JP2009237074A - Cassette type radiographic image detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cassette type radiographic image detector incorporating a battery and equipped with a radio communication means, which can utilize existing equipment fit to a cassette of JIS standard size while securing a communication function, and is easily loaded. <P>SOLUTION: The cassette type radiographic image detector incorporates: a signal detection part 151 for detecting radiation; a detector control part 27 for generating radiographic image data; a communication part 28 for transmitting and receiving information by radio with an external device; and the battery 25 for supplying power to each of the parts in a housing 3 of dimension having interchangeability with the cassette of JIS standard size, and the cassette type radiographic image detector has a grip member 8 detachably attached to the housing 3 and having an antenna device 9b electrically connected to the communication part 28. The communication part 28 is constituted to be electrically connected to the antenna device 9b provided in the grip member 8 when the grip member 8 is attached to the housing 3. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a cassette type radiation image detector.

Conventionally, for the purpose of disease diagnosis and the like, a radiographic image taken using radiation, represented by an X-ray image, has been widely used.
Such medical radiographic images were conventionally taken using a screen film, but in recent years, digitization of radiographic images has been realized. For example, a stimulable phosphor layer forms radiation transmitted through a subject. After being stored in the photostimulable phosphor sheet, the photostimulable phosphor sheet is scanned with laser light, and thereby the photostimulated light emitted from the photostimulable phosphor sheet is photoelectrically converted to image data. A CR (Computed Radiography) apparatus for obtaining the above has been widely used.

  The cassette for CR used for photographing with a CR device will be able to continue to use existing equipment such as a Bucky table or cassette holder that has been introduced to be compatible with conventional screen / film cassettes. The screen / film cassette is designed and manufactured according to the JIS standard size. In other words, cassette size compatibility is maintained, effective use of existing facilities and digitization of image data are achieved.

  Recently, as a means for obtaining a medical radiation image, an FPD (Flat Panel Detector) is known as a detector for detecting irradiated radiation and acquiring it as digital image data (see, for example, Patent Document 3). Furthermore, portable imaging devices (portable radiation image detectors) in which this FPD is housed in a housing have come into practical use.

Since such a portable detector can be carried, it can also be taken in a patient's room or the like, and imaging can be performed. Since the angle can be adjusted, it is expected to be widely used.
However, if the transfer of the acquired image data or the supply of power to each part of the apparatus is performed by wire, the detector must be used with the wires connected for that purpose, so it is free to carry and position / The ease of adjustment of the angle or the like is hindered, and the merit of the portable type is impaired.

  In view of this, a device has been proposed in which a battery (rechargeable battery) is provided in the detector, and wireless communication means (antenna device or the like) is provided so that image data and the like can be transmitted wirelessly and power can be supplied wirelessly ( For example, see Patent Document 1).

  However, when transmitting captured image data to the outside by wireless communication means, in the case of bedside imaging, metal objects that interfere with the wireless communication function are located around the radiation image detector at the time of imaging. When there is not, there is not much problem, but when radiography is loaded on a bucky table or the like made of metal or the like, radio communication function may be hindered by surrounding metal parts.

  Therefore, when the radiation image detector is loaded on the Bucky table or the like, a method of switching to use the communication path on the Bucky table side is also conceivable. However, for this purpose, it is necessary to replace the existing Bucky table with one having such a communication path, which entails a great investment in the operation of the radiation image detector, which is not preferable.

In addition, the photographing unit that performs photographing and the operation unit that controls the photographing unit have wireless communication means for transmitting and receiving control signals and image signals, and the wireless communication means of the photographing unit is a housing of the photographing unit. A directional antenna provided at the distal end of the extended communication cable extended from the cable, and when the radiation image detector is loaded on a bucky table or the like, pull out the communication cable built in the housing, A technique is disclosed in which an antenna is positioned outside the Bucky table so that communication can be performed without being affected by peripheral components (see, for example, Patent Document 2).
JP 2001-224579 A Japanese Patent No. 3990914

  As described above, the currently popular CR cassettes are sized according to the JIS standard size of conventional screen / film cassettes, and the Bucky table and the like are also made according to the JIS standard size. . For this reason, if the FPD can be used in a cassette that conforms to this JIS standard size, the existing equipment installed in the facility can be used for photographing using the FPD, and as a photographing means Equipment investment when introducing FPD can be minimized.

  However, in the method described in Patent Document 2, it is necessary to secure a space for storing the extension communication cable in the housing. For this reason, there is a problem that it is difficult to fit the size of the radiation image detector into a size compatible with a conventional JIS standard size cassette.

  In addition, what is described in Patent Document 2 requires that an extension communication cable be pulled out before loading the radiation image detector onto a bucky table or the like, which is complicated in the loading operation.

  Also, even if the communication cable can be pulled out after loading, when the radiation image detector is loaded on a Bucky table or the like, the side with the cable pull-out portion is positioned on the distal end side in the insertion direction. It is necessary to reload it again.

  The present invention has been made in view of the circumstances as described above, and is a cassette type radiation image detector with a built-in battery and wireless communication means, which is compatible with a JIS standard size cassette while ensuring a communication function. It is an object of the present invention to provide a cassette type radiation image detector that can use existing facilities and can easily perform a loading operation.

In order to achieve the above object, the present invention provides:
Radiation image data is generated on the basis of the detection result of the radiation image detection means and the radiation image detection means for detecting the radiation that has passed through the subject in a casing formed to a size compatible with the JIS standard cassette size. Incorporating radiation image data generating means, communication means for wirelessly transmitting / receiving information to / from an external device, and power supply means for supplying power to the respective units,
A handle having an antenna device detachably attached to the housing and electrically connectable to the communication means;
The communication means is a cassette type radiation image detector configured to be electrically connected to an antenna device provided in the handle portion when the handle portion is attached to the housing.

According to the cassette type radiation image detector (cassette FPD) configured as in the present invention, the power supply means and the antenna device are provided. It can be done without using it.
Since the antenna device is provided on the handle portion, the antenna device can be separated from a bucky table made of metal or the like at the time of photographing without providing an extension communication cable or the like. For this reason, while maintaining the wireless communication sensitivity, the casing can be made to have dimensions compatible with the JIS standard cassette size, and the existing equipment can be effectively used.

  Further, since the handle portion can be attached, the cassette type radiation image detector that tends to be relatively heavy can be easily carried and moved. In addition, because the detector is loaded onto the Bucky table etc. with the handle, it is possible to prevent reloading without having to check the orientation of the detector and to prevent reloading. It is possible to easily carry out the loading operation when loading to the like.

  Hereinafter, an embodiment of a cassette type radiation image detector according to the present invention will be described with reference to FIGS. However, the scope of the invention is not limited to the illustrated examples.

FIG. 1 is a perspective view of a cassette type radiation image detector (hereinafter referred to as “cassette type detector”) in the present embodiment.
The cassette type detector 1 in the present embodiment is a portable cassette type flat panel detector (hereinafter referred to as “FPD”), and the cassette type detector 1 detects the irradiated radiation digitally. A detector unit 2 (see FIG. 4 and the like) that is acquired as image data, and a housing 3 that is a housing that houses the detector unit 2 are provided. The cassette type detector 1 includes a gripping member 8 that is detachably attached to the housing 3.

FIG. 2 is an exploded perspective view of the cassette type detector 1 in the present embodiment.
As shown in FIG. 2, the housing 3 has a bottom surface portion 41 and a side wall portion 42 and is formed in a substantially box shape. When the cassette type detector 1 is used for imaging, an opening 48 is formed on the radiation incident side. And a front member 5 disposed on the radiation incident side of the cassette type detector 1.

  The front member 5 includes a flat portion 51 that is a rectangular portion formed in a rectangular shape, and a bent rising portion (side wall portion) 52 that is configured integrally with the flat portion 51. Similarly, it is formed in a box shape. The front member 5 has an opening 58 on the side opposite to the radiation incident side when the cassette type detector 1 is used for imaging, and functions as a lid for closing the opening 48 of the back member 4.

The housing 3 is integrated by joining the back member 4 and the front member 5 together. The joining method of the back member 4 and the front member 5 is not specifically limited, For example, you may join by screwing, and you may adhere and fix.
In addition, it is preferable that the height of the bending rising part 52 of the front member 5 and the height of the side wall part 42 of the back member 4 are substantially 1: 1.

  In the present embodiment, the thickness of the housing 3 in the radiation incident direction is 15 mm. Although the thickness dimension of the housing 3 in the radiation incident direction is not limited to 15 mm, it is a dimension that falls within the range of the JIS standard cassette size (15 mm + 1 mm and 15 mm-2 mm) in a conventional screen / film cassette. Preferably there is. Since most existing devices such as CR cassettes and Bucky tables are made in accordance with the JIS standard size of this screen / film cassette, by adjusting the dimensions of the housing 3 to the JIS standard cassette size, Even when imaging is performed by the cassette type detector 1 which is a cassette type FPD, existing equipment can be used.

  An antenna device 9a for wirelessly transmitting and receiving information between the cassette type detector 1 and an external device is embedded in the side wall portion 52 of the front member 5.

As shown in FIG. 3, a pair of flat radiation plates 91 and 92 made of metal and a pair of radiation plates 91 and 92 are connected to the antenna device 9a, and power is supplied to the pair of radiation plates 91 and 92. A power feeding unit 93 is provided.
In the present embodiment, of the pair of radiation plates 91 and 92, one radiation plate 91 is formed so that the shape in front view is a trapezoid, and the other radiation plate 92 has a substantially circular shape in front view. It is formed to become. The power feeding portion 93 is connected to the approximate center of the upper bottom portion of one radiation plate 91 and is connected to a part of the outer periphery of the other radiation plate 92.
A predetermined gap is formed between the pair of radiation plates 91 and 92 by being connected by the power supply unit 93.

  The type and shape of the antenna device 9a are not limited to those exemplified here. The position of the antenna device 9a is not limited to the illustrated example. For example, you may affix on the side wall part 42 grade | etc., Of the back member 4. FIG. The number of antenna devices 9a is not limited to one, and a plurality of antenna devices 9a may be provided. An antenna device 9b described later has the same configuration as the antenna device 9a.

Further, in this embodiment, a gripping member 8 to be described later is attached to one side surface of the housing 3, and one side surface of the back member 4 and the front member 5 on the surface to which the gripping member 8 is attached. Two mounting screw holes 31 for mounting the gripping member 8 are formed.
An antenna to which an antenna side connection terminal 95 of an antenna device 9b provided on the gripping member 8 described later is connected on one side surface of the back member 4 and in the vicinity of any one of the mounting screw holes 31. A connector 32 is provided. The antenna connector 32 electrically connects the antenna-side connection terminal 95 and the circuit board 23 (see FIG. 4). When the antenna device 9b of the holding member 8 communicates with an external device, the antenna connector 32 9b is adapted to transmit and receive signals to and from the communication unit 28 (see FIG. 12) via the antenna connector 32. The antenna connector 32 is connected to a detector control unit 27 described later. When the antenna-side connection terminal 95 is connected to the antenna connector 32, this is detected and the detection result is transmitted to the detector control unit 27. To do.

  A rechargeable battery 25 provided inside the housing 3 is provided on the same side of the side surface of the back member 4 as the surface on which the mounting screw hole 31 and the antenna connector 32 are provided, as shown in FIGS. A charging terminal 45 that is connected to an external power source or the like when charging (see FIG. 4 etc.) is formed, and a power switch 46 that switches ON / OFF of the power source of the cassette type detector 1 is disposed. ing. Further, a notch portion 55 into which the upper edge portion of the power switch is fitted is formed at one end of the bent rising portion 52 of the front member 5 and at a position corresponding to the power switch 46. Furthermore, the corner formed by the bent rising portion 52 and the flat portion 51 where the cutout portion 55 is formed is configured by, for example, an LED or the like to display the charging status of the rechargeable battery 25 and various operation statuses. An indicator 56 is provided.

  Of the members constituting the housing 3, at least the front member 5 is formed of a material having a high radiation transmittance including carbon fiber or the like. The formation method is not particularly limited. For example, the front member 5 is formed by laminating a plurality of carbon prepregs (carbon plate materials) which are sheets in which carbon fibers are impregnated with a thermosetting resin such as an epoxy resin or an unsaturated polyester. It can arrange | position on the type | mold shape | molded in this shape, and can be set as a desired shape by baking this at high temperature and high pressure.

  In the present embodiment, the back member 4 is formed of a light metal such as aluminum or magnesium. In addition, the material which forms the back member 4 is not specifically limited, For example, it may be formed with the material containing a carbon fiber etc. similarly to the front member 5. FIG.

The gripping member 8 is detachably attached to the side surface of the housing 3, and has a handle portion 81 having a handle portion formed in a substantially U shape, and is fixed to the housing 3 at both ends of the handle portion 81. And a fixed portion 82.
An antenna device 9b is embedded in the handle portion 81 for wirelessly transmitting and receiving information between the cassette-type detector 1 and an external device. As described above, the configuration of the antenna device 9b is the same as that of the antenna device 9a (see FIG. 3).
Each fixing portion 82 is provided with two insertion holes 84 corresponding to the positions of the mounting screw holes 31. As shown in FIG. 2, the gripping member 8 is mounted and fixed to the housing 3 by inserting a screw 85 from the insertion hole 84 and screwing it into the mounting screw hole 31.
Further, on one surface of the one fixing portion 82 and a surface that contacts the housing 3 when the gripping member 8 is attached, the antenna device 9b and the circuit board in the housing 3 correspond to the position of the antenna connector 32. A convex antenna-side connection terminal 95 is provided for electrical connection with the terminal 23.

  In this embodiment, the antenna side connection terminal 95 is automatically connected to the antenna connector 32 by attaching the gripping member 8 to the housing 3. When the antenna side connection terminal 95 is connected to the antenna connector 32, the antenna connector 32 detects this and transmits a signal to that effect to the detector control unit 27.

  4 is a plan view of the state in which the detector unit 2 is housed in the housing 3 as viewed from the upper side (radiation incident side during imaging), FIG. 5 is a cross-sectional view taken along the line CC in FIG. 4, and FIG. FIG. 5 is a DD cross-sectional view in FIG. 4. In FIG. 4, for convenience, the arrangement of each member inside the cassette type detector 1 when the flat surface portion 51 and the detection panel 21 of the front member 5 are removed is schematically shown.

  As shown in FIGS. 4 to 6, the detector unit 2 includes a detection panel 21, a circuit board 23 on which various electronic components 22 are mounted, and the like. In the present embodiment, the circuit board 23 is fixed to a base 24 made of resin or the like, and the circuit board 23 is attached via the base 24 by bonding and fixing the base 24 to the detection panel 21. It is fixed to the detection panel 21. The base 24 is not an essential component of the present invention, and the circuit board 23 or the like may be directly fixed to the detection panel 21 without the base 24 being interposed.

  As shown in FIG. 4, in this embodiment, the circuit board 23 on which the electronic component 22 is mounted is divided into four parts, which are arranged close to each corner of the detection panel 21. The electronic component 22 is disposed on the circuit board 23 along the outer periphery of the detection panel 21. The electronic component 22 is preferably disposed at a position as close to each corner of the detection panel 21 as possible. By arranging the electronic component 22 on the circuit board 23 in this way, when the detector unit 2 is housed in the housing 3, the electronic component 22 is near the corner of the housing 3 and the flat portion 51 (rectangular shape of the front member 5). Part).

  In the present embodiment, as the electronic component 22 arranged on the circuit board 23, for example, a CPU (central processing unit) (not shown) constituting a detector control unit 27 (see FIG. 12) that controls each unit, There are a storage unit (not shown) composed of a ROM (read only memory), a RAM (Random Access Memory), etc., a scanning drive circuit 16 (see FIG. 12), a signal readout circuit 17 (see FIG. 12), and the like. In addition to the ROM and RAM, an image storage unit that includes a rewritable read-only memory such as a flash memory or the like and that stores an image signal output from the detection panel 21 may be provided.

  The detector unit 2 is provided with a communication unit 28 that transmits and receives various signals to and from an external device. For example, the communication unit 28 transfers the image signal output from the detection panel 21 to the external device via the antenna devices 9a and 9b described above, and transmits the imaging start signal transmitted from the external device to the antenna devices 9a and 9b. It is supposed to receive via.

  Further, on the base 24, a plurality of drive units constituting the cassette type detector 1 (for example, a scan drive circuit 16 (see FIG. 12) described later, a signal readout circuit 17 (see FIG. 12), a communication unit 28, A rechargeable battery 25 is provided as power supply means for supplying power to the image storage unit 18, a charge amount detection unit (not shown), the indicator 56, the detection panel 21, and the like.

  As the rechargeable battery 25, for example, a rechargeable battery such as a nickel cadmium battery, a nickel metal hydride battery, a lithium ion battery, a small sealed lead battery, or a lead storage battery can be used. Further, a fuel cell or the like may be applied instead of the rechargeable battery 25. Note that the shape, size, number, arrangement, and the like of the rechargeable battery 25 as the power supply means are not limited to those illustrated in FIG.

  The rechargeable battery 25 is electrically connected to the aforementioned charging terminal 45 by being installed at a predetermined position on the base 24. For example, the cassette type detector 1 is connected to an external power source. By attaching to a charging device such as a cradle (not shown), the terminal on the charging device side and the charging terminal 45 on the housing 3 side are connected and the rechargeable battery 25 is charged. .

  As shown in FIGS. 4 and 6, a buffer member 26 is provided between each electronic component 22 and the rechargeable battery 25 to protect these components from being damaged by interference with the housing 3. ing. In addition, the number, arrangement | positioning, etc. of the buffer member 26 and the electronic component 22 are not limited to what was illustrated here. The material of the buffer member 26 is not particularly limited, and for example, an elastic resin such as polyurethane can be applied.

7 is a plan view of the detection panel 21, FIG. 8 is a side view of the detection panel 21 viewed from the direction of arrow F in FIG. 7, and FIG. It is sectional drawing.
The detection panel 21 includes a scintillator layer (light emitting layer) 211 that converts incident radiation into light, a first glass substrate 214 formed on one surface, and is laminated below the scintillator layer 211 and converted by the scintillator layer 211. The signal detector 151 (see FIG. 11) that detects the converted light and converts it into an electrical signal is configured to include a second glass substrate 213 formed on one surface, and these are laminated. It has a laminated structure.

  The scintillator layer 211 has, for example, a phosphor as a main component and outputs an electromagnetic wave having a wavelength of 300 nm to 800 nm, that is, an electromagnetic wave (light) ranging from ultraviolet light to infrared light centering on visible light, based on incident radiation. It is like that.

The phosphor used in the scintillator layer 211 is, for example, a material using CaWO ₄ or the like as a base material, or a luminescent center substance in a base material such as CsI: Tl, Cd ₂ O ₂ S: Tb, or ZnS: Ag. An activated material can be used. Further, when the rare earth element is M, a phosphor represented by a general formula of (Gd, M, Eu) ₂ O ₃ can be used. In particular, CsI: Tl and Cd ₂ O ₂ S: Tb are preferable because of high radiation absorption and light emission efficiency. By using these, high-quality images with low noise can be obtained.

  The scintillator layer 211 is formed, for example, on a support (not shown) formed of various polymer materials (polymers) such as a cellulose acetate film, a polyester film, and a polyethylene terephthalate film by, for example, vapor deposition using a phosphor. The phosphor layer is formed of a columnar crystal of the phosphor. As the vapor deposition method, a vapor deposition method, a sputtering method, a chemical vapor deposition (CVD) method or the like is preferably used. In any of the methods, the phosphor layer can be vapor-grown into independent elongated columnar crystals on the support.

The scintillator layer 211 is affixed to the lower side of the first glass substrate 214 (the side opposite to the side on which radiation is incident during imaging), and the upper side of the first glass substrate 214 (the side on which radiation is incident during imaging). ) Is further laminated with a glass protective film 215.
A second glass substrate 213 is laminated on the lower side of the scintillator layer 211 (the side opposite to the side on which radiation is incident at the time of photographing), and glass is formed on the lower side of the second glass substrate 213. A protective film 216 is further laminated.

  Both the first glass substrate 214 and the second glass substrate 213 have a thickness of about 0.6 mm, and the end surfaces are cut by a laser, that is, the cut surfaces, the cut surfaces, and the glass substrates. Smoothing processing is performed to smooth the ridge line portion with the upper surface of the material and the ridge line portion between the cut surface and the lower surface of the glass substrate. In addition, the thickness of the 1st glass base material 214 and the 2nd glass base material 213 is not limited to 0.6 mm. Further, the first glass substrate 214 and the second glass substrate 213 may have different thicknesses.

Here, the smoothing process by cutting the end surfaces of the first glass substrate 214 and the second glass substrate 213 with a laser will be described.
When cutting glass, first, streaks (scratches) are formed on the glass surface to form vertical cracks in the thickness direction of the glass (scribing work), and stress is applied to break up the cracks. It is common to go through two work processes called (work). Conventionally, the work of scuffing the glass surface (scribing work) has been performed using cemented carbide, electrodeposited diamond, sintered diamond, or the like. However, when the glass surface is scratched with cemented carbide or diamond, fine irregularities are formed on the cut (divided) glass end face, and this irregularity part is applied when a load such as bending is applied to the glass. Since stress concentrates on the surface, there is a problem that it is easy to break.
In this regard, in the present embodiment, a work (scribing work) for scratching the surfaces of the first glass base material 214 and the second glass base material 213 using a laser is performed. When the laser is used in this way, the end face of the glass after cutting (dividing) is smoothed, so that the strength of the glass against a load such as bending can be increased.
Rather than the size of the external force, the glass substrate cracks are caused by the formation of partial burrs and partial protrusions that cause stress concentration when cutting the glass substrate. Thus, by performing the process of smoothing the end face after cutting, it is possible to prevent the occurrence of cracking of the glass substrate even for a considerable external force (stress).

  As a cutting device for cutting the end surfaces of the first glass substrate 214 and the second glass substrate 213 with a laser, for example, in a laser oscillation unit, YAG (Yttrium Aluminum Garnet yttrium / aluminum / garnet crystal) is laser optical. A YAG laser or the like used as a medium is preferably used, but the cutting apparatus used for cutting is not limited to this.

  On the upper side of the second glass substrate 213 (side facing the scintillator layer 211), electromagnetic waves (light) output from the scintillator layer 211 are converted into electric energy and accumulated, and an image based on the accumulated electric energy. A signal detection unit 151 that is a detection unit that outputs a signal is formed.

As described above, in the present embodiment, the signal detection unit 151 is stacked on the lower side of the scintillator layer 211, and the second glass substrate 213 disposed on the lower side of the signal detection unit 151, and the scintillator layer The signal detection unit 151 and the scintillator layer 211 are sandwiched between the first glass substrate 214 disposed on the upper side of the 211 and the first glass substrate 214.
Conventionally, it was thought that cracking of the glass substrate could not be prevented unless the stress acting on the internal glass substrate through the housing was suppressed, so a space was provided between the housing and the glass substrate. A buffer member that relaxes / reduces the external force is frequently used. For this reason, the housing is further increased in size.
In this regard, the inventors of the present invention, rather than the size of the external force acting on the glass substrate, the partial burrs that cause stress concentration during the cutting of the glass substrate, It has been found that this is due to the formation of partial convex and concave portions. Therefore, in order to remove the burrs and the convex and concave portions that cause the stress concentration, a process of smoothing the end face after cutting is performed, and thereby the patient acting on the housing 3 having the above-described configuration is processed. It has become possible to prevent the occurrence of cracks and the like of the glass base materials 213 and 214 with respect to loads and deflections caused by weight and the like.

  In addition, a sealing member 217 is provided along the outer peripheral edge of the first glass base material 214 and the second glass base material 213, and the first glass base material 214 and the second glass base material 217 are provided by the sealing member 217. The glass substrate 213 is bonded and bonded. Thereby, intensity | strength can be raised more with respect to loads, such as a bending.

  Further, when the first glass substrate 214 and the second glass substrate 213 are bonded together, air is sucked from the space between the first glass substrate 214 and the second glass substrate 213. After the deaeration, the sealing member 217 is used for bonding and bonding. This prevents moisture contained in the air from affecting the scintillator layer 211 and the like. Long life can be achieved.

  Further, a buffer member 218 for protecting the detection panel 21 from an external impact or the like is provided near each corner of the detection panel 21 and between the corners.

  Here, the circuit configuration of the detection panel 21 will be described. FIG. 10 is an equivalent circuit diagram of a photoelectric conversion unit for one pixel constituting the signal detection unit 151.

  As shown in FIG. 10, the configuration of the photoelectric conversion unit for one pixel is a photodiode 152 and a thin film transistor (hereinafter referred to as “TFT”) 153 that extracts electrical energy accumulated in the photodiode 152 as an electrical signal by switching. It consists of and. The photodiode 152 is an image sensor that generates and accumulates charges. The electrical signal taken out from the photodiode 152 is amplified by an amplifier 154 to a level that can be detected by the signal readout circuit 17.

  Specifically, when light is irradiated, a charge is generated in the photodiode 152, and when a signal reading voltage is applied to the gate G of the TFT 153, the charge is transferred from the photodiode 152 connected to the source S of the TFT 153. It flows to the drain D side of the TFT 153 and is stored in a capacitor 154 a connected in parallel to the amplifier 154. The amplifier 154 outputs an electric signal amplified in proportion to the electric charge accumulated in the capacitor 154a.

  When the amplified electrical signal is output from the amplifier 154 and the electrical signal is extracted, the switch 154b connected in parallel to the amplifier 154 and the capacitor 154a is turned on, and the charge accumulated in the capacitor 154a is released. The amplifier 154 is reset. The photodiode 152 may simply be a photodiode having a regulation capacitance, or may include an additional capacitor in parallel so as to improve the dynamic range of the photodiode 152 and the photoelectric conversion unit.

  FIG. 11 is an equivalent circuit diagram in which such photoelectric conversion units are two-dimensionally arranged, and between the pixels, the scanning lines Ll and the signal lines Lr are arranged to be orthogonal to each other. One end side of the photodiode 152 is connected to the source S of the TFT 153, and the drain D of the TFT 153 is connected to the signal line Lr. On the other hand, the other end side of the photodiode 152 is connected to the other end side of the adjacent photodiode 152 arranged in each row, and is connected to a bias power source 155 through a common bias line Lb.

  The bias power source 155 is connected to the detector control unit 27 so that a voltage is applied to the photodiode 152 through the bias line Lb according to an instruction from the detector control unit 27. The gate G of the TFT 153 arranged in each row is connected to a common scanning line Ll, and the scanning line Ll is connected to the detector control unit 27 via the scanning drive circuit 16. Similarly, the drain D of the TFT 153 arranged in each column is connected to a signal readout circuit 17 that is connected to the common signal line Lr and controlled by the detector control unit 27.

  The signal readout circuit 17 is provided with the amplifier 154 for each signal line Lr described above. At the time of signal reading, a signal reading voltage is applied to the selected scanning line Ll, whereby a voltage is applied to the gate G of each TFT 153 connected to the scanning line Ll, and each photodiode is connected via each TFT 153. The charge generated in the photodiode 152 flows from the signal line 152 to each signal line Lr. Then, each amplifier 154 amplifies the charge for each photodiode 152, and information of the photodiode 152 for one row is extracted. This operation is performed for all the scanning lines Ll by switching the scanning lines Ll, whereby information is extracted from all the photodiodes 152.

  A sample hold circuit 156 is connected to each amplifier 154. Each sample and hold circuit 156 is connected to an analog multiplexer 157 provided in the signal readout circuit 17, and the signal read out by the signal readout circuit 17 is described above from the analog multiplexer 157 via the A / D converter 158. It is output to the detector control unit 27.

  Note that the TFT 153 may be either an inorganic semiconductor type used in a liquid crystal display or the like, or an organic semiconductor type.

  Further, in the present embodiment, the case where the photodiode 152 as a photoelectric conversion element is used as the imaging element is illustrated, but a solid-state imaging element other than the photodiode may be used as the photoelectric conversion element.

  On the side of the signal detector 151, a scanning drive circuit 16 that sends a pulse to each photodiode (photoelectric conversion element) 152 to scan and drive each photodiode 152, and the electric power stored in each photoelectric conversion element A signal readout circuit 17 for reading out energy is arranged.

Next, the functional configuration of the cassette type detector 1 will be described with reference to FIG.
The cassette type detector 1 includes, for example, a general-purpose CPU (not shown), a detector control unit 27 configured by a storage unit (not shown) configured by ROM and RAM. The detector control unit 27 reads out a predetermined program stored in the ROM, develops it in the work area of the RAM, and the CPU executes various processes according to the program.
As will be described later, the detector control unit 27 is a radiographic image data generation unit that generates radiographic image data based on a detection result by a signal detection unit 151 that is a radiographic image detection unit that detects radiation transmitted through a subject.

  Further, when the handle member 8 is mounted on the housing 3 and the antenna side connection terminal 95 is connected to the antenna connector 32, the fact is transmitted from the antenna connector 32 to the detector control unit 27.

FIG. 13 is an explanatory diagram illustrating switching control of the antenna devices 9a and 9b when the antenna side connection terminal 95 is connected to the antenna connector 32. FIG.
When the detector control unit 27 receives a signal indicating that the antenna side connection terminal 95 is connected from the antenna connector 32, the detector control unit 27 functions as a connection switching unit, controls the communication unit 28, and the communication unit 28 transmits and receives signals. The antenna device for switching is switched from the antenna device 9a provided on the side wall 52 to the antenna device 9b.

Further, the cassette type detector 1 includes an image storage unit 18 composed of a rewritable memory or the like. The image storage unit 18 stores the image data output from the detection panel 21. The capacity of the image storage unit 18 is not particularly limited, but preferably has a capacity capable of storing a plurality of pieces of image data.
The image storage unit 18 may be a built-in memory or a removable memory such as a memory card.

  Information received from the communication unit 28 is input to the detector control unit 27 as an electrical signal, and the detector control unit 27 controls each unit based on the input signal. It has become.

  The detector control unit 27 drives the scanning drive circuit 16 to send a pulse to each photoelectric conversion unit 160 to scan and drive each photoelectric conversion unit 160. The electric energy accumulated in the photodiode 152 (photoelectric conversion element) of each photoelectric conversion unit 160 is read by the signal reading circuit 17, and the read image signal is output to the detector control unit 27. It has become.

  The detector control unit 27 generates image data based on the image signal output from the signal reading circuit 17. The generated image data is sent to the image storage unit 18, and the image data is stored in the image storage unit 18 in association with the subject to be imaged. Further, the image data stored in the image storage unit 18 is appropriately sent to an external device (not shown) such as an external computer via the communication unit 28.

  Next, the operation of the cassette type detector 1 in the present embodiment will be described.

In the present embodiment, the detector unit 2 is housed in the back member 4 so that the first glass substrate 214 is on the upper side, and the power switch 46 and the charging terminal 45 provided on the side surface of the back member 4. The indicator 56, the antenna connector 32, the antenna device 9a, and each electronic component 22 are electrically connected. Then, the front member 5 is joined to the back member 4.
Further, the gripping member 8 is attached to the housing 3 with a screw. As a result, the antenna device 9 b provided on the gripping member 8 is connected to the antenna connector 32, and the antenna device 9 b is electrically connected to the communication unit 28 via the antenna connector 32.

When the cassette type detector 1 is used for imaging, for example, the cassette type detector 1 is set on a Bucky table or the like of an imaging apparatus used for imaging using an existing CR cassette.
FIG. 14 is a view showing a state in which the cassette type detector 1 is loaded in the photographing apparatus.
FIG. 14A shows a state in which the cassette type detector 1 is loaded in the photographing apparatus 7a for standing position photographing. The imaging device 7 a includes a bucky table 71 that holds the cassette-type detector 1 and a support column 72 that supports the bucky table 71 so as to be movable up and down. The bucky table 71 is provided with a detector insertion port 73 extending along the vertical direction of the imaging device 7 a, and the cassette type detector 1 is inserted into the bucky table 71 by being inserted from the detector insertion port 73. Loaded.
FIG. 14B shows a state in which the cassette type detector 1 is loaded in the photographing device 7b for lying position photographing. The imaging device 7b is a bed-type imaging device that performs imaging in a state in which a patient who is to be inspected is lying on his / her back or lying down. The imaging device 7 b includes a support plate 75 that supports the patient, and a bucky table 76 that is provided below the support plate 75 and holds the cassette type detector 1. The bucky table 76 is provided with a detector insertion port 77 extending along the horizontal direction of the imaging device 7 b, and the cassette type detector 1 is inserted into the bucky table 76 by being inserted from the detector insertion port 77. Loaded.

When the cassette type detector 1 is loaded in either the photographing device 7a for standing position photographing or the photographing device 7b for standing position photographing, the user holds the grasping member 8 by hand and the grasping member 8 is provided. The cassette type detector 1 is inserted into the detector insertion ports 73 and 77 so that the side opposite to the side is the back side. Therefore, the user can easily load the cassette type detector 1 in the correct direction without checking the insertion direction of the cassette type detector 1 one by one.
Further, when the cassette type detector 1 is loaded in either of the photographing devices 7a and 7b, the gripping member 8 is exposed to the outside of the bucky tables 71 and 76 from the detector insertion ports 73 and 77 of the bucky tables 71 and 76. The antenna device 9b provided in the handle portion 81 of the gripping member 8 is located outside the bucky tables 71 and 76. For this reason, even when the bucky tables 71 and 76 and the like are made of metal parts, the reception sensitivity of the antenna device 9b is hardly affected and signals can be transmitted and received satisfactorily.

  It is also possible to lay the patient to be imaged on the bed, and insert the cassette type detector 1 with the scintillator layer 211 facing up between the bed and the patient's body to perform imaging. .

  As described above, according to the present embodiment, since the cassette type detector 1 includes the rechargeable battery (battery) 25 and the antenna devices 9a and 9b, power supply to each part of the device, transfer of image data, and the like. Can be performed without using a cable.

  When the antenna device 9b is provided on the handle portion 81 of the handle member 8 and the handle member 8 is attached to the housing 3, the antenna device 9b is effective as an antenna device for transmitting and receiving signals. The antenna device 9b can be separated from the bucky tables 71, 76 and the like when used on the bucky tables 71, 76 made of metal or the like. For this reason, wireless communication sensitivity can be maintained, and signals can be transmitted and received satisfactorily.

  Further, since the antenna device 9b is provided on the handle member 8, the receiving sensitivity of the antenna device 9b can be maintained without using an extension cable or the like, whereby the housing 3 can be made thicker in the radiation incident direction of the housing 3. It can be formed in a size within a range compatible with a cassette size of 15 mm. For this reason, even when photographing with the cassette type detector 1 which is a cassette type FPD, the existing equipment made in accordance with the JIS standard size such as a bucky table provided for the cassette for CR is used. Can reduce capital investment.

  In addition, since the handle member 8 can be attached, the cassette type detector 1 that is relatively heavy in weight can be easily carried and moved. Further, since the cassette type detector 1 is loaded into the bucky tables 71 and 76 with the handle member 8, the loading direction is not mistaken even if the orientation of the cassette type detector 1 is not checked one by one. Thus, the loading operation when loading the cassette type detector 1 onto the bucky tables 71, 76 and the like can be easily performed.

In the present embodiment, the housing 3 is composed of the back member 4 and the front member 5 as an example, but the configuration of the housing 3 is not limited to this.
For example, the housing may be composed of a hollow cylindrical member and lid members that close both ends thereof. In this case, for example, the cylindrical member constituting the housing is formed by winding a carbon fiber on a core material (mold) to adjust the shape, flowing a thermosetting resin on the wound carbon fiber, Molding is performed by baking at high pressure, and then the core material is removed. When the housing has such a configuration, the power switch 46, the charging terminal 45, the indicator 56, the mounting screw hole 31 and the antenna connector 32 are provided on one lid member, and the gripping member 8 is attached to the lid member. To be configured. In this case, the tubular member of the housing can be integrally formed of carbon fiber, so that it can be seamless and has high rigidity and hermeticity, and simplifies the manufacturing process. Can do. In this case, the gripping member 8 may be formed integrally with the lid member.

  In the present embodiment, an indirect conversion type FPD in which the detection panel 21 includes the scintillator layer 211 and the signal detection unit 151 has been described as an example. However, the FPD is not limited to the indirect conversion type. For example, an amorphous selenium (a-Se) layer that absorbs radiation and converts the radiation into electric charge is provided, and radiation photons are drawn into the a-Se layer at a high voltage, so that It is possible to apply the configuration of the present invention in which an a-Se layer is sandwiched between two glass substrates even in a direct conversion type FPD that directly converts radiation energy into an electric charge amount (converts into an electrical signal). is there.

  In the present embodiment, the housing 3 is also provided with the antenna device 9a, and when the gripping member 8 is not mounted, the antenna device 9a is effective as an antenna device for transmitting and receiving signals, and when the gripping member 8 is mounted, Although the antenna device for transmitting and receiving signals is switched from the antenna device 9a to the antenna device 9b, the housing 3 may not be provided with the antenna device 9a. In this case, the detector control unit 27 does not need to function as connection switching means for switching to the antenna device. When the gripping member 8 is attached and the antenna device 9b is electrically connected to the communication unit 28, the antenna device 9b is effective as an antenna device for transmitting and receiving signals.

  In the present embodiment, the detector control unit 27 serves as an example of a connection switching unit that switches the antenna device that transmits and receives signals from the antenna device 9a to the antenna device 9b. It is not limited to what is shown. For example, when the antenna side connection terminal 95 of the antenna device 9b is connected to the antenna connector 32, the route connecting the antenna device 9a and the communication unit 28 is blocked, and the antenna device 9b and the communication unit 28 are connected. A mechanical connection switching unit may be provided so that the route is opened.

  Moreover, although this embodiment demonstrated as an example the case where a rechargeable secondary battery (rechargeable battery 25) was used as an electric power supply means, an electric power supply means is not limited to a secondary battery. For example, a primary battery that requires battery replacement such as a manganese battery, a nickel / cadmium battery, a mercury battery, or a lead battery may be used.

  In addition, it is needless to say that the present invention is not limited to the above embodiment and can be modified as appropriate.

It is a perspective view which shows the cassette type detector which concerns on this embodiment. It is a disassembled perspective view of the cassette type detector shown in FIG. It is a front view of the antenna apparatus shown in FIG. It is the schematic which shows the internal structure of the cassette type detector shown in FIG. It is CC sectional drawing of FIG. It is DD sectional drawing of FIG. It is a top view which shows the detection panel in this embodiment. It is the side view which looked at the detection panel shown in FIG. 7 from the arrow F direction. It is GG sectional drawing of the detection panel shown in FIG. It is an equivalent circuit block diagram for 1 pixel of the photoelectric conversion part which comprises a signal detection part. FIG. 11 is an equivalent circuit configuration diagram in which the photoelectric conversion units illustrated in FIG. 10 are two-dimensionally arranged. It is a principal part block diagram which shows the functional structure of the cassette type detector which concerns on this embodiment. It is explanatory drawing which showed typically the switching control of an antenna apparatus. FIG. 14A is a perspective view illustrating a state in which the cassette type detector according to the present embodiment is loaded in an imaging apparatus, FIG. 14A illustrates a case of an imaging apparatus for standing position imaging, and FIG. This shows a case of a photographing apparatus for taking a position.

Explanation of symbols

1 Cassette type detector (Cassette type radiation image detector)
2 detector unit 3 housing 4 back member 5 front member 8 gripping member 9a, 9b antenna device 21 detection panel 22 electronic component 23 circuit board 24 base 25 rechargeable battery (power supply means)
26 Buffer member 27 Detector control unit (radiation image data generating means, connection switching means)
28 Communication unit (communication means)
41 bottom face part 42 side wall part 51 flat part 52 bending rising part 151 signal detection part (radiation image detection means)
211 scintillator layer 213 second glass substrate 214 first glass substrate 217 sealing member

Claims (3)

Radiation image data is generated on the basis of the detection result of the radiation image detection means and the radiation image detection means for detecting the radiation that has passed through the subject in a casing formed to a size compatible with the JIS standard cassette size. Incorporating radiation image data generating means, communication means for wirelessly transmitting / receiving information to / from an external device, and power supply means for supplying power to the respective units,
A handle having an antenna device detachably attached to the housing and electrically connectable to the communication means;
The cassette-type radiation image is characterized in that the communication means is configured to be electrically connected to an antenna device provided in the handle portion when the handle portion is attached to the housing. Detector. The housing further comprises an antenna device that can be electrically connected to the communication means,
Connection switching means is provided for switching the antenna device connected to the communication means from the antenna device on the housing side to the antenna device on the handle portion side when the handle portion is attached to the housing. The cassette type radiation image detector according to claim 1.   The cassette type radiographic image detector according to claim 1, wherein the communication unit transmits the radiographic image data generated by the radiographic image data generation unit to an external device.

Images