JP4862952B2 - Radiation image generation system - Google Patents

Description

 The present invention relates to a radiographic image generation system used for radiographic imaging for medical diagnosis, for example.

 In recent years, digital radiography uses a photoconductive material that generates charges of electrons and holes by X-ray energy such as a-Se in the X-ray receiving layer, and charges are separated by applying an electric field to the photoconductor during X-ray irradiation. The charge amount depending on the intensity of the irradiated X-ray is measured two-dimensionally in a minute area unit and converted into an electric signal, and an X-ray image is displayed on the CRT or film using the electric signal. The forming apparatus is being put into practical use.

 A feature of this apparatus is that X-ray energy is directly converted into an electric signal, and an electric field is applied at this time to suppress charge diffusion, so that a sharp X-ray image can be obtained. This technology has a function to convert flat panel detectors, that is, X-ray energy irradiated through a subject into electric signals for reconstructing them as X-ray transmission images. Are beginning to be used in flat plate X-ray image flat detectors having a sufficiently large area.

  In such a radiation image reading apparatus, a flat panel detector and a controller, an X-ray source, or the like is connected by a line such as a cable. The X-ray source sends an X-ray exposure signal to the flat panel detector via the controller and serves as a trigger to start reading. The controller also receives a signal read by the flat panel detector, thereby obtaining an X-ray image.

  As described above, the flat panel detector and the controller or the X-ray source are connected by a wire such as a cable.

  Further, since the wiring cannot be made long, it is possible to take pictures only near the controller, or when taking pictures in a hospital room or the like, for example, the controller must be moved, which is inconvenient.

  The present invention has been made in view of the above points, and can be driven as a cassette in a state where the cassette is fixed to the cassette fixed body and a state where it is detached from the cassette fixed body, and is independent of the controller and is located away from the controller. However, the object is to provide a radiation image generation system that can be photographed and is easy to use.

  In order to solve the above-described problems and achieve the object, the present invention is configured as follows.

The invention described in claim 1
“An X-ray source, an imaging panel that reads image data by generating image data with a plurality of detection elements arranged two-dimensionally according to the intensity of radiation emitted from the X-ray source, Radiation detection means for detecting irradiation, control means capable of controlling reading start of the imaging panel based on detection of radiation irradiation by the radiation detection means, and power supply to the imaging panel, the radiation detection means and the control means A portable cassette-type radiation image reading device having power supply means,
A controller for acquiring image data from the portable cassette-type radiation image reading device;
A cassette fixing body on which the portable cassette-type radiation image reading apparatus can be set;
A radiation image generation system comprising:
The portable cassette-type radiation image reading device is:
It can be used alone or in a state set in the cassette fixed body,
In a state where the cassette fixed body is set, it is possible to input an X-ray exposure signal from the X-ray source or the controller via the cassette fixed body,
The control means of the portable cassette type radiographic image reading apparatus comprises:
In a single state, the reading start of the imaging panel is controlled based on detection of radiation irradiation of the radiation detection means,
A radiation image generation system that controls reading start of the imaging panel based on the X-ray exposure signal in a state where the cassette fixing body is set . ].

The invention described in claim 2
“An imaging panel that reads image data by generating image data with a plurality of detection elements arranged two-dimensionally according to the intensity of radiation emitted from the X-ray source, and radiation detection that detects radiation irradiation Means,
Control means capable of controlling reading start of the imaging panel based on detection of radiation irradiation of the radiation detection means;
Power supply means for supplying power to the imaging panel, the radiation detection means and the control means;
Have
It can be used in the state of being set to a single unit or a cassette fixed body,
In a state where the cassette fixed body is set, it is possible to input an X-ray exposure signal from the X-ray source or the controller via the cassette fixed body,
The control means includes
In a single state, the reading start of the imaging panel is controlled based on detection of radiation irradiation of the radiation detection means,
The portable cassette-type radiographic image reading apparatus, wherein the reading start of the imaging panel is controlled based on the X-ray exposure signal in a state where the cassette fixing body is set. ].

  With the above configuration, the present invention has the following effects.

In the invention according to claim 1 or claim 2 , the cassette can be driven as a cassette in a state where the cassette is fixed to the cassette fixing member and a state where the cassette fixing member is detached from the cassette fixing member. Capable of shooting and easy to use. Further, the reading start is controlled based on any one of the X-ray exposure signal from the X-ray source or the controller and the detection result of the radiation detection means, which is easy to use. Further, in the state where the cassette is fixed to the cassette, the start of reading is controlled based on the exposure signal, wiring is not required, and usability is good.

It is a perspective view which shows the structure which fractured | ruptured a part of cassette type radiographic image reader. It is a block diagram which shows schematic structure of a cassette type | mold radiographic image reading apparatus. It is a schematic sectional drawing which shows an imaging panel. It is a figure which shows the state which irradiated the X-ray to the imaging panel. It is a schematic plan view which shows an imaging panel. It is a schematic sectional drawing which shows an imaging panel. It is a perspective view which shows the structure which fractured | ruptured a part of cassette type radiographic image reader. It is a block diagram which shows schematic structure of a cassette type | mold radiographic image reading apparatus. It is a perspective view which shows the structure which fractured | ruptured a part of cassette type radiographic image reader. It is a block diagram which shows schematic structure of a cassette type | mold radiographic image reading apparatus. It is a block diagram which shows schematic structure of a cassette type | mold radiographic image reading apparatus. It is a figure which shows the attachment or detachment state of a cassette type | mold radiographic image reader. It is a figure which shows the other attachment or detachment state of a cassette type | mold radiographic image reader.

  Hereinafter, an embodiment of the radiation image generation system of the present invention will be described. However, the configuration of the present invention is not limited to that described in the embodiment or shown in the drawings.

  FIG. 1 is a perspective view showing a structure in which a cassette type radiation image reading apparatus is partially broken, and FIG. 2 is a block diagram showing a schematic configuration of the cassette type radiation image reading apparatus.

  In the cassette type radiation image reading apparatus 1 of this embodiment, as shown in FIG. 1, a case plate 3 is attached to a base plate 2 to form a case 4. The case 4 is provided with a handle 5. As portable. A grid 6 is attached to the case plate 3 of the housing 4, and a display unit 8 is further disposed. Furthermore, an imaging panel 10, a control unit 13, a memory unit 14, and a power supply unit 15 are built in the housing 4. The imaging panel 10 includes a drive circuit 11 and a signal readout circuit 12.

  In such a cassette type, since it is not known when radiation is irradiated, a reading start means 20 is provided, and reading of the radiation image is started by the reading start means 20. This cassette type does not require wiring, is independent of the controller, and can be photographed at a distant position, making it easy to use.

  Further, in this embodiment, the image data transfer means 24 for converting the image data into a radio signal and transferring it to an external signal receiver in the housing 4 and the image data are automatically sent to the controller after being sent to the controller. Is provided to the external output machine. The external output control means 25 is constituted by a switch.

  The housing 4 is provided with a sensor 60 for measuring the distance between the X-ray source and the cassette, but may be provided on the X-ray source side. As this sensor 60, an infrared sensor, an ultrasonic sensor or the like is used. In addition, since the cassette-type radiation image reading apparatus 1 of this embodiment may carry a person, the outer casing 4 must be made of a strong material. Further, a vibration / impact absorber such as an elastic member may be provided in the casing 4 so that the imaging panel 10 in the casing 4 of the cassette is not broken.

  The cassette type radiation image reading apparatus 1 of this embodiment generates image data with a plurality of detection elements arranged two-dimensionally according to the intensity of radiation irradiated on the imaging panel 10 as shown in FIG. Read the radiation image. In addition, a reading start unit 20 including a switch is provided, and the reading start unit 20 starts reading of the radiation image of the imaging panel 10. In addition, the memory unit 14 is provided with a storage unit 21, and the storage unit 21 stores image data read from the signal reading circuit 12 of the imaging panel 10.

  The control unit 13 is provided with a control unit 22, which controls the reading start unit 20, the drive circuit 11 of the imaging panel 10 and the signal readout circuit 12, and starts the reading of the radiation image on the imaging panel 10 and The image data is read and stored in the storage means 21.

  Further, the power supply unit 15 is provided with a power supply unit 23, which supplies power for driving the imaging panel 10, the reading start unit 20, the storage unit 21, the display unit 8, and the control unit 22. .

  Further, the cassette type radiation image reading apparatus 1 of this embodiment has an image data transfer means 24 that returns image data to a radio signal and transfers it to an external signal receiver 100. The image data transfer means 24 returns the image data to an optical signal having a wavelength of 100 nm to 1 mm and transfers it to the external signal receiver 100. In this way, the image data transfer means 24 returns the image data to a radio signal, transfers it to the external signal receiver 100, and further transfers it to the controller 110. For this reason, no wiring is required, and photographing is possible even at a distant position, which is convenient.

  Further, the cassette type radiation image reading apparatus 1 of this embodiment has an external output control means 25 which is automatically sent to the external output machine 101 after being sent to the controller 110, and this external output control means 25 is It is controlled by the control means 22 and is supplied with power by the power supply means 23.

  The image data is sent to the controller 110 based on a command from the external output control means 25, and thereafter the image is automatically output from the external output device 101. The external output control means 25 can be constituted by a switch 25a. When the switch 25a is pressed at a predetermined timing, for example, the corresponding image data is transferred to the controller 110, and then the image is automatically displayed on the external output device 101. Can be output. Thus, after the image data is sent to the controller 110, the image is automatically output to the external output device 101, which is convenient for use, and an operation for outputting the image data from the controller 110 to the external output device 101 again. There is no need to do.

  The memory unit 14 stores ID information previously input (read) elsewhere, and when the image information is input to the ID information, the image data is transferred to the controller 110. After the transfer, an image is output from the external output device 101. Further, information (command information) on whether or not to output an image does not necessarily have a cassette, and the controller 110 may have it.

  Further, the display unit 8 is provided with a transfer display unit 27 for displaying whether or not the image data has been transferred to the controller 110, and by displaying whether or not the image data has been transferred to the controller 110 on the transfer display unit 27. Transfer confirmation is easy and convenient to use.

  The power supply means 23 is constituted by a rechargeable battery, and the display unit 8 is provided with a charge state display means 28 for displaying a charge state of a battery constituting the power supply means 23. By displaying the charging state of the power supply unit 23 on the charging state display unit 28, it is possible to easily know the charging state visually, and it is possible to avoid being unusable due to insufficient power. The charging state display means 28 may warn when the charging voltage of the power supply means 23 is lower than a predetermined value based on the charging voltage value from the voltage detection 29. For example, when the power supply voltage is insufficient, a flashing or buzzer By warning, etc., it can be surely notified in advance of insufficient charging.

  Further, a power switch 30 for driving the power supply means 23 is provided. When the power switch 30 is turned on, power is supplied to various places, and after photographing is finished, the power switch 30 is turned off to save power. Further, the power switch 30 automatically turns off and saves power when the radiographic image of the imaging panel 10 is not read for a certain period of time.

  The imaging panel 10 is configured as shown in FIGS. 3 is a schematic sectional view showing the imaging panel, FIG. 4 is a diagram showing a state in which the imaging panel is irradiated with X-rays, and FIG. 5 is a schematic plan view showing the imaging panel.

  As shown in FIG. 3, the imaging panel 10 is configured by sequentially laminating a photoconductive layer 121, a dielectric layer 122, and a front conductive layer 123 on a dielectric substrate layer 120, and the dielectric layer 122 is not always necessary.

  A plurality of first micro conductive electrode microplates 124 are provided on the dielectric substrate layer 120, and the outline of the minimum pixel that can be resolved by the imaging panel 10 is determined by the dimensions of the first micro conductive electrode microplate 124. . A capacitive dielectric material 125 is applied on the plurality of first minute conductive electrode microplates 124.

  Further, a plurality of transistors 129 having two electrodes 126 and 127 and a gate 128 are stacked on the dielectric substrate layer 120. Further, a plurality of second micro conductive electrode microplates 130 are stacked on the dielectric substrate layer 120.

  As shown in FIG. 4, when X-rays are irradiated, electrons-and holes + are generated in the dielectric layer 122 of the photoconductor, and the two charges are separated by the applied voltage. Then, for example, holes + are read as electrical signals by the first minute conductive electrode plate 124.

  As shown in FIG. 5, at least one transistor 129 connects a plurality of second minute conductive electrode microplates 130 to the X address line 141 and the Y sense line 142. The charge storage capacitor 136 is formed by the first micro conductive electrode micro plate 124, the second micro conductive electrode micro plate 130, and the electrostatic capacitance dielectric material 125. The second micro conductive electrode microplate 130 is also connected to the electrode 127 of the transistor 129. The first minute conductive electrode microplate 124 is connected to the ground.

  Transistor 129 acts as a bi-directional switch, allowing current to flow between Y sense line 142 and charge storage capacitor 136 depending on whether a bias voltage is applied to the gate via X address line 141.

  Conductive electrodes or X address lines 141 and conductive electrodes or Y sense lines 142 are arranged in a space between the plurality of second micro conductive electrodes microplates 130. The X address line 141 and the Y sense line 142 are arranged so as to be substantially orthogonal to each other as shown. The X address line 141 and the Y sense line 142 are individually accessible along the side or edge of the imaging panel 102 through lead wires or connectors.

  Each of the X address lines 141 is sequentially addressed by applying a bias voltage to the line and thus to the gate of the transistor 129 connected to the addressed X address line 141. As a result, the transistor 129 becomes conductive, and the charge stored in the corresponding charge storage capacitor 136 flows to the Y sense line 142 and to the input side of the charge detector 146. The charge detector 146 generates a voltage output that is proportional to the charge detected on the Y sense line 142. The output of the charge detector 146 is sampled sequentially to obtain an image signal representing the charge distribution of the microcapacitor on the addressed X address line 141, each microcapacitor representing one image pixel. When a signal is read from a certain pixel line on the X address line 141, the charge amplifier is reset through the reset line 149. The next X address line 141 is addressed and this process is repeated until all charge storage capacitors 136 have been sampled and the entire image has been read.

  The imaging panel 10 used in the cassette type radiation image reading apparatus 1 of this embodiment may have a two-layer panel structure. An embodiment of this two-layer panel structure is shown in FIG. 6 and has a structure in which a radiation shielding member 10c, a processing circuit portion 10d, and a radiation shielding member 10e are arranged in this order between two layers of panels 10a and 10b.

  In this way, the imaging panel 10 has a two-layer panel structure, and the radiation shielding members 10c and 10e are arranged between the two-layer panels 10a and 10b, so that the front and back can be photographed, while the other is photographed. While reading or transferring image data, you can shoot on the other side.

  Further, the radiation shielding members 10c and 10e are arranged between the two panels 10a and 10b. When one panel is irradiated with X-rays by the radiation shielding member 10c, X-rays are emitted to the opposite panel. Prevent it from leaking. Further, the radiation shielding member 10c, the processing circuit unit 10d, and the radiation shielding member 10e are arranged in this order between the two-layer panels 10a and 10b, and the influence of X-rays on the processing circuit unit 10d can be eliminated. it can.

  Next, another embodiment of the cassette type radiation image reading apparatus is shown in FIGS. FIG. 7 is a perspective view showing a structure in which a part of the cassette type radiation image reading apparatus is broken, and FIG. 8 is a block diagram showing a schematic configuration of the cassette type radiation image reading apparatus.

  The cassette type radiographic image reading apparatus 1 having the same reference numerals as those in the embodiment shown in FIG. 1 to FIG. In this embodiment, a radiation detection means 40 is attached to the case plate 3 in place of the reading start means 20 in the embodiments of FIGS. Radiation is detected by the radiation detection means 40 and reading of the radiation image of the imaging panel 10 is started.

  Thus, in the cassette type, since it is not known when the radiation is irradiated, the radiation detecting means 40 is provided, the radiation detecting means 40 detects the radiation, and the reading of the radiation image is started from the detection of the radiation. This cassette type does not require wiring, is independent of the controller, and can be photographed at a distant position, making it easy to use.

  Next, still another embodiment of the cassette type radiation image reading apparatus is shown in FIGS. FIG. 9 is a perspective view showing a structure in which a part of the cassette type radiographic image reading apparatus is broken, and FIG. 10 is a block diagram showing a schematic configuration of the cassette type radiographic image reading apparatus.

  Since the cassette type radiation image reading apparatus 1 is configured in the same manner as that of the embodiment shown in FIGS. 1 to 6 and the embodiment shown in FIGS. 7 and 8, the description thereof will be omitted. In this embodiment, the scanning start unit 20 shown in FIGS. 1 to 6 and the radiation detection unit 40 shown in FIGS. 7 and 8 are provided, and switching to switch between the scanning start unit 20 and the radiation detection unit 40 is performed. Means 41.

  Thus, in the cassette type, since it is not known when the radiation is irradiated, the reading start means 20 and the radiation detection means 40 are provided, and the switching means 41 switches between the reading start means 20 and the radiation detection means 40 to switch the radiation. Start reading the image. This cassette type does not require wiring, is independent of the controller, and can be photographed at a distant position, making it easy to use.

  Next, still another embodiment of the cassette type radiation image reading apparatus is shown in FIG. FIG. 11 is a block diagram showing a schematic configuration of a cassette type radiation image reading apparatus.

  The cassette type radiographic image reading apparatus 1 having the same reference numerals as those in the embodiment shown in FIG. 1 to FIG. In this embodiment, radiation detection means 45 that detects radiation and a grid 46 that moves according to a signal from the radiation detection means 45 are provided. By moving the grid 46, it is possible to remove the influence of moire that is a problem in the fixed grid. Further, unlike a conventional method of synchronizing with an X-ray generation signal, since a cable or the like is not used, the usability of the reading apparatus is good.

  Further, the conventional cassette-type radiation image reading apparatus 1 can be detachably attached to the cassette fixing members 50 and 51 as shown in FIGS. The cassette fixing body 50 of the embodiment of FIG. 12 is configured by attaching a case 50b to a support base 50a, and the cassette type radiation image reading apparatus 1 is set in the case 50b. The cassette fixing body 51 of the embodiment of FIG. 13 is configured by attaching a jig 51b to a support base 51a, and the cassette type radiation image reading apparatus 1 is set on the jig 51b.

  As described above, the cassette type radiation image reading apparatus 1 can be driven by being set on the cassette fixing bodies 50 and 51, and can be removed and driven as a cassette. The cassette type radiation image reading apparatus 1 can be used as a fixed type or removed and used as a cassette. Available.

  The cassette type radiation image reading apparatus 1 can supply power by being set in the cassette fixing members 50 and 51, and can be used in a fixed type by being set in the cassette fixing members 50 and 51. The power supply means 23 can be charged.

  Further, the cassette type radiation image reading apparatus 1 can transfer image data to the controller by being set in the cassette fixing members 50 and 51, and can be used in a fixed type or stored in the storage means 21. Existing image data can be transferred to the controller. Further, the cassette type radiation image reading apparatus 1 can be set to the cassette fixing members 50 and 51 to input the ID information, and the ID information can be transferred to the cassette.

  When the cassette is set on the cassette fixed body and used, the movement of the grid and the start of reading of the radiation image of the imaging panel 10 may be synchronized with the signal from the X-ray source.

  The imaging panel 10 is not limited to the one that converts radiation directly into electric charge and reads the electric charge with a capacitor to generate image data. For example, the imaging panel 10 converts the radiation into light by a phosphor such as a scintillator. The image data may be generated by reading light with a photodetector such as a photodiode, CCD, or C-MOS sensor.

  As described above, by transferring the image data read from the imaging panel in the state set in the cassette fixed body and in the state removed from the cassette fixed body, it can be used as a fixed type or removed as a cassette Available. In addition, in a state where the cassette is fixed on the cassette, the start of reading of the radiation image on the imaging panel is synchronized with the signal from the X-ray source, and imaging can be performed at a distant position, which is convenient. Further, in a state where the cassette is fixed to the cassette, the movement of the grid is synchronized with a signal from the X-ray source, wiring is not required, and convenience is good. Moreover, in the state set to the cassette fixed body, electric power is supplied to a power supply means, and it can be used as a fixed type or a cassette type. Also, in the state where the cassette is fixed, the ID information can be input to the cassette. For example, according to the input ID information, if the input is made, the corresponding image data is automatically displayed as an external image. The output can be output. Further, there is no need to perform an operation for outputting image data from the controller to the external output device.

  The present invention can be applied to, for example, a radiographic image generation system used for radiographic imaging for medical diagnosis and the like, and can be driven as a cassette in a state where the cassette is fixed to the cassette and a state where the cassette is detached from the cassette. Yes, it is independent from the controller, and can be taken from a remote location, making it easy to use.

DESCRIPTION OF SYMBOLS 1 Cassette type radiographic image reader 10 Imaging panel 20 Reading start means 21 Storage means 22 Control means 23 Power supply means 24 Image data transfer means 50, 51 Cassette fixed body

Claims (2)

An X-ray source;
An imaging panel that reads image data by generating image data by a plurality of detection elements arranged two-dimensionally according to the intensity of radiation emitted from the X-ray source, and radiation detection that detects radiation irradiation Means, control means capable of controlling reading start of the imaging panel based on detection of radiation irradiation of the radiation detection means, and power supply means for supplying power to the imaging panel, the radiation detection means and the control means A portable cassette-type radiation image reader;
A controller for acquiring image data from the portable cassette-type radiation image reading device;
A cassette fixing body on which the portable cassette-type radiation image reading apparatus can be set;
A radiation image generation system comprising:
The portable cassette-type radiation image reading device is:
It can be used alone or in a state set in the cassette fixed body,
In a state where the cassette fixed body is set, it is possible to input an X-ray exposure signal from the X-ray source or the controller via the cassette fixed body,
The control means of the portable cassette type radiographic image reading apparatus comprises:
In a single state, the reading start of the imaging panel is controlled based on detection of radiation irradiation of the radiation detection means,
A radiation image generation system that controls reading start of the imaging panel based on the X-ray exposure signal in a state where the cassette fixing body is set . An imaging panel that reads image data by generating image data with a plurality of detection elements arranged two-dimensionally according to the intensity of radiation emitted from the X-ray source;
Radiation detecting means for detecting radiation irradiation;
Control means capable of controlling reading start of the imaging panel based on detection of radiation irradiation of the radiation detection means;
Power supply means for supplying power to the imaging panel, the radiation detection means and the control means;
Have
It can be used in the state of being set to a single unit or a cassette fixed body,
In a state where the cassette fixed body is set, it is possible to input an X-ray exposure signal from the X-ray source or the controller via the cassette fixed body,
The control means includes
In a single state, the reading start of the imaging panel is controlled based on detection of radiation irradiation of the radiation detection means,
The portable cassette-type radiographic image reading apparatus, wherein the reading start of the imaging panel is controlled based on the X-ray exposure signal in a state where the cassette fixing body is set.