JP5788651B2 - Radiation imaging system - Google Patents

Description

The present invention relates to a radiation imaging system for imaging the radiation transmitted through the human body.

  In the medical field, a portable radiation imaging apparatus (for example, FPD (Flat Panel Detector)) that performs imaging inside a human body by detecting the intensity of radiation transmitted through the human body is used. Since portable FPDs are portable, the portable FPDs may be damaged by accidentally dropping the portable FPDs when handling them or hitting them against solid objects such as photography tables or doors. is there.

  In Patent Document 1 shown below, an impact sensor is provided in a portable FPD, self-diagnosis is executed by a signal from the impact sensor, and if it is determined that there is a problem based on the result of the self-diagnosis, an imaging operation, radiation The prohibition of irradiation is described.

JP 2005-177379 A

  In Patent Document 1, if there is a problem with the portable FPD, the FPD cannot be used continuously, and if there is only one in the hospital, the examination will be affected. In addition, if an expensive FPD is replaced every time a malfunction occurs, it is not economical.

The present invention has been made in view of such conventional problems, among the radiation imaging apparatus, it aims to provide a radiation imaging system that can be continuously use partial undamaged And

  In order to achieve the above object, the present invention provides a radiation imaging system including a radiation apparatus that irradiates radiation and a radiation imaging apparatus that includes an imaging panel that images the irradiated radiation. Is a failure factor detector that detects an environmental disturbance or a fall that causes a failure of itself, and if the detected environmental disturbance value is greater than or equal to a threshold value, or if a fall is detected, A defect diagnosis unit that diagnoses a defect, and a function restriction unit that restricts the function of the radiation imaging apparatus that is continuously used according to the diagnosis result of the defect diagnosis unit.

  The defect diagnosis unit includes a self-diagnosis unit that self-diagnose the radiation imaging apparatus, and the self-diagnosis includes a first non-imaging region in which the radiation cannot be imaged among all imaging regions of the imaging panel. Diagnosis is performed, and the function restriction unit restricts the function of the radiation imaging apparatus so as not to perform an imaging operation in the first imaging impossible area.

  The self-diagnosis includes a function of diagnosing a wiring state, and the function restriction unit restricts the function of the radiation imaging apparatus by not supplying a current to a wiring whose wiring state is not normal.

  The defect diagnosis unit includes a real image diagnosis unit that diagnoses a second non-imageable region in which the radiation cannot be imaged based on the image data obtained by sky imaging, and the radiation device is detected by the failure factor detection unit. When the disturbance value of the environment is equal to or greater than a threshold value or when a fall is detected, the imaging panel is irradiated with the radiation for diagnosis for diagnosing the radiation imaging apparatus, and the real image diagnostic unit Diagnoses the second non-imaging region based on image data obtained by performing an aerial imaging of the diagnostic radiation, and the function restriction unit obtains an image of the second non-imaging region. The function of the radiation imaging apparatus is limited so as not to be present.

  A notifying unit for notifying a user of a diagnosis result by the defect diagnosis unit or a function restricted by the function restriction unit;

  The radiation apparatus prohibits irradiation of the radiation for imaging until the diagnosis by the failure diagnosis unit is completed.

  The environmental disturbance is any one of an external pressure applied to the imaging panel, an environmental temperature or a change thereof, and an environmental humidity.

  The radiation imaging apparatus is a portable radiation imaging apparatus.

  The radiation imaging apparatus includes a communication unit that wirelessly transmits and receives signals to and from other devices, the self-diagnosis unit diagnoses whether the communication function of the communication unit is normal, and the function restriction unit includes If it is determined that the communication function of the communication unit is not normal, the communication function of the communication unit is limited.

  The radiation imaging apparatus includes a storage unit that stores image data obtained by imaging radiation, the self-diagnosis unit diagnoses the storage unit, and the function restriction unit can be stored in the storage unit. When the capacity is lower than a predetermined value, the continuous imaging function is limited.

  The radiation imaging apparatus includes a built-in battery, the self-diagnostic unit diagnoses the built-in battery, and the function restriction unit is configured when the remaining battery level of the built-in battery is lower than a predetermined value, or the built-in battery When the degree of deterioration of the battery is higher than a predetermined value, use of the built-in battery is restricted.

  In order to achieve the above object, the present invention provides a radiation imaging system including a radiation apparatus that irradiates radiation and a radiation imaging apparatus that includes an imaging panel that images the irradiated radiation. A failure factor detection unit that detects environmental disturbance or a fall that is a failure factor of the self, and when the detected environmental disturbance value is equal to or greater than a threshold value or when a fall is detected, A failure diagnosing unit that diagnoses a non-imagingable region in which the radiation cannot be imaged in the imaging region, and the radiation imaging system performs imaging when it is determined that the non-imagingable region exists It is provided with the alerting | reporting part which alert | reports an impossible area to a user.

  In order to achieve the above object, the present invention provides a radiation imaging apparatus, a failure factor detection unit that detects an environmental disturbance or a fall that causes a failure of the device, and a detected environmental disturbance value that is greater than or equal to a threshold value. Or when a fall is detected, a fault diagnosis unit for diagnosing its own fault and a function restriction unit that limits its function according to the diagnosis result of the fault diagnosis unit And

  According to the present invention, when the environmental disturbance value is equal to or greater than the threshold value, or when a fall is detected, a failure of the electronic cassette 20 is diagnosed, and the function of the electronic cassette 20 is limited according to the diagnosis result. Therefore, even if the electronic cassette 20 has a problem, it can be used continuously. In addition, since the function is limited according to the malfunction, the electronic cassette 20 does not have abnormal heat, and the power consumption can be minimized.

It is a lineblock diagram of a radiation imaging system of an embodiment. It is a perspective view of the electronic cassette shown in FIG. It is III-III sectional drawing of the electronic cassette shown in FIG. FIG. 4A is a schematic configuration diagram of the radiation detector shown in FIG. 3, FIG. 4A shows the radiation detector when the scintillator is formed on an aluminum substrate by vacuum deposition, and FIG. 4B shows the scintillator on the TFT substrate. The radiation detector at the time of forming by a vacuum evaporation method is represented. It is an electrical schematic block diagram of the electronic cassette shown in FIG. It is a figure which shows an example of the imaging impossible area | region diagnosed by the self-diagnosis part. It is an electrical schematic block diagram of the console shown in FIG. It is a figure which shows the example of a display of the function restrict | limited by the function restriction | limiting part according to the self-diagnosis result. It is a flowchart which shows operation | movement of an electronic cassette. It is a figure which shows the state at the time of mammo imaging.

  A radiation imaging system having a radiation imaging apparatus according to the present invention will be described in detail below with reference to the accompanying drawings.

  FIG. 1 is a configuration diagram of a radiation imaging system 10 according to the present embodiment. The radiation imaging system 10 detects a radiation device 18 that irradiates radiation 16 and a radiation 16 transmitted through the subject 14 to a patient who is a subject 14 lying on an imaging table 12 such as a bed, and converts the radiation 16 into a radiation image. An electronic cassette (radiation imaging apparatus) 20, a console 24 that controls the entire radiation imaging system 10, and a display device 26 that displays a captured radiation image and the like are provided. The console 24 has an input unit that accepts an input operation by a doctor or an engineer (hereinafter referred to as a user).

  Between the console 24, the radiation device 18, the electronic cassette 20, the display device 26, and the server 32, for example, UWB (Ultra Wide Band), IEEE 802.11. Signals are transmitted and received by wireless LAN such as a / b / g / n or wireless communication using millimeter waves or the like. Note that signals may be transmitted and received by wired communication using a cable.

  The console 24 is connected to a radiology information system (RIS) 28 for comprehensively managing radiographic images and other information handled in the radiology department in the hospital. The RIS 28 is used for comprehensive management of medical information in the hospital. A medical information system (HIS) 30 to be managed is connected.

  A server 32 wirelessly connected to the console 24 is provided by a maintenance company, and the console 24 transmits a diagnosis result of the electronic cassette 20 described later to the server 32. Thereby, the maintenance contractor can grasp the state of the electronic cassette 20.

  The radiation device 18 includes a radiation source 34 that irradiates the radiation 16, and a radiation control device 36 that controls the radiation source 34. The radiation source 34 irradiates the electronic cassette 20 with the radiation 16. The radiation 16 irradiated by the radiation source 34 may be X-rays, α-rays, β-rays, γ-rays, electron beams, or the like.

  2 is a perspective view of the electronic cassette 20 shown in FIG. 1, and FIG. 3 is a cross-sectional view taken along the line III-III of the electronic cassette 20 shown in FIG. The electronic cassette 20 includes a panel unit (imaging panel) 40 and a control unit 42 disposed on the panel unit 40. Note that the thickness of the panel unit 40 is set to be thinner than the thickness of the control unit 42.

  The panel unit 40 includes a substantially rectangular housing 44 made of a material that can transmit the radiation 16, and the imaging surface 46 of the panel unit 40 is irradiated with the radiation 16. A guide line 48 indicating the imaging area and imaging position of the subject 14 is formed at a substantially central portion of the imaging surface 46. An outer frame of the guide line 48 becomes an imageable region 50 indicating an irradiation field of the radiation 16. The center position of the guide line 48 (intersection where the guide line 48 intersects in a cross shape) is the center position of the imageable area 50. The imaging surface 46 is provided with an area scale for specifying the imaging area. The area scale is composed of numbers (1, 2,...) Representing columns and English letters (A, B,...) Representing rows. In addition, the area | region scale may be printed on the sheet | seat stuck on the imaging surface 46, or the storage bag of the electronic cassette 20. FIG.

  The panel unit 40 includes a radiation detector (imaging panel) 56 having a scintillator 52 and a radiation conversion panel 54, and a drive circuit unit 80 (see FIG. 5) to be described later for driving the radiation conversion panel 54. The scintillator 52 converts the radiation 16 that has passed through the subject 14 into fluorescence that is included in the visible light region. The radiation conversion panel 54 is an indirect conversion type radiation conversion panel that converts the fluorescence converted by the scintillator 52 into an electrical signal. A scintillator 52 and a radiation conversion panel 54 are arranged inside the housing 44 in order from the imaging surface 46 irradiated with the radiation 16. When the radiation conversion panel 54 is a direct radiation conversion panel that directly converts the radiation 16 into an electrical signal, the radiation conversion panel 54 serves as the radiation detector 56. This is because the scintillator 52 is unnecessary in this case.

  The control unit 42 includes a substantially rectangular casing 58 made of a material that is impermeable to the radiation 16. The housing 58 extends along one end of the imaging surface 46, and the control unit 42 is disposed outside the imageable region 50 on the imaging surface 46. In this case, a cassette control unit 84 for controlling the panel unit 40 (to be described later), a communication unit 88 capable of wirelessly transmitting and receiving signals to and from the console 24, a built-in battery 90, and the like are arranged inside the housing 58. (See FIG. 5). The built-in battery 90 supplies power to the cassette control unit 84, the communication unit 88, and the like. Information is transmitted and received between the input terminal 60 of the AC adapter for charging the built-in battery 90 from an external power source and an external device (for example, the console 24) on the side surface in the short direction of the control unit 42. A USB terminal 62 is provided as a possible interface means.

  FIG. 4 is a schematic configuration diagram of the radiation detector 56. 4A shows the radiation detector 56 when the scintillator 52 is formed on the aluminum substrate 70 by vacuum deposition, and FIG. 4B shows the radiation detection when the scintillator 52 is formed on the TFT substrate by vacuum deposition. The device 56 is shown.

  In FIG. 4A, the scintillator 52 is formed by forming, for example, cesium iodide (CsI (Tl)) into a strip-like columnar crystal structure 72 on an aluminum substrate 70 by a vacuum deposition method. A radiation conversion panel 54 is provided on the side opposite to the aluminum substrate 70. The scintillator 52 and the radiation conversion panel 54 are fixed while pressed against each other. The radiation conversion panel 54 is obtained by stacking pixels on a TFT substrate. Since CsI of the columnar crystal structure 72 has a characteristic that it is weak against humidity (the non-columnar crystal portion of the scintillator 52 is particularly vulnerable to humidity), the scintillator 52 is sealed with a moisture-proof protective material 74. The scintillator 52 and the radiation conversion panel 54 are pressed against each other to fix the relative position between the scintillator 52 and the radiation conversion panel 54. However, the scintillator 52 and the radiation conversion panel 54 are fixed to each other. May be.

  In FIG. 4B, the scintillator 52 is a TFT substrate in which cesium iodide (CsI (Tl)) is formed in a strip-like columnar crystal structure 72 by a vacuum deposition method. The scintillator 52 is sealed with a moisture-proof protective material 74. Since the columnar crystal structure 72 has hard and brittle characteristics, it is vulnerable to external pressure and stress. Therefore, by dropping the electronic cassette 20 or applying excessive pressure from the outside, the columnar crystal structure 72 is broken or wrinkled, and not only the imaging performance and sensitivity are lowered, but also a radiographic image. There is also a possibility that an area where the image cannot be captured may occur. In addition, since the thermal expansion coefficient differs between the scintillator 52 and the TFT substrate, stress is applied to the scintillator 52 due to temperature change, and the columnar crystal structure 72 may be broken or wrinkled.

  FIG. 5 is a schematic electrical configuration diagram of the electronic cassette 20 shown in FIG. The electronic cassette 20 includes a drive circuit unit 80, a failure factor detection unit 82, a cassette control unit 84, a memory 86, a communication unit 88, a built-in battery 90, and a light emitting unit (notification unit) 92. The built-in battery 90 supplies power to the failure factor detection unit 82, the cassette control unit 84, the communication unit 88, and the light emitting unit 92. The cassette control unit 84 supplies the power supplied from the built-in battery 90 to the bias power source 108, the gate IC 114, the ASIC 116, and the like, and also supplies the power of the built-in battery 90 to the failure factor detection unit 82 and the communication. Whether power is supplied to the unit 88 and the light emitting unit 92 is controlled.

  The radiation conversion panel 54 has a structure in which a photoelectric conversion layer for forming the pixel 104 is disposed on a TFT substrate on which TFTs 102 are arranged in a matrix. In each pixel 104 to which a bias voltage is supplied from the bias power source 108 constituting the drive circuit unit 80, charges generated by photoelectric conversion of the fluorescence converted by the scintillator 52 are accumulated.

  To the TFT 102 connected to each pixel 104, a gate line 110 extending in the row direction and a signal line 112 extending in the column direction are connected. Each gate line 110 is connected to a gate IC 114 constituting the drive circuit unit 80. Each signal line 112 is connected to the ASIC 116 that constitutes the drive circuit unit 80.

  In FIG. 5, for convenience, only one gate line 110 is connected to each gate IC 114, but a plurality of gate lines 110 are connected to each gate IC 114, and each gate line 110 is connected via the TFT 102. A plurality of pixels 104 are connected. Further, for convenience, only one signal line 112 is connected to each ASIC 116, but a plurality of signal lines 112 are connected to each ASIC 116, and each signal line 112 is connected to a plurality of pixels via the TFT 102. 104 is connected.

  The gate IC 114 outputs a gate signal to the gate line 110. When the gate signal is output to the gate line 110, the TFTs 102 connected to the gate line 110 to which the gate signal is output are turned on all at once, and the charge accumulated in the pixel 104 is passed through the TFT 102 as a charge signal. Read out from the signal line 112. Thereby, the electric charge accumulated in the pixels 104 is read out in units of one row.

  When a drive signal is sent from the cassette control unit 84, the gate IC 114 sequentially selects the gate lines 110 connected to the gate IC 114, and outputs a gate signal to the selected gate line 110, thereby The charges accumulated in 104 are sequentially read out in units of rows. When the gate IC 114 outputs a gate signal to all the gate lines 110 connected to the gate IC 114 (reads all charges of the pixel 104 that can be read by the gate IC 114), the gate IC 114 outputs an end signal to the cassette control unit 84.

  The ASIC 116 includes an amplifier that amplifies the read charge signal (electric signal), a multiplexer, an AD converter, and the like. The ASIC 116 amplifies the electric signal read from the plurality of signal lines 112 and then amplifies it. The electrical signals are sequentially selected, and the selected electrical signals are converted into digital signals and output to the cassette control unit 84.

  The failure factor detector 82 detects an environmental disturbance or a drop that becomes a failure factor of the electronic cassette 20. Environmental disturbances are environmental humidity, environmental temperature, temperature change, and external pressure. If there is a possibility that the electronic cassette 20 may fail due to disturbances other than environmental humidity, environmental temperature, temperature change, and external pressure, the failure factor detection unit 82 may also detect the other disturbances.

  Specifically, the failure factor detection unit 82 includes an acceleration sensor, a gyro sensor, or the like, includes a drop detection unit 120 that detects a drop of the electronic cassette 20, and an electric resistance type or capacitance type humidity sensor, and includes an electronic cassette. 20 includes a humidity detection unit 122 that detects environmental humidity (humidity of the environment in which the electronic cassette 20 is placed) and a thermocouple, thermistor, or infrared temperature sensor, and the environmental temperature of the electronic cassette 20 (electronic cassette 20 Temperature sensor 124 for detecting the temperature of the environment in which the sensor is placed and a pressure sensor such as a pressure sensitive element (semiconductor diaphragm type, capacitance type, piezoelectric type) and the like, and external pressure applied to the electronic cassette 20 And a pressure detection unit 126 for detecting. The failure factor detection unit 82 may be provided at any location of the electronic cassette 20. Note that the temperature detection unit 124 may have a function of detecting a temperature change (temperature difference between the maximum temperature and the minimum temperature) in a certain time (for example, 24 hours).

  The cassette control unit 84 includes an imaging control unit 130, a failure diagnosis unit 132, and a function restriction unit 134. The imaging control unit 130 controls imaging of the radiation 16. Specifically, the exposure start timing and exposure end timing of the radiation conversion panel 54 and image reading are controlled. The imaging control unit 130 controls the exposure start timing so as to be synchronized with the irradiation start timing of the radiation 16 of the radiation apparatus 18 and controls the exposure end timing so as to be synchronized with the irradiation end timing of the radiation 16. The imaging control unit 130 synchronizes the exposure start timing and the exposure end timing by wirelessly communicating with the radiation apparatus 18 via the console 24.

  The imaging control unit 130 sequentially selects the gate ICs 114 and outputs a drive signal to the selected gate ICs 114 to control image reading. The gate IC 114 is sequentially selected such that the drive signal is output to the selected gate IC 114, and then the end signal is sent from the selected gate IC 114, the next gate IC 114 is selected and the drive signal is output. Then, the drive signal is output to the selected gate IC 114. As a result, the electrical signals accumulated in all the pixels 104 of the radiation conversion panel 54 are sequentially read out in units of rows. That is, image reading is performed. In the imaging control unit 130, the cassette control unit 84 stores the digital signal of the image data sent from the ASIC 116 in the memory 86. The communication unit 88 transmits the image data stored in the memory 86 to the console 24.

  The defect diagnosis unit 132 includes a self-diagnosis unit 140 and a real image diagnosis unit 142. The self-diagnosis unit 140 diagnoses whether the bias power supply 108, the gate IC 114, and the ASIC 116 operate correctly (failure). For example, the self-diagnosis unit 140 sends a test signal to the gate IC 114 or ASIC 116, and diagnoses whether or not the gate IC 114 or ASIC 116 has failed based on a response signal sent from the gate IC 114 or ASIC 116.

  In addition, the self-diagnosis unit 140 determines whether the wiring state of the electronic cassette 20 is normal (whether the wiring is short-circuited, the wiring is disconnected, or the connection is unstable (the connection state or disconnection occurs). If a defect has occurred))), or a non-imagingable area where the radiation 16 cannot be imaged is diagnosed.

  FIG. 6 is a diagram illustrating an example of a non-imagingable area diagnosed by the self-diagnosis unit 140. In FIG. 6, it is assumed that the uppermost gate IC 114 among the plurality of gate ICs 114 and the leftmost ASIC 116 among the plurality of ASICs 116 have failed due to disconnection or short-circuit, and the non-imagingable area is shaded. It is represented by The failed gate IC 114 cannot output a gate signal to the plurality of gate lines 110 connected to the gate IC 114. Therefore, the gate IC 114 accumulated in the plurality of pixels 104 connected to the plurality of gate lines 110 via the TFTs 102 is stored. The charge cannot be read. Therefore, an area in which the plurality of pixels 104 connected to the plurality of gate lines 110 connected to the failed gate IC 114 via the TFT 102 is an image-capable area.

  Further, the malfunctioning ASIC 116 cannot output the charge signal transmitted from the plurality of signal lines 112 connected to the ASIC 116 to the cassette control unit 84. Therefore, an area in which a plurality of pixels 104 connected to the plurality of signal lines 112 connected to the failed ASIC 116 via the TFT 102 are unimaginable areas.

  Further, the self-diagnosis unit 140 diagnoses the memory 86, the communication unit 88, and the built-in battery 90. For example, the self-diagnosis unit 140 diagnoses whether there is an abnormality in the cells of the memory 86, diagnoses the possible storage capacity of the memory 86, or performs a communication test of the console 24, so that the communication function of the communication unit 88 is achieved. Diagnose whether it is normal. Further, the remaining battery capacity (capacity) of the built-in battery 90 and the degree of deterioration of the built-in battery 90 are diagnosed based on the charging voltage of the built-in battery 90 detected by the voltage sensor provided in the built-in battery 90. A load current test may be performed to diagnose the remaining battery level of the internal battery 90 and the degree of deterioration of the internal battery 90.

  The real image diagnosis unit 142 diagnoses a non-imagingable region that cannot be imaged based on image data obtained by performing sky imaging of the actually irradiated radiation 16. Even if the region is diagnosed by the self-diagnostic unit 140 as not being an image-capable region, there may be a region where the image cannot be actually captured. For example, since the radiation 16 cannot be converted into fluorescence in a region where the columnar crystal structure 72 of the scintillator 52 is broken, the radiation 16 cannot be imaged in the region. In addition, when the relative position between the scintillator 52 and the radiation conversion panel 54 is shifted, a region where the fluorescence converted by the scintillator 52 is not incident may be generated in the imageable region 50. The region where the fluorescence is not incident is an image. Cannot be imaged. Here, the aerial imaging refers to imaging in a state where there is no subject 14 as a patient between the radiation device 18 and the electronic cassette 20.

  For example, if a value that is significantly different from the surroundings is detected, such as a streak or a band, the real image diagnosis unit 142 may diagnose the area where the different value is detected as a non-imagingable area. Further, since the imaging conditions for the sky imaging of the radiation 16 are determined in advance, it is assumed that the value of the image data obtained by the sky imaging is also in a certain range. Therefore, an area of data outside the assumed range may be diagnosed as a non-imaging area. At this time, the radiation device 18 emits diagnostic radiation 16, and the imaging control unit 130 performs imaging control of the irradiated diagnostic radiation 16. The real image diagnostic unit 142 diagnoses a non-imagingable region using image data obtained by imaging diagnostic radiation 16. In this imaging control of the radiation 16 for diagnosis, the irradiation start timing and the exposure start timing of the diagnostic radiation 16 may not be synchronized, and the irradiation end timing and the exposure end timing are not synchronized. Also good. In short, it is only necessary that the radiation 16 for diagnosis can be imaged.

  The function restriction unit 134 restricts the function of the electronic cassette 20 that is continuously used according to the diagnosis result of the failure diagnosis unit 132. For example, when the self-diagnosis unit 140 determines that the gate IC 114 or the ASIC 116 has failed, the supply of power to the gate IC 114 or ASIC 116 that has failed is prohibited. As a result, the malfunctioning gate IC 114 can be prevented from being abnormally heated, and the imaging operation in the non-imaging area is limited. Further, since the self-diagnosis unit 140 does not supply current to the wiring whose wiring state is not normal (wiring that is disconnected or short-circuited), it is possible to prevent generation of heat caused by short-circuiting or disconnection. If it is determined that the gate IC 114 has failed, output of the drive signal to the failed gate IC 114 may be prohibited.

  In addition, the function restriction unit 134 restricts the function of the electronic cassette 20 so that an image of a non-imageable area diagnosed by the real image diagnosis unit 142 cannot be obtained. For example, the readout operation of the charge accumulated in the pixels determined as the non-imaging area is not performed. Specifically, the gate IC 114 or the ASIC 116 is configured by prohibiting power supply to the gate IC 114 that reads out pixels in the non-imaging area or the ASIC 116 that outputs charges accumulated in the pixels 104 in the non-imaging area as digital signals. Are stopped, or the output of the gate signal to the gate line 110 that reads out the charges accumulated in the pixels in the non-imagingable area is prohibited. As a result, the imaging operation is not performed in the non-imagingable area, and thus an image in the non-imagingable area cannot be obtained.

  Here, the gate IC 114 reads out the charges accumulated in the pixels 104 in the plurality of rows. Therefore, if any pixel in the non-imagingable region is present in the pixels 104 in the plurality of rows, the pixels in the plurality of rows. 104 All the charges are not read out. Accordingly, the ratio of the number of pixels 104 in the non-imagingable area to the number of pixels 104 that are not in the non-imagingable area out of all the pixels 104 that are read by the gate IC 114 that reads out the pixels 104 in the non-imagingable area is a predetermined ratio. In the above case, the power supply to the gate IC 114 may be prohibited and the reading operation of the pixel 104 may be prohibited. This is because a good image cannot be obtained when the number of pixels 104 in the non-imagingable area with respect to the number of pixels 104 in the non-imagingable area is equal to or greater than a predetermined ratio. The same applies to the ASIC 116.

  Furthermore, the ratio of the number of pixels 104 in the non-imagingable area to the number of pixels 104 that are not in the non-imagingable area out of all the pixels 104 that are read by the gate IC 114 that reads out the pixels 104 in the non-imagingable area is a predetermined ratio. If the number of pixels 104 in the non-imagingable region continues for a predetermined number or more, the power supply to the gate IC 114 is prohibited and the reading operation of the pixel 104 is prohibited. This is because when the pixels 104 in the non-imagingable area are continuous for a predetermined ratio or more, the non-imageable area becomes large and a good image cannot be obtained. The same applies to the ASIC 116.

  Note that the case where the reading operation of the pixel 104 is not prohibited is handled by performing image correction (for example, pixel interpolation) so that the non-imagingable area is eliminated. This image correction may be performed on the console 24 side, or may be performed by the cassette control unit 84. In addition, if the image correction is performed excessively, the accuracy of illness diagnosis is reduced. For example, when measuring the shape and size of a lesion in cancer diagnosis, the predetermined ratio or the predetermined number is reduced. Thus, the power supply to the gate IC 114 is prohibited, and the reading operation of the pixel 104 is prohibited.

  In addition, the power supply to the gate IC 114 or the ASIC 116 is not prohibited, but the image data of the diagnosed non-capable area is trimmed and extracted from the image data obtained by imaging the radiation 16 for imaging. Thus, the imaging area may be limited. As a result, the image data obtained by radiation imaging is image data obtained by extracting an image of a non-imagingable area. The image data extracted by trimming is stored in the memory 86 and transmitted to the console 24 by the communication unit 88. Note that the radiation 16 for imaging and the radiation 16 for diagnosis may be the same or different, ie, tube current, tube voltage, and irradiation time, which are irradiation conditions. Further, since the diagnostic radiation 16 is used for diagnosis, the exposure dose (mAs value) may be smaller than the imaging radiation 16.

  Further, when the function limiting unit 134 determines that the possible storage capacity of the memory 86 is smaller than the predetermined value, the function limiting unit 134 limits the continuous imaging function or determines that the communication function of the communication unit 88 is not normal. If the communication function is restricted by prohibiting power supply to the internal battery 90, or the remaining battery level of the internal battery 90 is lower than a predetermined value, or if the deterioration degree of the internal battery 90 is higher than the predetermined value, The use of the internal battery 90 is restricted. When the use of the internal battery 90 is restricted, the use of the internal battery 90 may not be restricted immediately, but the use may be restricted after a certain period of time (for example, after 5 minutes). Further, when the use of the internal battery 90 is restricted, the use of the internal battery 90 is not restricted at all, and the power supplied by the internal battery 90 may be restricted.

  When the wireless function of the communication unit 88 is restricted (for example, when power supply to the communication unit 88 is prohibited), the user connects the USB connector at the tip of the USB cable connected to the console 24 to the USB terminal 62. By connecting to the electronic cassette 20, the electronic cassette 20 and the console 24 can be wired. By not supplying power to the communication unit 88, abnormal heat generation of the failed communication unit 88 can be prevented. When there is a malfunction in the communication function, data to be transmitted to the console 24 is stored in the memory 86, and after the electronic cassette 20 and the console 24 are connected by a USB cable, the data is transmitted to the console 24. In this embodiment, the case of performing wired communication using a USB cable that also has a function as a power cable has been described. However, instead of a USB cable, a communication cable that does not have a function as a power cable may be used. Good.

  When the use of the built-in battery 90 is restricted, power can be supplied from the external power supply to the electronic cassette 20 by connecting the AC connector at the tip of the cable of the external power supply to the input terminal 60. As a result, it is possible to prevent a situation where the battery becomes insufficient during use of the electronic cassette 20.

  The light emitting unit 92 emits light to notify the user that the functions of the communication unit 88 and the built-in battery 90 are limited. The light emitting unit 92 includes a plurality of light emitting elements of different colors (for example, red, blue, etc.). When the function of the communication unit 88 is restricted by the function restriction unit 134, the cassette control unit 84 controls the light emitting unit 92 to turn on the red light emitting element, for example, and restricts the function of the built-in battery 90, for example, blue The light emitting unit 92 is controlled to turn on the light emitting elements. Thereby, the user can recognize that the functions of the communication unit 88 and the built-in battery 90 are limited.

  The function restriction unit 134 transmits the restricted function to the console 24 via the communication unit 88. At this time, when the communication unit 88 is restricted, the restricted function is transmitted to the console 24 after the electronic cassette 20 and the console 24 are connected by the USB cable.

  FIG. 7 is an electrical schematic configuration diagram of the console 24. The console 24 is a communication for wirelessly transmitting and receiving signals to and from the input unit 150 that receives user input operations, a control unit 152 that controls the entire console 24, a display unit (notification unit) 154, the electronic cassette 20, and the like. Part 156. The control unit 152 causes the display unit 154 to display the diagnosis result of the failure diagnosis unit 132 and / or the function restricted by the function restriction unit 134. That is, the display unit 154 notifies the user of the restricted function.

  FIG. 8 is a diagram illustrating a display example of functions restricted by the function restriction unit 134 according to the self-diagnosis result. FIG. 8 is a display example when the imaging area and the built-in battery are limited. On the left side of the display unit 154, an electronic cassette 20 ′ simulating the electronic cassette 20 as viewed from above is displayed, and on the right side, an explanation column for explaining the restricted function is displayed.

  A diagnosed (restricted) non-imagingable area (area indicated by diagonal lines) is displayed in the imageable area 50 ′ of the electronic cassette 20 ′ displayed on the display unit 154. The imaging area of column 1 and row A is a non-imaging area. ”Is displayed. Thus, the user can recognize which imaging region is specifically limited by looking at the area scale displayed on the electronic cassette 20. In the description field, “The built-in battery capacity is low. Connect the cable to limit the built-in battery.”

  FIG. 9 is a flowchart showing the operation of the electronic cassette 20. The failure factor detector 82 periodically detects drops and disturbance values (environmental humidity value, environmental temperature value, external pressure value).

  The failure diagnosis unit 132 determines whether or not the detected disturbance value is greater than or equal to a threshold value (step S1). Specifically, it is determined whether any of the environmental humidity value detected by the humidity detection unit 122, the environmental temperature value detected by the temperature detection unit 124, and the external pressure value detected by the pressure detection unit 126 is greater than or equal to a threshold value. to decide. An evaluation value is obtained from the environmental humidity value detected by the humidity detection unit 122, the environmental temperature value detected by the temperature detection unit 124, and the external pressure value detected by the pressure detection unit 126, and the obtained evaluation value is equal to or greater than a threshold value. It may be determined whether or not there is. Further, it may be determined whether or not the temperature change detected by the temperature detection unit 124 is equal to or greater than a threshold value.

  If it is determined in step S1 that the disturbance value is not equal to or greater than the threshold value, the failure diagnosis unit 132 determines whether or not a drop is detected by the drop detection unit 120 (step S2). If it is determined in step S2 that no drop has been detected, the process returns to step S1.

  On the other hand, if it is determined in step S1 that the disturbance value is equal to or greater than the threshold value or that a fall has been detected in step S2, the self-diagnosis unit 140 performs self-diagnosis (step S3). Specifically, diagnosis of whether the gate IC 114 and the ASIC 116 are out of order, diagnosis of the wiring state, diagnosis of a non-imaging area, diagnosis of the memory 86, the communication unit 88, and the built-in battery 90 are performed. The self-diagnosis unit 140 transmits the diagnosis result to the console 24 via the communication unit 88. Here, the cassette control unit 84 issues an irradiation prohibition request for prohibiting the irradiation of the radiation 16 for imaging until the trouble diagnosis (self-diagnosis and actual image diagnosis) of the electronic cassette 20 is completed via the communication unit 88. 24, the console 24 transmits an irradiation prohibition command to the radiation device 18. The radiation device 18 prohibits irradiation of the radiation 16 for imaging until the failure diagnosis is completed. If the communication unit 88 is out of order, the console 24 cannot perform wireless communication with the electronic cassette 20, so the console 24 determines that there is a problem with the communication unit 88, and radiation for imaging. 16 prohibition control of irradiation. The prohibition of irradiation with the radiation 16 for photographing may be performed prior to step S3 or may be started at step 4.

  Next, the function limiting unit 134 limits the function of the electronic cassette 20 that is continuously used according to the diagnosis result of the self-diagnosis (step S4). For example, when it is determined that the gate IC 114 or the ASIC 116 has failed, the supply of power to the failed gate IC 114 or ASIC 116 is stopped. Thereby, the imaging operation in the non-imaging area is limited. Also, power supply to wiring that has been diagnosed as disconnected, shorted, or unstable is prohibited. The function restriction unit 134 transmits the function restricted according to the self-diagnosis from the communication unit 88 to the console 24. The non-imagingable area diagnosed by the self-diagnosis is referred to as a first non-imaging area.

  Next, the control unit 152 of the console 24 causes the display unit 154 to display the self-diagnosis result and the function limited according to the self-diagnosis result (step S5). For example, the gate IC 114 that reads out the charges accumulated in the pixels 104 in the row A indicated by the area scale on the imaging surface 46 and the charge signal accumulated in the pixels 104 in the first column are output to the cassette control unit 84. When it is diagnosed that the ASIC 116 is out of order, as shown in FIG. 8, the area corresponding to the diagnosed first non-imaging area in the imageable area 50 ′ of the electronic cassette 20 ′ is hatched. In addition to the display, in the explanation column, “the imaging area of column 1 and row A is an imaging impossible area” is displayed. If it is diagnosed that the battery level of the built-in battery 90 is lower than the specified value, the message “Internal battery capacity is low. Connect the cable to limit the built-in battery.” Is displayed.

  Next, the imaging control unit 130 performs sky imaging of the diagnostic radiation 16 (step S6). Specifically, the imaging control unit 130 outputs a request signal for requesting irradiation of the diagnostic radiation 16 to the console 24 via the communication unit 88. When the console 24 receives the request signal, the console 24 outputs a command signal instructing the radiation apparatus 18 to irradiate the radiation 16 for diagnosis. When receiving the command, the radiation device 18 emits diagnostic radiation 16. When outputting the request signal, the imaging control unit 130 causes the radiation conversion panel 54 to perform exposure for a certain period of time, and reads out the electric charge accumulated in the pixel 104 by the exposure. Image data obtained by imaging the radiation 16 for diagnosis is stored in the memory 86. At this time, the diagnostic radiation 16 is imaged in a state where the function is limited according to the diagnosis result of the self-diagnosis.

  When imaging of the diagnostic radiation 16 is performed, the actual image diagnostic unit 142 diagnoses an impossible area that cannot be captured based on the image data obtained by imaging of the diagnostic radiation 16 (step S7). . The non-imagingable area diagnosed by the real image diagnosis unit 142 is referred to as a second non-imaging area. The real image diagnosis unit 142 transmits the diagnosis result to the console 24 via the communication unit 88.

  Next, the function limiting unit 134 limits the function of the electronic cassette 20 that is continuously used according to the actual image diagnosis result (step S8). That is, the function restriction unit 134 restricts the function of the electronic cassette 20 so that an image of the second non-capturable area diagnosed by the real image diagnosis unit 142 cannot be obtained. For example, the power supply to the gate IC 114 and the ASIC 116 may be prohibited so as not to perform the read operation of the charge accumulated in the pixel 104 determined to be the second imaging impossible region, or an image obtained by radiation imaging Of the data, the image data of the second uncapable area may be trimmed and extracted. The function restriction unit 134 transmits the function restricted according to the actual image diagnosis from the communication unit 88 to the console 24.

  Next, the control unit 152 of the console 24 causes the display unit 154 to display the actual image diagnosis result and the function limited according to the actual image diagnosis result (step S9). The control unit 152 may display the second non-capturing area diagnosed by the actual image diagnosis in the manner shown in FIG. In addition, when the imaging area is limited by prohibiting the power supply to the gate IC 114 that reads the pixels 104 in the second imaging impossible area, the actually limited imaging area is wider than the second imaging impossible area. Thus, the actually limited imaging region does not match the second imaging impossible region. In such a case, the actually limited imaging area is displayed as the non-imagingable area instead of the diagnosed second imaging impossible area. In addition to the function restricted according to the self-diagnosis result, the function restricted according to the actual image diagnosis result may be displayed. For example, the first image-capable region and the second image-capable region may be displayed together. When the failure diagnosis is completed, the cassette control unit 84 transmits a signal indicating that the radiation 16 for imaging 16 can be irradiated to the console 24 via the communication unit 88, and the console 24 transmits the radiation 16 for imaging. The fact that irradiation is possible is transmitted to the radiation device 18. Thereby, the radiation device 18 can irradiate the radiation 16 for imaging.

  As described above, when the environmental disturbance value is equal to or higher than the threshold value or when a fall is detected, the malfunction of the electronic cassette 20 is diagnosed, and the function of the electronic cassette 20 is limited depending on the diagnosis result. Even if the electronic cassette 20 is defective, it can be used continuously. In addition, since the function is limited according to the malfunction, the electronic cassette 20 does not have abnormal heat, and the power consumption can be minimized.

  When the environmental disturbance value is equal to or greater than the threshold value or when a fall is detected, the first non-imaging area where the radiation 16 cannot be imaged is self-diagnosed and the imaging operation is performed in the first non-imaging area. Therefore, the abnormal heat generation caused by the imaging operation in the first imaging impossible area can be prevented, and the power consumption can be minimized.

  If the environmental disturbance value exceeds the threshold value or if a fall is detected, the wiring status of the electronic cassette 20 is diagnosed, and the wiring status is not normal (short, disconnected, unstable connection) Since no current is passed through, no current is passed through the wiring whose wiring state is not normal, abnormal heat generation can be prevented, and power consumption can be minimized.

  When the environmental disturbance value is equal to or greater than the threshold value or when a fall is detected, the sky imaging is performed, and the radiation 16 cannot be captured based on the image data obtained by the sky imaging. Since the imaging impossible area is diagnosed, it is possible to detect an image area that is not actually obtained by imaging.

  Since the function of the restricted electronic cassette 20 is displayed on the display unit 154, the user can recognize the restricted function. In addition, when the environmental disturbance value is equal to or greater than the threshold value or when a fall is detected, irradiation of the radiation 16 for imaging is prohibited until the diagnosis by the failure diagnosis unit 132 is completed. Can be prevented from being exposed to the subject 14.

  The above embodiment can be modified as follows.

(Modification 1)
In the above embodiment, when the second image uncapable area is diagnosed by the real image diagnostic unit 142, the function of the electronic cassette 20 is limited so that an image of the second uncapable area cannot be obtained in step S8. However, it need not be limited. In this case, the operation in step S9 is unnecessary, and in step S9, the diagnosed second uncapable area is simply displayed on the display unit 154. At this time, the first non-imaging area may be displayed together with the second non-imaging area.

(Modification 2)
Although both the self-diagnosis and the actual image diagnosis are performed, only one of the self-diagnosis and the actual image diagnosis may be performed.

(Modification 3)
A display unit such as a liquid crystal panel is provided on the back surface (the surface opposite to the imaging surface 46) of the panel unit 40, and the display unit provided on the back surface of the panel unit 40 is restricted by self-diagnosis and / or actual image diagnosis. The captured non-imaging area may be displayed. As a result, by turning the panel unit 40 upside down, it is possible to sensuously recognize which region is a non-imagingable region. Further, a light emitting element such as an LED may be arranged at a position of the area scale of the electronic cassette 20, and the cassette control unit 84 may display the non-imagingable area by lighting or blinking the light emitting element.

(Modification 4)
In mammography, breast cancer often occurs in the axilla, so imaging of the axilla is particularly important. As shown in FIG. 10, in the case of mammography, the image is taken in a state where the breast 160 is placed on the imaging panel 40 of the electronic cassette 20, so that the region on the chest wall side in the end-side region of the imageable region 50. 162 is an area for imaging the axilla. Accordingly, if the region 162 on the chest wall side of the electronic cassette 20 becomes an image-capable region, the axilla portion cannot be imaged. Therefore, when the area 162 of the imageable area 50 is diagnosed as an unimaginable area by self-diagnosis or actual image diagnosis, the function restriction unit 134 restricts the mammo image pickup function. For example, the user operates the input unit 150 of the console 24 to select an imaging order to be performed from among a plurality of imaging orders, but the function restriction unit prevents the console 24 from selecting an imaging order for mammo imaging. 134 may limit the type of imaging.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Radiation imaging system 16 ... Radiation 18 ... Radiation apparatus 20 ... Electronic cassette 24 ... Console 26 ... Display apparatus 34 ... Radiation source 36 ... Radiation control apparatus 40 ... Panel part (imaging panel) 42, 152 ... Control part 50 ... Image pick-up possible Area 52 ... Scintillator 54 ... Radiation conversion panel 56 ... Radiation detector 84 ... Cassette control unit 86 ... Memory 88, 156 ... Communication unit 90 ... Built-in battery 92 ... Light emitting unit 102 ... TFT
DESCRIPTION OF SYMBOLS 104 ... Pixel 110 ... Gate line 112 ... Signal line 120 ... Drop detection part 122 ... Humidity detection part 124 ... Temperature detection part 126 ... Pressure detection part 130 ... Imaging control part 132 ... Defect diagnosis part 134 ... Function restriction part 140 ... Self-diagnosis Unit 142 ... Real image diagnostic unit 150 ... Input unit 154 ... Display unit

Claims (9)

A radiation imaging system comprising: a radiation device that irradiates radiation; and a radiation imaging device that includes an imaging panel that images the irradiated radiation.
The radiation imaging apparatus includes:
A failure factor detector that detects environmental disturbances or drops that cause the failure of itself;
When the detected environmental disturbance value is equal to or greater than a threshold value, or when a fall is detected, a fault diagnosis unit that diagnoses a fault of the radiation imaging apparatus,
A function restriction unit that restricts a part of the function of the radiation imaging apparatus according to the diagnosis result of the defect diagnosis part, and enables the radiation imaging apparatus to be used continuously,
Equipped with a,
The defect diagnosis unit includes a self-diagnosis unit for self-diagnosis of the radiation imaging apparatus,
The self-diagnosis includes a function of diagnosing a first non-imaging area where the radiation cannot be imaged among all imaging areas of the imaging panel, and a function of diagnosing a wiring state,
The function restriction unit restricts the function of the radiation imaging apparatus so as not to perform an imaging operation in the first non-imaging region, and prevents a current from flowing in a wiring in which the wiring state is not normal, whereby the radiation imaging apparatus The radiation imaging system characterized by restricting the function of . The radiation imaging system according to claim 1 ,
The defect diagnosis unit includes an actual image diagnosis unit that diagnoses a second non-imageable region where the radiation cannot be imaged based on image data obtained by sky imaging,
When the disturbance value of the environment detected by the failure factor detection unit is greater than or equal to a threshold value or when a fall is detected, the radiation device uses the radiation for diagnosis for diagnosing the radiation imaging device. Irradiate the imaging panel,
The real image diagnostic unit diagnoses the second non-imaging region based on image data obtained by performing sky imaging of the diagnostic radiation,
The function restriction unit restricts functions of the radiation imaging apparatus so that an image of the second imaging impossible region cannot be obtained. The radiation imaging system according to claim 1 or 2 ,
A radiation imaging system comprising: a notification unit that notifies a user of a diagnosis result by the defect diagnosis unit or a function restricted by the function restriction unit. The radiation imaging system according to any one of claims 1 to 3 ,
The radiation imaging system, wherein the radiation apparatus prohibits the irradiation of the radiation for imaging until the diagnosis by the failure diagnosis unit is completed. The radiation imaging system according to any one of claims 1 to 4 , wherein
The radiation disturbance imaging system according to claim 1, wherein the environmental disturbance is any one of an external pressure applied to the imaging panel, an environmental temperature or a change thereof, and an environmental humidity. The radiation imaging system according to any one of claims 1 to 5 ,
The radiation imaging system, wherein the radiation imaging apparatus is a portable radiation imaging apparatus. The radiation imaging system according to claim 1 ,
The radiation imaging apparatus includes a communication unit that wirelessly transmits and receives signals to and from other apparatuses,
The self-diagnosis unit diagnoses whether the communication function of the communication unit is normal,
The radiation imaging system according to claim 1, wherein the function restriction unit restricts the communication function of the communication unit when determining that the communication function of the communication unit is not normal. The radiation imaging system according to claim 1 ,
The radiation imaging apparatus includes a storage unit that stores image data obtained by imaging radiation,
The self-diagnosis unit diagnoses the storage unit,
The function limiting unit limits a continuous imaging function when the possible storage capacity of the storage unit is lower than a predetermined value. The radiation imaging system according to claim 1 ,
The radiation imaging apparatus includes a built-in battery,
The self-diagnosis unit diagnoses the built-in battery,
The function restriction unit restricts the use of the built-in battery when the remaining battery level of the built-in battery is lower than a predetermined value, or when the degree of deterioration of the built-in battery is higher than a predetermined value. A radiation imaging system.

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