased by operating the erasing unit. Normally, in the image erasing apparatus, the process of increasing the temperature of the roller pair 21 by operating the heater 205 consumes the most power. However, when the number of sheets P on which an image is to be erased is small, the heater 205 must be operated and the roller pair 21 must be raised to the erasing temperature each time, so the operation of the erasing unit is inefficient. Even when the image of the paper P is not erased by the eraser, the roller pair 21 needs to be preheated so that the temperature of the roller pair 21 does not drop too much. Even if not, power is consumed by the heater 205. Conventionally, in order to read the image on the paper P, the image on the paper P must be erased. For this reason, when transitioning from a preheated state to an erasable state, the heater 205 generates heat at a higher temperature than usual in order to shorten the transition time from the preheated state to an erasable state. It is necessary and power consumption increases. In contrast, in the present embodiment, first, the first reading unit 13 and the second reading unit 14 read both sides of the paper P. For the operator, the image data of the read paper P may be needed immediately. As a result, it is possible to provide the image information of the paper P that the operator needs immediately without delay. However, there are few cases where the paper P from which the image has been erased is urgently needed. For this reason, if the amount of the paper P temporarily stored in the standby tray 41 is equal to or greater than the paper threshold, the power can be efficiently handled by operating the erasing unit 15 to erase the image of the paper P collectively. . Further, since the paper P is temporarily stored in the standby tray 41 and erased collectively, it is not necessary to preheat the roller pair 21 and the power consumption can be further reduced. Therefore, it is possible to provide an image erasing apparatus with reduced power consumption.
Moreover, in this Embodiment, although the standby part 40 was provided in the 2nd conveyance path 12, it is not limited to this. For example, the first reading unit 13, the second reading unit 14, the standby unit 40, and the erasing unit 15 may be provided in one conveyance path without providing the second conveyance path 12. In this case, the sheet P on which the image is read by the reading unit is always conveyed to the erasing unit 15 via the standby unit. Further, the paper P from which the image has been erased by the erasing unit is directly conveyed to the paper ejection unit.
In this embodiment, as an example of the erasing process, a description has been given of erasing the color of an image by heating. However, the image erasing apparatus described in the present embodiment is not limited to an apparatus that erases the color of an image by heat. For example, a device that erases the color of an image on a sheet by light irradiation or a device that erases an image formed on a special sheet may be used. The image erasing device may be configured so as to make the image on the paper invisible so that the paper can be reused.
As mentioned above, although embodiment of this invention was described, this embodiment is shown as an example and is not intending limiting the range of invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

13 First reading unit
14 Second reading unit
15 Erasing part
30 Paper discharge unit
40 standby section
100 Image erasing device

Therefore, in order to achieve the above-described problem, the following measures are taken in the embodiment of the present invention. An erasing unit for erasing the erasable image formed on a recording medium, a conveying unit that conveys the recording medium along the transport path, and position along the conveying section, to temporarily accommodate a record medium A standby unit, a detection unit that detects the amount of the recording medium temporarily stored in the standby unit, a storage unit that stores a plurality of time data, a timer that counts time, and a time that the timer counts When the same time as the time data stored in the storage unit is reached , it is determined whether the amount of the recording medium detected by the detection unit is equal to or greater than a predetermined amount, and the amount of the recording medium detected by the detection unit is determined. A controller that controls the erasure unit to sequentially convey the recording medium accommodated in the standby unit to the erasure unit and erase the image of the conveyed recording medium when the conveyance unit is equal to or greater than a predetermined amount; An image erasing device having .

Claims (6)

An erasing unit for erasing an erasable image formed on the recording medium;
A transport unit for transporting the recording medium;
A standby unit that temporarily stores a recording medium that is transported by the transport unit and erases an image by the erasing unit;
A detection unit for detecting the amount of the recording medium temporarily stored in the standby unit;
When it is determined that the amount of the recording medium detected by the detection unit has reached a predetermined amount or more, the recording unit sequentially conveys the recording medium accommodated in the standby unit to the erasing unit and conveys the recording A control unit that controls the erasing unit to erase the image on the medium;
An image erasing apparatus. The eraser has a heat source,
The erasable image of the recording medium is formed of a recording material that can be erased by heating,
When the control unit determines that the amount of the recording medium stored in the standby unit is stored in a predetermined amount or more based on the detection result of the detection unit, the control unit heats the erasing unit to a predetermined temperature by the heat source, The image erasing apparatus according to claim 1, wherein the conveyance unit controls the recording medium stored in the standby unit to the erasing unit. A reading unit for reading a recording medium,
The control unit controls the reading unit to read an image of a recording medium, controls the conveying unit to convey the recording medium to the standby unit,
The image erasing apparatus according to claim 1, wherein the standby unit accommodates a recording medium on which an image is read by the reading unit. A paper discharge unit for storing the recording medium from which the image has been erased by the erasing unit;
A path changing unit that is provided on the downstream side of the reading unit and switches between a path to the standby unit and a path to the paper discharge unit;
The image erasing apparatus according to claim 3. A paper feed unit that is provided upstream of the reading unit and feeds a recording medium to the reading unit via the transport unit.
The control unit controls the erasing process of the image of the recording medium stored in the standby unit by the erasing unit so that the recording medium fed from the paper feeding unit is not performed during the reading process by the reading unit. The image erasing apparatus according to any one of claims 3 and 4. An erasing unit for erasing an erasable image formed on a recording medium, a standby unit for temporarily storing a recording medium for erasing an image by the erasing unit, and a recording medium temporarily stored in the standby unit In an image erasing method by an image erasing apparatus comprising: a detection unit that detects an amount; and a transport unit that transports a recording medium from the standby unit to the erasing unit.
The amount of the recording medium accommodated in the standby unit is detected by the detection unit,
When it is determined that the amount of the recording medium is equal to or greater than a predetermined amount, the recording medium accommodated in the standby unit is sequentially conveyed to the erasing unit by the conveyance unit,
An image erasing method for erasing an image on a conveyed recording medium by the erasing unit.

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