JP2009291338A - Radiation image capturing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radiation image capturing system which exactly prevents radiation image detectors which is not used for capturing of radiation images from capturing a ghost image under a situation where radiation can reach the radiation image detectors. <P>SOLUTION: The radiation image capturing system 1 includes: the mobile radiation image detectors 2 which can switch the state of power source consumption between a sleeping state and an imaging possible state; a Bucky's device 3; and a console 7. The mobile radiation image detectors 2 are capable of imaging a subject even in a single state that is a state of not being loaded to the Bucky's device 3. When the power source consumption of the console 7 determines that two or more of the mobile radiation image detectors 2 in the single state are in the imaging possible state, the console 7 performs switching processing to the sleeping state which switches the state of power source consumption of the mobile radiation image detectors 2 in the single state other than one of the selected mobile radiation image detector 2 among the two or more mobile radiation image detectors 2. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a radiographic imaging system.

  For the purpose of disease diagnosis and the like, radiographic images taken using radiation typified by X-ray images are widely used. Conventionally, such medical radiographic images have been taken using a screen film. In order to digitize radiographic images, CR (Computed Radiography) devices using stimulable phosphor sheets have been developed recently. Then, a radiation image detector that detects irradiated radiation with a radiation detection element such as a photodiode (photoelectric conversion element) and acquires it as digital image data has been developed.

  This type of radiation image detector is known as an FPD (Flat Panel Detector), and is conventionally formed integrally with a Bucky device (see, for example, Patent Document 1). However, in recent years, a portable radiation image detector (hereinafter simply referred to as a portable radiation image detector) has been developed and put to practical use in which a radiation detection element or the like is housed in a housing. (See, for example, Patent Document 2).

  Such a radiation image detector 100 is normally configured to be used by being loaded into the cassette holding unit 102 of the bucky device 101 as shown in FIG. When the radiation image detector 100 is loaded into the Bucky device 101, power is supplied via the Bucky device 101, and image data, necessary information, and the like are transmitted to and received from a console (not shown). Often done.

  Further, in Patent Document 3, when the radiation image detector 100 is loaded into the bucky device 101, the fact that the radiation image detector 100 has been loaded is notified from the bucky device 101 to the console via a network or the like, and loaded at the console. The system which can grasp | ascertain is disclosed.

  Also, in recent years, taking advantage of the portability of the radiation image detector, it is not loaded into the bucky device, so to speak, is used alone, for example, the patient's hand as the subject is placed on the radiation incident surface of the radiation image detector. Increasingly, radiation imaging is performed by irradiating radiation from a portable radiation generator. Furthermore, portable radiographic image detectors that have wireless communication means such as an antenna device, and that can transmit and receive image data and the like to and from an external device such as a console via the wireless communication means have also been developed (for example, Patent Documents). 4).

  By the way, as described above, when the radiological image detector becomes portable and radiographic image capturing can be performed using the radiographic image detector alone, a plurality of radiographic image detectors are provided in the imaging chamber. In some cases, other radiation image detectors may detect the radiation applied to one radiation image detector.

  In this case, for example, when an image data transmission instruction is transmitted from the console to the radiation image detector in the imaging room, not only regular image data is transmitted from the radiation image detector used for radiographic imaging, A so-called ghost image is transmitted from the other radiation image detector. As described above, when wasteful image detection, transmission of image data (ghost image data), and the like are performed, there arises a problem that the battery of the radiation image detector is wasted.

In order to avoid such a situation, in the apparatus described in Patent Document 5, a cassette box capable of storing a plurality of radiological image detectors is provided in a photographing room or the like, and the radiographic image detector is stored in the cassette box. If the radiation image detector is housed in the cassette box, the power consumption state is set to the sleep state (power saving state), and the radiation image detector is removed from the cassette box. It has been proposed to switch the power consumption state of the extracted radiographic image detector to a radiographable state when it is extracted.
JP-A-9-73144 JP 2006-058124 A US Pat. No. 7,197,122 JP 2006-263339 A Japanese Patent Laid-Open No. 2002-248095

  However, in the normal case, the radiation image detector is not left in the photographing room, for example, and if it is in a sleep state, image detection, transmission of image data, and the like are not performed even if radiation is irradiated.

  In addition, when a radiographic image detector is loaded into a bucky device and radiation imaging is performed by irradiating radiation from the radiation generating device associated with the bucky device, the radiation emitted from the radiation generating device is The irradiation field is narrowed so that only a predetermined portion (a portion corresponding to the region of interest of the patient) is irradiated. For this reason, another radiological image detector is in a state where it can be photographed and is present in another location in the imaging room, and the other radiographic image detector automatically detects the radiation irradiation and automatically starts the reading process. However, radiation does not reach the radiation image detector, and a ghost image is not usually captured by the radiation image detector.

  Therefore, even in those cases, as described in Patent Document 5, if a radiological image detector that is not used for radiographic imaging must be returned to the cassette box, a radiographer or doctor who performs radiographic imaging Etc. (hereinafter referred to as an operator) has a problem that it feels troublesome.

  Therefore, the present invention has been made to solve the above-described problems, and in a situation where radiation can reach a plurality of radiation image detectors, a ghost is generated by a radiation image detector that is not used for radiographic imaging. An object of the present invention is to provide a radiographic image capturing system capable of accurately preventing an image from being captured.

In order to solve the above-described problem, the radiographic imaging system of the present invention includes:
A plurality of portable radiographic image detectors that have a built-in battery, include wireless communication means, and can switch a power consumption state between at least a sleep state and a radiographable state;
A bucky device capable of loading the portable radiographic image detector;
A radiation generator for emitting radiation;
A console capable of communicating with the plurality of portable radiographic image detectors;
With
The portable radiographic image detector is capable of photographing a subject in a single state not loaded in the bucky device, and can notify the console of the power consumption state.
When the portable radiographic image detector is loaded, the Bucky device notifies the console of the loading of the portable radiographic image detector, and when the loaded portable radiographic image detector is pulled out, the console is notified. Notifying release of loading of the portable radiation image detector,
When the console determines that the power consumption state of two or more portable radiographic image detectors among the portable radiographic image detectors in the single state is an imageable state, the power consumption state is an imageable state. One of the two or more portable radiographic image detectors is selected, and one of the portable radiographic image detectors other than the selected portable radiographic image detector is selected. Switching processing for switching the power consumption state of the device to the sleep state is performed.

  According to the radiographic imaging system of the system as in the present invention, the console is in a state where the power consumption state of two or more radiographic image detectors among the radiographic image detectors in a single state is not in a radiographable state. If it is determined that the power consumption state of two or more radiation image detectors in a single state is an imaging enabled state, one of the radiation image detectors is selected and the selected radiation is selected. A switching process for forcibly switching the power consumption state of the radiation image detector in a single state other than the image detector to the sleep state is performed.

  Therefore, for example, when radiation is irradiated in an arbitrary direction from a portable radiation generation device, there is a possibility that the radiation reaches a plurality of single-state radiation image detectors that are not loaded in the bucky device. Even if the radiographic image detectors that are not used for radiographic image capture are forcibly switched to the sleep state, the radiation image detectors are exposed to radiation and detect ghost images. Can be prevented accurately.

  Embodiments of a radiation image capturing system according to the present invention will be described below with reference to the drawings. However, the present invention is not limited to the following illustrated examples.

  The radiographic imaging system 1 according to the present embodiment is a system that assumes radiographic imaging performed in a hospital or a clinic, and is, for example, a part of a patient M irradiated with radiation as shown in FIG. An imaging room R1 for imaging a subject (a part to be imaged by the patient M) and an anterior room R2 for controlling radiation applied to an object by an operator such as a radiographer or a doctor, processing an image of the acquired radiation image, and the like. Is to be placed.

  In the present embodiment, in the radiographing room R1, a bucky device 3 that can be loaded with a portable radiographic image detector 2 (hereinafter simply referred to as a radiographic image detector 2), and radiation generation for irradiating a subject with radiation. A wireless access point (base station) 5 or the like is provided to relay the communication when the apparatus 4, the radiation image detector 2 and the console 7 perform wireless communication.

  The front chamber R2 is provided with a tag reader 6 for detecting a tag (described later) built in the radiographic image detector 2 and a console 7 for controlling the radiographic image capturing system 1 as a whole. In the present embodiment, the radiographic image capturing system 1 is configured to include at least these bucky devices 3, a radiation generation device 4, a radiographic image detector 2, and a console 7.

  As shown in FIG. 2, the radiation image detector 2 may be one in which a photoelectric conversion element such as a photodiode (not shown), a scintillator, or the like is incorporated in the housing 21. 2 shows a case where the casing 21 is formed of a front member 21a and a back member 21b. In addition, the casing 21 may be formed in a cylindrical monocoque shape. Is possible.

  A power supply / mode changeover switch 22 is arranged on the side surface portion of the radiation image detector 2, and the power supply / mode changeover switch 22 is manually pressed by continuously pressing the power supply / mode changeover switch 22 for a relatively long time (for example, about 1 or 2 seconds). The radiation image detector 2 can be turned on / off. In addition, when the power / mode changeover switch 22 is operated and the power is turned on, the radiation image detector 2 is a signal indicating that the power is turned on via an antenna device 24 described later (hereinafter referred to as a power ON signal). ) And the power is turned off, a signal indicating that the power has been turned off (hereinafter referred to as a power off signal) is sent to turn off the power before the power is turned off.

  In addition, a lid member 23 that is opened and closed for replacement of a battery (not shown) built in the casing 21 is provided on the side surface portion, and radiation image detection is performed on the side surface portion of the lid member 23. An antenna device 24 is embedded as a wireless communication means for the device 2 to transmit / receive information wirelessly to / from the outside via the wireless access point 5.

  In addition, the radiation image detector 2 is in a radiographable state in which necessary power is supplied to each member so that radiographic imaging can be performed when the power is on, and in a power saving state. Can be switched between at least two types of power consumption states, ie, a sleep state in which no radiographic imaging is performed.

  In the present embodiment, the radiation image detector 2 is configured such that when the power is turned on, the power consumption state is automatically set to a radiographable state. When the power / mode changeover switch 22 is pressed briefly, the power consumption state is switched between the photographing enabled state and the sleep state each time the power / mode changeover switch 22 is pressed. In addition, the radiation image detector 2 is automatically set to a sleep state when a predetermined time elapses without being irradiated with radiation after the power supply is turned on and the power consumption state is ready for photographing. It is supposed to switch to.

  Then, when the power consumption state is switched, the radiation image detector 2 has a signal indicating that the power consumption state has been switched (hereinafter referred to as a mode switching signal) and a power consumption state after the switching (that is, a radiographable state or (Sleep state) is transmitted via the antenna device 24.

  Further, as will be described later, when the polling signal is transmitted from the console 7, the radiological image detector 2 wirelessly accesses a response signal indicating whether the power consumption state of the radiographic image detector 2 is the imaging ready state or the sleep state. The console 7 is notified via the point 5.

  On the side surface portion of the radiation image detector 2, an indicator 25 that is configured by, for example, an LED or the like and displays a battery charging status, various operation statuses, and the like is provided. When the radiographic image detector 2 is loaded on the bucky device 3, an electrode (not shown) in the bucky device 3 is provided on the side surface portion opposite to the side surface portion of the radiographic image detector 2 provided with the indicator 25 or the like. A terminal (not shown) is provided for the radiation image detector 2 to be connected and to receive external power supply via the Bucky device 3 and to exchange signals with the outside.

  The radiographic image detector 2 includes a tag (not shown). In the present embodiment, a tag called a so-called RFID (Radio Frequency IDentification) tag is used as the tag, and the tag stores a control circuit that controls each part of the tag and unique information of the radiation image detector 2. The part is built in compactly.

  When the radiographic image detector 2 receives the radio wave transmitted from the tag reader 6 via the antenna device 24, the radiographic image detector 2 transmits the unique information including the cassette ID stored in the tag storage unit to the tag reader 6 via the antenna device 24. It is configured as follows. The unique information includes, for example, a cassette ID, scintillator type information, size information, resolution, and the like as identification information assigned to the radiation image detector 2.

  In the present embodiment, the radiation image detector 2 is configured with a size conforming to JIS Z 4905 (corresponding international standard is IEC 60406) in a conventional screen / film cassette. That is, the thickness in the radiation incident direction is within a range of 15 mm + 1 mm to 15 mm-2 mm, and is 8 inches × 10 inches, 10 inches × 12 inches, 11 inches × 14 inches, 14 inches × 14 inches, 14 inches × 17 inches. (Half cut size) etc. are prepared.

  Further, the radiation image detector 2 can be used by being loaded into the bucky device 3 as described above, but can also be used in a single state not loaded in the bucky device 3.

  That is, in a single state where the radiographic image detector 2 is not loaded in the bucky device 3, for example, the patient is placed on a support stand provided in the radiographing room R1 and is a subject on the radiation incident surface X (see FIG. 2). An M hand or the like is placed, or the patient M lying on the bed is inserted between the waist and legs of the patient and the bed, and is associated with the portable radiation generator 4c, that is, the bucky device 3. In other words, image data can be obtained by irradiating radiation from a free radiation generator 4c or the like.

  When the radiographic image detector 2 is loaded into the bucky device 3 and photographing is performed, the radiation image detector 2 is supplied with electric power from the outside via the above-described terminal via the bucky device 3, and receives external power such as transmission of image data. It is designed to exchange signals.

  Further, when used in a single state, the radiation image detector 2 is operated by the power of a built-in battery, and exchanges signals with the outside, particularly with the console 7 such as transmission of image data. Is performed by wireless communication via the wireless access point 5 provided in the photographing room R1 via the antenna device 24 of the radiation image detector 2. Note that, for example, the radiation image detector 2 may be brought into the anterior chamber R2 and connected to the console 7 by wire to transmit image data to the console 7.

  In addition, the radiation image detector 2 includes a storage unit (not shown) so that each image data obtained by a plurality of radiographic image captures can be temporarily stored. Therefore, by continuously irradiating a subject with radiation using the radiation image detector 2 and recording image data each time, continuous shooting and moving image shooting can be performed. ing.

  The radiation image detector (FPD) 2 may be a so-called indirect radiation image detector that converts irradiated radiation into light with a scintillator and detects it with a photoelectric conversion element such as a photodiode. In addition, it is possible to use various radiation image detectors such as a so-called direct radiation image detector that directly detects irradiated radiation with a radiation detection element without using a scintillator.

  The imaging room R1 is shielded with lead or the like so that radiation does not leak outside. The imaging room R1 is provided with a bucky device 3 into which the radiation image detector 2 can be loaded. In the present embodiment, a bucky device 3a for standing position photography and a bucky device 3b for lying position photography are provided as the bucky device 3, respectively. The bucky device 3 is also provided with a cassette holding unit 31 for holding the radiation image detector 2 in a predetermined position.

  In this embodiment, as the bucky device 3, the above-described CR cassette bucky device as the CR device is used. Although not shown in the drawings, the CR cassette is often configured with dimensions conforming to the JIS standard for the conventional screen / film cassette described above, and the bucky device 3 may be loaded with a CR cassette of that dimension. It is configured to be able to.

  Therefore, as described above, by configuring the radiographic image detector 2 with dimensions conforming to the same JIS standard, it is possible to load both the radiographic image detector 2 and the CR cassette into the same Bucky device 3. It has become. Therefore, in the present embodiment, not only the radiographic image detector 2 but also a CR cassette can be brought into the radiographing room R1 to perform radiographic imaging.

  Although illustration is omitted, the cassette holding unit 31 of the bucky device 3 is normally loaded with a loading detection device such as a microswitch that physically detects that the radiation image detector 2 has been loaded, or the radiation image detector 2 is operating normally. An electrode connected to the terminal of the radiation image detector 2 when loaded is provided. Since the CR cassette may be loaded as described above, the cassette holding unit 31 is provided with a barcode reader or the like that optically reads a barcode (not shown) of the CR cassette.

  The bucky device 3 includes a monitor (not shown) such as a CRT (Cathode Ray Tube) and an LCD (Liquid Crystal Display), an operation input unit such as a keyboard and a touch panel, a voice generation unit, a CPU (Central Processing Unit), and the like. An operation unit 32 is provided. Information such as patient information and imaging conditions transmitted from the console 7 is displayed on the monitor of the operation unit 32 so that the operator can confirm the patient and the imaging region by viewing the display. It has become.

  Even when the loading detection device detects the loading of the radiation image detector 2 or the CR cassette into the cassette holding unit 31, communication with the radiation image detector 2 via the electrode is not established, When the reader cannot read the barcode of the CR cassette, a voice is uttered from the utterance unit of the operation unit 32 to alert the operator.

  This is because the radiographic image detector 2 loaded in the cassette holding unit 31 of the bucky device 3 is not ready for photographing (the power switch is forgotten to be turned on) or the terminal of the radiographic image detector 2 is provided. The radiographic image detector 2 is loaded into the cassette holding unit 31 from the side portion on the side where the antenna device 24 is provided, or the radiographic image detector 2 and the CR cassette are loaded upside down. This is because both of them need to be reloaded.

  When the bucky device 3 detects that the radiation image detector 2 has been normally loaded based on signals from the loading detection device and the electrodes, it indicates that the radiation image detector 2 has been loaded into the console 7. Information such as a signal (hereinafter referred to as a loading signal) and a cassette ID is notified.

  Further, when the bucky device 3 detects that the loaded radiation image detector 2 has been pulled out based on signals from the loading detection device, electrodes, etc., the loading of the radiation image detector 2 to the console 7 is performed. A signal indicating that has been released (hereinafter referred to as a release signal) or the like is notified.

  In the present embodiment, the bucky device 3 allows the operator to operate the operation unit 32 via the operation input unit only when it is detected that the cassette 2 has been normally loaded. . That is, the operation unit 32 is configured not to accept an operation unless the cassette 2 is normally loaded in the bucky device 3. In addition, in the bucky device 3a for standing position photography and the bucky device 3b for standing position photography, for example, it is possible to appropriately adjust the position of the device itself, the height adjustment of the cassette holding portion 31 with respect to the apparatus body, and the like. It is the same as that of a known Bucky device.

  The imaging room R1 is provided with at least one radiation generating device 4 having a radiation source for irradiating the subject with radiation. In this embodiment, the buoy devices 3a and 3b for standing imaging and lying imaging are provided. The radiation generators 4a and 4b are arranged in advance in association with each other. In the present embodiment, it is also possible to provide a single radiation generator associated with each of the bucky devices 3a and 3b for standing position shooting and standing position shooting. .

  In the present embodiment, there is also provided a portable radiation generation device 4c that is not associated with the standing-up imaging device 3a and the standing-up imaging device 3b. It can be carried anywhere in the photographing room R1 and can irradiate radiation in any direction.

  In the present embodiment, the portable radiation generator 4c is activated by a radio signal from the radiation image detector 2 when used for the radiation image detector 2 without being controlled by the console 7, and the CR cassette is used. However, it can be configured to be activated by operating the console 7 or the like.

  The radiation generating device 4 includes an X-ray tube as a radiation source, and the X-ray tube emits a dose of radiation corresponding to the voltage when a high voltage is applied. The radiation image detector 4 is provided with a diaphragm (not shown) that can be opened and closed, and the radiation generators 4a and 4b associated with the standing-up photographing and the standing-up photographing bucky devices 3a and 3b. Then, the diaphragm is adjusted so that the radiation field is narrowed, so that the radiation is irradiated only to predetermined portions of the corresponding bucky devices 3a and 3b. In the portable radiation generation apparatus 4c, the dose and aperture of the radiation irradiated from the X-ray tube are appropriately adjusted and used.

  The radiation generators 4a and 4b respectively associated with the standing and radiographing bucky devices 3a and 3b are suspended from the ceiling of the imaging room R1, for example. At the time of photographing, it is activated based on an instruction from the console 7 and is moved to a predetermined position by a moving means (not shown).

  A wireless access point (base station) 5 is installed in one corner of the radiographing room R1 to relay these communications when the radiographic image detector 2 and the console 7 communicate wirelessly. FIG. 1 shows a case where the wireless access point 5 is provided in the vicinity of the entrance of the photographing room R1. However, the present invention is not limited to this. Installed.

  In the vicinity of the entrance of the front chamber R2, a tag reader 6 for exchanging information with the radiation image detector 2 using RFID technology is installed. The tag reader 6 transmits predetermined instruction information on radio waves or the like via a built-in antenna (not shown), and enters or exits the front room R2, that is, the radiographic image detector 2, that is, the radiographing room R1 or the front room R2. The radiation image detector 2 that has entered the range is detected. The tag reader 6 reads the unique information stored in the detected RFID tag of the radiation image detector 2 and transmits the read unique information to the console 7.

  A console 7 is provided in the front chamber R2. The console 7 is composed of a computer in which a CPU, a ROM (Read Only Memory), a RAM (Random Access Memory), an input / output interface, and the like (not shown) are connected to the bus, and reads a predetermined program stored in the ROM. The entire radiographic imaging system 1 is controlled as described above by developing it in the work area of the RAM and executing various processes according to the program.

  The console 7 is connected to the stand-up and stand-up shooting bucky devices 3a and 3b, the radiation generating devices 4a and 4b associated therewith, the tag reader 6 and the like via cables or the like. The wireless communication means 8 for performing wireless communication with the radiation image detector 2 is connected via the wireless access point 5.

  The console 7 is connected to storage means 9 composed of a hard disk or the like, and the console 7 is connected to other input means (not shown) such as a keyboard and a mouse.

  When the console 7 receives the unique information including the cassette ID of the radiation image detector 2 detected by the tag reader 6 as described above, the imaging room registered in the storage means 9 as shown in FIG. A list of radiation image detectors 2 existing in R1 or the like is referred to.

  If the transmitted unique information is not registered in the storage means 9, the console 7 detects that the radiation image detector 2 is newly brought into the imaging room R1 or the front room R2, and detects the radiation image. The cassette ID of the device 2 is added to the above list and registered in the storage means 9. Further, if the transmitted unique information is already registered in the storage means 9, the radiation image detector 2 is assumed to have been taken out from the imaging room R1 or the front room R2. Delete the cassette ID etc. from the above list. In this way, the console 7 grasps the radiation image detector 2 brought into or taken out of the photographing room R1 or the like and manages it on the storage means 9.

  Further, the console 7 is periodically provided via the wireless access point 5 for each radiation image detector 2 that exists in the radiographing room R1 or the like and is not loaded in any of the bucky devices 3a and 3b. Based on the response signal from each radiographic image detector 2 to the polling signal, the power ON / OFF of each radiographic image detector 2 and the power consumption state are grasped in the imaging enabled state or the sleep state It is supposed to be.

  In the example shown in FIG. 3, there are three radiological image detectors 2 that exist in the radiographing room R <b> 1 and are not loaded in the bucky devices 3 a and 3 b, and a radiographic image having a cassette ID “1010103”. The power consumption state of the detector 2 is an imageable state, and the other radiation image detectors 2 are in a sleep state. Hereinafter, for convenience, the radiation image detectors 2 with the cassette IDs “1010103”, “1010104”, and “1010111” will be referred to as radiation image detectors 2a, 2b, and 2c, respectively.

  In addition, when the console 7 receives a loading signal from the bucky device 3 as described above, the console 7 displays in the “loading state” column of the list of radiation image detectors 2 corresponding to the cassette ID notified accordingly. The ID of the Bucky device 3 loaded with the radiation image detector 2 is written, and when the release signal is notified from the Bucky device 3, the radiation image detector 2 corresponding to the cassette ID notified accompanying the release signal. By rewriting the “loading state” column in the list of “No.”, which radiation image detector 2 is currently loaded in which of the Buckie devices 3a and 3b, and which radiation image detector 2 is It is configured to manage and grasp whether any of the bucky devices 3a and 3b are not loaded and are in a single state.

  In the present embodiment, as described above, the console 7 periodically transmits a polling signal to each radiation image detector 2 in a single state existing in the imaging room R1 or the like. Based on the response signal transmitted from the radiation image detector 2, whether or not there are two or more radiation image detectors 2 that are not loaded in the Bucky device 3 and whose power consumption state is in the imaging enabled state. To come to judge.

  At that time, if there is a radiological image detector 2 not loaded in the bucky devices 3a and 3b in the front chamber R2, a polling signal transmitted via the wireless access point 5 is sent to the radiological image detector 2. In some cases, the radiation image detector 2 may not reach, but even if the radiographic image detector 2 is ready to be photographed, the irradiated radiation does not reach the anterior chamber R2, so that a ghost image is photographed by the radiographic image detector 2. There is no.

  Therefore, if the console 7 transmits a polling signal via the wireless access point 5 and no response signal is transmitted, the radiographic image detector 2 is present in the front chamber R2 or the power is turned off. Therefore, the radiological image detector 2 is excluded from the monitoring target at the time when the periodic polling signal is transmitted this time.

  When there are two or more radiation image detectors 2 in a single state in which the power consumption state is in the imaging enabled state, the console 7 has two or more consoles in which the power consumption state is in the imaging enabled state. One of the radiation image detectors 2 is selected, and the power consumption state of the radiation image detector 2 in a single state other than the selected radiation image detector 2 is selected. Is switched from the photographing enabled state to the sleep state via the wireless access point 5, and a switching process for switching the power consumption state is performed.

  Therefore, when there are two or more radiation image detectors 2 in a single state where the power consumption state is ready to be photographed in the photographing room R1, etc., the power consumption state can be photographed by performing this operation. Only one of the selected radiographic image detectors 2 is in a single state.

  In the present embodiment, when the console 7 selects the radiation image detector 2 in a single state as described above, the radiation image detector 2 in a single state in which the power consumption state is a photographing enabled state is selected. The radiation image detector 2 whose power consumption state is set to the imaging enabled state is selected at the time closest to the time when it is determined that there are two or more (ie, at the end). Rather than the radiation image detector 2 which has been left in a state where the power consumption state has been ready for imaging, the radiation image detector 2 which has been finally enabled for imaging by the operator is used for radiographic imaging to be performed in the future. This is because there is a high possibility that

  The console 7 stores and manages a history of the power consumption state for each radiation image detector 2 existing in the imaging room R1 shown in FIG. 3 and the like. It is configured to recognize whether the power consumption state of the radiation image detector 2 is finally set to the photographing enabled state.

  In addition to the transmission of the above-mentioned periodic polling signal, the console 7 is a power ON signal from the radiological image detector 2 via the wireless access point 5 or the power consumption state after switching “capable of imaging”. Each time a mode switching signal accompanied by "state" information is transmitted, each radiation image detector in a single state that is present in the imaging room R1 or the like and is not loaded in any of the bucky devices 3a and 3b 2, a polling signal is transmitted via the wireless access point 5.

  In this case as well, when there are two or more radiation image detectors 2 in a single state in which the power consumption state is in the imaging enabled state, the power is turned on or the power consumption state is switched from the sleep state to the imaging enabled state. Since the radiographic image detector 2 that has been used is the radiographic image detector that is finally ready for imaging, the console 7 keeps the power consumption state of the radiographic image detector 2 in the imaging enabled state, and the rest The power consumption state of the radiation image detector 2 is switched to the sleep state.

  Further, each time the console 7 receives a release signal indicating that the radiation image detector 2 loaded from the Bucky device 3 is pulled out and released from the Bucky device 3, the console 7 is notified each time. A polling signal is transmitted via the wireless access point 5 to each radiological image detector 2 that exists in the radiographing room R1 or the like and is not loaded in any of the bucky devices 3a and 3b. It has become.

  In this case, the radiation image detector 2 pulled out from the bucky device 3 is likely to be subsequently subjected to processing such as transmission of image data. Therefore, based on the response signal to the polling signal transmission described above. If it is determined that there are two or more radiation image detectors 2 in a single state in which the power consumption state is in the imaging enabled state, the console 7 is connected to the radiation image detector 2 pulled out from the bucky device 3. The power consumption state remains in the imaging enabled state, and the power consumption state of the other radiation image detectors 2 is switched to the sleep state.

  Although not shown in FIG. 1, the console 7 includes, for example, an imager that records and outputs a radiographic image on an image recording medium such as a film based on image data output from the console 7. Connected appropriately.

  In addition, the storage unit 9 of the console 7 associates the cassette ID with information such as scintillator type information, size information, and resolution for the radiation image detector 2 that can be used for radiographic imaging in the imaging room R1. The stored table is stored in advance. Further, the storage means 9 stores information on the patient who is the subject of radiographic imaging in the imaging room R1 and imaging order information including imaging conditions.

  In the present embodiment, as shown in FIG. 4, the imaging order information includes “patient ID” P2, “patient name” P3, “gender” P4, “age” P5, “clinical department” P6 as patient information. The imaging conditions include “imaging region” P7, “imaging direction” P8, and “mode imaging” P9. Then, “shooting order ID” P1 is automatically assigned to each shooting order information in the order in which the shooting orders are received.

  The patient information and the imaging conditions to be written in the imaging order information are not limited to those described above, and include, for example, information such as the patient's date of birth, the number of medical examinations, the radiation dose, and whether the patient is fat or thin. It can also be configured as described above, and can be set as appropriate. Further, for example, the console 7 is connected to a HIS (Hospital Information System) or RIS (Radiology Information System) via a network, and imaging order information, information about the radiation image detector 2 and the like are obtained from them. It is also possible.

  “Simple” in “mode imaging” P9 represents an imaging method for obtaining a radiographic image by irradiating the radiation only once using the radiographic image detector 2, and “subtraction” indicates the radiation applied to the subject. Represents an imaging method for removing shadows and the like other than the target object by, for example, calculating a difference between pixels of a plurality of image data obtained from the plurality of radiation image detectors 2, "Represents an imaging method in which a single radiation image detector 2 is used and a subject is continuously irradiated with radiation a plurality of times to obtain a plurality of time-series radiation images. However, “mode shooting P9” of the shooting conditions is not necessarily set in the shooting order information, and may be set at a later stage.

  The console 7 is provided with a display unit 71 (see FIG. 1) composed of a CRT (Cathode Ray Tube), an LCD (Liquid Crystal Display) or the like, and the console 7 is stored in the storage means 9 when radiographic images are taken. The above-mentioned list of imaging order information is read out (or obtained by acquiring a list of imaging order information from the HIS / RIS via the network), for example, as shown in FIG. It is displayed on H1.

  In the present embodiment, the selection screen H1 is provided with a shooting order information display field h11 for displaying a list of shooting order information, and the left side of the shooting order information display field h11 is scheduled to be shot this time. A selection button h12 for selecting shooting order information is provided corresponding to each shooting order information. Further, an enter button h13 and a return button h14 are provided below the imaging order information display field h11.

  Then, when the shooting order information to be shot this time is selected by clicking the selection button h12 corresponding to the shooting order information and clicking the decision button h13, the screen of the display unit 71 is switched. Subsequently, an icon as illustrated in FIG. 6 is displayed on the selection screen H2 of the display unit 71, for example.

  As shown in FIG. 6, while standing on the left side of the selection screen H <b> 2, the standing position and the standing position are surrounded by a rectangular frame, and the standing position shooting Bucky device 3 a and the standing position shooting position are displayed. Icons 3A and 3B corresponding to the bucky device 3b are respectively displayed. In addition, on the right side of the selection screen H2, icons 2A, 2B, and 2C corresponding to the radiation image detectors 2a, 2b, and 2c (see FIG. 3) in a single state existing in the imaging room R1 and the like are rectangular. It is displayed.

  FIG. 6 shows a state where none of the bucky devices 3a, 3b is loaded with the radiation image detector 2, but in this embodiment, one or both of the bucky devices 3a, 3b are exposed to radiation. When the image detector 2 is loaded, the frame lines of the icons 3A and 3B corresponding to the bucky devices 3a and 3b loaded with the radiation image detector 2 are displayed as solid lines, and the inside of the frame line is a predetermined line. It is colored and displayed. Further, since the radiation image detector 2 loaded in the bucky device 3 is not in a single state, the icon corresponding to the radiation image detector 2 displayed on the right side of the selection screen H2 is not displayed.

  In addition, the display such as “100 μ” shown in the frame lines of the icons 2A, 2B, and 2C corresponding to the radiation image detectors 2a, 2b, and 2c in FIG. 6 indicates the corresponding radiation image detectors 2a, 2b. Although it represents the resolution of 2c, it is also possible to display the necessary information about each of the radiation image detectors 2a, 2b, and 2c.

  In the present embodiment, the operator clicks one of the icons 2A, 2B, and 2C corresponding to each of the radiation image detectors 2a, 2b, and 2c in the single state displayed on the selection screen H2. When selected, the console 7 switches the power consumption state of the radiation image detector 2 corresponding to the selected icon to the imaging enabled state.

  At the same time, when the power consumption state of the radiographic image detector 2 is set to the radiographable state, two or more radiographic image detectors 2 of the radiographic image detectors 2 in a single state in the radiographing room R1 or the like. When the power consumption state becomes a state where imaging is possible, the console 7 sets the power consumption state for all the radiation image detectors 2 other than the radiation image detector 2 corresponding to the selected icon. Switching processing for switching to the sleep state is performed.

  In this case, on the selection screen H2, for example, an icon corresponding to the radiation image detector 2 whose power consumption state is the imaging enabled state and an icon corresponding to the radiation image detector 2 being in the sleep state are displayed. The radiographic image detector 2 is configured so that the operator can recognize which power consumption state of the radiographic image detector 2 is in a photographing enabled state by coloring the different colors or displaying the same with different shades of the same color. It is also possible.

  As described above, it is possible to set shooting conditions in the shooting order information, and it is possible to specify “subtraction” in the “mode shooting” P9 (see FIGS. 4 and 5) of the shooting conditions. . When radiographic imaging using a plurality of radiographic image detectors 2 is performed as in subtraction imaging, the power consumption state of the radiographic image detector 2 in a single state as described above in the imaging room R1 or the like. If the switching process for limiting the number of the radiation image detectors 2 in which imaging is possible to one or less remains functioning, subtraction imaging or the like cannot be performed.

  Therefore, in the present embodiment, the console 7 indicates that the power consumption state of two or more radiographic image detectors 2 among the radiographic image detectors 2 in a single state in advance at the time of radiographic imaging is a radiographable state. When an allowable shooting condition is set, the above switching process is not performed.

  That is, when the operator selects shooting order information (shooting order ID “009”) in which “subtraction” is specified as a shooting condition on the selection screen H1 shown in FIG. It is assumed that an imaging condition is set that allows the power consumption state of two or more radiographic image detectors 2 to be in a radiographable state among the radiographic image detectors 2 in a single state. After that, for example, even if two or more radiation image detectors 2 are clicked and selected on the selection screen H2 shown in FIG. 6, the above-described switching processing is not performed, and the selected plurality of radiation image detectors 2 are selected. All the power consumption states of are switched to the shooting ready state.

  Next, the operation of the radiographic image capturing system 1 according to the present embodiment will be described.

  When the radiation image detector 2 is brought into the front room R2 or the photographing room R1 from the outside, the tag reader 6 installed in the vicinity of the entrance of the front room R2 receives the unique information stored in the RFID tag of the radiation image detector 2. The read unique information is transmitted to the console 7. Further, even when the radiation image detector 2 is taken out from the imaging room R1 or the front room R2, the tag reader 6 transmits the read unique information of the radiation image detector 2 to the console 7.

  When the console 7 receives unique information including the cassette ID of the radiation image detector 2 detected by the tag reader 6, the console 7 registers or deletes the radiation image detector 2 in the storage unit 9. In this way, as shown in FIG. 4, the console 7 grasps the radiation image detector 2 brought into or taken out of the imaging room R <b> 1 and manages it on the storage unit 9. The console 7 also grasps and manages the power on / off of each radiation image detector 2, the power consumption state (imaging enabled state or sleep state), the presence / absence of loading into the bucky device 3, and the like.

  The console 7 periodically transmits a polling signal via the wireless access point 5 to each radiation image detector 2 in a single state existing in the imaging room R1 and the like, and is transmitted from each radiation image detector 2. It is determined whether or not there are two or more radiological image detectors 2 whose power consumption state is an imaging enabled state based on the response signal. If there are two or more radiographic image detectors 2 that are in a radiographable state, the radiographic image detector 2 that is in the radiographable state is selected last, and the other single state is selected. The power consumption state of the radiation image detector 2 is switched from the imaging enabled state to the sleep state.

  Further, when the radiographic image detector 2 transmits a power ON signal or a mode switching signal with information on “imaging ready state” which is a power consumption state after switching, the console 7 is similar each time. A polling signal is transmitted to each of the radiographic image detectors 2, and it is determined whether or not there are two or more radiographic image detectors 2 in which the power consumption state is ready for imaging based on the response signal transmitted from each radiographic image detector 2. To do. And when there are two or more radiographic image detectors 2 in the radiographable state, the radiographic image detector 2 that has transmitted the above signal is the radiographic image detector that is in the radiographable state last. The console 7 keeps the power consumption state of the radiation image detector 2 in the imaging enabled state, and switches the power consumption state of the other radiation image detectors 2 to the sleep state.

  Further, when the release signal indicating that the radiation image detector 2 loaded from the Bucky device 3 is pulled out and released from the Bucky device 3 is notified, the console 7 similarly A polling signal is transmitted to each of the radiographic image detectors 2, and it is determined whether or not there are two or more radiographic image detectors 2 in which the power consumption state is ready for imaging based on the response signal transmitted from each radiographic image detector 2. To do. If there are two or more radiological image detectors 2 that are ready for imaging, there is a possibility that the radiographic image detector 2 pulled out from the bucky device 3 may continue to perform processing such as transmission of image data thereafter. Since it is high, the console 7 keeps the power consumption state of the radiation image detector 2 pulled out from the bucky device 3 in the imaging enabled state, and switches the power consumption state of the other radiation image detectors 2 to the sleep state.

  In addition, the console 7 displays one of the icons 2A, 2B, and 2C corresponding to the radiation image detectors 2a, 2b, and 2c in a single state on the selection screen H2 (see FIG. 6) of the display unit 71. When the icon is clicked and selected, the console 7 switches the power consumption state of the radiation image detector 2 corresponding to the selected icon to a radiographable state. At the same time, when the power consumption state of the radiation image detector 2 is set to the imaging enabled state, the power sources of two or more radiation image detectors 2 in the radiation image detector 2 in a single state in the imaging room R1 or the like. When the consumption state is a state in which imaging is possible, the console 7 switches the power consumption state of all the radiation image detectors 2 other than the radiation image detector 2 corresponding to the selected icon to the sleep state. .

  By performing the switching process for switching the power consumption state of the radiation image detectors 2 other than the radiation image detector 2 selected in this way to the sleep state, the power consumption state becomes a photographable state in the photographing room R1 or the like. The number of the radiation image detectors 2 in a single state can be reduced to one or less.

  However, as in the above-described subtraction imaging, the operator allows the power consumption state of two or more radiological image detectors 2 among the radiographic image detectors 2 in a single state in advance to be in a radiographable state. When the condition is set, the above switching process is not performed.

  As described above, according to the radiographic image capturing system 1 according to the present embodiment, the console 7 detects two or more radiographic images in the single radiographic image detector 2 existing in the radiographing room R1 or the like. If the power consumption state of the device 2 is not ready for imaging, and it is determined that the power consumption state of the radiation image detector 2 in two or more single states is the imaging enabled state A switching process for selecting any one of the radiation image detectors 2 by the above-described method and forcibly switching the power consumption state of the radiation image detectors 2 other than the selected radiation image detector 2 to the sleep state. Do.

  Therefore, for example, when radiographic imaging is performed using a portable radiation generation device 4c that can irradiate radiation in any direction with an arbitrary dose, a plurality of single-state radiographic images that are not loaded in the bucky device 2 Although there is a possibility that radiation reaches the detector 2, even under such circumstances, for example, by forcibly switching the power consumption state of the radiation image detector 2 that is not used for radiographic imaging to the sleep state, for example, It is possible to accurately prevent the radiation image detector 2 from being irradiated with radiation from the portable radiation generator 4c and detecting a ghost image.

  In addition, since the radiographic image capturing system 1 according to the present embodiment is configured as described above, it is not necessary to manage the radiographic image detector 2 according to whether or not the radiographic image detector 2 is housed in a cassette box as in the past. The radiation image detector 2 in a single state that is not housed in the cassette box and is not used for imaging can be accurately put into a sleep state. Therefore, an operator such as a radiographer or doctor who performs radiographic imaging does not have to return the radiographic image detector 2 that is not used to the cassette box one by one. .

  In the present invention, a cassette box is provided in the radiographing room R1 or the front room R2, and it is excluded that the radiation image detector 2 in a single state not loaded in the bucky device 3 is stored in the cassette box. is not.

  When the cassette box is provided, it is normally provided in the front chamber R2 so that radiation is not irradiated. Therefore, the radiation image detector 2 housed in the cassette box includes two or more radiation image detectors 2 in a single state. However, when the cassette box is provided in the imaging room R1, the radiation image detector 2 housed in the cassette box is not required to be determined. Since there is a possibility of radiation reaching, it is possible to configure the radiation image detectors 2 as the object of the determination.

  In the present embodiment, the case where the imaging order information is created in advance prior to radiographic imaging and stored in the storage unit 9 or the HIS / RIS has been described. It can also be applied to later creation. In this case, when setting the imaging conditions before radiographic imaging, the selection screen H1 (see FIG. 5) is not displayed on the display unit 71 of the console 7, but the selection screen H2 (see FIG. 6) is displayed. Similarly, the power consumption state of the radiation image detector 2 corresponding to the selected icon is switched to the radiographable state, and the power consumption state of the radiation image detector 2 in another single state is switched to the sleep state.

  Further, in this case, the setting of imaging conditions that allow the power consumption state of the plurality of single-state radiation image detectors 2 to be in the imaging enabled state as in the case of performing subtraction imaging is based on the imaging order information. However, it is possible to set the above imaging conditions in advance by other methods such as by displaying a screen for setting imaging conditions. Even in the case of creation, it is possible to set an imaging condition that allows the power consumption state of a plurality of radiation image detectors 2 in a single state to be an imaging enabled state, and not to perform the above switching process. .

  Furthermore, as described above, when the radiation generating device 4 irradiates the radiation image detector 2 loaded in the bucky device 3, the diaphragm is usually adjusted to narrow the radiation field, and the radiation field is reduced. Is not leaked out of the bucky device 3, so that the radiographic image loaded in the bucky device 3 is detected based on the determination as to whether or not there are two or more radiographic image detectors 2 that are ready for imaging. Vessel 2 was excluded. However, in order to prevent the detection of a ghost image more strictly, the console 7 may be configured to manage the power consumption state of the radiation image detector 2 loaded in the bucky device 3 as a determination target. Is possible.

  On the other hand, in the present embodiment, for example, when the radiological image detector 2 in a single state exists in the imaging room R1 in the imaging enabled state, the operator removes the bucky device 3 from the outside in order to load the bucky device 3. When the other radiographic image detector 2 is turned on or the power consumption state is switched from the sleep state to the radiographable state, the radiographic image detector 2 in the other radiographable state immediately after the polling processing is processed. The power consumption state is switched to the sleep state.

  Further, in the present embodiment, for example, when imaging is completed, when the operator pulls out the radiographic image detector 2 in the imaging enabled state loaded in the Bucky device 3 from the Bucky device 3, it is transmitted from the Bucky device 3. If the console 7 transmits a polling signal based on the release signal and there is a radiographic image detector 2 in a state other than the extracted radiographic image detector 2 in an imageable state, the other radiographic image detection is performed at the moment of extraction. The power consumption state of the device 2 is switched to the sleep state.

  However, this may cause the operator to feel annoyance. For example, the console 7 is determined that there are two or more radiation image detectors 2 in a state where the power consumption state is an imaging enabled state. Then, after a predetermined time has elapsed, it is possible to perform the switching process for the radiation image detector 2 in a single state other than the selected radiation image detector 2. If comprised in this way, it can prevent that an operator feels troublesome in the above situations.

  In the present embodiment, the case where the bucky device 3a for standing position shooting and the bucky device 3b for standing position shooting are provided as the bucky device 3 has been described. However, a single or three or more bucky devices 3 are provided. The present invention is also applied to the case where the is provided.

  Furthermore, although the case where the console 7 is provided in the front room R2 adjacent to the imaging room R1 has been described in the present embodiment, the console 7 does not need to be provided in the front room R2, and may be provided in another place. Further, in the present embodiment, the case where the shooting room R1 and the console 7 are associated one-to-one has been described. However, the plurality of shooting rooms R1 and one or more consoles 7 are connected by a network or the like, for example, the console It is also possible to configure the photographing room R1 and the console 7 in a one-to-one correspondence by designating the photographing room R1 by an operation on the 7 side. In addition, it goes without saying that the present invention is not limited to the present embodiment and can be appropriately changed.

It is a figure which shows the whole structure of the radiographic imaging system which concerns on this embodiment. It is a perspective view which shows the external appearance structure of a radiographic image detector. It is a figure showing cassette ID of a radiographic image detector etc. registered in the memory | storage means, the ON / OFF state of a power supply, a power consumption state, and the loading state to a Bucky device. It is a figure which shows an example of imaging | photography order information. It is a figure which shows an example of the selection image by which the imaging | photography order information displayed on the display part of a console was displayed. It is a figure which shows an example of the selection image in which the icon of the Bucky apparatus displayed on the display part of a console or the radiographic image detector was displayed. It is a figure explaining the radiographic image detector with which a bucky apparatus provided with a cassette holding part and a bucky apparatus are loaded.

Explanation of symbols

1 Radiographic imaging system 2 Portable radiographic image detector (Radiological image detector)
24 Wireless communication means (antenna device)
2A, 2B, 2C Icon 3 Bucky device 4 Radiation generator 7 Console 71 Display unit

Claims (7)

A plurality of portable radiographic image detectors that have a built-in battery, include wireless communication means, and can switch a power consumption state between at least a sleep state and a radiographable state;
A bucky device capable of loading the portable radiographic image detector;
A radiation generator for emitting radiation;
A console capable of communicating with the plurality of portable radiographic image detectors;
With
The portable radiographic image detector is capable of photographing a subject in a single state not loaded in the bucky device, and can notify the console of the power consumption state.
When the portable radiographic image detector is loaded, the Bucky device notifies the console of the loading of the portable radiographic image detector, and when the loaded portable radiographic image detector is pulled out, the console is notified. Notifying release of loading of the portable radiation image detector,
When the console determines that the power consumption state of two or more portable radiographic image detectors among the portable radiographic image detectors in the single state is an imageable state, the power consumption state is an imageable state. One of the two or more portable radiographic image detectors is selected, and one of the portable radiographic image detectors other than the selected portable radiographic image detector is selected. The radiographic imaging system characterized by performing the switching process which switches the power consumption state of a device to a sleep state.   The console periodically transmits a polling signal to the portable radiographic image detector in the single state, and based on each response signal from the portable radiographic image detector with respect to the polling signal, the single console 2. The radiographic imaging according to claim 1, wherein it is determined whether or not the power consumption state of two or more portable radiographic image detectors among the portable radiographic image detectors in a state is a radiographable state. system.   The console manages the history of the power consumption state of the portable radiation image detector in a single state not loaded in the Bucky device, and can photograph the power consumption state of two or more portable radiation image detectors The radiographic imaging system according to claim 1 or 2, wherein a portable radiographic image detector whose power consumption state is set to an imaging enabled state is selected at a time closest to the time when it is determined to be a state. .   The console polls the plurality of portable radiographic image detectors including the pulled out portable radiographic image detectors when receiving notification of release of loading of the portable radiographic image detectors from the Bucky device. A power source of two or more portable radiographic image detectors out of the single portable radiographic image detectors based on each response signal from the portable radiographic image detector to the polling signal When it is determined that the consumption state is an imaging enabled state, the switching process is performed for the portable radiation image detector in the single state other than the portable radiation image detector pulled out from the Bucky device. The radiographic imaging system according to any one of claims 1 to 3.   When the console determines that the power consumption state of two or more portable radiographic image detectors among the single radiographic image detectors in the single state is a radiographable state, The portable radiographic image detector is selected, and the switching process is performed for the single portable radiographic image detector other than the selected portable radiographic image detector. The radiographic imaging system as described in any one of Claims 4-5.   The console includes a display unit that displays an icon corresponding to the portable radiographic image detector that can be used. When the icon is selected, a power source of the portable radiographic image detector corresponding to the selected icon is displayed. 6. The method according to claim 1, wherein the consumption state is switched to a radiographable state, and the switching process is performed for the portable radiation image detector in the single state other than the portable radiation image detector. The radiographic imaging system according to claim 1.   When the imaging condition for allowing the power consumption state of two or more portable radiographic image detectors to be in a radiographable state among the portable radiographic image detectors in the single state is set in advance in the console The radiographic imaging system according to any one of claims 1 to 6, wherein the switching process is not performed.

Images