JPH0411211B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] This invention belongs to the technical field of X-ray imaging devices.

[Technical background of the invention and its problems]

2. Description of the Related Art Conventionally, as an X-ray imaging apparatus, there is, for example, an X-ray diagnostic apparatus for the gastrointestinal tract, mainly for the gastrointestinal tract. In this type of field where X-ray imaging is performed in large quantities, approximately 50 to 100 X-ray sheet films are stored in a supply magazine, and an photographic devices) have been developed. Moreover, in the above device, an X-ray automatic exposure control device is used when taking X-ray photographs,
For example, an I, I phototimer that receives I, I output light as a photoprint, or a thin phototimer that receives photoprinted light by combining an acrylic plate with fluorescent paper is often used.

The former type of automatic X-ray exposure control device receives light behind the X-ray sheet film, and the X-ray energy characteristics of the intensifying screen-film system are different from those of the photo-lighting through the contact plate mechanism and I/I. For,
The phototimer circuit is complex because it has different x-ray energy characteristics. Moreover, if you try to use the so-called multi-lighting field method in which there are many detection lighting fields, in a narrow space near the front of the X-ray detector,
It is necessary to distribute the light from the I, I output parts into a lighting field, and there is a drawback that a precise optical system and structure are required for this purpose.

In addition, the latter type of thin phototimer in the automatic X-ray exposure control device has a simple structure and is approximately 2.5 to 3 mm thick, so it can be used without significantly increasing the X-ray magnification. However, it has been difficult to realize multiple lighting fields.

In addition, there is an ionospheric phototimer called an ion chamber, but its thickness is about 15 mm, which increases the X-ray magnification rate, so it has the disadvantage that the quality of the X-ray image is low.

[Purpose of the invention]

This invention has been made in view of the above circumstances, and provides an X-ray automatic exposure control type spot shot device that can reduce the X-ray magnification rate and perform multi-lighting type X-ray detection. The object of the present invention is to provide an X-ray imaging device.

[Summary of the invention]

The outline of this invention for achieving the above object is as follows:
In an X-ray imaging apparatus that includes an automatic X-ray exposure control device that controls the necessary X-ray dose by detecting the dose of X-rays irradiated to the subject, and a spot shot device, the spot shot device A supply magazine that stores photography media,
It consists of a take-up magazine for storing the photographic medium after photographing, an upper plate part and a lower plate part, one side of the upper plate part and the lower plate part is rotatably fixed, and the upper plate part rotates. The imaging medium holder is reciprocally moved between the position where the imaging medium is attached and removed and the X-ray imaging position, and the imaging medium holder is moved from the supply magazine to the imaging medium holder. a moving supply device that supplies a medium and supplies the photographic medium after photographing from the photographic medium holder to a take-up magazine, and a semiconductor X-ray detector is disposed on a lower plate portion of the photographic medium holder. This is a characteristic feature.

[Embodiments of the invention]

Hereinafter, an embodiment of the present invention will be described using an example in which the imaging medium is an imaging plate. 1st
The figure relates to an embodiment of the present invention and is a specific example of a so-called under-table type X-ray television bed, and is an explanatory diagram mainly showing a spot shot device schematically, and Fig. 2 is an explanatory diagram showing an imaging plate holder. FIG. 3 and FIG. 3 are explanatory diagrams showing an automatic X-ray exposure control device.

In FIG. 1, 1 is an X-ray tube having an X-ray diaphragm 2, and a bed top plate 3 on which a subject is placed.
is located below. Reference numeral 5 indicates a spot shot device, which is arranged above the bed top 3. Reference numeral 6 indicates image intensifiers I, I.
The X-ray input surface of I6 is arranged to face the X-ray tube 1. 7 is the optical system, I, I6
is configured to guide the output fluorescent image to the television camera 8.

The spot shot device 5 stores a large number of imaging plates 20 that have not yet been imaged, and releases the imaging plates 2 one by one by driving a lever 14 in the direction of the arrow shown by a drive means (not shown).
A supply magazine 12 that sends 0 to a mobile supply device described below, a take-up magazine 13 that stores a photographed imaging plate 20c sent from the mobile supply device described below, and an imaging plate 20a sent out from the supply magazine 12. Guide roller 15g, 15 that can move up and down
The imaging plate holder 10 having the imaging plate 20a is loaded into the imaging plate holder 10 which is specially installed at the attachment/detachment position C using the fixed roller group 15a to 15f, and then the imaging plate holder 10 having the imaging plate 20a is moved from the attachment/detachment position C to the X-ray imaging position A. It is transported by an appropriate transport means 9, and after the X-ray imaging is completed,
The imaging plate holder 10 is returned from the X-ray imaging position A to the attachment/detachment position C by the conveyance means 9, and the imaging plate 20b in the imaging plate holder 10 at the attachment/detachment position C is moved by guide rollers 15g, 15h that can move up and down and position fixed rollers. A moving supply device configured to feed the take-up magazine 13 by means of roller groups 16a to 16d is provided. In addition, in Figure 1, 1
1 is an X-ray grid.

The imaging plate holder 10 is constructed as shown in FIG. That is, for example, the upper plate 21 rotates in the directions of arrows D ₁ and D ₂ in the figure around a hinge 23 connected to one end, and
A clamping body consisting of a lower plate portion 24 that is coupled via a hinge 23 and engages on the conveying means 9 to move between the attachment/detachment position C and the photographing position A, and the imaging plate 20 clamped thereto is prevented from shifting. Cushion material 22 attached to the lower surface of the upper plate 21 for
and a semiconductor X-ray detector 31 disposed on the upper surface of the lower plate 24 in order to detect the dose of X-rays emitted in the direction of the arrow shown in the figure. When the imaging plate 20a is in the attachment/detachment position C shown in _FIG . Reception, imaging plate 20a
When the upper plate 21 is placed on the semiconductor X-ray detector 31, the upper plate 21 rotates in the direction of the arrow _D2 shown in the figure to load the imaging plate 20a into the imaging plate holder 10. When is in the attachment/detachment position C, the guide rollers 15g and 15h descend onto the extension of the conveyance path of the roller groups 16a to 16d in synchronization with the rotation of the upper plate 21 in the direction of the arrow _D1 shown in the figure. The imaging plate 20b inside the imaging plate holder 10 is taken out using a take-out device, for example, a suction cup, and the guide rollers 15g, 15 are removed.
h and the roller groups 16a to 16d.

The semiconductor X-ray detector 31 disposed within the imaging plate holder 10 detects the dose of exposed X-rays, and is configured as follows, for example. That is, the semiconductor X-ray detection element 28 is mounted on a substantially ring-shaped mounting base 29, and then electrodes (not shown) are attached to the front and back surfaces. In this way, the mount stand 29
An X-ray detection element 28 integrally mounted on the fixing plate 27 is fitted into a hole provided in the fixing plate 27 and fixed therein, and electrode lead wires 30a and 30b are provided. Here, the mounting base 29 and the fixing plate 27 are made of a material with low X-ray attenuation, such as acrylic resin. Further, the thickness of the X-ray detection element 28 is 100 to 800 μm in terms of aluminum regarding X-ray attenuation (i.e., X-ray aluminum equivalent), and the electrode lead line 3
0a and 30b are formed of an aluminum film having a thickness of 80 μm or less. Both surfaces are covered with aluminum foil 25 for electromagnetic shielding via a thin film 26 for insulation. The semiconductor X-ray detector 31 having the above configuration can be formed to have a thickness of approximately 5 mm.

Note that the imaging plate holder 10 includes:
Electrode lead wire 30 in the semiconductor X-ray detector 31
Male connector connected to a and 30b (not shown)
is provided, and when the imaging holder 10 is located at the imaging position A, a female connector (not shown) and the male connector are coupled, and an X-ray detection signal output from the semiconductor X-ray detector 31 is transmitted to the The line is configured to output to an automatic exposure control device.

As shown in FIG. 3, the automatic X-ray exposure control device includes an amplifier 40 and a control signal generator 50, and uses X-rays output from a semiconductor X-ray detector 31 installed in the imaging plate holder 10. A control signal generator 50 that amplifies the detection signal with the amplifier 40 and then inputs the detected signal determines from the input signal the point in time when the X-ray image of the subject 4 reaches the optimal exposure state, and outputs the detected signal to the X-ray controller 60. The X-ray controller 60 is configured to send an X-ray beam disconnection signal to the X-ray tube device 1, and the X-ray controller 60 uses this signal to control the high voltage generator 70 to stop the X-ray tube device 1 from emitting X-rays. .

The imaging plate 20 accumulates an amount of electric charge on its surface corresponding to the amount of X-rays, and when the surface on which the amount of electric charge has been accumulated is irradiated with readout radiation using heat or light energy, an electric signal corresponding to the amount of electric charge is generated. It is a stimulable phosphor with a thickness of about 1 mm that can output On a substrate, for example, a stainless steel substrate, a two-dimensional material amount, for example, an amorphous silicon layer, which traps electrons to an energy localized level in the forbidden band with an amount of charge proportional to the amount of X-ray irradiation, and a two-dimensional material layer trapped within the two-dimensional material layer. A laminate plate formed by laminating in this order a layer of a transparent conductive material such as In ₂ O ₃ --SnO ₂ for extracting an electric signal corresponding to the distribution of electric charges can be suitably used. However, in this case, it goes without saying that insulation should be provided between the substrate and the laminate.
In addition, as the imaging plate 20,
No. 56-11346, Japanese Patent Application Publication No. 1983-12599, Japanese Patent Application Publication No. 1983-
It is also possible to use stimulable phosphors described in publications such as No. 15025 and JP-A-56-18798.

When the X-ray imaging apparatus is configured as described above, the following functions and effects are achieved. For example, during X-ray fluoroscopy, the imaging plate holder 10 is retracted to a position other than the imaging position A in the spot shot device 5. In this case, since the imaging plate holder 10 is not interposed in the fluoroscopy system, a clear X-ray fluoroscopic image of the subject can be obtained. This cannot be achieved with a conventional X-ray imaging apparatus that employs a fixed thin photo timer. Furthermore, in the case of X-ray snapshot photography, the X-ray photography apparatus operates as follows. That is, the imaging plate holder 10 is located at the attachment/detachment position C as an initial position, and the imaging plate 20 stored in the supply magazine 12 is sent out onto the conveyance path of the roller groups 15a to 15f by the lever 14, and the imaging plate 20 The upper plate 21 of the imaging plate holder 10 rotates in the direction of arrow _D1 in FIG. After the imaging plate 20 is placed in the imaging plate holder 1, the upper plate 21 is rotated in the direction of arrow _D2 in FIG.
0 will be clamped and loaded. Next, the imaging plate holder 10 is transported from the attachment/detachment position C to the imaging position A by the transport means 9, and X-ray imaging is performed. At this time, when X-rays are emitted from the X-ray tube 1, the imaging plate holder 10
The dose of X-rays emitted from the X-ray tube 1 is adjusted by the aforementioned X-ray automatic exposure control device which detects the dose of X-rays by the semiconductor X-ray detector 31 inside and inputs the obtained detection signal. Then, an X-ray image of the subject 4 is captured on the imaging plate 20 with the X-ray dose. At this time, the X-rays are detected by the semiconductor X-ray detector 31
The semiconductor X-ray detector 31 has a mounting base 29 made of a material with low X-ray attenuation, and
X for a thickness of 100 to 800 μm in terms of Al regarding linear attenuation
Since it has a unique structure such as configuring the ray detection element 28, it is possible to capture an X-ray image on the imaging plate 2 without an X-ray shadow caused by the X-ray detection element 28 portion. Furthermore, the structure of the semiconductor X-ray detector 31 allows the overall thickness to be within 5 mm, so the distance between the imaging plate 20 and the subject 4 can be made shorter than in conventional X-ray imaging devices. As a result, the X-ray magnification can be lowered, so a clear X-ray image without blur can be obtained. Furthermore, since it uses a semiconductor
This eliminates the need for a relatively high voltage; therefore,
Electrical implementation can be simplified. Next,
When radiography is completed, the imaging plate holder 10 moves from the radiography position A to the attachment/detachment position C, rotates the upper plate 21 in the direction of arrow _D1 in FIG. The photographed imaging plate 20 is removed by a device (not shown) such as a suction cutter roller 15g,
15h, 16a to 16d, and the imaging plates 20, 20c are stored in the take-up magazine 13. After this, the imaging plate holder 10 waits at the attachment/detachment position C for the next imaging. Then, the series of operations for the next X-ray imaging continues again. The obtained imaged imaging plate 20 can be displayed as a visible image by providing it to an image processing device that reproduces the X-ray image recorded by the readout irradiation for photostimulation. .

Although one embodiment of the present invention has been described above in detail, the present invention is not limited to the embodiment described above, and can be implemented with appropriate modifications within the scope of not changing the gist of the invention.

For example, in order to compensate for the strength of the semiconductor X-ray detector 31, CFRP with a thickness of about 1 mm may be attached to the fixing plate 27.

Moreover, as shown in FIG. 2, a plurality of X-ray detection elements 28 may be appropriately arranged in the semiconductor X-ray detector 31. In this way, by arranging a plurality of X-ray detection elements 28 at appropriate positions, multiple lighting fields can be provided.

〔Effect of the invention〕

According to the invention described in detail above, the following effects can be achieved. In other words, since the imaging medium holder incorporating the semiconductor X-ray detector can be retracted from the imaging position to the attachment/detachment position within the spot shot device, clear X-ray images without X-ray attenuation can be displayed during X-ray fluoroscopy. Moreover, since the semiconductor X-ray detector is placed on the lower plate of the imaging medium holder, even if the upper plate of the imaging medium holder is rotated when attaching or removing the imaging medium, the semiconductor X-ray detector will not be damaged. Even in X-ray rapid photography, since the X-ray attenuation rate of the semiconductor X-ray detector is small, a clear X-ray image can be captured on the recording medium. Further, by arranging a plurality of X-ray detection elements at appropriate positions within the semiconductor X-ray detector, multiple light fields can be provided. Moreover, semiconductor
Since the overall thickness of the ray detector can be made thinner, the distance between the subject and the recording medium can be reduced, making it possible to reduce the X-ray magnification rate and record clear X-ray images without blur. Can be imaged onto a medium.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram showing one embodiment of the present invention, FIG. 2 is a sectional view showing an imaging plate holder, and FIG. 3 is an explanatory diagram showing an X-ray automatic exposure control device. 4... Subject, 5... Spotshot device, 10
...imaging plate holder, 12...supply magazine, 13...take-up magazine, 20...
Imaging plate, 27...fixing plate, 28...X
Line detection element, 29...Mount stand, 30a, 30b
...Electrode lead wire, 31...Semiconductor X-ray detector, A...
X-ray imaging position, C... attachment/detachment position.

Claims (1)

[Scope of Claims] 1. An X-ray imaging apparatus comprising a spot shot device and an automatic exposure device that controls the necessary amount of X-rays by detecting the amount of transmitted X-rays irradiated to the subject, wherein the spot shot device is a supply magazine that stores unphotographed photographic media,
It consists of a take-up magazine for storing the photographic medium after photographing, an upper plate part and a lower plate part, one side of the upper plate part and the lower plate part is rotatably fixed, and the upper plate part rotates. The imaging medium holder is reciprocally moved between the position where the imaging medium is attached and removed and the X-ray imaging position, and the imaging medium holder is moved from the supply magazine to the imaging medium holder. a moving supply device that supplies a medium and supplies the photographic medium after photographing from the photographic medium holder to a take-up magazine, and a semiconductor X-ray detector is disposed on a lower plate portion of the photographic medium holder. Characteristic X-ray imaging equipment. 2. The semiconductor X-ray detector has a semiconductor X-ray detection element having a thickness of 800 μm or less in terms of aluminum in terms of the amount of attenuation of X-rays, which is integrally mounted and fixed on a mounting base with tapered outer and inner circumferences. Claim 1, characterized in that it is configured by fitting and fixing into a hole provided in a plate, and arranging an electrode lead wire made of an aluminum film having a thickness of 80 μm or less from the detection element. X-ray imaging equipment.