JPWO2017145444A1 - Portable radiographic imaging device - Google Patents

Abstract

Provided is a portable radiographic imaging device that can reliably return the shape of the housing to the original shape even if the housing is distorted. The sensor panel SP is provided with a sensor panel SP in which a plurality of radiation detection elements 7 are arranged two-dimensionally, and is formed in a housing 40 formed by a front plate 41 on the side on which radiation is incident and a back plate 42 on the opposite side. In the portable radiographic image capturing apparatus 1 configured by storing the front plate 41, one of the front plate 41 and the back plate 42 has a substantially flat plate shape, and the other is provided perpendicular to the flat plate surface 41A and the outer peripheral edge thereof. One of the front plate 41 and the back plate 42 is movable in the surface direction, and is attached to the end surface of the other side wall portion 41B of the front plate 41 and the back plate 42. Yes.

Description

  The present invention relates to a portable radiographic image capturing apparatus.

  Conventionally, CR (Computed Radiography) cassettes with a built-in photostimulable phosphor sheet that accumulates the energy of radiation that has passed through a subject have been widely used as devices used for radiographic imaging for the purpose of disease diagnosis and the like. Then, in order to be able to use the CR cassette on a photographing stand on which a conventional screen / film cassette is loaded, the JIS standard size (corresponding international standard) for the screen / film cassette is used. Are often formed in a shape conforming to IEC 60406).

  In recent years, as an alternative to the above-mentioned screen / film cassette and CR cassette, a plurality of radiation detection elements are arranged in a two-dimensional form (matrix), and each radiation detection element is irradiated through the subject. Development of a radiographic imaging device (flat panel detector, also referred to as a semiconductor image sensor) that generates a charge in accordance with the dose of radiation and reads the generated charge as a signal value is in progress. In addition, development of a portable radiographic imaging device (also referred to as an FPD cassette or the like) in which a sensor panel in which a plurality of radiation detection elements are arranged is housed in a housing is being promoted (see, for example, Patent Documents 1 and 2). ).

  In many cases, the portable radiographic image capturing apparatus is also configured to be loaded on an imaging stand and used for imaging. Then, in order to be able to be used by being loaded on an imaging table in which a conventional screen / film cassette or CR cassette is loaded, the portable radiographic imaging device is equipped with the above-mentioned screen / film cassette. In many cases, it is formed into a shape conforming to the JIS standard size (see, for example, Patent Document 3).

  In addition, the portable radiographic imaging device is required to be lightweight because a doctor or a nurse needs to position the imaging device with one hand. Therefore, it has become a big subject to achieve both rigidity and weight reduction of the portable radiographic image device.

JP-A-6-342099 JP 2000-258541 A JP 2009-103609 A

  By the way, when the radiographic image capturing apparatus is formed in a portable type (also referred to as a cassette type) as described above, it is not only mounted on the imaging stand and used for imaging as described above, but also, for example, a portable radiographic image capturing apparatus is used. It is also possible to take a picture in a state where the subject is inserted between the patient and the bed, or directly on the patient's body.

  However, if an excessive force is applied to the portable radiographic imaging device by the imaging as described above, the casing of the portable radiographic imaging device is distorted, and even if the portable radiographic imaging device is separated from the patient. There is a case where the distortion does not return to the original shape of the housing.

  If distortion remains in the casing of the portable radiographic image capturing apparatus in this way, not only the quality of the portable radiographic image capturing apparatus is deteriorated, but also, for example, the portable radiographic image capturing apparatus is imaged. There is a case where the operability of the portable radiographic image capturing device deteriorates due to the fact that it cannot be loaded even if it is loaded on the table.

  For example, when charging the built-in power source of the portable radiographic imaging device, the portable radiographic imaging device is loaded into a charging device such as a cradle, but the casing of the portable radiographic imaging device is distorted as described above. If it is, the charging device cannot be loaded, and there is a possibility that the built-in power source of the portable radiographic imaging device cannot be charged.

  The present invention has been made in view of the above problems, and a portable radiographic imaging device capable of reliably returning the shape of the housing to the original shape even when the housing is distorted. The purpose is to provide.

In order to achieve at least one of the above-described objects, a portable radiographic image capturing apparatus reflecting one aspect of the present invention includes the following.
A sensor panel in which a plurality of radiation detection elements are arranged two-dimensionally is provided, and the sensor panel is housed in a housing formed by a front plate on which radiation is incident and a back plate on the opposite side. In the portable radiographic imaging device
One of the front plate and the back plate is substantially flat,
The other of the front plate and the back plate has a flat plate-like surface and a side wall portion provided perpendicular to the outer peripheral edge thereof,
One of the front plate and the back plate is movable in the surface direction, and is attached to the end surface of the other side wall portion of the front plate and the back plate. .
Moreover, in order to implement | achieve at least one among the objectives mentioned above, the portable radiographic imaging apparatus reflecting the other side surface of this invention has the following.
A sensor panel in which a plurality of radiation detection elements are arranged two-dimensionally is provided, and the sensor panel is housed in a housing formed by a front plate on which radiation is incident and a back plate on the opposite side. In the portable radiographic imaging device
One of the front plate and the back plate is substantially flat,
The other of the front plate and the back plate has a flat plate-like surface and a side wall portion provided perpendicular to the outer peripheral edge thereof,
At the tip of the side wall provided perpendicular to the flat plate surface and its outer periphery, it further has an integral or separate protrusion.
The substantially flat plate has an opening having an area larger than the area of the protrusion when viewed from a direction perpendicular to the surface,
One of the front plate and the back plate is a portable radiographic imaging device attached to an end surface of the other side wall portion of the front plate and the back plate via a waterproof member.

  According to the portable radiographic image capturing apparatus of the system as in the present invention, even when the casing is distorted, the shape of the casing can be surely restored to the original shape.

It is a block diagram showing the equivalent circuit of the portable radiographic imaging apparatus which concerns on this embodiment. It is sectional drawing which shows the structure of the portable radiographic imaging apparatus which concerns on this embodiment. It is a figure showing the case where the dent of a back board is formed in linear form. It is a figure showing the case where the recess of a back board is formed in cyclic | annular form. It is a figure showing the state attached to the side wall part of the front board with the some screw over the perimeter of the peripheral part of a back board. It is an enlarged view showing the attachment structure of the front board and back board in the structural example 1 of a portable radiographic imaging apparatus. It is an enlarged view showing the attachment structure of the front board and back board in the modification 1-1 of a portable radiographic imaging apparatus. It is an enlarged view showing the attachment structure of the front board and back board in the modification 1-2 of a portable radiographic imaging apparatus. It is an enlarged view showing the attachment structure of the front board and back board in the structural example 2 of a portable radiographic imaging apparatus. It is an enlarged view showing the attachment structure of the front board and back board in the structural example 3 of a portable radiographic imaging apparatus. It is an image figure showing applying force so that it may dent inside a back board. It is a figure showing the structural example which can move a back board and a front board in all the fastening locations. It is a figure showing the example of composition at the time of arranging three places which regulate movement in one direction. It is a figure showing the structural example at the time of arrange | positioning one place which restricts the movement to one direction and one place which restrict | limits the movement to one direction. It is a figure showing another structural example at the time of arrange | positioning one place which restricts the movement to one direction, and one place which regulates the movement to one direction. It is sectional drawing showing the structural example of the cross section of the direction which regulates a movement of the fastening location which regulates a movement. It is sectional drawing showing the structural example of the cross section of the direction which regulates a movement of the fastening location which regulates a movement. It is sectional drawing showing the structural example of the cross section of the direction which regulates a movement of the fastening location which regulates a movement. It is sectional drawing which shows the case where a housing | casing has a level | step difference. It is sectional drawing which shows the case where the part of a ridge is formed in the curved surface. It is sectional drawing which shows the case where it forms so that the angle which a radiation incident surface and a side wall part make becomes an obtuse angle. It is a figure showing the state which mounts a several radiographic imaging apparatus on an imaging stand, and performs long imaging | photography with one shot. It is sectional drawing showing the part which the edge part of the some radiographic imaging apparatus with which the imaging stand was loaded overlaps back and forth. It is sectional drawing showing the structural example which provided the elastic member which has electroconductivity between the back board and the head part of a screw.

  Embodiments of a portable radiographic image capturing apparatus according to the present invention will be described below with reference to the drawings.

  In the following, the portable radiographic image capturing device may be simply referred to as a radiographic image capturing device. In the following, a so-called indirect radiographic imaging apparatus that includes a scintillator or the like as a radiographic imaging apparatus and converts an emitted radiation into electromagnetic waves of other wavelengths such as visible light to obtain an electrical signal will be described. The present invention can also be applied to a so-called direct type radiographic imaging apparatus in which radiation is directly detected by a radiation detection element without using a scintillator or the like.

[Circuit configuration of radiation imaging equipment]
First, the circuit configuration and the like of the radiographic image capturing apparatus according to the present embodiment will be described. FIG. 1 is a block diagram showing an equivalent circuit of the radiographic image capturing apparatus according to the present embodiment. As shown in FIG. 1, in the radiographic imaging apparatus 1, a plurality of radiation detection elements 7 are arranged in a two-dimensional shape (matrix shape) on a sensor substrate 50 (described later, see FIG. 2).

  A bias line 9 is connected to each radiation detection element 7, and a reverse bias voltage is applied from a bias power supply 14 via the bias line 9 and their connection 10. Each radiation detection element 7 is connected to a TFT (Thin Film Transistor) 8 as a switch element, and the TFT 8 is connected to the signal line 6.

  In the scanning drive unit 15, the on-voltage and the off-voltage supplied from the power supply circuit 15 a via the wiring 15 c are switched by the gate driver 15 b and applied to the lines L 1 to Lx of the scanning line 5. Each TFT 8 is turned off when a turn-off voltage is applied via the scanning line 5, and the conduction between the radiation detection element 7 and the signal line 6 is interrupted to accumulate charges in the radiation detection element 7. . Further, when an on-voltage is applied via the scanning line 5, the on-state is turned on, and the charge accumulated in the radiation detection element 7 is discharged to the signal line 6.

  Each signal line 6 is connected to each readout circuit 17 in the readout IC 16. Then, in the process of reading the signal value D, when a turn-on voltage is applied from the gate driver 15b to the line L where the scanning line 5 is located, the TFT 8 is turned on, and the charge from the radiation detection element 7 is transferred to the TFT 8 and the signal line. 6 and flows into the readout circuit 17 and the amplifier circuit 18 outputs a voltage value corresponding to the amount of electric charge.

  A correlated double sampling circuit (indicated as “CDS” in FIG. 1) 19 reads out and outputs the voltage value output from the amplifier circuit 18 as an analog signal value D. As described above, in this embodiment, each readout circuit 17 of the readout IC 16 reads out the electric charge generated in each radiation detection element 7 as the signal value D in accordance with the dose of irradiated radiation.

  Then, the signal value D output from the amplifier circuit 18 is sequentially transmitted to the A / D converter 20 via the analog multiplexer 21, and is sequentially converted into a digital signal value D by the A / D converter 20, and stored. The data are sequentially stored in the means 23. In the present embodiment, the signal is transmitted from all the radiation detection elements 7 by performing the above-described readout process while sequentially applying the on-voltage from the gate driver 15b of the scanning drive unit 15 to each of the lines L1 to Lx of the scanning line 5. The value D is read out.

  The control means 22 is a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), an input / output interface, etc., not shown, connected to the bus, an FPGA (Field Programmable Gate Array), or the like. It is configured. It may be configured by a dedicated control circuit.

  The control means 22 is connected to a storage means 23 composed of SRAM (Static RAM), SDRAM (Synchronous DRAM), NAND flash memory or the like, and a built-in power supply 24 composed of a lithium ion capacitor or the like. The control unit 22 is connected to a communication unit 30 for performing communication with the outside by a wireless method or a wired method via the antenna 29 or the connector 27 described above.

  Further, as described above, the control unit 22 controls the application of the reverse bias voltage from the bias power supply 14 to each radiation detection element 7 and controls the operation of the scanning drive unit 15 and the readout circuit 17 to The signal value D from the radiation detection element 7 is read out, the read signal value D is stored in the storage unit 23, or the stored signal value D is stored via the communication unit 30. Control such as transferring to the outside is performed.

[Configuration of portable radiographic imaging device]
FIG. 2 is a cross-sectional view showing the configuration of the portable radiographic image capturing apparatus according to this embodiment. As shown in FIG. 2, the radiographic image capturing apparatus 1 is configured by housing a sensor panel SP (also referred to as a TFT panel or the like) in a housing 40. In FIG. 2, the radiographic imaging device 1 is shown in a state where the radiation incident surface 41 </ b> A to which the radiation is irradiated is arranged on the lower side in the drawing. In the following, the vertical direction of the radiographic image capturing apparatus 1 will be described based on the case where the radiographic image capturing apparatus 1 is arranged in the state shown in FIG.

  In the present embodiment, the housing 40 of the radiographic image capturing apparatus 1 mainly includes a radiation incident surface 41A formed in a substantially rectangular flat plate shape and a side wall portion 41B provided perpendicular to the outer peripheral edge thereof. It is formed of a plate 41 and a back plate 42 formed in a substantially flat plate shape. In this embodiment, the front plate 41 is made of, for example, fiber reinforced plastic, and the back plate 42 is made of, for example, metal.

  The back plate 42 is attached to the side wall portion 41B of the front plate 41 with screws 43 that are engaging members. In the present embodiment, the support column 44 is provided vertically from the base 50, which will be described later, of the sensor panel SP toward the back plate 42, and the back plate 42 is attached to the support column 44 with the screw 43. ing.

  In FIG. 2, the back plate 42 is described as being screwed and attached to the side wall portion 41 </ b> B of the front plate 41 with screws 43, but actually, it is shown in FIG. As described above, a gap α is formed between the back plate 42 and the side wall portion 41 </ b> B of the front plate 41. Further, the configuration of the attachment portion of the back plate 42 to the front plate 41 by the screw 43, the configuration of the back plate 42, and the like including such a configuration will be described in detail later.

  On the other hand, in the present embodiment, the sensor panel SP is formed as follows. In the following description, the surface of each substrate or the like that faces the radiation incident surface 41A of the front plate 41 (that is, the lower surface in the drawing) is the front surface, and the surface that faces the back plate 42 (that is, the upper surface in the drawing). Surface) is called the back surface.

  The sensor panel SP includes a base 50 having a metal layer (not shown) such as lead that shields radiation. A sensor substrate 51 made of a glass substrate or the like is disposed on the surface side of the base 50. On the surface of the sensor substrate 51, the plurality of radiation detection elements 7 and the like described above are arranged in a two-dimensional manner.

  A scintillator 55 is formed on one surface of the scintillator substrate 54 formed of a glass substrate or the like. In the present embodiment, the sensor substrate 51 and the scintillator substrate 54 are disposed so that the scintillator 55 and each radiation detection element 7 face each other, and the sensor substrate 51 is disposed outside the radiation detection elements 7, the scintillator 55, and the like. And the scintillator substrate 54 are attached with an adhesive (not shown).

  A signal line 6 (see FIG. 1) or the like wired on the sensor substrate 51 is connected to a flexible circuit board 56 in which a chip such as a readout IC 16 is incorporated on a film. It is routed to the back side of the base 50 and connected to the PCB substrate 57 and the like.

  The PCB substrate 57 is provided with circuits such as the control means 22 and the storage means 23 (see FIG. 1) and electronic members (hereinafter collectively referred to as electronic equipment 58). 2 shows a state in which the electronic device 58 is arranged on the front surface side of the PCB substrate 57, the electronic device 58 is on the back surface side of the PCB substrate 57 (or on both the front surface side and the back surface side). You may arrange.

  In the radiographic image capturing apparatus 1 according to the present embodiment, the sensor panel SP is formed as described above. Since the electronic device 58 is disposed on the back side of the sensor panel SP, that is, on the back plate 42 side, the electronic device 58 is simply removed (that is, the center panel SP is not removed from the housing 40). The electronic device 58 can be easily exchanged.

  Further, as shown in FIG. 2, a spacer 60 is disposed between the scintillator substrate 54 and the front plate 41. In the present embodiment, a heat conducting member 61 is disposed between the readout IC 16 and the back plate 42, and heat generated by the readout IC 16 is conducted to the back plate 42 side from the back plate 42 to the outside of the apparatus. To dissipate heat. Further, a heat insulating member 62 is disposed between the readout IC 16 and the base 50 of the sensor panel SP so as to prevent heat generated by the readout IC 16 from being transmitted to the center panel SP side.

  On the other hand, in the present embodiment, the back plate 42 is formed with a recess 42 </ b> A on the inside of the housing 40 at a part thereof. Thus, by providing the recess 42A in the back plate 42, the strength of the substantially flat back plate 42 (especially the strength against bending and torsion), for example, as in the case of providing irregularities in the iron plate in order to improve the strength of the iron plate. ) Can be improved, and the strength of the radiographic imaging apparatus 1 itself can be improved.

  At this time, as shown in FIG. 2, if the recess 42 </ b> A of the back plate 42 is provided at a position in contact with the heat conducting member 61, the back plate 42 is attached to the side wall portion 41 </ b> B of the front plate 41. The heat conduction member 61 is pressed between the recess 42A of the 42 and the readout IC 16 and the like, and the adhesion between the readout IC 16 and the like, the heat conduction member 61, and the back plate 42 can be improved to improve the heat transfer efficiency.

  In the actual sensor panel SP, a plurality of readout ICs 16 may be arranged in parallel on the left side of FIG. 2 so as to be aligned in a direction perpendicular to the paper surface. In such a case, for example, as shown in FIG. 3A when the back plate 42 is viewed from the outside, a back corresponding to a portion where a plurality of readout ICs 16 (not shown in FIGS. 3A and 3B) are arranged in parallel. A recess 42A is formed so that the position of the plate 42 is linearly recessed inward, and all the heat conducting members 61 (not shown in FIGS. 3A and 3B) attached to each readout IC 16 with one recess 42A. ) Can be configured to press.

  Further, at that time, as shown in FIG. 3B, if the recess 42A is formed in an annular shape (in a rectangular shape) over the entire periphery of the peripheral portion of the back plate 42, the strength of the substantially flat plate-like back plate 42 is further improved. Thus, the strength of the radiation image capturing apparatus 1 itself can be further improved. Further, when the reading IC 16 does not generate heat as when the radiographic imaging device 1 is carried, the radiographic technician or the like can easily carry the radiographic imaging device 1 by hooking a finger on the recess 42A of the back plate 42. There is also a merit of becoming.

[Sealing of internal space with waterproof material]
In the radiographic imaging apparatus 1 according to the present embodiment, as shown in FIG. 2, the back plate 42 formed in a substantially flat plate shape is hermetically sealed in the internal space S formed by the back plate 42 and the front plate 41. In a state where the above is maintained, it is movably attached to the side wall portion 42B of the front plate 41. In addition, attaching the back plate 42 to the side wall portion 42B of the front plate 41 so as to be movable will be described later.

  And in this embodiment, packing 41C as a waterproofing member is arrange | positioned in the side wall part 41B of the front board 41 which is an attachment part of the front board 41 and the back board 42 over the perimeter. The packing 41C is made of an elastic material such as rubber.

  The packing 41 </ b> C is sandwiched between the back plate 42 and the side wall portion 41 </ b> B of the front plate 41 in a state where the back plate 42 is movably attached to the side wall portion 41 </ b> B of the front plate 41 by screws 43 that are engaging members. In addition to the deformation, the back plate 42 is urged away from the front plate 41 (upward in FIG. 2).

  In the following description, the case where the packing 41C is arranged on the side wall portion 41B of the front plate 41 as described above over the entire circumference will be described, but instead of such a configuration, for example, the packing is arranged on the back plate 42 side. It is also possible to arrange them. That is, although illustration is omitted, it is also possible to arrange the packing at the position of the back plate 42 corresponding to the entire circumference of the side wall portion 41B of the front plate 41. And even if comprised in this way, the exact effect similar to the case where packing 41C is arrange | positioned to the side wall part 41B of the front board 41 like this embodiment can be acquired.

  In the present embodiment, as described above, the back plate 42 is movably attached to the side wall portion 42B of the front plate 41. However, as described above, the packing disposed over the entire circumference of the side wall portion 41B of the front plate 41. Since 41C urges the back plate 42 in a direction away from the front plate 41, even if the back plate 42 moves slightly with respect to the side wall portion 42B of the front plate 41, the packing 41C is separated from the back plate 42. I will not leave.

  Therefore, as in the present embodiment, even if the back plate 42 moves slightly with respect to the side wall portion 42B of the front plate 41, the sealing 41C can seal the internal space S of the housing 40 of the radiographic imaging device 1 or It becomes possible to maintain watertightness accurately.

[About the back plate being movably attached to the side wall of the front plate]
Next, in the radiographic image capturing apparatus 1 according to the present embodiment, a configuration for movably attaching the back plate 42 to the side wall portion 42B of the front plate 41 will be specifically described below with some configuration examples. To do. The operation of the radiographic image capturing apparatus 1 according to this embodiment will also be described.

  In the present embodiment, as shown in FIG. 4, the back plate 42 is attached to the side wall portion 41 </ b> B of the front plate 41 by a plurality of screws 43 over the entire periphery of the peripheral portion. In addition, the direction in which the back plate 41C is pressed and the screwing direction are the same when the back plate 42 is attached, and the back plate 42 and the packing 41C are in close contact with each other. It becomes possible to seal. Further, as described above, the back plate 42 is also attached to the support column 44 (see FIG. 2) provided vertically from the base 50 or the like of the sensor panel SP toward the back plate 42 by the screw 43. .

[Configuration example 1]
FIG. 5 is an enlarged view showing a mounting structure of the front plate and the back plate in the configuration example 1 of the radiographic image capturing apparatus 1. The same applies to each of the following configuration examples. However, in the configuration example 1, the back plate is formed with a gap α between the back plate 42 and the side wall portion 41B of the front plate 41 as shown in FIG. 42 is attached to the side wall portion 41 </ b> B of the front plate 41 by a screw 43.

  In FIG. 5 and FIGS. 6A and 6B described later, the gap α is described relatively larger than the back plate 42 and the front plate 41 in order to make the gap α easier to see. Further, in FIG. 5 and the like, the sensor panel SP and the like are illustrated in a simplified manner, and the description of the configuration of the recess 42A and the like of the back plate 42 is omitted.

  In the configuration example 1, as shown in FIG. 5, the packing 41 </ b> C that is the waterproof member described above is located on the inner side of the attachment position where the back plate 42 is attached to the side wall portion 41 </ b> B of the front plate 41 by the screw 43 that is the engagement member. It is arranged. An insert nut 41D is embedded at the attachment position of the side wall portion 41B of the front plate 41 so that the upper end portion protrudes upward from the upper surface of the side wall portion 41B of the front plate 41.

  A hole β having a diameter larger than the diameter of the insert nut 41D and smaller than the diameter of the head of the screw 43 is provided at a position corresponding to the insert nut 41D of the back plate 42. Then, when attaching the back plate 42 to the side wall 41B of the front plate 41, the screw 43 in a state where the upper end portion of the insert nut 41D provided on the side wall 41B of the front plate 41 is inserted into the hole β of the back plate 42. Is screwed to the insert nut 41D.

  If the degree to which the upper end portion of the insert nut 41D protrudes from the upper surface of the side wall portion 41B of the front plate 41 is too small, the side wall of the back plate 42 and the front plate 41 is secured when the screw 43 is screwed to the insert nut 41D. The gap α is not formed between the portion 41B and the back plate 42 is attached in a state where it cannot move with respect to the side wall portion 41B of the front plate 41.

  Further, if the degree of protruding the upper end portion of the insert nut 41D from the upper surface of the side wall portion 41B of the front plate 41 is too large, the screw 43 is screwed to the insert nut 41D as described above and the back plate 42 is attached to the front plate 41. When attached to the side wall 41B, the back plate 42 and the packing 41C are not in contact with each other, and the sealing and water-tightness of the internal space S of the housing 40 of the radiation imaging apparatus 1 by the packing 41C are ensured. Can not be.

  Therefore, in the configuration example 1, the degree of protruding the upper end portion of the insert nut 41D from the upper surface of the side wall portion 41B of the front plate 41 is appropriately adjusted, and the gap α is defined between the back plate 42 and the side wall portion 41B of the front plate 41. And the packing 41C is sandwiched between the back plate 42 and the side wall portion 41B of the front plate 41 so as to be deformed.

  In the configuration example 1, even if the screw 43 is screwed to the insert nut 41D, the gap α is formed between the back plate 42 and the side wall portion 41B of the front plate 41. It is possible to move in a direction approaching the front plate 41 or moving away from the front plate 41 (that is, the vertical direction in FIG. 5).

  Further, since the diameter of the hole β provided in the back plate 42 is larger than the diameter of the insert nut 41D, the screw 43 is screwed to the insert nut 41D and the back plate 42 is attached to the side wall portion 41B of the front plate 41. Thus, the back plate 42 can also move in the left-right direction (that is, the left-right direction in FIG. 5) with respect to the front plate 41.

  Therefore, the back plate 42 is attached to the side wall portion 41B of the front plate 41 so as to be movable in the vertical direction and the horizontal direction within a predetermined range.

  At that time, in a state where the screw 43 is screwed to the insert nut 41D and the back plate 42 is attached to the side wall portion 41B of the front plate 41, the packing 41C is sandwiched between the back plate 42 and the side wall portion 41B of the front plate 41. It will be in a state to be deformed. Therefore, as described above, even if the back plate 42 moves slightly with respect to the side wall portion 42B of the front plate 41, the packing 41C is not separated from the back plate 42. Therefore, the casing 41 of the radiographic image capturing apparatus 1 is used by the packing 41C. The airtightness and watertightness of the internal space S are accurately maintained.

  Therefore, in the configuration example 1, the back plate 42 is movably attached to the side wall portion 41B of the front plate 41 in a state in which the airtightness and watertightness of the internal space S of the housing 40 of the radiographic imaging device 1 are maintained. It becomes possible.

[Modification 1-1]
In the configuration example 1, as shown in FIG. 5, instead of embedding the insert nut 41 </ b> D in the side wall portion 41 </ b> B of the front plate 41, for example, as shown in FIG. 6A, from the upper surface of the side wall portion 41 </ b> B of the front plate 41, A protrusion having a diameter smaller than the diameter of the hole β of the back plate 42 is protruded, and a female screw 41E is formed there. Even if the back plate 42 is attached to the side wall portion 41B of the front plate 41 by screwing the screw 43 to the female screw 41E, the back plate 42 is formed in the same manner as in the configuration example 1 described above. It becomes possible to movably attach to the side wall portion 41B of the front plate 41 in a state where the airtightness and watertightness of the internal space S of the housing 40 of the photographing apparatus 1 are maintained.

[Modification 1-2]
Further, instead of forming the female screw 41E on the side wall portion 41B of the front plate 41 as shown in FIG. 6A, for example, a pilot hole 41F is provided in the side wall portion 41B of the front plate 41 as shown in FIG. Even if it is configured to be screwed (that is, self-tapping) while cutting the screw with 43 itself, it can be configured in the same manner as described above.

[Configuration example 2]
On the other hand, instead of embedding the insert nut 41D so that the upper end portion of the insert nut 41D protrudes from the upper surface of the side wall portion 41B of the front plate 41 as in the configuration example 1, for example, as shown in FIG. The insert nut 41D is embedded so that the upper end portion of the front plate 41 is substantially flush with the upper surface of the side wall portion 41B of the front plate 41, and the stepped screw 43 ^* is screwed to the insert nut 41D. The back plate 42 can be movably attached to the side wall portion 41B of the front plate 41 in exactly the same manner as in the above configuration example 1.

Also in the configuration example 2, in a position corresponding to the insert nut 41D of the back plate 42 is larger than the diameter of the shoulder screw 43 ^* of the cylindrical portion 43 * ^A, than the diameter of the shoulder screw 43 ^* of the head Is also provided with a small diameter hole β. In addition, the length of the cylindrical portion 43 ^* A of the stepped screw 43 ^* (the length in the direction orthogonal to the radial direction) is adjusted as appropriate so that a gap α is formed between the back plate 42 and the side wall portion 41B of the front plate 41. And the packing 41C is sandwiched between the back plate 42 and the side wall portion 41B of the front plate 41 so as to be deformed.

  Even in the case of the configuration example 2, exactly as in the case of the configuration example 1 described above, the back plate 42 is made to have the airtightness and watertightness of the internal space S of the housing 40 of the radiographic imaging device 1. It becomes possible to attach to the side wall part 41B of the front board 41 so that a movement is possible.

[Modification 2]
Although illustration is omitted, also in the configuration example 2, as shown in FIG. 7, instead of embedding the insert nut 41 </ b> D in the side wall portion 41 </ b> B of the front plate 41, a female screw is provided on the side wall portion 41 </ b> B itself of the front plate 41. The stepped screw 43 ^* may be screwed to the formed screw, or a pilot hole may be provided instead of the female screw, and the stepped screw 43 ^* itself may be screwed while self-tapping. Is possible.

[Configuration example 3]
On the other hand, in the above configuration examples 1 and 2, etc., the packing 41C that is a waterproof member is disposed on the inner side of the attachment position where the back plate 42 is attached to the side wall portion 41B of the front plate 41 by the screws 43 that are engaging members. However, it is also possible to configure the packing 41 </ b> C to be disposed outside the attachment position of the back plate 42 to the side wall portion 41 </ b> B of the front plate 41.

  In the following, the case where the attachment structure of the back plate 42 to the side wall portion 41B of the front plate 41 is configured in the same manner as in the above configuration example 1 (see FIG. 5) will be described. The same can be said for the case of 2 or each modified example. In this case, for example, as shown in FIG. 8A, a packing 41 </ b> C that is a waterproof member is disposed outside each insert nut 41 </ b> D provided on the side wall 41 </ b> B of the front plate 41.

  With this configuration, the back plate 42 is attached to the side wall portion 41B of the front plate 41 with the screw 43 screwed to the insert nut 41D in the same manner as in the first and second configuration examples. A gap α is formed between 42 and the side wall portion 41 </ b> B of the front plate 41. Further, the packing 41 </ b> C is configured to be deformed by being sandwiched between the back plate 42 and the side wall portion 41 </ b> B of the front plate 41.

  Therefore, even when configured as in Configuration Example 3, the back plate 42 is sealed with the internal space S of the housing 40 of the radiographic image capturing apparatus 1 as in the case of the above-described Configuration Examples 1 and 2 or the like. It becomes possible to attach to the side wall portion 41B of the front plate 41 so as to be movable while maintaining water tightness.

  However, in the case of the above configuration examples 1 and 2, etc., the packing 41C is disposed on the inner side of the attachment position of the back plate 42 to the side wall portion 41B of the front plate 41 (see FIG. 5 and the like). Even if moisture such as blood or urine of the patient enters through the gap α between the back plate 42 and the front plate 41, the inside of the housing 40 of the radiographic imaging apparatus 1 is covered with the packing 41C (waterproof member) that exists inside it. Although it is possible to prevent moisture from entering the space S, in the configuration example 3 (see FIG. 8A), moisture can enter the internal space S from the hole β portion of the back plate 42.

  Therefore, when the housing 40 of the radiographic imaging apparatus 1 is configured as in the configuration example 3, as shown in FIG. 8A, a screw packing 45 is disposed in the hole β portion of the back plate 42, and the screw When the screw 43 is screwed to the insert nut 41D, the screw packing 45 is preferably sandwiched between the screw 43 and the back plate 42 so as to be waterproofed.

  At this time, as described above, in this embodiment, even if the screw 43 is screwed to the insert nut 41D, the back plate 42 is not only in the horizontal direction but also in the vertical direction (that is, on the front plate 41). It can also move in the direction of approaching or moving away from the front plate 41. For this reason, even if the back plate 42 is pushed into the state closest to the front plate 41 (that is, the back plate 42 is in contact with the upper surface of the side wall portion 41B of the front plate 41), the screw packing 45 is A screw packing 45 having an appropriate thickness is used so that the state of being sandwiched between the head of the screw 43 and the back plate 42 is maintained.

  On the other hand, if it comprises like the structural example 3, it will be in the state by which the edge part of the back board 42 was urged | biased upwards by packing 41C which is a waterproof member. However, since the screw 43 is inside the packing 41C, the portion inside the screw 43 of the back plate 42 is urged downward with the screw 43 as a fulcrum. Therefore, when configured as in configuration example 3, as shown in the image diagram of FIG. 8B, a force is applied to the back plate 42 so as to be recessed inward, and the back plate 42 is prevented from swelling outward.

  When the housing 40 (ie, the back plate 42 or the front plate 41) of the radiographic image capturing apparatus 1 is expanded, for example, the radiographic image capturing apparatus 1 cannot be loaded even if an attempt is made to load the radiographic image capturing apparatus 1 on an imaging stand or cradle (not shown). As a result, the operability of the radiographic image capturing apparatus 1 deteriorates. However, when configured as in Configuration Example 3, the casing 40 (at least the back plate 42) of the radiographic image capturing apparatus 1 is prevented from expanding as described above. Therefore, it is possible to accurately prevent the operability of the radiographic image capturing apparatus 1 from deteriorating.

[effect]
As described above, according to the radiographic image capturing apparatus 1 according to the present embodiment, even if the back plate 42 is attached to the side wall portion 41B of the front plate 41 with the screw 43 or the stepped screw 43 ^* that is the engaging member, The plate 42 is attached to the front plate 41 so as to be movable in the vertical direction and the horizontal direction within a predetermined range.

  Therefore, for example, a force that causes distortion of the radiographic imaging apparatus 1 by applying the radiographic imaging apparatus 1 to a patient is applied, and the back plate 42 and the front plate 41 of the radiographic imaging apparatus 1 are relatively moved. Even if the position shift occurs, if no force is applied to the radiographic image capturing apparatus 1, the back plate 42 moves relative to the front plate 41 and returns to the original undistorted state.

  Therefore, in the radiographic image capturing apparatus 1 according to the present embodiment, even if a force is applied to the housing 40 of the radiographic image capturing apparatus 1 and the housing 40 is distorted, the force is not applied to the radiographic image capturing apparatus 1. The shape of the housing 40 can be reliably returned to the original shape. Therefore, it is possible to accurately prevent problems such as distortion remaining in the housing 40 of the radiographic image capturing apparatus 1 and making it impossible to mount the radiographic image capturing apparatus 1 on an imaging stand, a cradle, etc., thereby improving the operability of the radiographic image capturing apparatus 1. It becomes possible to keep.

  It is also possible to configure the front plate 41 and the back plate 42 in the present embodiment to be reversed. That is, in the above embodiment, as shown in FIG. 2, for example, the front plate 41 has a flat radiation incident surface 41A and a side wall portion 41B provided perpendicularly to the outer periphery thereof, and the back plate 42 is The back plate 42 is configured to be attached to the end surface of the side wall portion 41 </ b> B of the front plate 41 while being movable in the surface direction of the back plate 42.

  However, although not shown, on the contrary, the front plate 41 is configured in a substantially flat plate shape, and the back plate 42 is configured to have a flat plate surface and a side wall portion provided perpendicular to the outer peripheral edge thereof. However, the front plate 41 can be configured to be attached to the end surface of the side wall portion of the back plate 42 in a state in which the front plate 41 can move in the surface direction of the front plate 41.

  And the structure demonstrated about the radiographic imaging apparatus 1 which concerns on this embodiment is applicable similarly to the structure which reversed the structure of the front board 41 and the back board 42 as mentioned above. And even if comprised in this way, the completely same beneficial effect as the radiographic imaging apparatus 1 which concerns on this embodiment can be acquired.

  Further, as in the radiographic imaging apparatus 1 according to the present embodiment, even if the back plate 42 or the like moves with respect to the front plate 41 or the like as described above, the internal space S of the housing 40 of the radiographic imaging apparatus 1. If it is configured to maintain the airtightness and watertightness of the patient, it becomes possible to accurately prevent moisture such as blood and urine of the patient from entering the housing 40 of the radiographic imaging device 1. It is possible to accurately prevent the occurrence of problems such as the intrusion of the electronic device 58 and the failure of the electronic device 58.

  Further, as shown in FIG. 2 and the like, the thickness of the side wall portion 41B of the front plate 41 (the thickness in the left-right direction in FIG. 2 and the like) is the thickness of the radiation incident surface 41A of the front plate 41 (in FIG. 2 and the like). If it is configured to be larger than the thickness (vertical thickness), it is bent with respect to the housing 40 of the radiographic imaging apparatus 1 as compared to the case where both are configured to have the same thickness. That is, it becomes possible to improve the rigidity (bending rigidity) when a force is applied (so that the casing 40 is shaped like a “<”) upward or downward in FIG. 2 or the like, and the casing of the radiation imaging apparatus 1 can be improved. It is possible to more accurately prevent the body 40 from being distorted.

  In the study by the present inventors, if the thickness of the side wall 41B of the front plate 41 is 3 to 6 times or more than the thickness of the radiation incident surface 41A, for example, the front plate 41 of the radiographic imaging apparatus 1 Even if a bending force is applied to the housing 40 of the radiographic imaging apparatus 1 as in the case where the patient's body is placed on the radiation incident surface 41A, the casing 40 of the radiographic imaging apparatus 1 is sufficiently damaged. It has been found that bending stiffness can be obtained.

  For example, as shown in FIG. 4, the back plate 42 of the radiographic imaging apparatus 1 is attached to the side wall portion 41 </ b> B of the front plate 41 with a plurality of screws 43, but the back plate 42 is a portion of all the screws 43. If attached to the front plate 41 so as to be movable, the back plate 42 may be entirely displaced with respect to the front plate 41. As a result, for example, the product outer shape becomes larger than a predetermined dimension, which causes a problem that the image photographing apparatus cannot be loaded on the photographing stand.

  Therefore, the back plate 42 is movably attached to the front plate 41 or the like as in the present embodiment for the screw 43 portion of a predetermined location (for example, 3, 4 locations, or 1 location) among all the screws 43. Instead of this, it is possible to restrict the movement of the screw portions of the back plate 42 and the front plate 41 in the plane direction, or it is possible to provide an additional positioning shape while keeping the screw portions movable at all positions. . Hereinafter, this point will be described.

  10 to 12 show examples of arrangements of fastening points that restrict the movement of the back plate 42 and the front plate 41. For reference, FIG. 9 shows an example in which the back plate 42 and the front plate 41 are movable at all fastening points. 9 to 12 show a case where eight holes β are provided in the back plate 42 for easy viewing of the drawings, and the diameter of the hole β is much larger than the actual diameter. ing.

  Moreover, in FIGS. 9-12, the screw 43 is not fastened and the state which can see insert nut 41D in the back of the hole (beta) provided in the back board 42 is shown. In FIG. 9, since all the holes β are formed in the same diameter and the same shape, the back plate 42 and the front plate 41 are movable at all fastening points.

  In order to prevent the overall displacement of the back plate 42 and the front plate 41, for example, as shown in FIG. 10, three locations that restrict movement in one direction may be arranged (p1 to p1 in the drawing). p3). In FIG. 10, movement in the x direction is restricted at two places (p1, p2 in the figure), and movement in the y direction is restricted at one place (p3 in the figure).

  Further, as shown in FIG. 11 and FIG. 12, one place (p4 in FIG. 11 and p6 in FIG. 12) that restricts movement in all directions and one place that restricts movement in one direction (FIG. 11). P5 of FIG. 12 and p7) of FIG. 12 may be combined. That is, it is possible to prevent the relative positions of the back plate 42 and the front plate 41 from shifting by providing at least two locations that restrict movement in one direction. In addition, in p4 of FIG. 11 and p6 of FIG. 12, for example, the insert nut 41D is fitted into the hole β (that is, the outer diameter of the insert nut 41D and the inner diameter of the hole β are substantially the same). Movement is regulated.

  13A to 13C show a configuration example of a cross section of the fastening portion that restricts the movement (see, for example, p1 in FIG. 10) in the direction in which the movement is restricted. 13A and the like are cross-sectional views taken along line AA in FIG.

  For example, as shown in FIG. 13A, with a gap α in the thickness direction between the back plate 42 and the front plate 41, the clearance CL between the insert nut 41D and the like and the hole β in the back plate 42 (that is, the diameter of the hole β). The difference between the outer diameter of the insert nut 41D and the insert nut 41D may be narrowed to such an extent that the position is determined (that is, the relative movement between the back plate 42 and the front plate 41 is restricted). Specifically, if it is configured so that CL <0.4 mm, generally a sufficient positioning effect can be obtained.

  Further, as shown in FIG. 13B, the back plate 42 and the front plate 41 are grounded with the insert nut 41D and the like and the clearance CL of the hole β of the back plate 42 being packed to such an extent that the position is determined and the screw 43 is tightened. Further, the height of the insert nut 41D and the shape of the front plate 41 may be configured. According to the configuration of FIG. 13B, the front plate 41 and the back plate 42 can be made conductive, which may be advantageous in terms of electrical performance (for example, prevention of image unevenness due to static electricity).

  13A and 13B show an example of positioning using the insert nut 41D for fastening. As shown in FIG. 13C, a positioning-dedicated structure such as a positioning pin 46 is provided separately from the fastening member. May be. Further, the shape of the insert nut 41 </ b> D and the positioning pin 46 may be integrated with the front plate 41.

  With this configuration, as described above, even if a force is applied to the housing 40 of the radiographic image capturing apparatus 1 and the housing 40 is distorted, if the force is not applied to the radiographic image capturing apparatus 1, The back plate 42 moves as necessary at the portion of the screw 43 that is movably attached to the plate 41 or the like, so that the shape of the housing 40 can be surely returned to the original shape, and the screw 43 at the predetermined position is also provided. Alternatively, since the back plate 42 does not move with respect to the front plate 41 in the additional positioning shape portion, it is possible to accurately prevent the back plate 42 from being entirely displaced with respect to the front plate 41. .

  Further, in FIGS. 2 and 5, etc., the head of the screw 43 is positioned outside the back surface of the back plate 42 (the upper surface of the back plate 42 in FIG. 2, etc.) with the screw 43 screwed. Although not shown, although the illustration is omitted, the head of the screw 43 in a screwed state, for example, by recessing the back plate 42 inward at the mounting position of the screw 43, is outside the back surface of the back plate 42. It is also possible to configure so as not to come out.

  If comprised in this way, when inserting the radiographic imaging apparatus 1 between a patient and a bed, for example, the head of the screw | thread 43 will be hooked on a patient's clothes, sheets, etc. of the radiographic imaging apparatus 1 It is possible to accurately prevent the operability from deteriorating.

  In this way, when considering the operability of the radiographic imaging apparatus 1 when the radiographic imaging apparatus 1 is inserted between a patient and a bed, for example, as shown in FIG. If there is a step γ between the radiation incident surface 41A and the side wall 41B of the front plate 41 of the body 40, the operability of the radiographic imaging apparatus 1 may deteriorate due to the step γ being caught on the patient's clothes or sheets. There is sex.

  Therefore, as shown in FIGS. 2 and 5, the radiation incident surface 41 </ b> A and the side wall portion are formed by integrally forming the radiation incident surface 41 </ b> A and the side wall portion 41 </ b> B of the front plate 41 of the radiographic imaging apparatus 1. It is desirable that 41B is smoothly connected with no step. If comprised in this way, when inserting the radiographic imaging device 1 between a patient and a bed, for example, it will become possible to insert the radiographic imaging device 1 smoothly, and the operativity of the radiographic imaging device 1 will be improved. It becomes possible to improve.

  Further, for example, as shown in FIG. 14B, at least a ridge portion δ (that is, a corner portion) between the radiation incident surface 41A and the side wall portion 41B of the front plate 41 is formed with a curved surface (for example, an R chamfering process may be performed). For example, when the radiographic imaging apparatus 1 is inserted between the patient and the bed, the radiographic imaging apparatus 1 can be inserted more smoothly, and the operability of the radiographic imaging apparatus 1 can be improved. It becomes. Note that the corners of the back plate 42 (that is, the peripheral edge of the back plate 42) can be similarly configured.

  Furthermore, for example, as shown in FIG. 14C, if the angle θ formed between the radiation incident surface 41A of the front plate 41 and the side wall portion 41B is formed to be an obtuse angle, for example, the radiographic imaging apparatus 1 is connected to the patient and the bed. Therefore, the radiographic image capturing apparatus 1 can be more smoothly inserted, and the operability of the radiographic image capturing apparatus 1 can be improved. At this time, the ridge portion δ may be formed with a curved surface.

  For example, as shown in FIG. 15, a plurality of radiographic imaging apparatuses 1 are loaded in the cassette holder 101 of the imaging stand 100, and the radiation generating apparatus 102 is applied to an imaging site such as the entire spine of the patient as the subject H. In some cases, the long exposure is performed by so-called one shot.

  And in such a long imaging | photography, as shown in FIG. 16, the edge part of the some radiographic imaging apparatus 1 with which the cassette holder 101 of the imaging stand 100 was loaded will be in the state which overlaps back and forth. That is, when viewed from the radiation generator 102 (not shown in FIG. 16, disposed on the left side in FIG. 16), for example, among the plurality of radiographic imaging apparatuses 1 loaded in the cassette holder 101, the radiation The upper end portion of the radiographic imaging device 1A near the generation device 102 and the lower end portion of the radiographic imaging device 1B far from the radiation generation device 102 are overlapped in the front-rear direction.

  When long imaging is performed by irradiating radiation from the radiation generation apparatus 102, the housing 40 of the radiographic imaging apparatus 1A on the side close to the radiation generation apparatus 102 is captured on the side far from the radiation generation apparatus 102. Reflected in the radiographic image captured by the apparatus 1B, a horizontal stripe or the like is generated in the radiographic image captured by the radiographic image capturing apparatus 1B. Therefore, after correcting the horizontal streaks of the radiographic image captured by the radiographic image capturing apparatus 1B, the radiographic image captured by the radiographic image capturing apparatus 1A, the radiographic image captured and corrected by the radiographic image capturing apparatus 1B, and the like Are combined to obtain a single long image (not shown).

  At this time, for example, as shown in FIG. 14A, if there is a step γ between the radiation incident surface 41A and the side wall 41B of the front plate 41 of the housing 40 of the radiographic image capturing apparatus 1, as shown in FIG. The step γ of the housing 40 of the radiographic imaging device 1A on the side close to the generation device 102 is reflected in the radiographic image captured by the radiographic imaging device 1B on the side far from the radiation generation device 102.

  Therefore, compared with the case where there is no level difference γ in the housing 40 of the radiographic imaging device 1A on the side close to the radiation generating device 102, the radiographic image captured by the radiographic imaging device 1B on the side far from the radiation generating device 102 is included. More horizontal stripes and the like occur, and correction processing for horizontal stripes becomes more complicated and troublesome.

  However, as shown in FIGS. 2 and 5, etc., if the radiation incident surface 41A and the side wall 41B of the front plate 41 of the radiographic image capturing apparatus 1 are smoothly connected without any step, as described above. It is possible to accurately avoid that the correction processing such as horizontal stripes in the radiographic image taken by the radiographic imaging device 1B far from the radiation generating device 102 is complicated or troublesome due to the step γ. There is also a merit that it becomes.

  Further, as shown in FIG. 14A, if there is a step γ between the radiation incident surface 41A and the side wall portion 41B of the front plate 41 of the housing 40 of the radiographic imaging apparatus 1, dust or dirt that has entered the step γ portion. Etc. may be difficult to remove.

  However, as shown in FIG. 2, FIG. 5, etc., if the radiation incident surface 41A of the front plate 41 of the radiographic imaging apparatus 1 and the side wall portion 41B are smoothly connected in a state where there is no step, such a step is formed. There is an advantage that dust and dirt are not accumulated in the portion γ, and the quality of the radiographic imaging apparatus 1 can be improved in terms of hygiene.

  Although not shown, if the radiographic imaging device 1 is inserted between the subject patient and the bed or is directly applied to the patient's body, the human body or other charged object is captured. There is a case where static electricity is applied by touching the device. Static electricity causes noise by adding noise to the signal at the time of shooting, causing image unevenness, or destroying elements in the circuit.

  On the other hand, if the front plate 41 and the back plate 42 are electrically connected to function as a ground (GND) having a large electric capacity, the above-described adverse effects can be prevented. Referring to FIG. 5 described above, the insert nut 41D and the screw 43 are in contact with the front plate 41, and the back plate 42 is urged by the packing 41C to come into contact with the head of the screw 43. The conduction from the plate 41 to the back plate 42 is ensured, and the above configuration is realized.

  However, when a load is applied to the radiographic imaging device 1 during imaging and the back plate 42 is pushed in a direction approaching the front plate 41 side, the contact between the back plate 42 and the head of the screw 43 is cut off, and the front plate Since the continuity between 41 and the back plate 42 cannot be maintained, it is easily affected by static electricity.

  For such a problem, as shown in FIG. 17, it is effective to provide a conductive elastic member 47 between the back plate 42 and the head of the screw 43. The conductive elastic member 47 is compressed by the urging force of the packing 41C when no load is applied to the radiographic imaging device 1, and forms a gap α between the back plate 42 and the head of the screw 43. Contact to ensure continuity. In order to appropriately form the gap α, it is preferable to adjust the elasticity of the elastic member 47 by the elasticity of the packing 41C to be small.

  The elastic member 47 having conductivity is not affected by the elasticity of the elastic member 47 even when a load is applied and the back plate 42 approaches the front plate 41 and the distance between the back plate 42 and the head of the screw 43 increases. Follow and maintain contact with both to ensure continuity. Further, the elastic member 47 is disposed so as not to be fixed to at least one of the back plate 42 and the head of the screw 43 while maintaining the gap β, thereby preventing the back plate 42 from moving in the surface direction. It becomes possible not to be.

  In addition, examples of the elastic member 47 include conductive rubber and foamed material, but a material that exhibits elasticity depending on the shape, such as a spring washer or a waved washer, is made of a conductive material such as metal. Also good. If conductive rubber or foam material is used as the elastic member 47, the metals are not brought into direct contact with each other, and there is an effect of preventing the occurrence of electrolytic corrosion.

  Needless to say, the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist of the present invention.

  It can be used in the field of radiographic imaging (especially in the medical field).

1 Radiographic imaging device (portable radiographic imaging device)
7 Radiation Detection Element 40 Housing 41 Front Plate 41A Radiation Incident Surface 41B Side Wall 41C Packing (Waterproof Member)
42 Back plate 42A Recess 43 Screw (engagement member)
43 ^* Stepped screw (engagement member)
SP sensor panel γ step δ ridge θ angle

Claims (14)

A sensor panel in which a plurality of radiation detection elements are arranged two-dimensionally is provided, and the sensor panel is housed in a housing formed by a front plate on which radiation is incident and a back plate on the opposite side. In the portable radiographic imaging device
One of the front plate and the back plate is substantially flat,
The other of the front plate and the back plate has a flat plate-like surface and a side wall portion provided perpendicular to the outer peripheral edge thereof,
One of the front plate and the back plate is movable in the surface direction, and is a portable radiographic imaging device attached to an end surface of the other side wall portion of the front plate and the back plate.   The portable radiographic image capturing apparatus according to claim 1, wherein a waterproof member is disposed on the side wall portion over the entire circumference.   The portable radiographic imaging device according to claim 1, wherein a waterproof member is disposed at a position corresponding to the entire circumference of the side wall portion of one of the front plate and the back plate.   The waterproof member has elasticity, and in a state where one of the front plate and the back plate is movably attached to the side wall portion by the engaging member, 4. The portable radiographic image capturing apparatus according to claim 2, wherein the portable radiographic image capturing apparatus is deformed by being sandwiched between one of the first side wall and the side wall portion and urges the back plate in a direction away from the front plate.   The said waterproof member is arrange | positioned inside the position from which the one of the said front board and the said back board was attached to the said side wall part by the engagement member. The portable radiographic imaging apparatus described.   The said waterproof member is arrange | positioned outside from the position where one of the said front board and the said back board was attached to the said side wall part by the engagement member. The portable radiographic imaging apparatus described.   The portable radiographic imaging device according to any one of claims 1 to 6, wherein a thickness of the side wall portion is larger than a thickness of the other surface of the front plate and the back plate.   The portable radiographic imaging device according to any one of claims 1 to 7, wherein one of the front plate and the back plate is partially provided with a recess.   The portable radiographic imaging device according to any one of claims 1 to 7, wherein one of the front plate and the back plate is provided with an annular recess around the entire periphery of the peripheral portion thereof. .   The portable radiation according to any one of claims 1 to 9, wherein the other of the front plate and the back plate is smoothly connected with the surface and the side wall without any step. Image shooting device.   The portable radiographic imaging device according to any one of claims 1 to 10, wherein a ridge between at least the other surface of the front plate and the back plate and the side wall portion is formed as a curved surface. .   The other of the said front board and the said back board is formed so that the angle | corner which the said surface and the said side wall part make becomes an obtuse angle, The portable type as described in any one of Claims 1-11. Radiation imaging device.   13. The structure according to claim 1, wherein the other side wall portion of the front plate and the back plate is provided with a structure that restricts movement in at least one of the plane directions at two or more locations. The portable radiographic imaging device according to the item. A sensor panel in which a plurality of radiation detection elements are arranged two-dimensionally is provided, and the sensor panel is housed in a housing formed by a front plate on which radiation is incident and a back plate on the opposite side. In the portable radiographic imaging device
One of the front plate and the back plate is substantially flat,
The other of the front plate and the back plate has a flat plate-like surface and a side wall portion provided perpendicular to the outer peripheral edge thereof,
At the tip of the side wall provided perpendicular to the flat plate surface and its outer periphery, it further has an integral or separate protrusion.
The substantially flat plate has an opening having an area larger than the area of the protrusion when viewed from a direction perpendicular to the surface,
One of the front plate and the back plate is a portable radiographic imaging device attached to an end surface of the other side wall portion of the front plate and the back plate via a waterproof member.

Images