JPH0820687B2 - Method of erasing afterimage of stimulable phosphor sheet - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of use] The present invention relates to a method for erasing an afterimage of a stimulable phosphor sheet,
More specifically, for example, a radiation image remaining on a stimulable phosphor sheet such as a long stimulable phosphor sheet is introduced into a short erasing box, and an erasing light source arranged in the erasing box is turned on. The present invention relates to a residual image erasing method for a stimulable phosphor sheet, wherein the erasable image of the stimulable phosphor sheet is erased over the entire image recording surface while intermittently conveying the stimulable phosphor sheet.

BACKGROUND OF THE INVENTION Recently, a radiation image recording / reproducing system that obtains a radiation image of a subject using a stimulable phosphor (stimulable phosphor) has attracted attention. Here, the stimulable phosphor means radiation (X-ray,
Irradiation with α-rays, β-rays, γ-rays, electron beams, ultraviolet rays, etc.) accumulates a part of this radiation energy, and later irradiation with excitation light such as visible light causes stimulated emission according to the accumulated energy. Refers to phosphor.

The above-mentioned radiation image recording / reproducing system uses this stimulable phosphor, and the radiation image information of a subject such as a human body is once provided with a sheet having a layer composed of the stimulable phosphor (hereinafter referred to as “accumulative phosphor sheet” or simply "Sheet")
The stimulable phosphor sheet is scanned with excitation light such as laser light to generate stimulated emission light, and the stimulated emission light is photoelectrically read to obtain an electric signal. A radiation image of the subject is output as a visible image on a recording material such as a photographic material or a display device such as a CRT based on the radiation image. Here, the expression as a visible image on a recording material such as a photographic photosensitive material or a display device such as a CRT as described above is referred to as reproduction.

Therefore, in such a radiation image recording / reproducing system, the following method is specifically adopted to read the radiation image from the stimulable phosphor sheet on which the radiation image is accumulated and recorded.

That is, in the image reading device, the stimulable phosphor sheet is two-dimensionally scanned with a light beam such as a laser beam, and the stimulated emission light emitted by this is time-sequentially detected by a photodetector such as a photomultiplier. Detect and obtain image information. The two-dimensional scanning of the light beam is usually performed one-dimensionally by deflecting and irradiating the stimulable phosphor sheet with the light beam, and performing main scanning, and moving the sheet in a direction substantially orthogonal to the main scanning direction. The paper is mechanically conveyed by a belt conveyor or the like, thereby performing sub-scanning, thereby achieving the above.

By the way, in such a radiation image information recording / reproducing system, the stimulable phosphor sheet temporarily stores the radiation image information in order to give an image to the recording medium as described above, without finally recording the image information. Since the stimulable phosphor sheet is only retained, it may be repeatedly used, and if it is repeatedly used in this way, it is extremely economical and convenient.

Therefore, in order to reuse the stimulable phosphor sheet, the radiation energy remaining in the stimulable phosphor sheet after being read by the irradiation of the excitation light is emitted by the irradiation of the erasing light and the remaining radiation image is displayed. After erasing, this stimulable phosphor sheet may be used again for recording a radiation image.
As described above, various erasing mechanisms have been devised in which an erasing light source is provided to remove the radiation energy remaining on the stimulable phosphor sheet.

In this case, as described above, the erasing light source is arranged inside the erasing mechanism, and the stimulable phosphor sheet conveyed at a predetermined speed is irradiated with the erasing light from the light source so that the stimulable phosphor is The remaining image on the sheet is erased. However, since the radiation energy remaining in the stimulable phosphor sheet needs to be released almost completely, it is necessary to irradiate the stimulable phosphor sheet with erase light for a considerable time. However, when the radiation image recording / reproducing system of this kind is particularly downsized, it is necessary to relatively downsize the erasing mechanism itself. On the other hand, there are various sizes of stimulable phosphor sheets of various sizes depending on the application, and therefore, there is no choice but to use an erasing mechanism that fits the sheets of the maximum size, so it is possible to meet the demand for miniaturization. I have a concern that I cannot do it.

[Object of the Invention] The present invention has been made in order to overcome the above-mentioned inconvenience, and conveys a long storable phosphor sheet by a predetermined amount at a relatively high speed and introduces it into an erasing mechanism. The stimulable phosphor sheet is temporarily stopped so as to face the erasing light source, and the stimulable phosphor sheet is irradiated with erasing light to erase a part of the remaining image. After transporting, this is stopped again and the erasing light is irradiated to erase the image remaining on the other part of the stimulable phosphor sheet, that is, the stimulable phosphor sheet is substantially intermittently transported. While performing the erasing process, the radiation image remaining on the stimulable phosphor sheet can be almost completely erased, and the time spent in the erasing process can be shortened and the entire device can be further improved. Achieved miniaturization It is an object of the present invention to provide a method for eliminating an afterimage of a stimulable phosphor sheet that enables the above.

[Means for Achieving the Purpose] In order to achieve the above-mentioned object, the present invention provides a method of irradiating a stimulable phosphor sheet on which a radiation image is recorded with excitation light to read the radiation image, and then performing the accumulation. A method for erasing a radiation image remaining on a luminescent phosphor sheet, wherein the stimulable phosphor sheet has a light source for erasing and is introduced into an erasing mechanism shorter than the stimulable phosphor sheet, and inside the erasing mechanism. In the irradiation of erasing light to the stimulable phosphor sheet and the intermittent conveyance of the stimulable phosphor sheet are sequentially performed,
Thus, the radiation image remaining on the stimulable phosphor sheet is erased.

Further, the invention is characterized in that the erasing light source which emits the erasing light is energized and turned on only when the image record carrier is stopped in the erasing mechanism.

[Embodiment] Next, a preferred embodiment of the method for erasing the residual image of the stimulable phosphor sheet according to the present invention in relation to an image reading / reproducing apparatus for carrying out the method will be given and described in detail below with reference to the accompanying drawings. explain.

In FIG. 1, reference numeral 10 indicates an image reading / reproducing apparatus, the image reading / reproducing apparatus 10 includes a housing 12 extending substantially in a vertical direction, and the inside of the housing 12 includes a first A loading section 16 and a second loading section 18 are provided. The first loading section
The stimulable phosphor sheet S is loaded into the cassette 16 via a cassette 20 or a sheet magazine (not shown), and the film F can be loaded into the second loading section 18 via a film magazine 22. The first loading unit 16 is provided with a lid opening mechanism including a suction disk 24, and the suction disk 24 functions to suck and open the lid member 25 of the cassette 20. Further, on the side of the first loading unit 16 where the stimulable phosphor sheet S is taken out, a sheet-feeding mechanism including a suction plate 26 is provided. The stimulable phosphor sheet S separated by the suction plate 26 constituting the single-wafer mechanism is separated into single sheets along a predetermined track, and then the first conveying means
Supplied to 28. The first conveying means 28 is substantially composed of a pair of rollers 30. The pair of rollers 30 is displaceable in a direction of approaching the suction plate 26 for sandwiching the stimulable phosphor sheet S, and the sandwiched storability is maintained. The phosphor sheet S can be displaced in a direction away from the suction plate 26 in order to feed the phosphor sheet S to the second conveying means 32.

The second conveying means 32 includes a large-diameter drum 34 and the drum 34
The first conveyor belt 36 slidably contacting with the first conveyor belt 36 and the second conveyor belt 38 composed of a plurality of belt-shaped endless belts arranged at a predetermined interval. The first conveyor belt 36 is suspended by three rollers as shown in the drawing, and a part of the first conveyor belt 36 is in sliding contact with the drum 34. On the other hand, the second conveyor belt 38 extends vertically from a portion in sliding contact with the drum 34, then extends at a right angle and extends horizontally along the inner surface of the upper wall of the housing 12. are doing. A large-diameter roller 40 is arranged at the bent portion to substantially secure the bent state. A first switching guide member 42 is arranged at a sliding contact portion between the second conveyor belt 38 and the drum 34, and a third conveyor belt 44 is slidably contacted at a vertical portion of the second conveyor belt 38. A guide plate 46 is arranged below the horizontal portion.

Therefore, an erasing mechanism 47 is arranged near the horizontal portion of the second conveyor belt 38.

As shown in FIGS. 1 and 2, the erasing mechanism 47 is slightly separated from the first optical sensor 48 disposed near the horizontal tip of the second conveyor belt 38 and the second conveyor belt 38. The first optical sensor 48 including a pair of rollers 50 arranged as
Is composed of an issuing unit 48a and a light receiving unit 48b. A roller pair 52 is disposed near the roller pair 50, and the roller pair 52
A guide plate 60 having a bent shape and a housing 62 are arranged close to the. An erasing light source 64 such as a sodium lamp, a tungsten lamp, or a xenon lamp is provided in the housing 62, and a guide plate is driven by the roller pair 50, 52.
The stimulable phosphor sheet S guided and conveyed by 60 is irradiated with erasing light from the erasing light source 64. Further, a roller pair 66 is arranged on the downstream side of the guide plate 60 and the casing 62. In this case, the roller pair 66 functions together with the roller pair 52 to prevent the erasing light emitted from the erasing light source 64 from leaking to the outside.

A second optical sensor 68 is arranged close to the roller pair 66, and the second optical sensor 68 has an issuing unit 68a and a light receiving unit 68b. Incidentally, the first optical sensor 48 and the second optical sensor 68
Detects that the stimulable phosphor sheet S has been conveyed to the area where these are arranged, and sends the detection signal to a control unit or the like (not shown). The control unit stops the carrying work after a predetermined time has elapsed after detecting that the stimulable phosphor sheet S has reached the portion where the first optical sensor 48 or the second optical sensor 68 is arranged, by the detection signal. By doing so, the stimulable phosphor sheet S is configured to be stopped at a predetermined site.

A roller pair 70 is disposed below the second optical sensor 68, and a pair of short guide plates 72 are arranged close to the roller pair 70.
a and 72b are provided. The guide plates 72a and 72b are trays 74
In view of the above, the tray 74 is a mechanism for reading and erasing image information for a plurality of stimulable phosphor sheets S that are stacked and stored in the sheet magazine when the sheet magazine is loaded in the first loading section 16. This is for accommodating the stimulable phosphor sheet S after the work of erasing the image information in 47 is completed.

On the other hand, below the second transport means 32 is a third transport means.
A guide plate 78 that constitutes 76 is provided, and a roller pair 80 is arranged near the lower end portion of the guide plate 78. Further, an auxiliary erasing mechanism 82 is provided near the third carrying means 76.

A fourth conveying means 84 is provided below the roller pair 80. That is, the fourth conveying means 84 has a relatively long fourth conveying belt 86 extending vertically downward and a short fifth conveying belt slidably contacting the upper side of the fourth conveying belt 86. A belt 88 and a sixth conveyor belt 90 that slidably contacts the lower side of the fourth conveyor belt 86 are included. A roller 92 having a relatively large diameter is in sliding contact with an intermediate portion of the fourth conveyor belt 86, and
A second switching guide member 94 is arranged near the roller 92. In this case, by driving the second switching guide member 94 and oscillating and displacing it to a portion indicated by a broken line in the drawing, the tip end thereof can be exposed to the roller pair 96.
In fact, the stimulable phosphor sheet S conveyed by the fourth conveying means 84 can be introduced into the stacker 98 via the roller pair 96.

The stacker 98 is configured to be movable in the direction of arrow A under the action of a motor or the like (not shown), and has a sheet receiving portion 100 in which a plurality of stimulable phosphor sheets S fed by the roller pair 96 are arranged in parallel. , And can be stored in a desired sheet receiving portion 100. Further, the stimulable phosphor sheet S stored in the stacker 98 is fed to the fourth conveying means 84 via the roller pair 96 and the guide member 94.

A pair of movable guide plates 102a and 102b are arranged at a distance from the tip end portions of the fourth conveyor belt 86 and the sixth conveyor belt 90 that form the fourth conveyor means 84. In this case, the movable guide plates 102a and 102b can integrally swing about a fulcrum 104 made of a pin member. The movable guide plates 102a, 102b
The lower end of the roller faces the roller pair 106, and a pair of curved guide plates 108a, 108 is provided below the roller pair 106.
b is provided. The guide plates 108a and 108b are for guiding the stimulable phosphor sheet S and the film F to the sub-scan transporting means 110.

The sub-scanning transporting unit 110 includes an endless sub-scanning transport belt 112 having a plurality of holes (not shown), a stimulable phosphor sheet S and a film F transported by the sub-scanning transport belt 112. It is composed of a first suction box 114 and a second suction box 116 for sucking toward the sub-scanning transport belt 112 side through the holes. The first suction box 114 and the second suction box 116 are connected to a vacuum pump or the like (not shown). The sub-scanning conveyance belt 112 is provided with a guide plate 108.
The stimulable phosphor sheet S and the like supplied from the sides a and 108b are once conveyed to the guide plate 118 side and then are sub-scanned in the opposite direction to the above. At that time, a roller 120 is disposed near the guide plate 118 to prevent the storage phosphor sheet S and the like from being lifted up due to bending.

A stimulable phosphor sheet S is provided above the sub-scan transporting means 110.
An image reading and recording mechanism for reading the image information recorded on the film and exposing the read image information on the film F.
122 is provided. The image reading / recording mechanism 122 includes a laser light source 124, and a mirror 128 for reflecting the laser light 126 is provided on the laser light output side of the laser light source 124. The laser light 126 reflected by the mirror 128 is a light beam. Modulator
It passes through 130 and reaches the mirror 132. In this case, the light modulator 130 is driven only when an image is recorded on the film F, and is not driven when the image of the stimulable phosphor sheet S is read. Further, a galvanometer mirror 134 and a converging reflection mirror 136 for scanning the stimulable phosphor sheet S with the laser light 126 reflected by the mirror 132 are provided.

A light guide 138 is arranged along the main scanning line at the scanning position of the laser light 126 on the stimulable phosphor sheet S, and a photomultiplier 140 is mounted on the light guide 138. An image information processing circuit 142 is connected to the photomultiplier 140. Therefore, the electric signal obtained by the photomultiplier 140 is transferred to the image information processing circuit 142.
After the image processing is performed, the image data is stored in a storage unit (not shown). In this case, the stimulable phosphor sheet S whose image has been read under the action of the image reading / recording mechanism 122 is erased through the fourth conveying means 84, the third conveying means 76, the second conveying means 32, etc. Delivered to 47.

On the other hand, the second loading section 18 includes the detachable magazine 22 for storing the film F, as described above. A single-wafer mechanism including a suction board 144 is arranged near the film extraction opening of the magazine 22. The suction board 144 is a magazine 22.
The film F laminated inside is sheet-fed and supplied to the roller pair 146. A pair of guide plates 148a, 1a facing the roller pair 146 and slightly separated from the roller pair 146.
48b is provided. One ends of the guide plates 148a and 148b face the guide plates 102a and 102b, and the film F supplied to the roller pair 146 is conveyed between the movable guide plates 102a and 102b under the driving action of the roller pair 146. Will be.
Further, the film F is conveyed in the sub-scanning direction (direction of arrow C ₂ ) in substantially the same manner as the stimulable phosphor sheet S, and is read from the stimulable phosphor sheet S via the image reading / recording mechanism 122. The light modulator 130 is driven based on the image information to modulate the laser light 126, and the image for reproduction is exposed. The film F exposed with the image is a roller pair.
After being conveyed to the 106 side, the movable guide plates 102a and 102b are configured to be guided by the film conveying means 150 arranged substantially parallel to the fourth conveying means 84 under the swinging action.

The film transporting means 150 includes roller pairs 152, 154, 156 and 158 which are arranged at a predetermined interval, and a pair of guide plates 160a and 160b are arranged between the roller pairs 152 and 154. To be done. Further, a pair of guide plates 162a, 162b is arranged between the roller pairs 154 and 156, and a pair of curved guide plates 164a, 164b is arranged between the roller pairs 156 and 158. . The roller pair 158 is arranged in the vicinity of the opening 166 provided on the side surface of the housing 12 that constitutes the image reading / reproducing apparatus 10, and the film F conveyed through the film conveying means 150 is The housing 12 through the opening 166
It is delivered to a receive magazine 168 which is detachably attached to.

The image reading / reproducing apparatus for carrying out the residual image erasing method for the stimulable phosphor sheet according to the present invention is basically constructed as described above. Next, its operation and effect will be explained.

First, the first loading unit 16 of the image reading / reproducing apparatus 10 is loaded with the cassette 20 containing the stimulable phosphor sheet S or a sheet magazine (not shown). In this case, in the present embodiment, the cassette 20 is loaded in the first loading section 16. Therefore, in actual operation, the lid member of the cassette 20 is used.
The lid 25 is opened by suction and held by a suction disk 24 constituting a lid opening mechanism.

Next, the stimulable phosphor sheet S accommodated in the opened cassette 20 is sheet-leaved by the suction plate 26 constituting the sheet-feeding mechanism, and the roller pair 30 constituting the first transport means 28 is attracted by the suction. Displace to the board 26 side. At this time, the roller pair 30
Is driven to rotate in the direction of the arrow. As a result, the stimulable phosphor sheet S is sandwiched between the roller pairs 30, and the stimulable phosphor sheet S is displaced toward the first transport belt 36 constituting the second transport means 32, whereby the stimulable phosphor sheet S is It is fed to the second transport means 32. In the second conveying means 32, the stimulable phosphor sheet S is sandwiched between the drum 34 and the first conveyor belt 36, then sandwiched between the drum 34 and the second conveyor belt 38, and fed to the third conveyor means 76. To be done. Further, the stimulable phosphor sheet S is fed from the roller pair 80 constituting the third conveying means 76 between the fourth conveying belt 86 and the fifth conveying belt 88 of the fourth conveying means 84. At that time, the second switching guide member 94 is oscillated and displaced in the direction shown by the broken line in FIG. 1, and the stimulable phosphor sheet S is stored in the sheet receiving portion 100 of the stacker 98 via the roller pair 96. Next, the stacker 98 is displaced upward or downward in the direction of arrow A to select the stimulable phosphor sheet S previously stored in the stacker 98 and having another image recorded thereon, and the stimulable phosphor sheet S is first transferred through the roller pair 96. The sheet is fed to the fourth transport means 84 and is transported downward by the fourth transport means 84. In this case, the movable guide plates 102a and 102b are kept in a state of being swung in the direction of arrow B ₁ about the fulcrum 104 under the driving action of a driving source (not shown). Therefore, the stimulable phosphor sheet S is supplied into the gap defined by the movable guide plates 102a and 102b. The stimulable phosphor sheet S taken out from the cassette 20 is directly moved by the fourth conveying means 84 to the movable guide plate 102a,
Of course, it may be sent between 102b.

The stimulable phosphor sheet S fed between the movable guide plates 102a and 102b is nipped by a roller pair 106, and the roller pair 1
Under the driving action of 06, it is transferred to the sub-scanning conveyance means 110 via the guide plates 108a and 108b. In the sub-scanning conveyance means 110, the stimulable phosphor sheet S is conveyed to the sub-scanning conveyance belt 112
Is conveyed in the direction of arrow C ₁ under the action of, and is once fed onto the guide plate 118. When the rear end side of the stimulable phosphor sheet S passes through the scanning portion of the image reading / recording mechanism 122, the sub-scanning conveyance belt 112 is rotationally driven in the opposite direction to the arrow of the stimulable phosphor sheet S. Displace in the C ₂ direction. At that time, a vacuum pump (not shown) is driven, and one end side of the stimulable phosphor sheet S is suction-held by the first suction box 114 and the second suction box 116 toward the sub-scanning transport belt 112.

In this way, the stimulable phosphor sheet S is conveyed in the direction of the arrow C ₂ , and the image reading / recording mechanism 122 is driven so that the laser light 126 emitted from the laser light source 124 is reflected by the mirrors 128, 1.
It is reflected by 32 and made to reach the galvanometer mirror 134, and the laser beam 126 is scanned on the stimulable phosphor sheet S in the main scanning direction under the swinging action of the galvanometer mirror 134. At that time, the optical modulator 130 is not driven. This is because it is used for image recording. As a result, the stimulated emission light emitted from the stimulable phosphor sheet S is incident on the light guide 138 directly or via the reflection mirror 136, converted into an electric signal by the photomultiplier 140 and sent to the image information processing circuit 142. To pay. In this way, the stimulable phosphor sheet S has the laser light 126
Will be scanned two-dimensionally.

The stimulable phosphor sheet S for which image reading and scanning has been completed in this way is fed between the movable guide plates 102a and 102b via the guide plates 108a and 108b and the roller pair 106. In this case, similarly to the above, the movable guide plates 102a and 102b are left in a state of being oscillated and displaced in the arrow B ₁ direction, and the movable guide plates 102 are
The stimulable phosphor sheet S is guided between the fourth conveyor belt 86 and the sixth conveyor belt 90 constituting the fourth conveyor means 84 by a and 102b, and is conveyed upward by the fourth conveyor means 84. .

Further, the stimulable phosphor sheet S is transferred to the third conveying means 7
6. After being conveyed upward through the second conveying means 32, it is bent at a substantially right angle and conveyed, and reaches the erasing mechanism 47.

In the erasing mechanism 47, the stimulable phosphor sheet S is nipped by the pair of rollers 50 and 52, conveyed by a predetermined amount at a relatively high speed, and then stopped. At this time, the positioning of the stimulable phosphor sheet S is substantially performed after a predetermined time has passed since the stimulable phosphor sheet S passed between the light emitting portion 48a and the light receiving portion 48b of the first optical sensor 48. This is achieved by stopping the transportation of the stimulable phosphor sheet S. That is, the first
When the stimulable phosphor sheet S conveyed between the light emitting portion 48a and the light receiving portion 48b of the optical sensor 48 enters, the first optical sensor 48 detects the stimulable phosphor sheet S, and the detection signal thereof is not shown in the figure. To send to. In the control unit (not shown), the conveyance of the stimulable phosphor sheet S is stopped after a lapse of a predetermined time after the detection signal is sent, that is, the leading end portion is nipped by the roller pair 66. Roller 50 at the time,
Stop 52 etc. As a result, the stimulable phosphor sheet S is positioned and stopped with a part of it facing the erasing light source 64.

Then, the erasing light source 64 that constitutes the erasing mechanism 47 is turned on, and the erasing light is applied to the stimulable phosphor sheet S for a predetermined time to erase the image information remaining therein. That is,
Since the stimulable phosphor sheet S is relatively long, the erasing light is applied only to a part of the stimulable phosphor sheet S, and thus only a part of the remaining image information is erased. Reach the state. Therefore, the stimulable phosphor sheet S is conveyed again by the roller pairs 50 and 52 and the roller pair 66, and is held between the roller pair 70 and stopped at a predetermined portion. At that time, the stimulable phosphor sheet S detects that the stimulable phosphor sheet S has reached between the light emitting portion 68a and the light receiving portion 68b that form the second optical sensor 68, and performs substantially the same as above. After a lapse of a predetermined time, the transportation of the stimulable phosphor sheet S is stopped. Then, the erasing light is applied to the portion of the stimulable phosphor sheet S facing the present erasing light source 64. As a result, the image information remaining on the stimulable phosphor sheet S is erased. While achieving intermittent feeding of the stimulable phosphor sheet S, the image remaining on the stimulable phosphor sheet is almost completely erased. In addition, during this intermittent feeding, it is natural that no problem will occur even if a part of the stimulable phosphor sheet is irradiated with the erasing light twice in the previous erasing step and the current erasing step. is there.

Then, the stimulable phosphor sheet S from which the image information has been erased by the erasing mechanism 47 is again conveyed downward by the second conveying means 32 and is conveyed to the third conveying means 76. In this case, the second switching guide member 94 constituting the fourth conveying means 84 is kept in a state of being swung in the direction shown by the broken line in the figure, and the stimulable phosphor sheet S is moved to the second switching guide member 9
4. Stored in the sheet receiving portion 100 of the stacker 98 via the roller pair 96. At this time, the stimulable phosphor sheet S from which the image information has been erased by the erasing mechanism 47 is transferred in the opposite direction from the state of being sandwiched by the fourth conveyor belt 86 and the fifth conveyor belt 88 without being stored in the stacker 98, Of course, it can be directly stored in the cassette 20. Also, the first loading unit
When the magazine is loaded in 16, the stimulable phosphor sheet S from which the image information has been erased is stored in the tray 74 arranged below the erasing mechanism 47.

As described above, the stimulable phosphor sheet S in which the image information has been erased, which is stored in the predetermined sheet receiving portion 100 of the stacker 98 in advance, is carried into the cassette 20 from which the stimulable phosphor sheet S has been taken out. It That is, the stacker 98
Is displaced in the direction of arrow A so that the stimulable phosphor sheet S from which the image has been erased faces the roller pair 96. Then, if this stimulable phosphor sheet S is sent out from the right side of the drawing, the roller pair 96 holds it and sends it to the fourth conveying means 84.
The stimulable phosphor sheet S fed to the fourth transport means 84 is transported upward and reaches the third transport means 76.
Therefore, after the image remaining on the stimulable phosphor sheet S is completely erased by the auxiliary erasing mechanism 82 provided in the vicinity of the third conveying means 76, it is conveyed to the second conveying means 32. At this time, the first switching guide member 42 constituting the second conveying means 32 is oscillated and displaced to a portion indicated by a broken line in the drawing. Accordingly, the stimulable phosphor sheet S is guided by the first switching guide member 42 and is sandwiched by the pair of rollers 30 constituting the first transport unit 28 via the first transport belt 36. Then, the roller pair 30 is displaced toward the cassette 20 and is rotated together with the arrow in the direction opposite to the arrow to store the stimulable phosphor sheet S in the cassette 20.

On the other hand, when the stimulable phosphor sheet S is fed from the sub-scanning transporting means 110 to the fourth transporting means 84 via the roller pair 106, the sheet-fed mechanism arranged near the second loading section 18 is The magazine 1 is driven by the suction plate 144 that constitutes the single-wafer mechanism.
The film F that is stacked and stored in 8 is separated. The film F separated by the suction plate 144 is sandwiched by the roller pair 146, and the guide plate 148 is driven by the driving operation of the roller pair 146.
It is fed between the movable guide plates 102a and 102b via a and 148b. Further, like the stimulable phosphor sheet S, the film F is nipped and conveyed by the roller pair 106 and guided by the guide plate 108.
It is fed to the sub-scan transporting means 110 via a and 108b. The film F conveyed to the sub-scanning conveying means 110 is conveyed in the direction of arrow C ₁ under the action of the sub-scanning conveying belt 112, and is once conveyed to the guide plate 118 side. Next, the sub-scanning transport belt 112 is rotationally driven in the opposite direction to transport the film F in the direction of arrow C ₂ . At that time, like the stimulable phosphor sheet S, the film F is transferred under the action of the suction boxes 114 and 116 while being attracted to the sub-scanning transport belt 112 side.

When the film F is transported in the direction of arrow C ₂ , the image reading / recording mechanism 122 is driven again. That is, the laser light 126 emitted from the laser light source 124 is reflected by the mirror 128 and reaches the optical modulator 130. Here, in the light modulator 130, the stimulable phosphor sheet S processed by the image information processing circuit 142 and stored in a storage unit (not shown).
The image signal data of is sent. Therefore, the optical modulator
The laser beam 126 that has reached 130 is modulated by the optical modulator 130 based on the image signal data, and the modulated laser beam 126 is reflected by the mirror 132 and reaches the galvanometer mirror 134. Thus, the laser beam 126 that has reached the galvanometer mirror 134 is deflected in the main scanning direction under the swinging action thereof and is applied to the film F.
In this way, the film F is conveyed in the sub-scanning direction and is scanned by the laser beam 126 in the main scanning direction, so that the image read from the stimulable phosphor sheet S is exposed on the film F. Reach It should be noted that the photomultiplier 140 is kept in a deenergized state during the work of exposing an image on the film F.

The film F after completion of the image exposure is the sub-scanning conveying means 11
It is transferred from 0 to the movable guide plates 102a and 102b via the guide plates 108a and 108b and the roller pair 106. In this case, the movable guide plates 102a and 102b are oscillated and displaced in the arrow B ₂ direction under the driving action of a motor (not shown). When the movable guide plate 102a, 102b is swung in the arrow B ₂ direction, the film F is transported to the film conveyance means 150 side by operation of the roller pair 106, is nipped by the roller pair 152 which constitutes this It Film F sandwiched by the pair of rollers 152
Is conveyed upward under its driving action, and further, the roller pair
After being conveyed through the rollers 154 and 156, the rollers 158 and the opening 166 are guided by the guide plates 164a and 164b so as to be curved.
Is delivered to the receive magazine 168 via. Therefore, after a predetermined number of films F are stored in the receive magazine 168, the receive magazine 168 may be removed from the housing 12 in a light-shielded state, and the film F may be loaded into a developing device (not shown) for development processing. .

In this case, according to this embodiment, when erasing the image information remaining on the stimulable phosphor sheet S that has been read, the stimulable phosphor sheet S is intermittently fed,
That is, the erasing light is emitted after being stopped substantially. In other words, the stimulable phosphor sheet is the erase mechanism 47.
When the first photosensor 48 detects that the stimulable phosphor sheet S has been reached, the stimulable phosphor sheet S is stopped at a predetermined position after being conveyed at a relatively high speed for a predetermined time. Then, the erasing light source 64 constituting the erasing mechanism 47 is turned on and the erasing light is applied to the stimulable phosphor sheet S for a predetermined time to erase the image information remaining at that portion.
Next, the stimulable phosphor sheet S is conveyed again at a relatively high speed, and another portion of the stimulable phosphor sheet S is erased as a light source.
The stimulable phosphor sheet S is stopped by facing 64. At this time, the stimulable phosphor sheet S is positioned at a desired portion by detecting that the tip of the stimulable phosphor sheet S has reached the second optical sensor 68 and stopping it after a lapse of a predetermined time.
Then, in the same manner as above, the erasing light is irradiated to erase the image remaining on the stimulable phosphor sheet S. Therefore, the image information of the stimulable phosphor sheet S is erased as compared with the conventional method of erasing the image information while conveying the stimulable phosphor sheet S in the erasing mechanism 47 at a considerably low speed. The time spent to do this can be reduced considerably.
That is, in erasing while conveying, from immediately after the front end of the stimulable phosphor sheet S is introduced into the erasing mechanism 47 until the rear end of the stimulable phosphor sheet S is led out from the erasing mechanism 47. It is necessary to activate the erasing light source 64. Therefore, when the stimulable phosphor sheet S is introduced and led out, the erasing light is emitted in a state where the stimulable phosphor sheet S is hardly present in the erasing mechanism 47, and the erasing light is effectively used. This is because, if the total amount of light is equal, the erasing time becomes longer than that in the intermittent erasing.
As a result, the erase operation can be efficiently performed.
Moreover, even if the size of the stimulable phosphor sheet is large or small, the erasing mechanism can be downsized because it can be erased regardless of the size.

[Advantages of the Invention] As described above, according to the present invention, after the image information recorded on the stimulable phosphor sheet is read, the accumulation is performed when the image information remaining on the stimulable phosphor sheet is erased. Of the luminescent phosphor sheet at a relatively high speed to stop it at a predetermined position, and then the erasable light is irradiated to the stimulable phosphor sheet for a predetermined time to erase an afterimage, and then transported at a relatively high speed again. This is stopped at a predetermined site, and the image information remaining in other sites is erased. In this way, since the stimulable phosphor sheet is fed at high speed during transportation, the time spent for erasing the radiation image remaining on the stimulable phosphor sheet can be considerably shortened, and as a result, the erasing operation can be performed. Can be efficiently performed.

Moreover, as described above, since the erasing mechanism can be downsized, the device as a whole can be made more compact.

Although the present invention has been described above with reference to the preferred embodiments, the present invention is not limited to these embodiments, and various improvements and design changes can be made without departing from the scope of the present invention. Of course.

[Brief description of drawings]

FIG. 1 is a schematic explanatory view of an image reading / reproducing apparatus for carrying out a residual image erasing method of a stimulable phosphor sheet according to the present invention, and FIG. 2 is an enlarged explanatory view of a main part of the image reading / reproducing apparatus shown in FIG. . 10 …… Image reading / reproducing device, 16, 18 …… Loading section 28, 32 …… Conveying means, 47 …… Erase mechanism 48 …… Optical sensor, 62 …… Housing 64 …… Erase light source, 68 …… Light Sensors 76, 84 ... Transporting means, 98 ... Stacker 110 ... Sub-scanning transporting means 122 ... Image reading / recording mechanism

Claims (2)

[Claims] 1. A stimulable phosphor sheet having a radiation image recorded thereon is irradiated with excitation light to read the radiation image,
A method of erasing a radiation image remaining on the stimulable phosphor sheet, wherein the stimulable phosphor sheet has a light source for erasing and is introduced into an erasing mechanism shorter than the stimulable phosphor sheet, and the erasing is performed. In the mechanism, irradiation of erasing light to the stimulable phosphor sheet and intermittent conveyance of the stimulable phosphor sheet are sequentially performed, thereby erasing the radiation image remaining on the stimulable phosphor sheet. Method for erasing residual storage phosphor sheet. 2. The stimulable phosphor sheet according to claim 1, wherein the erasing light source for erasing light is energized only when the image record carrier is stopped in the erasing mechanism. Remaining elimination method.