JPH0662319A - Radiograph information recording and reading device - Google Patents

Abstract

PURPOSE:To reutilize stimulable phosphor for recording radiographs in circulation, to easily obtain homogeneous reproduced pictures repeatedly and to facilitate designing, manufacture, management and moving in a radiograph information recording and reading device. CONSTITUTION:This device is provided with a picture recording part for fixing a recording body 2 composed of a stimulable phosphor layer on a supporting body 1, irradiating the recording body 2 with radioactive rays through an object 6 and storing and recording the radiation transmitted pictures of the object, a picture reading part provided with photoelectric reading means 9 and 10 for scanning the recording body by excitation light, reading emitted stimulating phosphorescent light and obtaining picture signals, a means for moving the recording part and the reading part relatively to the recording body and an eliminating means 11 for releasing radiation energy remaining in the recording body after reading.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention accumulates and records radiation image information in a stimulable phosphor, then irradiates it with excitation light, and detects the light that stimulates emission in accordance with the accumulated and recorded image information. The present invention relates to a radiation image information recording / reading device which reads image information by converting it into an electric signal and then converts the read image information into a visible image for reproduction, and more specifically, a stimulable fluorescent material is circulated and regenerated in the device. The present invention relates to a radiation image recording / reading device used.

[0002]

2. Description of the Related Art Radiation (X-rays, α-rays,
When β-rays, γ-rays, ultraviolet rays, etc.) are irradiated, a part of the energy of this radiation is accumulated in the phosphor, and then when the phosphor is irradiated with excitation light such as visible light, the accumulated energy Accordingly, the phosphor exhibits stimulated emission. A phosphor exhibiting such a property is called a stimulable phosphor.

Using this stimulable phosphor, radiation image information of the human body or the like is once recorded on a sheet of the stimulable phosphor, and this is scanned with excitation light to cause stimulated emission, and this stimulated emission is performed. A method has been proposed in which light is photoelectrically read to obtain an image signal, and the image signal is processed to obtain an image with good diagnostic suitability (for example, JP-A-55-12429, JP-A-56-11395, and JP-A-55-11395). ‐163472
No. 56-104645, No. 55-116340, etc.). This final image may be reproduced as a hard copy or may be reproduced on a CRT. Anyway, in such a radiographic image information recording / reproducing method, various forms such as a stimulable phosphor sheet (strictly speaking, a panel-shaped sheet or a drum-shaped sheet can be adopted, The term “sheet” does not record image information in the end, but temporarily carries image information to give an image to the final recording medium as described above. The phosphor sheet may be used repeatedly, and if it is used repeatedly, it is very economical.

In order to reuse the stimulable phosphor sheet as described above, the radiation energy accumulated in the stimulable phosphor sheet after the stimulated emission light has been read is used, for example, in Japanese Patent Laid-Open No. Sho 56-56.
No. 11392, No. 56-12599, the radiation image is erased by the method as described in Nos. 11392 and 56-12599, and the stimulable phosphor sheet is reused for recording the radiation image.
In an actual device, the stimulable phosphor sheet after completion of reading is supplied to an image erasing device by a conveying means such as a belt conveyor, and the stimulable phosphor sheet from which the radiation image has been erased is further processed as described above. It is also possible to save the labor by returning the image to the image recording section by using a proper conveying means.

[0005]

However, it is extremely difficult to design and manufacture a transporting means capable of transporting a sheet-like substance such as the above-mentioned accumulative phosphor sheet without causing troubles such as clogging and catching. Have difficulty. Furthermore, it is needless to say that the above-mentioned accumulative phosphor sheet should not be damaged during transportation, such as scratches, and this also makes the design and manufacture of the above-mentioned transportation means difficult. Also, for example, a certain sheet is reproduced immediately after recording, a certain sheet is once stored after recording, and is collectively reproduced with another series of sheets,
When such a thing is performed, the order of use of the sheets becomes completely unequal, and the sheets returned to the image recording unit are gradually mixed with new ones and old ones. When new sheets and old sheets are mixed in this way, the image quality of the reproduced image varies depending on the sheets used, and it becomes impossible to obtain a uniform reproduced image. Therefore, it is desirable to replace old sheets with new ones as needed. In order to perform such sheet replacement, the quality of the reproduced image of each sheet is inspected or the number of times of use is controlled. However, it is then necessary to decide whether to replace the seat with a new one or to continue using it. In this way, quality control of each sheet is extremely troublesome.

In addition, when a mobile station such as an X-ray radiographing machine is equipped with such a radiographic image information recording / reading apparatus and travels to various places for a mass examination to take X-rays. Since the amount of recording material that can be loaded in a car is limited, a large number of sheets or panels of accumulative phosphors that are relatively large (such as the size of a conventional X-ray film cassette) can be loaded in multiple cars. Instead, it is equipped with a stimulable phosphor sheet that can be used repeatedly, and the image signals recorded and read for each subject are transferred to a recording medium with a large storage capacity, such as a magnetic tape, and the stimulable phosphor sheet, etc. If it is circulated and reused, a radiographic image of a large number of subjects can be taken by a moving vehicle, which is extremely useful in practice.

In particular, a reusable recording body made of a stimulable phosphor, an image recording section for irradiating the recording body with radiation through a subject, an image reading section for reading an image stored and recorded on the recording body, and If the elements that compose this device, such as the erasing means for releasing the radiation energy remaining in the recording medium after reading and preparing for the next recording, are combined into one device, this is mounted on a mobile vehicle and circulated for medical examination. It is easy to install and easy to install in a hospital, etc., which is practically convenient.

The present invention has been made in view of the above circumstances, and a stimulable phosphor for recording a radiation image can be circulated and reused, and a uniform reproduced image can be easily obtained repeatedly. In addition, it is an object of the present invention to provide a radiation image information recording / reading device which is easy to design, manufacture, manage and move.

[0009]

A radiographic image information recording / reading apparatus according to the present invention has a recording medium composed of a stimulable fluorescent material layer fixed on a support, and the recording medium is irradiated with radiation through the object to be photographed. An image recording section for accumulating and recording a radiation transmission image, an image reading section having a photoelectric reading means for scanning the recording medium with excitation light and reading emitted stimulated emission light to obtain an image signal, and after reading An erasing unit having an erasing unit for releasing the radiation energy remaining on the recording medium, and a unit for moving the recording unit, the reading unit, and the erasing unit relative to the recording medium. It is what

The apparatus of the present invention performs a reading operation and subsequent erasing. The image signal obtained by the reading operation may be temporarily stored in a storage medium such as a magnetic tape or a magnetic disk. It may be displayed on a display such as a CRT or the like for immediate observation, or may be made into a hard copy for permanent recording. A reproducing device for this purpose may be directly connected to the above device, or may be reproduced once at a distance via a storage device,
Alternatively, it may be placed at a remote place and wirelessly receive a signal for reproduction. In this way, for example, an image taken by a mobile vehicle can be reproduced by a receiver / reproducer of a hospital, and a specialist can observe the image and wirelessly report the diagnosis result to the mobile vehicle.

[0011]

In the radiation image information recording / reading apparatus of the present invention having the above-mentioned structure, the stimulable phosphor for recording the radiation image is fixed on the support and is circulated for use. As compared with the body sheet used independently, it is circulated and reused in order, so that a stable and homogeneous reproduced image is always obtained, and there is little risk of damage. In addition, if the quality of the fluorescent substance deteriorates, it is sufficient to replace it with a new one all at once, so quality control is easy.
Further, since the fluorescent body is installed in the apparatus, the fluorescent body is easy to handle and the apparatus is easy to operate. In addition, the device can be easily moved and is practically easy to use.

In the present invention, the stimulable phosphor means that when it is irradiated with radiation (X-rays, α-rays, β-rays, γ-rays, ultraviolet rays, etc.), a part of this radiation energy is stored inside, and When it is irradiated with excitation light such as visible light, it has the property of emitting stimulated emission light in an amount corresponding to the stored energy.

In the present invention, it is preferable that the wavelength region of the excitation light and the wavelength region of the stimulated emission light do not overlap in order to improve the S / N ratio, and the excitation light source and the excitation light source so as to satisfy such a relationship. It is preferred to select a stimulable phosphor. Specifically, it is desirable that the excitation light wavelength be 450 to 700 nm and the stimulated emission light wavelength be 300 to 500 nm.

As described above, as a stimulable phosphor which emits stimulated emission light of 300 to 500 nm and can be preferably used in the present invention, for example, a rare earth element-activated alkaline earth metal fluorohalide phosphor [specifically, Specifically, JP-A-55-12143
(Ba _1-xy , Mg _x , C
a _y ) FX: aEu ²⁺ (where X is at least one of Cl and Br, and x and y are 0 <x + y ≦ 0.
6 and xy ≠ 0, a is 10 ⁻⁶ ≦ a ≦ 5 × 10 ⁻² ), and is described in JP-A-55-12145 (Ba).
_1-x , M ^II _x ) FX: yA (where M ^II is Mg, Ca, S
at least one of r, Zn and Cd, X being C
at least one of l, Br and I, A is Eu,
At least one of Tb, Ce, Tm, Dy, Pr, Ho, Nd, Yb and Er, x is 0≤x≤0.6, y
Is 0 ≦ y ≦ 0.2), etc.]; ZnS: Cu, Pb, BaO.xAl described in JP-A-55-12142
₂ O ₃ : Eu (however 0.8 ≦ x ≦ 10) and M ^II O · xS
iO ₂ : A (where M ^II is Mg, Ca, Sr, Zn, Cd
Or Ba, where A is Ce, Tb, Eu, Tm, Pb
, Tl, Bi or Mn, and x is 0.5 ≦ x ≦ 2.5
L) described in JP-A-55-12144
nOX: xA, where Ln is at least one of La, Y, Gd and Lu, X is at least one of Cl and Br, A is at least one of Ce and Tb, and x is 0 <x. <0.1); and the like.
Among these, rare earth element activated alkaline earth metal fluorohalide phosphors are preferable, and among them, barium fluorohalides shown as specific examples are particularly preferable because they have excellent stimulable emission.

Further, a barium fluorohalide fluorescent material to which a metal fluoride is added as disclosed in JP-A-56-2385 and 56-2386, or Japanese Patent Application No. 54-15.
As disclosed in the specification of 0873, addition of at least one of a metal chloride, a metal bromide and a metal iodide is preferable because the stimulated emission is further improved.

Further, as disclosed in JP-A-55-163500, a phosphor layer of a stimulable phosphor plate prepared by using the stimulable phosphor as described above is prepared by using a pigment or a dye. Coloring is preferable because the sharpness of the image finally obtained is improved.

[0017]

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

FIG. 1 shows a first embodiment of the present invention. In this embodiment, an endless conveyor 1 such as a belt conveyor or a chain conveyor is used as a support for fixing the stimulable phosphor plate. On this conveyor 1, three stimulable phosphor plates 2 are fixed at equal intervals. The conveyor 1 for fixing the stimulable phosphor plate 2 is hung on a driving roller 3 and a driven roller 4 and travels in the direction of the arrow in the figure by the driving roller 3 rotated by a driving device (not shown). It is possible. In the vicinity of the driven roller 4, a radiation source 5 is arranged so as to face the conveyor 1 stretched between the driven roller 4 and the driving roller 3. The radiation source 5 is composed of, for example, an X-ray source and the like, and a transmission radiation image of a subject 6 arranged between the stimulable phosphor plate 2 and the radiative source 5 is transferred onto the stimulable phosphor plate 2. To project. An excitation light source 7 that emits excitation light such as laser light, and an optical deflector that scans the excitation light emitted from this excitation light source 7 in the width direction of the conveyor 1 near the drive roller 3, such as a galvanometer mirror. 8 and a photodetector 9 for reading the stimulated emission light emitted by the stimulable phosphor plate 2 excited by the excitation light. The photodetector 9 is, for example, a head-on type photomultiplier tube, a photoelectron amplification channel plate, or the like, and the light transmission means 10
The stimulated emission light guided by is detected photoelectrically.
An erasing light source 11 is provided at a position facing the conveyor 1 on the side opposite to the side where the radiation source 5, the excitation light source 7, the photodetector 9, etc. are provided. The erasing light source 11 irradiates the stimulable phosphor plate 2 with light included in the excitation wavelength region of the stimulable phosphor plate 2 so that the radiation energy accumulated in the stimulable phosphor plate 2 is emitted. For example, a tungsten lamp, a halogen lamp, an infrared lamp, or a laser light source as disclosed in JP-A-56-11392 can be arbitrarily selected and used. The radiation energy stored in the stimulable phosphor plate 2 is as shown in, for example, JP-A-56-12599.
The erasing light source 11 may be replaced by a heating means, as it can be emitted by heating the stimulable phosphor plate. A cylindrical cleaning roller 12 is provided at a position facing the driven roller 4 across the conveyor 1. The cleaning roller 12 is rotated counterclockwise in the figure by a driving device (not shown), and dust and dirt adhering to the surface of the accumulative phosphor plate 2 that moves while contacting the cleaning roller 12 is filtered. It is to be removed from the surface of the optical plate, and if necessary, it may be formed so as to adsorb the dust and the like by utilizing an electrostatic phenomenon.

Regarding the material and structure of the light transmitting means 10 or the method of using the same, JP-A-55-87970, JP-A-56-11397, and JP-A-56-11397.
No. 11396, No. 56-11394, No. 56-11398, No. 56-11395, etc., and the method can be used as they are.

The operation of the apparatus of this embodiment having the above structure will be described below. The conveyor 1 is intermittently fed by the driving roller 3 by 1/3 of its entire length. Here, the stop position of the conveyor 1 is set so that one stimulable phosphor plate 2 faces the radiation source 5 when the conveyor is stopped. The radiation source 5 is turned on when the conveyor 1 is stopped, and a transmitted radiation image of the subject 6 is stored and recorded on the stimulable phosphor plate 2 stopped at a position facing the radiation source 5.
After the radiation image recording is completed, the conveyor 1 is moved for 1/3 round and stopped. Then, the stimulable phosphor plate 2 on which the radiation image is recorded stops at a position facing the above-mentioned optical deflector 8 and photodetector 9. The stimulable phosphor plate 2 stopped at this position is scanned by the excitation light emitted from the excitation light source 7. The excitation light is scanned by the optical deflector 8 in the width direction of the conveyor 1 (main scanning), and at the same time, a stage (not shown) for fixing the excitation light source 7, the optical deflector 8, the photodetector 9, and the light transmission means 10 is provided. Is moved in the lengthwise direction of the conveyor 1, so that it is also scanned in the lengthwise direction of the conveyor 1 (sub-scanning). The stage that moves as described above can be easily formed by using a known linear movement mechanism.
Upon receiving the irradiation of the excitation light, the stimulable phosphor plate 2 emits stimulated emission according to the image information stored and recorded. This stimulated emission light is input to the photodetector 9 via the light transmission means 10, and from the photodetector 9, an electrical image signal corresponding to the radiation image stored and recorded in the stimulable phosphor plate 2 is obtained. Is output. When the image is read in this manner, the conveyor 1 is further moved by one third of a turn and stopped, and the stimulable phosphor plate 2 on which the image has been read stops facing the erasing light source 11. The stimulable phosphor plate 2 stopped at this position is irradiated with the erasing light source 11, and a small amount is mixed in the radiant energy remaining after the reading operation and the stimulable phosphor ^266.
It emits radiation energy from radiation emitted from radioisotopes such as Ra and ⁴⁰ K or environmental radiation. Therefore, the radiation image formed on the stimulable phosphor plate 2 is erased, and when the device has not been used for a long time, the stimulable phosphor plate 2 is accumulated. The radiation energy based on the radiation from the radioactive isotope or the environmental radiation that has been released is also released, and the reusable state is restored. Then conveyor 1
Storage phosphor plate 2 that has been erased after being moved by 1/3
Is sent to a position facing the radiation source 5, but the stimulable phosphor plate 2 is wiped off by the cleaning roller 12 during the movement, and fine dust and dust on the surface are removed. In this way, the radiation image is erased, and the stimulable phosphor plate 2 from which dust and dust are removed is sent to a position facing the radiation source 5 and is reused for recording a radiation image.

As described above, the stimulable phosphor plate 2 is used.
By the erasing light source 11 and the cleaning roller 12,
Recycled while being erased and cleaned. Considering a certain stimulable phosphor plate 2, this phosphor plate is used for image recording, image reading, and image erasing processing over time while the conveyor 1 travels once as described above. Needless to say, when the conveyor 1 is stopped, the above-mentioned processing may be performed on the three accumulative phosphor plates 2 in parallel at the same time.
By doing so, the image processing speed is naturally improved.

In the above embodiment, the stimulable phosphor plate 2 is fixed to the endless conveyor 1 and is reused by circulating the conveyor 1. Unlike the case where the stimulable phosphors are conveyed one by one, there is almost no risk of damaging the stimulable phosphors. Since the mechanism for circulating the stimulable phosphor plate 2 can also be configured by a simple conveyor mechanism, it can be easily designed and manufactured. Further, since the three stimulable phosphor plates 2 are always recycled in a fixed order, a uniform reproduced image without variations due to the sheets can be obtained.

The electrical image signal output from the photodetector 9 is immediately input to the reproducing device and is sent to a hard copy or CR.
The T display or the like may be obtained, or it may be digitized and temporarily recorded on a high-density recording medium such as a magnetic tape, a magnetic disk, or an optical disk and then applied to a reproducing device. When the radiation image recording / reading device is used for medical diagnostic imaging by being mounted on a circulating bus, for example, the image signal reading and recording are performed at the radiation imaging site, and high-density recording as described above is performed. If the medium is brought back to a medical center or the like and is reproduced there, the weight of the mobile device can be reduced. Further, the above image signals may be input to the reproducing device and the recording medium at the same time. That is, when used in a hospital, an image signal is transmitted from the radiation imaging room to a recording medium for recording and storage, and at the same time, the image signal is transmitted to a reproducing device such as a CRT in the examination room for diagnosis immediately after imaging. It may be allowed.

Prior to reproducing the radiation image,
It is also possible to perform signal processing on the image signal to enhance the image, change the contrast, and the like, and it is desirable to perform such signal processing in order to obtain a radiation image with excellent diagnostic performance. Examples of desirable signal processing used in the present invention include JP-A-55-87970 and JP-A-56-11038.
No. 56-75137, No. 56-75139, No. 56-75141,
Japanese Patent Laid-Open No. 56-104645, etc.
The gradation processing disclosed in Nos. 55-116339, 55-116340 and 55-88740 can be mentioned.

In the above embodiment, the sub-scanning for reading the radiation image is performed by the excitation light irradiation system and the photostimulable light reading system.
This is done by moving the accumulative phosphor plate 2 while it is stopped. However, on the contrary, the excitation light irradiation system and the photostimulable light reading system are fixed, and the auxiliary light is moved by moving the accumulative phosphor plate. You may make it scan. In order to move the stimulable phosphor plate in this manner, the stimulable phosphor plate is not directly fixed on the conveyer but is attached to the conveyer via the stage, and at the time of image reading, the above stage is kept on the stopped conveyer. May be moved to perform image reading, and the stage may be returned to a predetermined position after the reading is completed.Also, the accumulative phosphor plate may be fixed directly to the conveyor, and sub-scanning may be performed by moving the conveyor. May be. When obtaining sub-scanning by moving the conveyor, the distance between the image recording unit and the image reading unit is set differently from the fluorescent plate mounting pitch, and, for example, after the movement of the conveyor for sub-scanning is completed, the conveyor continues to operate. The next stimulable phosphor plate moved for circulation of the phosphor plate may be moved to the image recording unit so that the image recording may be performed at a time lag from the image reading, or the image recording may be performed. When it is desired to perform image recording and image reading in parallel at the same time in order to improve processing speed, etc., when a conveyor for sub-scanning is being moved, a radiation image is formed by slit exposure on the moving accumulative phosphor plate. It may be recorded. Further, the number of conveyors for moving the stimulable phosphor plate is not limited to one, and if the conveyer plate can be automatically transferred between them, several conveyors may be used. The stimulable phosphor plate may eventually be circulated via several conveyors. If a plurality of conveyors are used in this way, a plurality of image reading units are provided for one image recording unit when the reading speed is extremely slow with respect to the recording speed. Connect a conveyor branched from the image recording unit to each of the reading units,
It is also possible to increase the reading speed by supplying a stimulable phosphor plate in parallel to each image reading unit. Furthermore, when transferring the accumulative phosphor plate between a plurality of conveyors as described above, if two accumulators are connected via a stage where the accumulative phosphor plate is temporarily stored, It is convenient that the defective accumulative phosphor plate can be removed or a new accumulative phosphor plate can be added at this stage without stopping the device.

In the first embodiment described above, the stimulable phosphor plate 2 is a conveyor 1 stretched between two rollers.
Since it is fixed to the storage luminescent plate 2, the stimulable phosphor plate 2 must be formed so as to be flexible and freely bendable. However, in consideration of the durability of the phosphor and the formation of a more precise radiation image, it is preferable to avoid bending the stimulable phosphor plate. 2nd Example shown in FIG. 2, 3rd Example shown in FIG. 4, and FIG. 4 (A), (B)
In the fourth embodiment shown in Figure 4, the stimulable phosphor plate is fixed on a rigid support which circulates the stimulable phosphor plate without bending the stimulable phosphor plate. It is shaped to move.

In the second embodiment shown in FIG. 2, 4
A sheet of stimulable phosphor plate 102 is used, and each stimulable phosphor plate 102 is fixed on each side surface of a rectangular turret 101. A rotating member 101b such as a sprocket wheel is fixed to a support shaft 101a of the turret 101, and a driving force of a driving device 103 is transmitted to the rotating member 101b via a driving force transmitting member 103a such as a chain. The drive device 103 causes the turret 101 to move 90 in the direction of the arrow in the figure.
Rotated by °. A radiation source 105 is provided at a position facing one side surface of the turret 101, and an excitation light source 107, an optical deflector 108, and a photodetector are provided near the side surface opposite to this side surface.
109 and a light transmission means 110 are provided. An erasing light source 111 is provided at a position facing the adjacent side surface on the turret rotation upstream side with respect to the opposing turret side surface. The radiation source 105 described above,
As the parts such as the excitation light source 107 arranged around the turret 101, the same parts as those in the first embodiment are used. The device of FIG. 2 is different from the device of FIG. 1 in the means for fixing and circulatingly moving the stimulable phosphor plate.
The radiation source 10
5 is turned on and the transmission radiation image of the subject 106 is stored and recorded on the storage phosphor plate 102. The stimulable phosphor plate 102 on which the radiation image is accumulated and recorded is stopped at a position facing the light deflector 108, the photodetector 109, etc. when the turret 101 is stopped one after another. Here, the accumulative phosphor plate 102 is scanned by the excitation light emitted from the excitation light source 107,
The stimulable phosphor plate 102 emits stimulated light. Then, an electrical image signal carrying radiation image information is output from the photodetector 109 that photoelectrically reads this stimulated emission light. Here, in the apparatus of FIG. 2, it is difficult to perform the excitation light sub-scanning by rotating the turret 101, so the other sub-scanning method as described above is used. When the turret 101 is next stopped, the stimulable phosphor plate 102 from which the image has been read is irradiated with the erasing light source 111 to erase the remaining radiation energy, and is reused for recording a radiation image.

In FIG. 2, no processing is performed on one of the four stages in which the turret 101 rotates, but the position of this stage is not limited to the position shown in FIG. Therefore, for example, it is possible to form a device in which three fluorescent plates are fixed to a triangular turret. If it takes time to erase the stimulable phosphor plate 102, two erasing stages may be provided.

The number of accumulative phosphor plates fixed to the support is not limited to three in the first embodiment and four in the second embodiment described above, but can be set in various ways. It is not always necessary to make the zone for erasing the image independent of the zone for recording the image or the zone for reading the image. For example, in the third embodiment shown in FIG. 3, a plate-shaped support 201 which is rotated about the drive shaft 203 by 180 ° is used, and the stimulable phosphor plate 202 is formed on both surfaces of the support 201. There are two, one for each. Then, the radiation source 205 is disposed so as to face the one storage phosphor plate 202a on the support 201, and the excitation light source 207 is located at a position facing the other storage phosphor plate 202b.
An optical deflector 208, a photodetector 209, and a light transmitting means 210 are arranged, but the erasing light source 211 includes the optical deflector 208 and the photodetector 20.
9 and so on so as to face the stimulable phosphor plate 202b. The support 201 is rotated by 180 ° by the rotation of the drive shaft 203, and image recording and image reading are repeated on each of the accumulative phosphor plates 202a and 202b, but the erasing light source 211 reads the image. The light is turned off while the image reading is being performed, and is turned on for a predetermined time after the image reading is completed to erase the image. After the erasing light source is turned off, the support 201 is rotated to move the stimulable phosphor plates 202a and 202b. When the plate-shaped support as described above is used, the accumulative phosphor plate may be fixed to only one surface of the support. However, in such a case, it is impossible to perform image recording and image reading in parallel at the same time, which inevitably results in a decrease in image processing speed. In the third embodiment and the second embodiment described above, the fluorescent plate cleaning means such as the cleaning roller used in the first embodiment is not particularly provided, but if necessary, image erasing can be performed. A self-propelled phosphor plate cleaning roller or the like that runs while sweeping the surface of the stimulable phosphor plate after completion may be provided.

In the three embodiments described above, all the supports for fixing the stimulable phosphor plate are designed to be rotationally moved, but the supports can be moved by other methods such as reciprocating movement. May be performed by. Figure 4 (A),
In the fourth embodiment shown in (B), a plate-shaped support 301
This support 301 is loaded on a rail 304, and is reciprocated along the rail 304 by a drive device 303 that engages with a rack on the rail 304 side and drives a pinion gear that constitutes a rack and pinion mechanism. It is movable. Two accumulative phosphor plates 302a, b on the support 301
Is fixed to the center of the rail 304, above the stimulable phosphor plate
One radiation source 305 is provided on the side opposite to 302a. An image reading section including an excitation light source 307, a light deflector 308, a photodetector 309, and a light transmitting means 310 is provided on each side of the radiation source 305, one set each. An erasing light source 311 is provided in the image reading unit, and each image reading unit and the radiation source 305 are isolated by a light shielding plate 313, and the light shielding plate 31 is provided.
A cleaning roller 312 is disposed on the outer side of 3 and near the light shielding plate 313. Support 301 is drive unit 30
It is reciprocally moved on the rail 304 by 3 and alternately takes the position shown in FIG. 4 (A) and the position shown in FIG. 4 (B).
When the support 301 is set to the position shown in FIG. 4 (A), image recording is performed on the accumulative phosphor plate 302a on the left side of the figure, and the image is recorded from the accumulative phosphor plate 302b on the right side of the figure. Image reading is performed. As described above, the sub-scanning in image reading may be performed by moving the excitation light irradiation system and the photostimulable light reading system, or may be performed by using the movement of the support 301. After the image reading is completed, the erasing light source 311 is turned on for a certain period of time to erase the image. At this time, the light of the erasing light source 311 is blocked by the light shielding plate 313, so that the image on the other stimulable phosphor plate 302a on which the image is recorded is not erased. After image erasing is complete, support 301
Is moved to the left in the figure, but at this time, the cleaning roller 312 moves from the retracted position shown in the drawing to the storage phosphor plate.
The surface of the stimulable phosphor plate 302b, which is moved down to a position where it comes into contact with 302b and is moved, is cleaned. The cleaning roller 312 is returned to the original exit position after passing through the stimulable phosphor plate 302b. When the support 301 is moved to the position shown in FIG. 4 (B), an image is read from the accumulative phosphor plate 302a on the left side in the figure in which the image is recorded in the state of FIG. 4 (A), An image is recorded on the accumulative phosphor plate 302b on the right side in the figure which has been erased and cleaned. When the image reading and the image recording are completed, the support 301 is returned to the position shown in FIG. 4 (A) again, but the accumulative phosphor plate 302a on the left side in the figure where the image reading is completed is as described above. Then, it is erased, cleaned, and is ready for reuse. Even when the support is reciprocated as described above, if it is not necessary to increase the image processing speed, image recording and image reading are alternately performed using only one accumulative phosphor plate. It may be done at.

The recording state or recording pattern of the radiation image information accumulated and recorded on the accumulative phosphor sheet is grasped prior to the reading operation, the reading gain of the photoelectric reading means is set, and the appropriate recording scale factor is determined. In addition, it is preferable to set the signal processing conditions in order to obtain a radiographic image with excellent diagnostic performance. For this reason, the recording state or recording pattern of radiographic image information is read with low excitation light energy prior to the reading operation (hereinafter , "Preliminary reading." Then, a method and apparatus for performing a reading operation (hereinafter referred to as "main reading") for obtaining a radiation image used for diagnosis are disclosed in Japanese Patent Application Nos. 56-165111 and 56-165112.
No. 56-165113, No. 56-165114 and No. 56-165115. Also in the present invention, such a pre-reading is performed by separately providing a pre-reading reading section having a similar configuration on the upstream side of the image reading section, or by using the image reading section for both pre-reading and main reading. Can satisfy the request.

As described above, in the first to fourth embodiments, the example in which at least one stimulable phosphor plate is fixed on the support has been shown. However, the support is an endless support and is directly mounted on the support. You may make it accumulate | stack a stimulable fluorescent substance layer. For example, an endless belt provided with a stimulable phosphor layer on the surface,
Alternatively, it is also possible to use a rotating drum provided with a stimulable phosphor layer on the surface thereof. Such examples will be described below as fifth, sixth and seventh embodiments with reference to FIGS.

FIG. 5 shows a fifth embodiment of the present invention. In this embodiment, an endless belt-shaped recording member 401 is used. This endless belt-shaped recording member 401 is formed by stacking a stimulable phosphor layer 403 (recording member) on the surface of a flexible endless belt-shaped support 402 as shown in an enlarged view in FIG. It will be. The endless belt-shaped recording member 401 is a cylindrical drive roller 40.
The drive roller 404 is hung on three cylindrical driven rollers 405, 406, 407 similar to 4, and is driven by a drive device (not shown) so that the drive roller 404 can travel in the direction of the arrow in the figure. A radiation source 408 is disposed at a position facing the recording member 401 stretched between the driven rollers 406 and 407. The radiation source 408 is, for example, an X-ray source, and the driven roller 40
A transmission radiation image of a subject 409 arranged between the recording member 401 between 6, 6 and the radiation source 408 is projected on the recording member 401 at the above position. Drive roller 404 and driven roller 40
An excitation light source 410 that emits excitation light such as laser light is provided at a position facing the recording member 401 that is stretched between
And the excitation light emitted from the excitation light source 410
An optical deflector 411 such as a galvanometer mirror that scans in the width direction of 401, and a photodetector 41 that reads the stimulated emission light emitted by the storage phosphor layer 403 excited by the excitation light.
2 are provided. The photodetector 412 is, for example, a head-on type photomultiplier tube, a photoelectron amplification channel plate, or the like, and photoelectrically detects the stimulated emission light guided by the light transmission means 413. An erasing light source 414 is provided at a position facing the recording member 401 between the driven rollers 405 and 406. The erasing light source 414 is a storage phosphor layer 40.
By irradiating 3 with light included in the excitation wavelength region of the phosphor, the radiation energy accumulated in the stimulable phosphor layer 403 is released, and, for example, JP-A-56-11392. A tungsten lamp, a halogen lamp, an infrared lamp, a laser light source, or the like as shown in FIG. Note that the storage phosphor layer 40
Radiation energy stored in
As shown in 56-12599, the erasing light source 414 may be replaced by a heating means as it can also be emitted by heating the stimulable phosphor. Recording member 40
A cleaning roller 415 having a cylindrical shape is provided at a position facing the driven roller 406 with the cleaning roller 415 in contact with the recording member 401. The cleaning roller 415 is rotated counterclockwise in the figure by a drive unit (not shown), and removes dust and dirt attached to the surface of the recording member 401 that moves while contacting the cleaning roller 415 from the surface of the recording medium. However, if necessary, it may be formed so as to adsorb the dust and the like by utilizing an electrostatic phenomenon.

As the light transmitting means 413, the same one as the light transmitting means 10 in FIG. 1 can be used as it is.

The operation of the apparatus of this embodiment having the above structure will be described below. Recording member 401 is drive roller 404
Will send intermittently 1/4 of its own length. When the recording member 401 is stopped, the radiation source 408 is turned on, and the transmission radiation image of the subject 409 is accumulated and recorded on the accumulative phosphor layer 403 of the recording member 401 stretched between the driven rollers 406 and 407. The portion where the radiation image is accumulated and recorded is located between the driving roller 404 and the driven roller 405 when the recording member 401 is stopped one after another. The stimulable phosphor layer 403 of the recording member 401 stopped at this position is scanned by the excitation light emitted from the excitation light source 410. Excitation light is an optical deflector 41
1 is scanned in the width direction of the recording member 401 (main scanning), and the excitation light source 410, the optical deflector 411, and the photodetector
412, a stage for fixing the light transmission means 413 (not shown)
Is moved in the length direction of the recording member 401,
The recording member 401 is scanned in the lengthwise direction (sub-scanning). The stage that moves as described above can be easily formed by using a known linear movement mechanism. Upon receiving the irradiation of the excitation light, the stimulable phosphor layer 403 of the recording member 401 emits stimulated emission according to the image information stored and recorded. This stimulated emission light is input to the photodetector 412 via the light transmission means 413 and photoelectrically converted, and from the photodetector 412, the accumulative phosphor layer is emitted.
An electrical image signal corresponding to the radiation image stored and recorded in 403 is output. The recording member 401 of the portion where the image is read in this way is driven by the driven roller 405,
Located between 406. Recording member 401 stopped at this position
The stimulable phosphor layer 403 is irradiated with the erasing light source 414, and the radiant energy remaining after the reading operation and the radioactive isotopes such as ²⁶⁶ Ra and ⁴⁰ K which are contained in the stimulable phosphor in a trace amount. It emits radiation energy due to emitted radiation or environmental radiation. Therefore, the radiation image formed on the stimulable phosphor layer 403 is erased by the radiation image recording, and in the case where the apparatus has not been used for a long time until then, the stimulable fluorescence is generated. Radiation energy based on the radiation from the radioisotope accumulated in the body layer 403 or the environmental radiation is also released, and the reusable state is restored.

Next, when the recording member 401 in the portion where the radiation image is erased is sent between the driven rollers 406 and 407, the surface of the recording member 401 is wiped by the cleaning roller 415, and the surface of the recording member 401 is fine. Chile and dust are removed. In this way the radiation image is erased,
The recording member 401 from which dust and dirt have been removed is stopped between the driven rollers 406 and 407 and reused for recording a radiation image.

As described above, the recording member 401 is circulated and reused while being erased and cleaned by the erasing light source 414 and the cleaning roller 415. Recording material
Considering a portion on the 401, this portion undergoes image recording, image reading, and image erasing processing while the recording member 401 makes one revolution as described above, but the recording member 401 is stopped. As a matter of course, when an image is recorded on a portion of the recording member 401, the image reading and the image erasing may be performed on the other portion of the recording member 401 at the same time. If the image recording, the image reading, and the image erasing are simultaneously performed on different portions of the recording member 401, the image processing speed is naturally improved.

In the above embodiment, the stimulable phosphor layer
403 is laminated on the endless belt-shaped support 402,
Since the support 402 is reused by being circulated, unlike the case where the sheet-shaped accumulative phosphors are conveyed one by one, the accumulative phosphors are damaged. There is almost no danger. The mechanism for circulating the stimulable phosphor can be designed and manufactured easily because it can be configured only by the endless belt drive mechanism. Further, since one recording member 401 is reused by circulation, a uniform reproduced image without variations due to sheets can be obtained.

The electric image signal output from the photodetector 12 may be immediately input to the reproducing apparatus to obtain a hard copy or a CRT display as in the first embodiment, or a digital image may be displayed. Magnetic tape, magnetic disk,
Alternatively, the data may be temporarily recorded on a high-density recording medium such as an optical disc and then applied to a reproducing device.

In the above embodiment, the sub-scanning for reading the radiation image is performed by moving the exciting light irradiation system and the photostimulable light reading system with respect to the recording member 401 which is stopped. It is also possible to fix the excitation light irradiation system and the photostimulable light reading system, and perform sub-scanning by moving the recording medium. In such a case, when the recording member 401 is stopped and a radiation image is recorded, after the radiation image recording is completed, the recording member 401 is moved at a speed for sub-scanning, and reading is performed when the recording medium is moved. do it. Further, if the radiation image is recorded while moving the recording member 401 by using, for example, slit exposure, the radiation image can be recorded and read without stopping the recording member 401.

In the fifth embodiment described above, an endless belt-shaped recording member 401 which is flexible and can be freely bent is used, but the durability of the recording medium and more precise radiation are used. In consideration of the formation of an image, it is preferable that the recording body is formed to have rigidity, and bending during use is avoided. 7 and 8 show a sixth embodiment and a seventh embodiment of the present invention, in which a recording medium having such rigidity is used. In the embodiment of FIG. 7, the recording member 501 has a stimulable phosphor laminated on the peripheral surface of a drum-shaped support. A driving force of a driving shaft 504a of a driving device (not shown) is applied to the recording member 501 by the chain 50.
4B, the recording member 501 is intermittently rotated in the arrow direction with a predetermined stop period. Around the drum-shaped recording member 501, a radiation source 508, an excitation light source 510, an optical deflector 511, and a photodetector 51 similar to those in the fifth embodiment.
2, a light transmission means 513, an erasing light source 514, and a cleaning roller 515 are arranged. The apparatus of FIG. 7 is different from the apparatus of FIG. 5 only in the shape and driving method of the recording member 501, and the transmission radiation image of the subject 509 is accumulated on the recording member 501 by the same operation as the apparatus of FIG. Record and pump light source
Scan the recording member 501 with the excitation light emitted from 510,
An electrical image signal carrying a radiographic image is output from photodetector 512. Further, in the embodiment of FIG. 8, the recording member 60
1 is the accumulative phosphor layer 603 on the side surface of the disk-shaped support 602.
Are laminated. The recording member 601 is intermittently rotated by 1/4 rotation in the arrow direction by a drive shaft 604a of a drive device (not shown) and a chain 604b. An image recording zone 605 is set on the stimulable phosphor layer 603, and a transmitted radiation image of an object (not shown) by a radiation source as described above is set on the stimulable phosphor layer 603 in this portion. Is stored and recorded. This image recording zone 605
An image reading zone 606 is set at a position 180 ° away from the image reading zone 606, and the image reading zone 606 includes the above-mentioned excitation light source, scanning means such as an optical deflector, photodetector, and optical transmission means. A device (not shown) is provided. An erasing light source 608 surrounded by a light shielding member 607 is provided on the downstream side of the image reading zone 606, and a cleaning position is provided on the downstream side of the erasing light source 608 and on the upstream side of the image recording zone 605. Rollers 609 are provided. Also in the apparatus of FIG. 8, the recording member 601 is circulated and reused while being erased and cleaned by the erasing light source 608 and the cleaning roller 609. In the apparatus shown in FIG. 8, since the stimulable phosphor layer 603 is adapted to move in one plane, the erasing light emitted from the erasing light source 608 is emitted by the image recording zone 605 and the image reading zone 60.
A light blocking member 607 is provided so as not to irradiate 6.
Such a light-shielding member may be appropriately provided also in the fifth and sixth embodiments in which the stimulable phosphor moves in three dimensions.

The seventh embodiment described above and the sixth embodiment described above
Also in the embodiment, the recording medium is formed so as to have rigidity and is not bent. Therefore, it is excellent in durability, precise reproduction of images, and ease of manufacture, as compared with the endless belt-shaped recording medium. ing.

In the fifth, sixth and seventh embodiments described above, the endless recording bodies are all intermittently moved by 1/4 rotation, but the rotation pitch is limited to the above value. Of course, it is not something that is done,
For example, in an apparatus as shown in FIG. 7, the recording medium may be stretched in a triangular shape and continuously moved by 1/3 rotation. Further, it is not always necessary to make the erasing zone independent of the image recording zone or the image reading zone. For example, when the erasing light source is provided in the image reading zone, The erasing light source may be turned off, and when the image reading is completed, the erasing light source may be turned on to perform the erasing. In such a case, it is also possible to perform the above-described movement of the recording medium by 1/2 rotation. It is not always necessary to clean the recording medium with the cleaning roller, but by performing such cleaning, a higher quality radiation image can be obtained.

In each of the embodiments described above,
A plurality of radiographic images are sequentially moved to each zone of recording, reading, and erasing (in the case where erasing is arranged in the same zone as recording or reading, moving between those zones), recording, The operations of reading and erasing are sequentially performed for each image, but it is also possible to collectively record only a plurality of images first, and then perform reading and erasing collectively. For example, it is possible to fix 10 fluorescent plates to an endless belt, finish recording of all 10 sheets, read 10 sheets collectively, and then erase 10 sheets collectively. Regarding erasing after reading, erasing may be performed immediately after reading each image.
Such a recording / reading method is useful for continuous imaging such as angiography and dynamic imaging.

As a constitution for this, for example, in the first embodiment shown in FIG. 1, the fluorescent plates 2 are arranged at equal intervals over the entire endless belt 1, and in operation, only recording is carried out in advance around the endless belt 1. Alternatively, the reading and erasing may be performed in the next round, or the endless belt may be used in the fifth embodiment of FIG. A part of the recording member 401 in the shape of a stripe is meandered over a plurality of images to form a stacker, and the recorded parts of the recording material are retained in this stacker part, and then the reading part collectively collects the image of this part. You may do it. Of course, in the fifth embodiment of FIG. 5, recording, reading, and erasing may be collectively performed by an operation like the modification of the first embodiment, or conversely, the stacker is formed in the example of FIG. You may do it. It is needless to say that the above-described modification of collectively reading and erasing after collectively recording (erasing may be separately performed later) can be adopted in any of the first to seventh embodiments. Yes.

As described in detail above, the radiation image information recording / reading apparatus of the present invention enables the stimulable phosphor plate to be circulated and reused without damaging it, and provides a stable and homogeneous reproduced image. Is provided. The quality control of the stimulable phosphor plate is easy, and the structure is simple, so that it is easy to design and manufacture, and the device can be formed small and lightweight. Therefore, the apparatus of the present invention is particularly suitable for being loaded on a bus or the like and used for movement, and is extremely convenient in practice.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a first embodiment of the present invention.

FIG. 2 is a schematic diagram showing a second embodiment of the present invention.

FIG. 3 is a schematic diagram showing a third embodiment of the present invention.

FIG. 4 is a schematic diagram showing a fourth embodiment of the present invention.

FIG. 5 is a schematic view showing a fifth embodiment of the present invention.

FIG. 6 is an enlarged side view showing a part of the embodiment of FIG.

FIG. 7 is a schematic view showing a sixth embodiment of the present invention.

FIG. 8 is a schematic view showing a seventh embodiment of the present invention.

[Explanation of symbols]

 1 Conveyor 2, 102, 202, 302 Accumulative phosphor plate 3, 404 Drive roller 5, 105, 205, 305, 408, 508 Radiation source 6, 106, 306, 409, 509 Subject 7, 107, 207, 307, 410, 510 Excitation light source 8, 108, 208, 308, 411, 511 Optical deflector 9, 109, 209, 309, 412, 512 Photodetector 10, 110, 210, 310, 413, 513 Optical transmission means 11, 111, 211, 311,414, 514, 608 Elimination Light source 401, 501, 601 Recording member 402, 602 Support 403, 603 Accumulative phosphor layer

Claims (7)

[Claims] 1. A support, a recording body comprising a stimulable phosphor layer fixed on the support and capable of storing and recording a radiation image, and by irradiating the recording body with radiation through a subject, An image recording unit that stores and records a radiation transmission image of a subject on the recording body, an excitation light source that emits excitation light that scans the recording body on which the radiation image is stored and recorded, and a recording body that is scanned by the excitation light. An image reading unit having a photoelectric reading unit for reading the stimulated emission light thus obtained to obtain an image signal, and prior to the image recording being performed on the recording medium after the image reading is performed by the image reading unit. The erasing section provided with erasing means for releasing the residual radiation energy on the recording body, the support, and the image recording section, the image reading section, and the erasing section are relatively repeated in this order. So moved, the image recording unit of the recording medium on the support, a radiation image information recording and reading apparatus comprising the means for relatively circulating movement with respect to the reading unit and the erasing section. 2. The radiation image information recording / reading apparatus according to claim 1, wherein the support is an endless support. 3. The radiation image information recording / reading apparatus according to claim 2, wherein the endless support is an endless belt. 4. The radiation image information recording / reading apparatus according to claim 2, wherein the endless support is a rotating drum. 5. The radiation image information recording / reading apparatus according to claim 1, wherein the recording body is a stimulable phosphor layer laminated on the support. 6. The radiation image according to claim 1, wherein the recording medium is a stimulable fluorescent plate that is detachably attached to and fixed to the support. Information reader. 7. The radiation image information recording according to claim 1, wherein the support is a support that can be circulated between the image recording unit and the image reading unit. Reader.