JP2006095020A - Radiography system and radiation detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To specifically grasp the maximum number of radiographs in a radiation detector on performing radiography on a subject. <P>SOLUTION: The radiography system is used to acquire radiographs of the subject by carrying out the radiography on the subject, and is equipped with the radiation detector 10 for sensing radiation rays transmitting the subject and a console 3 for controlling the movements of the radiation detector 10. The radiation detector 10 includes a battery 19 which is an electric power supply source, a control unit 25 for sensing the amount of charge of the battery 19, and a connector 20 for transmitting the amount of charge of the battery 19 sensed by the control unit 25 as charge information. On the other hand, the console 3 includes a connector 31 for receiving the charge information, a control unit 35 for calculating the maximum number of radiographs of the radiation detector 10 based on the charge information received by the connector 31, and a display 32 for displaying the maximum number of radiographs calculated by the control unit 35. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a radiographic imaging system and a radiation detector applied when radiographing a subject.

  Conventionally, in the field of radiography for the purpose of medical diagnosis, there have been widely used radiographic imaging systems that obtain a radiographic image of a subject by irradiating the subject with radiation and detecting the intensity distribution of the radiation transmitted through the subject. Are known. In recent radiographic imaging systems, a so-called “Flat Panel Detector” radiation detector, which is a thin flat plate with a number of photoelectric conversion elements arranged in a matrix, has been developed and used. A radiation image of a subject can be easily and quickly obtained by photoelectrically converting the radiation transmitted through the light into an electrical signal and subjecting the electrical signal after the photoelectric conversion to image processing.

The radiation detector is roughly classified into a stationary type installed at a predetermined position as a part of the system and a portable type (cassette type) that is portable. The cassette type radiation detector is driven by a single detector. In some cases, a storage battery (battery) is usually arranged in the radiation detector. An example of such a radiation detector is disclosed in Patent Document 1. In particular, in the radiation detector (cassette type radiation image reading device 1) of Patent Document 1, the charge state of the power source means (23) configured by a battery is displayed on the charge state display means (28). The state of charge (remaining charge) of the power supply means can be easily confirmed visually (see paragraph 0063).
JP 2000-347330 A

  However, when the state of charge is simply displayed as in the radiation detector of Patent Document 1, the photographer is able to photograph how much of the remaining image can be captured (how many images can be captured). The possible number cannot be specifically grasped, and there are inconveniences such as the following (1) to (4).

(1) The photographer has anxiety that the battery may run out during shooting, and hesitates to continue using the radiation detector in use.
(2) If the battery runs out during shooting, it will cause the subject to wait until the radiation detector used is replaced with another radiation detector. I will spend.

(3) If the battery runs out during shooting, there is a possibility that a radiographic image of the subject used for the shooting may not be completely generated. Unnecessary radiation is exposed.
(4) Radiation detectors are generally very expensive, and many are owned by general hospitals. In hospitals and clinics where the number of radiation detectors is small, sewing intervals are taken. The battery must be recharged and replaced, and a detailed plan cannot be made for a large number of shots.

  An object of the present invention is to specifically grasp the number of images that can be captured by a radiation detector during radiography of a subject.

In order to solve the above problem, the invention according to claim 1
In a radiographic imaging system that obtains a radiographic image of a subject by radiographing the subject,
A radiation detector for detecting radiation transmitted through the subject;
A console for controlling the operation of the radiation detector;
With
The radiation detector is
A battery as a power supply source;
A charge amount detector for detecting the charge amount of the battery;
A transmission unit that transmits the charge amount of the battery detected by the charge amount detection unit to the console as charge information;
Have
The console is
A receiving unit for receiving the charging information transmitted from the transmitting unit;
A calculation unit that calculates the number of images that can be captured by the radiation detector based on the charging information received by the reception unit;
A display unit that displays the number of possible shots calculated by the calculation unit;
It is characterized by having.

The invention described in claim 2
In the radiographic imaging system of Claim 1,
In the calculation unit, the scheduled number of shooting of the subject is registered in advance,
The calculation unit
The calculated number of shootable images and the pre-registered scheduled number of shoots are collated to determine whether the calculated number of shootable images is greater than or equal to the pre-registered number of shootable images, and the determination result is It is characterized by being displayed on the display unit.

The invention according to claim 3
In the radiographic imaging system of Claim 1 or 2,
The charge amount of the battery indicates a drive voltage of the battery.

The invention according to claim 4
In the radiographic imaging system of Claim 3,
The calculation unit
It has a data table in which the drive voltage of the battery and the shootable number are associated with each other, and the shootable number is calculated from the drive voltage of the battery with reference to the data table.

The invention described in claim 5
In the radiographic imaging system of Claim 4,
The data table corresponds to a type of the radiation detector.

The invention described in claim 6
In a radiographic imaging system that obtains a radiographic image of a subject by radiographing the subject,
A radiation detector for detecting radiation transmitted through the subject;
A console for controlling the operation of the radiation detector;
With
The radiation detector is
A battery as a power supply source;
A charge amount detector for detecting the charge amount of the battery;
A calculation unit that calculates the number of images that can be captured by the radiation detector based on the charge amount of the battery detected by the charge amount detection unit;
A transmission unit that transmits the number of shootable images calculated by the calculation unit to the console as shootable number information;
Have
The console is
A receiver for receiving the number of shootable information transmitted from the transmitter;
A display unit for displaying the number of shootable images calculated by the calculation unit based on the number of shootable number information received by the receiving unit;
It is characterized by having.

The invention described in claim 7
In the radiographic imaging system of Claim 6,
The console is
A control unit in which the number of planned shootings of the subject is registered in advance;
The control unit is
Check whether the number of shootable images calculated by the calculating unit and the pre-registered scheduled number of shoots are equal to each other, and whether the shootable number calculated by the calculating unit is equal to or greater than the pre-registered planned number of shoots This is characterized in that the determination result is displayed on the display unit.

The invention according to claim 8 provides:
In the radiographic imaging system of Claim 6 or 7,
The charge amount of the battery indicates a drive voltage of the battery.

The invention according to claim 9 is:
In the radiographic imaging system of Claim 8,
The calculation unit
It has a data table in which the drive voltage of the battery and the shootable number are associated with each other, and the shootable number is calculated from the drive voltage of the battery with reference to the data table.

The invention according to claim 10 is:
The radiographic imaging system according to claim 9, wherein
The data table corresponds to a type of the radiation detector.

The invention according to claim 11
In radiation detectors used for radiography of subjects,
A battery as a power supply source;
A charge amount detector for detecting the charge amount of the battery;
A calculation unit that calculates the number of shootable images based on the charge amount of the battery detected by the charge amount detection unit;
A display unit that displays the number of possible shots calculated by the calculation unit;
It is characterized by having.

The invention according to claim 12
The radiation detector according to claim 11.
The charge amount of the battery indicates a drive voltage of the battery.

The invention according to claim 13
The radiation detector according to claim 12, wherein
The calculation unit
It has a data table in which the drive voltage of the battery and the shootable number are associated with each other, and the shootable number is calculated from the drive voltage of the battery with reference to the data table.

The invention according to claim 14
The radiation detector according to claim 13.
The data table corresponds to the type of the battery.

  According to the first aspect of the present invention, since the number of images that can be captured by the radiation detector is displayed on the display unit of the console, the number of images that can be captured by the radiation detector can be specifically grasped when the subject is subjected to radiation imaging. Therefore, the photographer's anxiety that the battery may run out during radiography is resolved, and the subject subjected to radiography does not have to wait or be exposed to unnecessary radiation. In hospitals and clinics with a small number of detectors, batteries can be charged and exchanged systematically, and a detailed plan can be created for many radiographs.

  According to the second aspect of the present invention, the determination result of whether or not the number of images that can be captured is greater than or equal to the scheduled number of images is displayed on the display unit of the console. Can be prevented in advance.

  According to the third aspect of the present invention, since the charge amount of the battery indicates the drive voltage of the battery, the number of shootable images is calculated with high accuracy, and the reliability of the shootable number can be improved.

  In the invention described in claim 4, since the data table is referred to when calculating the number of shootable images, the shootable number is calculated with high accuracy, and the reliability of the shootable number can be improved.

  In invention of Claim 5, the imaging | photography possible number according to the kind of radiation detector can be grasped | ascertained.

  In the invention described in claim 6, since the number of images that can be captured is displayed on the display unit, the number of images that can be captured by the radiation detector can be specifically grasped when the subject is subjected to radiation imaging. Therefore, the photographer's anxiety that the battery may run out during radiography is resolved, and the subject subjected to radiography does not have to wait or be exposed to unnecessary radiation. In hospitals and clinics with a small number of detectors, batteries can be charged and exchanged systematically, and a detailed plan can be created for many radiographs.

  In the invention according to claim 7, since the determination result of whether or not the number of images that can be captured is equal to or greater than the scheduled number of images is displayed on the display unit of the console, the radiation detector runs out of battery during the radiography of the subject. Can be prevented in advance.

  In the invention according to claim 8, since the charge amount of the battery indicates the drive voltage of the battery, the shootable number is calculated with high accuracy, and the reliability of the shootable number can be improved.

  In the invention described in claim 9, since the data table is referred to when calculating the number of shootable images, the shootable number is calculated with high accuracy, and the reliability of the shootable number can be improved.

  In invention of Claim 10, the imaging | photography possible number according to the kind of radiation detector can be grasped | ascertained.

  In the invention described in claim 11, since the number of images that can be captured is displayed on the display unit, the number of images that can be captured by the radiation detector can be specifically grasped when the subject is subjected to radiation imaging. Therefore, the photographer's anxiety that the battery may run out during radiography is resolved, and the subject subjected to radiography does not have to wait or be exposed to unnecessary radiation. In hospitals and clinics with a small number of detectors, batteries can be charged and exchanged systematically, and a detailed plan can be created for many radiographs.

  In the invention according to claim 12, since the charge amount of the battery indicates the drive voltage of the battery, the number of shootable images is calculated with high accuracy, and the reliability of the shootable number can be improved.

  In the invention according to the thirteenth aspect, since the data table is referred to when calculating the number of shootable images, the shootable number is calculated with high accuracy, and the reliability of the shootable number can be improved.

  In invention of Claim 14, the imaging | photography possible number according to the kind of battery can be grasped | ascertained.

  The best mode for carrying out the present invention will be described below with reference to the drawings. However, the scope of the invention is not limited to the illustrated examples.

[First Embodiment]
FIG. 1 is a diagram showing a schematic configuration of a radiographic image capturing system 1.
As shown in FIG. 1, the radiographic imaging system 1 includes an imaging device 2 that performs radiation imaging of a subject M by irradiating a subject M as a subject, and a console 3 that generates a radiographic image of the subject M. ing.

  The imaging device 2 is installed and used in a medical facility such as a clinic or a hospital. The imaging apparatus 2 has a radiation source 4 and emits radiation when a tube voltage is applied to the radiation source 4. A diaphragm device 5 for adjusting the radiation field is provided at the radiation outlet of the radiation source 4 so as to be freely opened and closed. A bed 6 on which the subject M is placed is provided below the radiation source 4 and in the radiation irradiation range. The bed 6 is provided with a radiation detector 10 that detects the amount of radiation transmitted through the subject M. The radiation detector 10 is of a portable cassette type that is detachably disposed on the bed 6.

  The console 3 is a general-purpose computer and has a built-in control device 30 (see FIG. 3) that generates a radiographic image of the subject M based on the detection result of the radiation detector 10. In addition, the console 3 communicates with the imaging device 2. A connector 31 (see FIG. 3) for performing the operation, a display 32 as a display unit for displaying a radiation image of the subject M, and a keyboard / mouse for inputting imaging information regarding the subject M and the radiation detector 10 to the control device 30. 33 etc.

FIG. 2 is a perspective view showing a schematic configuration of the radiation detector 10.
As shown in FIG. 2, the radiation detector 10 has a thin and rectangular parallelepiped casing 11, and a part of the top plate of the casing 11 is a grid 12 that absorbs and removes radiation scattering components. . A handle 13 is disposed on the side of the housing 11 so that the radiation detector 10 can be easily carried.

A scintillator 14 that emits fluorescence with an intensity corresponding to the intensity of radiation is disposed inside the housing 11. The scintillator 14 is made of a phosphor such as GOS (Gd ₂ O ₂ S: Tb) or CsI. A flat fluorescence detection panel 15 for detecting fluorescence is disposed below or below the scintillator 14.

  In the fluorescence detection panel 15, a large number of photoelectric conversion elements that receive fluorescence and accumulate charges corresponding to the amount of received light are arranged in a matrix (lattice). On the side of the fluorescence detection panel 15, a scanning driver 16 that sends a pulse to each photoelectric conversion element to scan and drive each photoelectric conversion element, and a signal driver 17 that reads out the amount of charge accumulated in each photoelectric conversion element, Is arranged.

  Inside the housing 11, a control device 18 for controlling operations of the scanning driver 16, the signal driver 17, and other members, and a battery 19 serving as a power supply source are arranged. In particular, the battery 19 is detachably attached to the housing 11 and can be easily replaced with another battery 19. The housing 11 having the above-described configuration is provided with a connector 20 for communicating with the console 3, an indicator 21 for displaying various messages, an operation button 22 for inputting various information to the control device 18, and the like. ing.

FIG. 3 is a block diagram showing a circuit configuration of the radiation image capturing system 1.
As shown in FIG. 3, in the radiation detector 10, the control device 18 includes a control unit 25 including a general-purpose CPU (Central Processing Unit), ROM (Read Only Memory), RAM (Random Access Memory), and the like. ing. The control unit 25 expands the processing program recorded in the ROM to the RAM, and executes the processing program by the CPU.

  Each member such as a scanning driver 16, a signal driver 17, a battery 19, a connector 20, an indicator 21, and an operation button 22 is connected to the control unit 25. The control unit 25 includes the scanning driver 16, the signal driver 17, the battery 19 and the like. The components are controlled based on the operation status of each member such as the connector 20, the indicator 21, the operation button 22, and the like. In particular, the control unit 25 can calculate the drive voltage of the battery 19 as the charge amount of the battery 19.

  On the other hand, in the console 3, the control device 30 has a control unit 35 constituted by a general-purpose CPU (Central Processing Unit), ROM (Read Only Memory), RAM (Random Access Memory) and the like. The control unit 35 develops the processing program recorded in the ROM on the RAM, and executes the processing program by the CPU.

  The control unit 35 is connected to each member such as the connector 31, the display 32, and the keyboard / mouse 33. The control unit 35 is based on the operating status of each member such as the connector 31, the display 32, and the keyboard / mouse 33. Each configuration is controlled. In particular, the photographer can register photographing information regarding the subject M and the radiation detector 10 in the control unit 35 of the control device 30 by performing an input operation on the keyboard / mouse 33.

  The “imaging information” is information including the planned number of subjects M to be photographed, the photographing mode (still image mode or moving image mode) for the subject M, the type of the radiation detector 10, the type of the battery 19, and the like. The moving image mode includes information such as a shooting interval (1 image / second, 10 images / second, etc.) and a shooting time (1 second, 10 seconds, 1 minute, etc.).

In the radiographic imaging system 1 described above, the connector 20 of the radiation detector 10 and the connector 31 of the console 3 are connected by a member such as a cable, and the radiation detector 10 and the console are connected through the connectors 20 and 31. 3 can communicate with each other.
The communication between the radiation detector 10 and the console 3 may be wired as described above, but may be well-known wireless, or well-known wired or wireless via a network. It may be.

  Next, the operation and action of the radiographic image capturing system 1, specifically, a method for generating a radiographic image of the subject M using the radiographic image capturing system 1 will be described.

  In a state where the radiation detector 10 of the imaging apparatus 2 and the console 3 can communicate with each other, first, the photographer operates the subject M with respect to the control unit 35 of the console 3 by an input operation of the keyboard / mouse 33 of the console 3. And “imaging information” of the radiation detector 10 is pre-registered.

  The control unit 35 of the console 3 receives the input operation of the photographer, recognizes the imaging information of the subject M and the radiation detector 10, and detects a radiation “start signal” from the connector 31 to start radiation imaging of the subject M. To the device 10. Then, the radiation detector 10 receives the start signal at the connector 20, and the control unit 25 as the charge amount detection unit detects the charge amount of the battery 19 and calculates the drive voltage of the battery 19 from the detection result. The radiation detector 10 transmits the drive voltage of the battery 19 calculated by the control unit 25 to the console 3 as “charging information” by the connector 20 as a transmission unit.

  The console 3 receives the charging information with the connector 31 as a receiving unit, and the control unit 35 recognizes the driving voltage of the battery 19 of the radiation detector 10 based on the charging information.

  Here, the control unit 35 of the console 3 includes a data table (see FIG. 4) in which the drive voltage of the battery 19 and the number of images that can be captured by the radiation detector 10 are associated with each other. A plurality of them are stored in advance corresponding to both of the 19 types. The control unit 35 as a calculation unit selects a specific data table corresponding to both the type of the radiation detector 10 and the type of the battery 19 based on pre-registered imaging information, and selects the selected data table. With reference to the data table, the number of images that can be captured by the radiation detector 10 is calculated from the drive voltage of the battery 19.

FIG. 4 shows an example of the data table.
In the data table shown in FIG. 4, the driving voltage of the battery 19 and the number of images that can be captured by the radiation detector 10 are listed in correspondence with each other, and the number of images that can be captured corresponding to the driving voltage decreases. Yes. For example, when the control unit 35 of the console 3 recognizes the drive voltage of the battery 19 as “55 (V)”, the control unit 35 calculates the number of shootable images as “30 to 26” from the drive voltage.

  The data table may simply correspond to the type of radiation detector 10 or simply correspond to the type of battery 19. In this case, the control unit 35 of the console 3 selects a specific data table corresponding to either the type of the radiation detector 10 or the type of the battery 19 based on the pre-registered imaging information from the plurality of data tables. select.

  When the control unit 35 of the console 3 calculates the number of images that can be captured by the radiation detector 10, the control unit 35 calculates the scheduled number of images of the subject M based on the previously registered imaging information. In this case, the control unit 35 of the console 3 also recognizes the shooting mode for the subject M based on the pre-registered shooting information, and calculates the total number of shots according to the type of shooting mode. For example, when the moving image mode is selected as the shooting mode in the pre-registration of shooting information by the photographer, the control unit 35 of the console 3 recognizes the moving image mode from the shooting information, The number of scheduled shots is calculated in consideration of all information such as shooting time.

  When the control unit 35 of the console 3 calculates the planned number of subjects M, the number of possible images calculated from the drive voltage of the battery 19 is collated with the scheduled number of images based on the image information. Compare / determine whether the number is higher than the planned number of shots based on.

  If the control unit 35 of the console 3 determines that the calculated number of images that can be captured is less than the scheduled number of images based on the imaging information, the battery 19 may run out of charge during the radiation imaging of the subject M. And the display 32 displays a message to that effect (to the subject M that radiography is not possible). In this case, the photographer determines that the battery 19 of the radiation detector 10 does not have a sufficient amount of charge to perform radiography of the subject M, and replaces the radiation detector 10 with another radiation detector 10. The above pre-registration must be repeated.

  On the other hand, when the control unit 35 of the console 3 determines that the calculated number of shootable images is equal to or greater than the planned number of photographic images based on the photographic information, the battery 19 may be out of charge during the radiography of the subject M. It is determined that there is no image, and a message indicating the number of images that can be captured is displayed on the display 32.

  In this case, the control unit 35 of the console 3 compares / determines whether or not the calculated number of shootable images is less than the specified number. The “specified number” here may be set in advance in the control unit 35 of the console 3 or may be appropriately changed by an input operation of the keyboard / mouse 33 by the photographer.

  When the control unit 35 of the console 3 determines that the calculated number of shootable images is equal to or greater than the specified number, the number of shootable images is displayed in an abstract display form such as “many”, “medium”, and “small”. On the other hand, when it is determined that the calculated number of shootable images is less than the prescribed number, the display form having specific numbers such as “3”, “2”, “1”, etc. The number of shootable images is displayed on the display 32.

  For example, when the control unit 35 of the console 3 calculates the number of shootable images using the data table shown in FIG. 4 and the specified number is “6”, the control unit 35 sets the number of shootable images. If it is calculated as “100 to 36”, the number of possible shots is “many”, and if the number of possible shots is calculated as “35 to 21”, the number of possible shots is “medium” and the number of possible shots is “20 to 6”. Once calculated, the number of shootable images is abstractly displayed on the display 32 as “small”, while the number of shootable images is calculated as “5”, “4”, “3”, “2”, and “1”, respectively. The number of possible shots is displayed on the display 32 with specific numbers such as “5”, “4”, “3”, “2”, and “1”, respectively.

  When the display 32 of the console 3 displays a message indicating the number of images that can be captured, the photographer determines that the battery 19 of the radiation detector 10 has a sufficient amount of charge to perform radiation imaging of the subject M. The radiation imaging of the subject M using the imaging device 2 can be started.

  In radiography, in a state where the subject M lies on the bed 6, the radiation source 4 irradiates the subject M with radiation through the diaphragm device 5, and the radiation transmitted through the subject M and the bed 6 enters the radiation detector 10. . When the radiation enters the radiation detector 10, the scattered component is absorbed and removed by the grid 12 of the radiation detector 10 and enters the scintillator 14, and the scintillator 14 emits fluorescence with an intensity corresponding to the intensity of the radiation. .

  When the scintillator 14 emits fluorescence, each photoelectric conversion element of the fluorescence detection panel 15 receives the fluorescence emitted by the scintillator 14 and accumulates charges corresponding to the amount of received light. When each photoelectric conversion element accumulates electric charge, the control unit 25 of the control device 18 controls the scan driver 16 and the signal driver 17 respectively, the scan driver 16 sends a pulse to each photoelectric conversion element, and the signal driver 17 The amount of charge accumulated in the conversion element is read out as a signal.

  When the signal driver 17 reads the signal, the signal driver 17 outputs the read signal as “radiation image information” of the subject M to the control unit 25 of the control device 18, and the control unit 25 of the control device 18 outputs the radiographic image. Information is transmitted from the connector 20 to the control unit 35 of the control device 30 of the console 3.

  The console 3 receives the radiation image information at the connector 31, and the control unit 35 of the control device 30 processes the received radiation image information to generate a radiation image, and the radiation image is displayed as a radiation image of the subject M on the display 32. To display.

  In the radiographic imaging system 1 described above, since the number of images that can be captured by the radiation detector 10 is displayed on the display 31 of the console 3, the photographer specifically sets the number of images that can be captured by the radiation detector 10 when the subject M is subjected to radiation imaging. Can grasp. Therefore, the photographer's anxiety that the battery 19 may be out of charge during radiation imaging is resolved, and the subject M subjected to radiation imaging may be kept waiting or subject M may be exposed to unnecessary radiation. In a hospital or clinic where the number of radiation detectors 10 is small, the battery 19 can be charged and replaced systematically, and a detailed plan can be made for many radiographs.

[Second Embodiment]
The radiographic image capturing system 1 according to the second embodiment is different from the radiographic image capturing system 1 according to the first embodiment in the following points in configuration, operation, and the like, and other than that in the first embodiment. It is the same as that of the radiographic imaging system 1 concerning.

  A plurality of the data tables as shown in FIG. 4 are stored in advance in the control unit 25 of the radiation detector 10 instead of the control unit 35 of the console 3.

  During the operation of the radiographic imaging system 1, the radiation detector 10 has a control unit 25 as a calculation unit configured to select either or both of the type of the radiation detector 10 and the type of the battery 19 from the plurality of data tables. A corresponding specific data table is selected, and the number of shootable images is calculated from the drive voltage of the battery 19 with reference to the selected data table.

  In the radiation detector 10, when the control unit 25 calculates the number of images that can be captured, the connector 20 transmits the number of images that can be captured, calculated by the control unit 25, to the console 3 as “number of images that can be captured”. The console 3 receives information on the number of images that can be captured by the connector 31, and the control unit 35 recognizes the number of images that can be captured by the radiation detector 10 based on the information on the number of images that can be captured, and performs the same processing as described above.

  In the second embodiment, the control unit 25 of the radiation detector 10 may display the number of possible images calculated from the drive voltage of the battery 19 on the indicator 21 as a display unit.

  In this case, the control unit 25 of the radiation detector 10 compares / determines whether or not the calculated number of shootable images is less than the specified number, and determines that the calculated number of shootable images is greater than or equal to the specified number. When the number of shootable images is displayed on the indicator 21 in an abstract display form such as “many”, “medium”, or “small”, on the other hand, when it is determined that the calculated number of shootable images is less than the prescribed number, “3” , “2”, “1”, etc., the displayable number may be displayed on the indicator 21 in a display form (see FIG. 4). The “specified number” here may be set in advance in the control unit 25 of the radiation detector 10 or may be changed as appropriate by an input operation of the operation button 22 by the photographer.

  If the control unit 25 of the radiation detector 10 displays the calculated number of images that can be captured on the indicator 21 of the radiation detector 10, the photographer can display the number of images that can be captured using the radiation detector 10 from the display of the indicator 21. Specifically, it is possible to easily determine whether or not the charged amount of the battery 19 is sufficient when the subject M is radiographed, and to determine whether to charge or replace the battery 19.

  The present invention is not limited to the first and second embodiments, and various improvements and design changes may be made without departing from the gist of the present invention.

  For example, the control unit 35 of the console 3 or the control unit 25 of the radiation detector 10 does not cause the display 32 or the indicator 21 to display the number of possible images calculated as described above in the display form corresponding to the calculated number. The possible number may be displayed on the display 32 or the indicator 21 in a display form indicating a smaller number of possible photographing.

  That is, an example will be described with reference to FIG. 4. When the control unit 35 of the console 3 or the control unit 25 of the radiation detector 10 calculates the number of images that can be captured as “100 to 36”, the number of images that can be captured is ”Is displayed on the display 32 or the indicator 21, and when the number of shootable images is calculated as“ 5 ”, the shootable number may be displayed as“ 3 ”on the display 32 or the indicator 21.

  In this case, the difference between the calculated number of images that can be captured and the number of images that can be displayed in a display form that indicates a smaller number is preset in the control unit 35 of the console 3 or the control unit 25 of the radiation detector 10. Alternatively, it may be appropriately changed by an input operation of the keyboard / mouse 33 or the operation button 22 by the photographer.

It is drawing which shows schematic structure of a radiographic imaging system. It is a perspective view which shows schematic structure of a radiation detector. It is a block diagram which shows the circuit structure of a radiographic imaging system. It is drawing which shows an example of a data table.

Explanation of symbols

M Subject (subject)
1 Radiographic imaging system 3 Console 31 Connector (receiver)
32 Display (display unit)
35 Control unit (calculation unit)
10 Radiation detector 19 Battery 20 Connector (transmitter)
21 Indicator (display section)
25 Control unit (charge amount detection unit, calculation unit)

Claims (14)

In a radiographic imaging system that obtains a radiographic image of a subject by radiographing the subject,
A radiation detector for detecting radiation transmitted through the subject;
A console for controlling the operation of the radiation detector;
With
The radiation detector is
A battery as a power supply source;
A charge amount detector for detecting the charge amount of the battery;
A transmission unit that transmits the charge amount of the battery detected by the charge amount detection unit to the console as charge information;
Have
The console is
A receiving unit for receiving the charging information transmitted from the transmitting unit;
A calculation unit that calculates the number of images that can be captured by the radiation detector based on the charging information received by the reception unit;
A display unit that displays the number of possible shots calculated by the calculation unit;
A radiographic imaging system comprising: In the radiographic imaging system of Claim 1,
In the calculation unit, the scheduled number of shooting of the subject is registered in advance,
The calculation unit
The calculated number of shootable images and the pre-registered scheduled number of shoots are collated to determine whether the calculated number of shootable images is greater than or equal to the pre-registered number of shootable images, and the determination result is A radiographic imaging system characterized by being displayed on a display unit. In the radiographic imaging system of Claim 1 or 2,
The radiographic image capturing system, wherein a charge amount of the battery indicates a drive voltage of the battery. In the radiographic imaging system of Claim 3,
The calculation unit
A radiation image having a data table in which the drive voltage of the battery and the number of images that can be captured are associated with each other, and the number of images that can be captured is calculated from the drive voltage of the battery with reference to the data table Shooting system. In the radiographic imaging system of Claim 4,
The radiographic image capturing system, wherein the data table corresponds to a type of the radiation detector. In a radiographic imaging system that obtains a radiographic image of a subject by radiographing the subject,
A radiation detector for detecting radiation transmitted through the subject;
A console for controlling the operation of the radiation detector;
With
The radiation detector is
A battery as a power supply source;
A charge amount detector for detecting the charge amount of the battery;
A calculation unit that calculates the number of images that can be captured by the radiation detector based on the charge amount of the battery detected by the charge amount detection unit;
A transmission unit that transmits the number of shootable images calculated by the calculation unit to the console as shootable number information;
Have
The console is
A receiver for receiving the number of shootable information transmitted from the transmitter;
A display unit for displaying the number of shootable images calculated by the calculation unit based on the number of shootable number information received by the receiving unit;
A radiographic imaging system comprising: In the radiographic imaging system of Claim 6,
The console is
A control unit in which the number of planned shootings of the subject is registered in advance;
The control unit is
Check whether the number of shootable images calculated by the calculating unit and the pre-registered scheduled number of shoots are equal to each other, and whether the shootable number calculated by the calculating unit is equal to or greater than the pre-registered planned number of shoots And determining the result of the determination on the display unit. In the radiographic imaging system of Claim 6 or 7,
The radiographic image capturing system, wherein a charge amount of the battery indicates a drive voltage of the battery. In the radiographic imaging system of Claim 8,
The calculation unit
A radiation image having a data table in which the drive voltage of the battery and the number of images that can be captured are associated with each other, and the number of images that can be captured is calculated from the drive voltage of the battery with reference to the data table Shooting system. The radiographic imaging system according to claim 9, wherein
The radiographic image capturing system, wherein the data table corresponds to a type of the radiation detector. In radiation detectors used for radiography of subjects,
A battery as a power supply source;
A charge amount detector for detecting the charge amount of the battery;
A calculation unit that calculates the number of shootable images based on the charge amount of the battery detected by the charge amount detection unit;
A display unit that displays the number of possible shots calculated by the calculation unit;
A radiation detector comprising: The radiation detector according to claim 11.
The radiation detector, wherein a charge amount of the battery indicates a drive voltage of the battery. The radiation detector according to claim 12, wherein
The calculation unit
Radiation detection, comprising: a data table in which the drive voltage of the battery and the number of images that can be captured are associated with each other, and the number of images that can be captured is calculated from the drive voltage of the battery with reference to the data table vessel. The radiation detector according to claim 13.
The radiation detector, wherein the data table corresponds to a type of the battery.

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