JP2008116986A - Radiographic system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system which can provide an environment which is excellent in working efficiency for a user and easy to work, that is, a radiologic technician can register patient information on radiographing and reading and radiographic information, confirm an image, change image processing, etc. at a position near a radiographic field, and which attains reduction in installation area of an apparatus, introduction cost reduction and high extendability. <P>SOLUTION: A controller and a radiation image reader are network-connected so that read radiation image data is transmitted to the controller in which the radiographic information corresponding to the radiation image data is registered. The controller has: an image display means on which an operator confirms the radiation image data; an image establishment input means for inputting the fact that the operator establishes the radiation image data after the confirmation; and a registering means for registering the established radiation image data and the radiographic information, in correspondence with each other, when the establishment of the radiation image data is inputted to the image establishment input means. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention mainly relates to a radiographic image capturing system including a radiographic image reading apparatus that outputs digitized image data and a controller.

  In recent years, there has been an increasing tendency to increase the efficiency and speed of diagnosis by digitizing and storing and transmitting radiological image information of patients generated in hospitals. For this reason, in the field of direct imaging, instead of the conventional screen / film system, a radiographic imaging system that outputs digital data using a stimulable phosphor has come to be frequently used.

  A radiographic imaging system using this photostimulable phosphor is commonly called computed radiography (CR). In this apparatus, a part of the radiation energy transmitted through the subject is temporarily stored in the photostimulable phosphor. The energy accumulated in the photostimulable phosphor can be extracted as photostimulated light by being excited with a laser beam having a predetermined wavelength. This stimulated light can be extracted as an electrical signal using a photoelectric conversion element such as a photomultiplier.

  The radiographic imaging system using the stimulable phosphor is roughly divided into a radiographic imaging system of a dedicated type that cannot be easily carried and a photostimulable phosphor inside. It is classified into a cassette type radiographic imaging system using a portable cassette.

  Based on FIG. 1 showing a cassette type radiographic imaging system using this stimulable phosphor, a cassette type radiographic imaging system using this photostimulable phosphor will be described. The cassette 6 is portable and contains a photostimulable phosphor sheet 8 that stores part of the radiation energy. In the radiation imaging room, a subject M is positioned between the radiation tube 9 and the cassette 6, and radiation is emitted from the radiation tube 9 toward the cassette 6. The photostimulable phosphor sheet 8 in the cassette 6 stores a part of the irradiated radiation energy.

  When the cassette 6 is set in the radiation image reading device 1, the radiation image reading device 1 reads the radiation image information accumulated in the photostimulable phosphor sheet 8 in the cassette 6. Further, the controller 2 has a monitor for inputting patient information of an image accumulated in the cassette 6 and information such as an imaging region and confirming an image read by the radiation image reading apparatus 1.

  Then, the radiation image reading device 1 irradiates the stimulable phosphor sheet with the excitation light in order to read out the radiation image information stored in the stimulable phosphor sheet 8 in the cassette 6, and the irradiated excitation light. The photostimulated light emitted in accordance with the radiation image information accumulated by the photoelectric conversion is photoelectrically converted and output as digital image data after A / D conversion. However, these systems are required to have high accuracy and cost is low. It is quite expensive.

  The radiographic image reading apparatus 1 is large in size so that a plurality of cassettes to be photographed in one inspection can be set simultaneously.

  Conventionally, in such a cassette-type radiographic imaging system, the radiographic image reading apparatus 1 and its dedicated controller 2 are integrated or separately connected one-on-one. For this reason, one set of radiation image reading apparatus 1 and a dedicated controller 2 are often installed per plurality of radiation imaging rooms. However, the radiography work in the radiography room where this set is not placed is inconvenient, and the time interval between radiography and patient information, imaging information etc. is long, so input errors of radiologists etc. Tended to occur.

  In addition, since it takes a long time to go to the radiation image reading apparatus 1 from the radiation imaging room, set the cassette and return to the radiation imaging room after confirming the image, during that time, it is not possible to instruct the patient for the next imaging, When a patient who has already been taken leaves the radiography room and the result of the image confirmation shows that re-imaging is necessary, there is a problem that a call is required. Therefore, it was considered that at least one set of the radiographic image reading apparatus 1 and its dedicated controller 2 is installed in each radiography room of the hospital, but it is installed regardless of the imaging frequency in the radiography room. In other words, it was uneconomical, and the installation space was large and the cost was high.

  In any case, if either the radiographic image reading apparatus 1 or its dedicated controller 2 breaks down, there is a problem that both cannot be used.

  A system shown in FIG. 2 has been proposed as a system different from the above-described radiation imaging system. In this system, the information input terminal 5 inputs patient information of a patient to be imaged by the cassette 6 and information such as an imaging region, and at the same time, identifies the photostimulable phosphor sheet 8 accommodated in the cassette 6. The ID number for reading is read and stored in the server 4 over the network 3 as a series of information associated with patient information, imaging region information, and the like. When the patient imaging using the cassette 6 is completed, the cassette 6 is set in the radiographic image reading device 1 and accumulated in the photostimulable phosphor sheet 8 in the set cassette 6 in the same manner as the radiographic image reading device 1 described above. Read the radiation image information. At this time, the radiation image reading device 1 also reads the ID number of the photostimulable phosphor sheet 8. The radiation image reading apparatus 1 queries the server 4 for registration information corresponding to the read ID number. The radiological image reading apparatus 1 associates the registration information returned from the server 4 with the read radiographic image information, and transfers them to the image confirmation apparatus 7. Since the registration information and radiation image information from the plurality of radiation image reading devices 1 are gathered in the image confirmation device 7, the final confirmation of the image is performed here.

  In this system, a plurality of information input terminals 5 and a radiation image reading apparatus 1 are connected to a network 3. By installing only the information input terminal 5 in each radiation imaging room of the hospital and installing a plurality of radiation image readers 1 in a common space between the radiation imaging rooms, the installation space can be further reduced.

  However, since the image confirmation device 7 is not installed in each radiation imaging room, there is a problem that a radiographer who is in charge of imaging cannot confirm the image. For this reason, a full-time person who performs image confirmation using the image confirmation apparatus 7 is required, and there is a disadvantage that labor costs increase.

  Moreover, when the image confirmation apparatus 7 breaks down, there is a drawback that it becomes impossible to confirm images read by all the radiation image reading apparatuses 1.

  Therefore, it is conceivable to install an image confirmation device 7 in each radiation imaging room. As a result, when a nurse or an assistant goes to set the cassette 6 in the radiographic image reading apparatus 1, the radiographer can input patient information and radiographing information and confirm images while in the radiographic room. it can. However, if the information input terminal 5 and the image checking device 7 are installed in each radiation imaging room, a large installation space is required, and there is a problem that wiring is likely to be complicated.

  Moreover, since both the information input terminal 5 and the image confirmation apparatus 7 must be installed in each radiation imaging room, the cost increases.

  In addition, the radiologist has to operate both the controller 2 and the image confirmation device 7, which reduces work efficiency.

  In addition, since images taken in other shooting rooms are returned to the image confirmation device 7, it takes a lot of time to find an image taken by the user. In order to avoid this problem, if the image confirmation device 7 is directly connected to each radiation image reading device 1, if either the radiation image reading device 1 or the image confirmation device 7 breaks down, both are used. A new problem arises that it cannot be done.

  The present invention solves the problem for solving the above-mentioned problem, and a radiographer inputs patient information and radiographing information related to radiography and reading at a position close to the site of radiography, image confirmation, and image processing. The purpose is to provide a highly scalable system that can reduce the installation area, reduce the installation cost, reduce the installation area, and provide an environment where the user can change the system, etc. . It is another object of the present invention to provide an easy-to-use and reliable system that can be handled by other components even when some of the components fail.

  The following means for solving the above-described problems and achieving the above-described object are proposed.

(1) a plurality of controllers for registering shooting information;
A radiographic imaging system in which radiographic image data is read using a detection unit that detects X-rays and a plurality of radiographic image reading devices that output the read radiographic image data are arranged on the same network,
The controller and the radiographic image reading device are connected to a network so that the radiographic image data is transmitted to the controller in which the imaging information corresponding to the radiographic image data is registered,
The controller is
An image display means for the operator to confirm the radiation image data;
After the confirmation, an image confirmation input means for inputting that the operator has confirmed the radiation image data;
Radiographic imaging, comprising: registration means for registering the confirmed radiographic image data and the imaging information in association with each other when radiographic image data confirmation is input to the image confirmation input means system.

(2) The controller includes image processing means for performing image processing on the received radiation image data.
The registration means is means for registering radiographic image data after image processing or radiographic image data before image processing to which the image processing conditions are added in association with the imaging information ( The radiographic imaging system described in 1).

  (3) The radiographic imaging system according to (1) or (2), wherein the detection means is a solid flat detector.

  (4) The radiographic imaging system according to (1) or (2), wherein the detection means is a radiographic image storage sheet.

  (5) A plurality of controllers for registering identification information of the radiation image storage sheet member and a plurality of radiation image reading devices that read the radiation image stored in the radiation image storage sheet member and output image data are the same. The radiographic imaging system arranged on the network of the radiographic image capturing system, wherein the controller can display the image for confirmation when receiving the image read from the radiographic image storage sheet by the radiographic image reader. The radiation image accumulating sheet whose identification information is registered by any controller of the plurality of controllers can be set in any radiation image reading device of the plurality of radiation image reading devices, The image reading device reads identification information of the set radiation image accumulating sheet body, Regardless of the radiation image reading device of the radiation image reading device, based on the identification information read by the radiation image reading device, the controller that registered the identification information of the radiation image storage sheet body is specified, A radiographic image capturing system, wherein the radiographic image reading device transmits a radiographic image read from the radiographic image storage sheet to a specified controller.

  (6) When the radiographic image read from the radiographic image storage sheet by the radiographic image reading device is transmitted to the specified controller, if the radiographic image cannot be transmitted to the controller, the radiographic image is transmitted to another controller. (3) The radiographic imaging system according to (5).

  (7) Each of the plurality of controllers has means for obtaining identification information unique to the operator of the controller, and when the controller registers the identification information of the radiation image storage sheet body, When the radiographic image reading apparatus transmits the radiographic image read from the radiographic image accumulating sheet body to the specified controller, it cannot be transmitted to the controller. In this case, the radiographic imaging system according to (6), wherein the identification information unique to the operator is transmitted to another controller among the other controllers.

  (8) When registering identification information of a plurality of radiation image accumulating sheet bodies relating to one subject, the controller can register together identification information unique to the subject, and a plurality of radiations relating to one subject. When registering the identification information of the image storage sheet body together with the identification information unique to the subject, a predetermined value is obtained when all the images read from the plurality of radiation image storage sheet bodies related to the one subject are received. The radiographic imaging system according to any one of (5) to (7), characterized in that:

  (9) Any one of (5) to (8), wherein the controller can output images read from a plurality of radiation image storage sheet bodies related to one subject in a predetermined order. The radiographic imaging system described in 1.

  (10) Database means for storing, on the same network, a record database including at least identification information of the radiation image accumulating sheet registered by the plurality of controllers and identification information of the controller in which the identification information is registered. The database means can search from the radiation image accumulating sheet body identification information from any of the plurality of radiation image reading devices, and returns a corresponding record. The plurality of radiation image reading devices Based on the controller identification information of the returned record, the controller registered for the radiographic image storage sheet is specified, and the radiographic image read from the radiographic image storage sheet by the radiological image storage sheet is specified. (5) to (9) characterized by being transmitted to the controller. Radiographic imaging system according to any one of.

  (11) Each of the plurality of controllers transmits a record including the identification information of the radiation image accumulating sheet member registered by the controller and the identification information of the controller to all of the plurality of radiation image reading apparatuses. Any of the plurality of radiological image reading devices stores the received record and attempts to transmit the read image based on the controller identification information of the record that matches the identification information of the read radiographic image storage sheet body. The radiographic imaging system according to any one of (5) to (9), wherein

  (12) In any of the plurality of radiation image reading devices, the identification information of the read radiation image storage sheet body is used to search for a record that matches all of the plurality of controllers, and to a controller that has a record that matches, The radiographic imaging system according to any one of (5) to (9), wherein the read image is transmitted.

  (13) When registering the identification information of the radiation image storage sheet body with the controller, the imaging information regarding the imaging part, imaging direction, imaging conditions, etc. of the subject to be imaged with the radiation image storage sheet body is also registered. And the controller determines a reading condition of the radiation image accumulating sheet body from the registered imaging information, and the radiological image reading apparatus is based on the read identification information of the radiation image accumulating sheet body. The radiographic imaging system according to any one of (5) to (12), wherein the reading condition is obtained, and image data is read from the radiation image accumulating sheet body based on the obtained reading condition.

  (14) When registering the identification information of the radiation image storage sheet body with the controller, the imaging information regarding the imaging part, imaging direction, imaging conditions, etc. of the subject to be imaged with the radiation image storage sheet body is also registered. The controller performs image processing on image data received together with the identification information of the radiation image storage sheet body based on imaging information matching the identification information of the radiation image storage sheet body, and outputs the processed image data. The radiation image capturing system according to any one of (5) to (13).

  (15) The controller can control the dedicated type radiological image reading apparatus, and image data output by the dedicated type radiographic image reading apparatus is radiographed by the dedicated type radiographic image reading apparatus. The radiographic imaging system according to any one of (5) to (14), wherein the radiographic imaging system is capable of receiving data in synchronization with the radiography.

  (Effects of Claims 1 to 4) According to the present invention, it is not necessary for the radiologist to move between the imaging information registration terminal and the image confirmation terminal, and the work efficiency can be improved. In addition, since registration of the shooting information and image confirmation can be performed by the single controller 2, the correspondence between the registered information and the image data can be confirmed, and the reliability of the work can be improved.

  (Effect of Claim 5) According to the present invention, the cassette in which the identification information is registered by any one of the plurality of controllers is set in any radiation image reading device of the plurality of radiation image reading devices. However, since any controller and any radiographic image reading apparatus can read the identification information of the radiographic image accumulating sheet body, it is possible to take correspondence between the registered information and the read image.

  Since the radiation image storage sheet body in which the identification information is registered by one controller can be set in any of the plurality of radiation reading apparatuses, the number of radiation image storage sheet bodies that can be set per radiation reading apparatus is small. Can be made relatively inexpensive.

  Since a plurality of cassettes can be set to be distributed to a plurality of radiation readers, the work efficiency is improved, and the processing power is improved because a plurality of radiation readers read image data in parallel. Since there are multiple controllers, the controller can be installed at a position close to the site of radiography, and the radiologist can input patient information and radiography information related to radiography and reading, confirm images, change image processing, etc. It can be located close to the site of radiography, providing high working efficiency and an easy working environment.

  In addition, the installation area of the apparatus can be reduced, the introduction cost can be reduced, the expandability can be increased, and any of the radiographic imaging apparatuses out of a plurality of radiographic image reading apparatuses can be operated. This is an easy-to-use and reliable system that can be handled by another radiographic imaging device that has not failed even if it is a radiographic image storage sheet body in which an identification number is registered.

  (Effect of Claim 6) In addition to the effect of the invention of the cited item, according to the present invention, even when some of the controllers fail in the middle of use, other controllers can handle them. It is an easy and reliable system.

  (Effect of Claim 7) According to the present invention, in addition to the effect of the invention of the cited item, even when some of the controllers fail during use, the radiation image storage sheet in other controllers Since the controller that is operated by the operator who registered the body identification information is used, the system is easy to use and reliable even when there is a failure.

  (Effect of Claim 8) According to the present invention, in addition to the effect of the invention of the cited claim, when a plurality of radiation image accumulating sheet bodies related to one subject are set dispersed in a plurality of radiation image readers, Although it is difficult to determine whether or not reading of all the radiation image storage sheet bodies related to the one subject has been completed based on the operating status of the reading apparatus, the identification information of the plurality of radiation image storage sheet bodies related to the one subject The registered controller displays something when all the images read from the plurality of radiation image storage sheets relating to the one subject are received, so that the operator can move on to the next operation with peace of mind.

  (Effect of Claim 9) According to the present invention, in addition to the effect of the invention of the cited claim, when a plurality of radiation image accumulating sheet bodies relating to one subject are set dispersed in a plurality of radiation image reading devices, a radiation image is obtained. The image transmitted from the reading device returns to an object that is not related to the imaging order and the cassette setting order depending on the operation status of the plurality of radiographic image reading apparatuses at that time. Since the images read from the plurality of radiation image accumulating sheet bodies can be rearranged in a predetermined order and output, it can be output in the predetermined order.

  (Effect of Claim 10) According to the present invention, in addition to the effect of the invention of the cited claim, a specific server having database means for establishing communication means between a plurality of radiation image reading apparatuses and a plurality of controllers. Therefore, the control method can be simplified and the system can be stably operated. In addition, since the database means can collectively manage various information related to radiation imaging, it is possible to refer to this information later and to manage the imaging history without fail.

  (Effect of Claim 11) According to the present invention, in addition to the effect of the invention of the cited claim, the identification information of the radiation image accumulating sheet member and the identification information of the controller registered in the controller are added to all the radiation image reading devices. Since the record to be stored is stored, when the record is stored only in a specific server, there is no possibility that the server can be dealt with unlike the case where the server fails, and the image data can be reliably returned to the controller.

  (Effect of Claim 12) According to the present invention, in addition to the effect of the invention of the cited item, the identification number of the radiation image accumulating sheet body read by the radiation image reader is directly inquired to each controller. Only when the record is stored, the server cannot be dealt with at all as in the case of the server failure, and the image data can be reliably returned to the controller.

  (Effect of Claim 13) According to the present invention, in addition to the effect of the invention of the cited item, the image is read under an appropriate reading condition registered by the controller, so that image data with good image quality can be obtained.

  (Effect of Claim 14) According to the present invention, in addition to the effect of the invention of the cited item, when the identification information of the radiation image accumulating sheet body is registered, image processing is performed on the basis of the registered photographing information. It is possible to suppress mistakes in registering photographing information over time, such as when photographing information is registered after reading, and correct image processing can be performed.

  (Effect of Claim 15) According to the present invention, in addition to the effect of the invention of the cited claim, a dedicated type radiological image reading apparatus can be controlled by a cassette type controller. The apparatus can be controlled and the image data output from the dedicated type radiographic image reading apparatus can be received by this controller, so that the dedicated type radiographic image reading apparatus and the cassette type radiographic image can be received in the same imaging room. When the reading device is arranged, it is not necessary to control each by a different controller, and the number of installed controllers, the installation area, and the device cost can be reduced.

  In addition, when imaging the same patient with a dedicated type radiographic image reader and a cassette type radiographic image reader, it is possible to register patient information and imaging information and confirm images with the same controller. Can be improved and operational errors can be reduced.

  Embodiments of the present invention will be described below. The present invention is not limited to the embodiments described below. In addition, although there is a description explaining the meaning of the terms in the following description, the meaning of the terms in the embodiments is described only, and the meaning of the terms of the present invention is not limited to this description.

Embodiment 1
As shown in FIG. 3, in the radiographic imaging system 01 of the present embodiment, a plurality of radiographic image reading apparatuses 1, a plurality of controllers 2, and a server 4 are connected via a network 3. The plurality of controllers 2 are connected to the DICOM network 90. An image recording device 91 such as a laser imager, an image diagnostic device 92, an image filing device 93, and the like can be connected to the DICOM network 90. The image recording device 91 provides the diagnostic image visualized to the doctor by outputting the image data output from the controller 2 on the film, and the image diagnostic device 92 displays the image data output from the controller 2 on the monitor. Thus, the diagnostic image visualized to the doctor is provided. The image filing device 93 stores image data output from the controller 2. The image data stored in the image filing device 93 can be output to the image output device 91 and the image diagnostic device 92 as necessary.

  First, the radiographic imaging system 01 of this embodiment will be described with reference to FIG.

  (1) A barcode corresponding to an ID number for identifying the photostimulable phosphor sheet 8 incorporated in the cassette 6 (hereinafter, this ID number is referred to as a sheet ID number) is provided on the casing of the cassette 6. 62 is attached. In the present embodiment, the sheet ID number is identified by the barcode 62. However, for example, a code written on an element such as a label is read using a wireless technology using electromagnetic waves or microwaves. A possible element called a non-contact ID label (S label) or a tyris may be used instead of the barcode 62.

  When such a label for reading a code (sheet ID number) using wireless technology is used, it is not necessary to attach a label to the casing of the cassette 6, for example, the back side of the photostimulable phosphor sheet 8 You may make it attach to. In this case, another label on which an ID number for identifying the photostimulable phosphor sheet 8 is written may be attached to the casing of the cassette 6.

  The radiologist goes in front of the controller 2 with the cassette 6 used for imaging, and inputs the operator ID number at the operator ID input unit 23 of the controller 2. This input unit reads an input device such as a fingerprint detector or a voiceprint detector that can identify identification information based on the operator's own physical characteristics such as a fingerprint or a voiceprint, an ID card reader that reads an ID card, or a barcode label Input devices such as barcode readers and portable signal receivers that receive portable transmitters (ID cards, barcode labels, and portable transmitters are convenient because the operator can always carry them around). However, a keyboard, a touch panel, or the like may be used.

  Further, the input unit 22 to be described later may be configured to also serve as the operator ID input unit 23. In order to save the trouble of inputting each time, in general, when one controller 2 is handled by one person, it is convenient to set it as a default after inputting once. Alternatively, the ID number of the radiologist to be used may be registered in the controller 2 in advance so that it can be selected via a keyboard or a touch panel.

  Then, the radiologist reads the sheet ID number from the barcode 62 of the cassette 6 by the barcode reader 24 of the controller 2 or inputs the sheet ID number from the input unit 22 of the controller 2, so that the sheet is sent to the controller 2. Register the ID number.

  Further, the radiologist inputs patient information of a patient to be imaged by the cassette 6 and imaging information for imaging the patient from the input unit 22. Here, the patient information includes the patient's name, age, sex, date of birth, patient ID number for identifying the patient, and the like.

  The imaging information refers to the imaging part (information on which part of the body of the subject M) and the imaging method (back-and-front direction imaging, front-and-rear direction imaging, measurement direction imaging, oblique imaging, and the like) Information), which is used not only for imaging and recording of a patient, but also as an image processing parameter for determining image processing conditions of read image data, particularly gradation conversion processing conditions. .

  When the imaging information is determined, the reading conditions such as the reading sensitivity and reading resolution (sampling pitch) of the radiation image reading apparatus 1 corresponding to the imaging information are automatically selected.

  Of these pieces of information, reusable information may be stored as a default value as it is to simplify the subsequent input. In addition, when imaging information and patient information are registered in advance, such information may be displayed on the screen 21 as a list, and the radiologist may select necessary information from the displayed list. good.

  For the sheet ID number or operator ID number input from the barcode reader 24 or the input unit 22, the controller 2 records a series of information such as imaging information, patient information, and reading conditions registered together with these ID numbers ( This series of information is referred to as accompanying information) and is temporarily stored in the controller 2.

  If the sheet ID number, operator ID number, and accompanying information displayed on the screen 21 are incorrect, the radiologist inputs a re-input instruction from the input unit 22, and if correct, performs the next input operation. When these inputs are completed for all cassettes scheduled to be photographed, an input for instructing the end of the input is performed. When a re-input instruction is input from the input unit 22, the controller 2 clears the primary storage such as the sheet ID number and waits for re-input.

  When the next sheet ID number is input or the input end is instructed, the primarily stored sheet ID number, operator ID number, and accompanying information are referred to as the controller 2 ID number (hereinafter referred to as the controller ID number). ) And sent to the server 4 for storage. Upon receiving these pieces of information, the server 4 registers the information in the photographing database as a record with a unique photographed image unique ID number for each photographed image.

  As described above, when the sheet ID number is registered by the controller 2, the photographing information corresponding to the cassette 6 is also registered. As will be described later, the controller 2 receives the image data received together with the sheet ID number as follows. Since the image processing is performed based on the photographing information that matches the sheet ID number and is output, the registration of the photographing information over time as in the case of registering the photographing information after reading the image from the photostimulable phosphor sheet 8 of the cassette 6 is performed. Errors can be suppressed and correct image processing can be performed.

  Further, when the sheet ID number is registered by the controller 2, the operator ID number and the controller ID number corresponding to the cassette 6 are also registered, so that these information can be utilized later. The radiographic image reading device 1 also has an ID number (device ID number) for identifying each radiographic image reading device 1.

  (2) Upon completion of a series of operations such as registration of various ID numbers and input of accompanying information, the radiologist positions a portion of the radiation tube 9 and cassette 6 where radiography of the subject M is desired to be performed. Usually, the cassette 6 is applied to the subject M). The radiation generation control device 10 of the radiation tube 9 is operated to irradiate the radiation. Then, a part of the radiation energy irradiated from the radiation tube 9 and transmitted through the subject M is temporarily accumulated in the photostimulable phosphor sheet 8 incorporated in the cassette 6.

  (3) When the radiography of the patient is completed, the assistant sets the cassette 6 for which radiography has been completed in the radiographic image reading apparatus 1. At this time, it is free to set the cassette 6 in which radiation image reading apparatus 1. Further, a plurality of cassettes 6 may be set in a distributed manner on a plurality of radiation image reading apparatuses 1.

  When the cassette 6 is set, the radiation image reading apparatus 1 reads the sheet ID number from the barcode 62 of the cassette 6 and searches the imaging database of the server 4 with this sheet ID number. The server 4 searches the imaging database with the sent sheet ID number, obtains the latest record among the matching records, and returns the information of the record to the radiation image reading apparatus 1.

  The radiation image reading apparatus 1 is stored in the photostimulable phosphor sheet 8 in the cassette 6 under the reading conditions (reading sensitivity, reading resolution, etc.) described in the information of the returned record. Read out radiation image information. That is, the stimulable phosphor sheet 8 is irradiated with excitation light, the stimulated light emitted according to the radiation image information accumulated by the irradiated excitation light is photoelectrically converted, and A / D converted digital image data ( Hereinafter, for simplicity, it is referred to as image data). The obtained image data is transmitted to the controller 2 having the controller ID number sent back from the server 4 together with the record information sent from the server 4.

  When the reading of the image data is completed, the radiation image reading device 1 erases the energy remaining in the photostimulable phosphor sheet 8, returns the photostimulable phosphor sheet 8 into the cassette 6, and takes out the cassette 6. Make it possible. The assistant returns the cassette 6 whose reading has been completed to the radiation imaging room and prepares for the next imaging.

  As described above, in the embodiment of the present invention, the reading condition of the photostimulable phosphor sheet 8 is automatically determined from the registered photographing information, and the determined reading condition is associated with the sheet ID number. Since the radiation image reading apparatus 1 is configured to store the photostimulable phosphor sheet of the cassette 6, the radiographic image reading device 1 searches for the reading conditions based on the read sheet ID number, and based on the obtained reading conditions. 8 can read image data.

  As described above, the image data can be read under an appropriate reading condition simply by registering the shooting information with the controller 2, so that it is possible to obtain image data with good image quality optimum for the shooting condition.

  (4) The radiologist confirms the received image data. First, the controller 2 generates a reduced image of the image data while receiving the image data from the radiation image reading apparatus 1, and sequentially displays the reduced image on the screen 21. In addition, the sheet ID number related to the received image data, the apparatus ID number of the radiation image reading apparatus 1 that transmitted the image data, and other accompanying information are displayed on the screen 21 together with the image data. The contents of the information displayed together with the image data (reduced image data) can be selected in advance by the user.

  When reception of all image data is completed, image processing such as non-linear gradation conversion processing is performed on the generated reduced image data under image processing conditions determined by shooting information corresponding to the image data, It is displayed again on the screen 21. The radiologist can check the re-displayed image and change the image processing condition to perform image processing on the reduced image data again if necessary.

  Further, the controller 2 notifies the server 4 of the sheet ID number corresponding to the received image data. In response to this notification, the server 4 adds the image transferred information to the corresponding record in the imaging database.

  The controller 2 searches the imaging database in the server 4 or information temporarily stored in the controller 2 by the patient ID number, and all the image data of the sheet ID number having the patient ID number is returned to the controller 2. Confirm whether or not. When all the image data of the sheet ID number having the patient ID number is returned to the controller 2, information indicating that all the image data of the patient has been received is displayed on the screen 21.

  Although it is difficult to determine whether or not reading of all the cassettes 6 related to one patient has been completed from the operating status of the radiation image reading apparatus 1, the controller 2 that has registered the sheet ID number When all the images read from the plurality of cassettes 6 related to the human patient are received, a message indicating that all the images have been received is displayed, so that the operator can move on to the next operation with peace of mind.

  In the embodiment of the present invention, the display position and output order of image data can be rearranged in a predetermined order. These may be performed automatically or may be specified by the user. If you want to do it automatically, set the order of arrangement in advance. For example, if the order of registration of the sheet ID numbers is set to be rearranged, the order of receiving image data received by the controller 2 is not limited even if the order of loading the cassette 6 into the radiation imaging apparatus 1 is varied. Even if it is mixed, the display position of the image is always determined in the registration order, so there is no confusion.

  In the embodiment of the present invention, registration of sheet ID numbers of a plurality of cassettes 6 for photographing one patient is performed by one controller 2, and the plurality of cassettes 6 that have been photographed are a plurality of cassettes 6. Even when set in the radiation image reading apparatus 1 in a distributed manner, the images read by the plurality of radiation image reading apparatuses 1 are automatically returned to the controller 2 in which the sheet ID numbers are registered.

  For this reason, even if it is the image data returned from the different radiographic image reading apparatus 1, the image data of the same patient can be handled together.

  When the radiologist finishes the image confirmation work, the radiologist inputs image confirmation. When image confirmation is input, image processing is also performed on image data that has not been reduced (the received original image data) under the image processing conditions that were last performed on the reduced image displayed on the screen 21. The image data subjected to the image processing is temporarily stored in the controller 2.

  Then, the image data that has been subjected to image processing or the image data that has not been subjected to image processing with image processing conditions added thereto, together with other accompanying information and ID information, is connected via the DICOM network 90 to the image recording device 91 and the image diagnostic device 92. Or the image filing device 93 according to the DICOM communication protocol. When image confirmation is input, a code indicating that processing has been completed is added to the record relating to the sheet ID number in the imaging database in the server 4.

  Next, the radiation image reading apparatus 1 will be described in detail with reference to FIG.

  When the cassette 6 is set in the radiation image output apparatus 1 after the radiation imaging is completed, the sheet ID number is read from the barcode 62 of the cassette 6 by the barcode reader 150. The server 4 is searched with this sheet ID number, and as described above, the reading conditions (reading sensitivity and reading resolution) and the controller ID number of the image data return destination are obtained. The sensitivity of the photoelectric reading unit 112 is set according to the reading sensitivity value, and the conveying speed of the conveying mechanism 160 and the sampling pitch of the A / D converter 113 are set according to the reading resolution value.

  When the cassette 6 is set in the radiation image output apparatus 1, the stimulable phosphor sheet 8 is pulled out from the cassette 6, and the stimulating phosphor sheet 8 is sub-scanned and conveyed in the X direction by the conveyance mechanism 160. The image data stored and held in the fluorescent phosphor sheet 8 is read by the reading unit 110.

  The reading unit 110 includes an excitation light generation unit 111, a photoelectric reading unit 112, and an A / D converter 113. While the photostimulable phosphor sheet 8 is transported in the sub-scan by the transport mechanism 160, the excitation light generator 111 scans the excitation light 14 in a direction (main scanning direction) perpendicular to the sub-scanning direction.

  When the excitation light 14 acts on the photostimulable phosphor sheet 8, the energy accumulated in the phosphor is generated as the photostimulated light 15. The photostimulated light 15 is collected and is read by the photoelectric reading unit 112. The electric signal is converted into an electric signal, and the electric signal is logarithmically converted by the logarithmic converter 114 (the electric signal is converted into a logarithm of the light intensity of the stimulating light 15 from the electric signal linear to the light intensity of the stimulating light 15. The signal is converted into a linear electric signal, that is, an electric signal linear in density), and digitized by the A / D converter 113.

  The image data output from the reading unit 110 is processed by the signal processing unit 120 in a correction process peculiar to the reading unit 110 or the photostimulable phosphor sheet 8 (shading correction of the photoelectric reading unit 112 or the excitation light generation unit 111). Correction, non-uniformity correction of the photostimulable phosphor sheet 8 and the like, and then temporarily stored in the primary storage unit 130 sequentially. Then, after the reading is completed (or while reading the image data), the communication unit 140 transmits the image data to the controller 2 having the controller ID number returned from the server 4 via the network 3.

  Here, the image data transmitted to the controller 2 is image data having a linear pixel value with respect to the logarithm of the light intensity of the stimulating light 15, and the gradation characteristics as it is are not suitable for diagnosis (in many cases, diagnosis is performed). Image data). In order to convert to image data that can be used for diagnosis, it is generally necessary to perform a non-linear gradation conversion process. In this embodiment, this process is performed by the controller 2. As described above, in this embodiment, image data is returned from the radiation image reading apparatus 1 to the controller 2 with the gradation characteristics unsuitable for diagnosis.

  Since the processing conditions of the non-linear gradation conversion process vary depending on the imaging region and the imaging direction, it is necessary to prepare an algorithm for each imaging region and imaging direction. In addition, since an algorithm for automatically detecting the radiation field stop and subject area at the time of imaging is required, an algorithm for nonlinear gradation conversion processing generally has a very complicated structure.

  Since an environment capable of executing such a complex image processing algorithm at high speed (referred to as an image processing environment) is very expensive, it is very difficult to construct an image processing environment for both the radiation image reading apparatus 1 and the controller 2. It is uneconomical. In the present embodiment, the image processing condition is changed after the radiologist confirms the image, and an environment in which the image processing is performed again under the changed image processing condition is provided. A processing environment is required. Therefore, it is preferable that image processing is not performed on the radiation image reading apparatus 1 side, and image processing is performed only on the controller 2 side.

  However, even if it is configured such that image processing can be performed on the radiation image reading apparatus 1 side, the essence of the present invention excluding cost is not impaired.

Next, the controller 2 will be described in more detail based on FIG.
The controller 2 includes a display unit 21 for displaying various information and read images, an input unit 22 for inputting instructions by a radiologist, and an ID number for an operator such as a radiologist. An operator ID input unit 23 and a barcode reader 24 for reading the barcode 62 of the cassette 6 are provided. The controller 2 is connected to the server 4 and the plurality of radiation image reading apparatuses 1 via the network 3. The controller 2 can also be connected to an image recording device 91, an image diagnostic device 92, an image filing device 93, and the like via the DICOM network 90.

  As the input unit 22, a keyboard, a touch panel, a voice input device, or the like can be used, but is not limited thereto.

  Further, the controller 2 and the server 4 can be connected to a hospital information system (HIS) or a radiation information system (RIS). In this case, it is preferable to capture patient information, imaging information, etc. online from these HIS and RIS. Further, the patient is provided with a portable storage medium storing the above information, and the controller 2 is provided with a storage medium reading device so as to read information such as patient information and imaging information from the portable storage medium brought by the patient. It may be. Examples of such portable storage media and storage medium readers include, but are not limited to, barcodes and barcode readers, magnetic cards and magnetic card readers, and IC cards and IC card readers.

  Moreover, you may make it search the matching data from HIS and RIS with a patient ID number. In this case, the patient may have a portable storage medium that stores the patient ID number, and a storage medium reader may be provided to read the information from the portable storage medium brought by the patient. Not limited to this, it may be input from the input unit 22, or patient-specific information such as fingerprints and voiceprints is stored in the HIS and RIS, and a fingerprint detection device or a voiceprint detection device is provided in the controller 2 to detect the detected fingerprint. Or data matching by voiceprint may be retrieved from HIS or RIS.

  The display unit 21 of the controller 2 may be any means capable of displaying character information and image information, such as a CRT display or a liquid crystal display, and the content to be displayed is the radiation image reading apparatus 1 that has acquired image data. Device ID number, operator ID number, patient information, imaging information, reading conditions, radiation imaging conditions acquired from the radiation generation controller 10 of the radiation tube 9 (for example, tube voltage and dose of the radiation tube), Examples include the number of pixels of image data, the matrix size, the number of bits per pixel of image data, the type of image processing, image processing parameters, the details of correction processing, etc., and the video of the captured image data. Not limited to.

  Further, the imaging region may be selected in two stages: a rough major classification based on the main components of the human body and a finer minor classification. Examples of major classifications in this case include classifications such as “head”, “chest”, “abdomen”, “upper limb”, “lower limb”, “spine”, and “pelvis”. The minor classification is a classification of the parts indicated by the major classification into more detailed parts. For example, when the major classification is “upper limb”, “shoulder joint”, “scapula”, “shoulder chain indirect” "," Humeral bones "," elbow joints "," forearm bones "," hand joints "," carpal bones "," finger bones ", etc. fall under the small classification.

  Further, the shooting direction is generally the shooting direction with respect to the human body, but is not limited thereto. As representative examples of such shooting directions, “backward forward shooting (PA)”, “backward shooting (AP)”, “LAT (Lateral Radiography)”, “ “Oblique Radiography” and the like.

  The types of image processing performed by the controller 2 include gradation conversion processing for converting the gradation of image data, frequency processing for converting the frequency characteristics of the image data, and dynamic range for compressing the dynamic range of the image data. Examples include, but are not limited to, compression processing.

  In particular, in the present embodiment, image data having a linear pixel value with respect to the logarithm of the light intensity of the stimulating light 15 is transmitted from the radiation image reading apparatus 1 to the controller 2. It is essential that non-linear gradation conversion processing can be performed.

  As described above, in the present embodiment, any controller 2 in which the sheet ID number is registered can be set in any radiation image reading apparatus 1 in a distributed manner, and any The image data read by the radiation image reading apparatus 1 is automatically returned to the controller 2 in which the sheet ID number of the stimulable phosphor sheet 8 corresponding to the image data is registered. .

  In this way, since the cassette in which the sheet ID number is registered by one controller 2 can be set in any of the plurality of radiation image reading apparatuses 1, the number of cassettes 6 that can be set per one radiation image reading apparatus is small. An inexpensive radiation image reading apparatus 1 can be used. As a result, the installation area of the apparatus can be reduced, the introduction cost can be reduced, and the expandability can be increased.

  In addition, since the cassette 6 in which the sheet ID number is registered by one controller 2 can be simultaneously read by a plurality of radiographic image reading apparatuses 1, radiographic imaging is performed in a hospital that performs many radiographs for one patient at a time. It is possible to improve the processing capacity of the system.

  In addition, when m radiation image reading apparatuses 1 capable of setting n cassettes are connected, a maximum of nxm cassettes can be set continuously, so if you want to process a large number of cassettes at once, The shooting cycle time can be significantly shortened without being bothered by the setting.

  In addition, when m radiation image reading apparatuses 1 are connected, a maximum of m radiation image reading apparatuses 1 can read image data at the same time. Compared with the case of reading data, the reading time is shortened to 1 / m (processing capacity is improved m times). Therefore, it is possible to provide an ideal work environment that is efficient and does not involve work delays even for hospitals that perform many imaging operations for a single patient or hospitals that have a short imaging cycle.

  In addition, even when a plurality of radiation image reading apparatuses 1 are used for each patient, incidental information such as patient information and imaging conditions can be input by a single controller 2, so that the input operation becomes efficient. .

  Further, even when a plurality of radiation image reading apparatuses 1 are used for one patient, the image data registers the patient information and imaging information of the patient (that is, the stimulable phosphor used for imaging the patient). Since it is gathered in one controller 2 (which has registered the sheet ID number of the sheet 8), it is not necessary for the radiologist to move between the patient information and imaging information registration terminal and the image confirmation terminal of the patient. Can be improved. In addition, registration of patient information and imaging information of a patient and image confirmation can be performed by a single controller 2, so that the correspondence between registered information and image data can be confirmed, and work reliability can be improved. Can do.

  In addition, since there are a plurality of controllers 2, the controller 2 can be installed at a position close to the site of radiation imaging, and the radiologist can input patient information and imaging information, confirm images, select image processing conditions, etc. It can be carried out at a position close to the radiography site, providing an efficient work environment and an easy work environment.

  In addition, even when some of the radiographic image capturing devices 1 out of the plurality of radiographic image reading devices 1 are out of order, the other radiographic image capturing devices 1 that are not in failure can cope with them, so that the system is reliable. Can be built.

  In addition, since the server 4 collectively manages the shooting database, this information can be referred to later, and the shooting history can be managed without mistake.

  Next, in this embodiment, when the radiographic image reading apparatus 1 tries to transmit the radiographic image read from the photostimulable phosphor sheet 8 of the cassette 6 to the specified controller 2, transmission to the controller 2 is performed. The case where it was not possible will be described.

  This occurs, for example, due to poor connection of network terminals, runaway CPU due to a bug or heat generation in a program, malfunction or failure of a component such as a hard disk drive. Further, when transmission to the specified controller 2 is attempted, whether or not transmission to the controller 2 could not be performed can be detected by detecting that communication could not be established.

  In addition, an alarm device for generating an alarm or displaying a warning under the control of the radiation image reading apparatus 1 or the server 4 is provided, or a means for detecting a communication failure is provided in the controller 2 to display the communication failure. This informs the radiologist that the controller 2 being used has failed in communication.

  The following six solutions can be considered as means for solving a communication failure. These may be appropriately selected depending on hospital circumstances. The first solution is a method of designating a controller 2 to which image data is transmitted from another controller 2. There are three further solutions to this method:

  1) A method in which the user selects another controller 2 and directly sends the controller ID number of the return destination to the radiation image reading apparatus 1 holding the image data to be received and requests the return of the image data. is there.

  Upon receiving this request, the radiation image reading apparatus 1 transmits all the stored image data to the controller 2 having the designated controller ID number.

  The advantage of this solution is that the control form on both the controller 2 side and the radiation image reading apparatus 1 side is the simplest, the development cost of control software is low, and stable operation is easy.

  2) The user selects another controller 2, registers the operator ID number with the selected controller 2, and sends the operator ID number and the controller ID number of the return destination to all the radiation image reading apparatuses 1. This is a method for requesting the return of the image data having the transmitted operator ID number.

  When the radiation image reading apparatus 1 that has received this request holds image data having the requested operator ID number, the requested operator ID number is sent to the controller 2 having the designated controller ID number. Is transmitted.

  3) The user selects another controller 2, registers the operator ID number with the selected controller 2, sends the operator ID number and the controller ID number of the return destination to the server 4, and transmits the operator This is a method for requesting the return of image data having an ID number.

  If the radiation image reading apparatus 1 that cannot establish communication is set to always search the server 4, the radiation image reading apparatus 1 can capture the request when the server 4 receives the request. it can. The radiation image reading apparatus 1 that has received this request transmits the image data having the requested operator ID number to the controller 2 having the designated controller ID number.

  The advantages of the above solutions 2) and 3) are that the image data that the user wanted to receive can be selectively and easily received by another controller 2 by using the operator ID number. Since the image data is received using the operator ID number as a keyword, it is possible to avoid a risk that the image data that the other person tried to receive is erroneously received.

  The second solution is a method in which the radiation image reading apparatus 1 forcibly transmits image data together with additional information indicating that it is secondary distribution data to all the remaining controllers 2 that have not failed. is there.

  The controller 2 that has received the image data and the additional information temporarily stores the received image data and the additional information, and deletes them when they are no longer needed. For example, when the user selects another controller 2, a confirmation declaration is made to confirm that the temporarily stored image data and additional information are own. By transmitting this declaration to the other controller 2, the other controller 2 can erase the temporarily stored image data and additional information.

  For example, an operator ID number may be used for the declarative declaration method. In this case, the operator ID number in which the sheet ID number is registered is included in the additional information sent by the radiation image reading apparatus 1. When the user selects another controller 2, the operator ID number is registered with the selected controller 2. The controller 2 compares the newly registered operator ID number with the operator ID number in the additional information temporarily stored, and if they match, the controller 2 regards that the confirmation declaration has been made.

  The advantage of this solution is that when the user selects another controller 2, image data has already been received (since it is highly likely that it has been received), so any controller 2 can immediately check the image. It is.

  In the third solution, the server 4 has an image storage function, and the radiation image reading apparatus 1 transmits image data to the server 4 instead of transmitting the image data to the specified controller 2. Data is temporarily saved.

  When the user selects another controller 2 and requests transmission of the image data temporarily stored from the selected controller 2 to the server 4, the image data temporarily stored in the controller 2 that made the request from the server 4 is stored. Sent.

  For example, it is convenient to use an operator ID number when requesting transmission of image data temporarily stored from the controller 2 to the server 4. That is, when the user selects another controller 2, the operator ID number is registered with the selected controller 2. Then, when requesting transmission of image data temporarily stored in the server 4, the operator ID number is also transmitted to the server 4. The server 4 finds image data having the same ID number as the operator ID number sent from the temporarily stored image data, and returns it to the controller 2.

  The advantage of this solution is that the transmission destination of the image data from the radiation image reading apparatus 1 is always fixed to the server, so that the development of control software on the radiation image reading apparatus 1 side is simple and the development cost is low. In addition, the system operates stably with simple control. Further, since the image data is searched using the operator ID number as a keyword, it is possible to avoid the risk that the image data that the other person has received is erroneously received.

  According to the fourth solution, when the image data cannot be transmitted to the controller 2 that should originally be returned, the order of the controller 2 that transmits the image data is determined in advance. This is a method for transmitting image data to a computer. In this case, it is preferable that the user knows in advance the controller 2 to go when the controller 2 fails in communication.

  The advantage of this solution is that the image data is automatically transmitted to another predetermined controller 2 without any operation by the user.

  A fifth solution is a method in which the radiation image reading apparatus 1 is provided with a function capable of designating a controller 2 for returning image data, and a user designates a controller 2 to which image data is returned using this function. It is. When the user designates a controller 2 that can communicate, image data is transmitted to the controller 2. Further, it is more convenient to configure so that a plurality of controllers 2 and servers 4 can be specified at the same time.

  The advantage of this solution is that the control forms on both the controller 2 side and the radiation image reading apparatus 1 side are simple, the development cost of control software is low, and stable operation is easy. Further, since a plurality of controllers 2 and servers 3 can be designated as transmission destinations, a highly secure system can be constructed.

  In the sixth solution, any radiation image reading device 1 is provided with a portable storage medium writing device, and any controller 2 is provided with the portable storage medium reading device, and transmission cannot be performed. In this method, image data is stored in the portable storage medium, the portable storage medium is set in another controller 2, and the image data is transferred to the controller 2.

  Examples of such portable storage media include, but are not limited to, magneto-optical disks, magnetic disks, optical disks, memory cards, and portable hard disk drives.

  The merit of this solution is that it can cope with a communication failure in the entire network 3.

  As described above, in the present embodiment, even when the image data read by the radiation image reading apparatus 1 cannot be transmitted to the identified controller 2, the image data can be transmitted to another controller 2. Therefore, even if some of the plurality of controllers 2 fail during use, the other controllers 2 can cope with it, and it is possible to provide an easy-to-use and reliable system.

  In addition, except for the fourth solution, there is an advantage that the radiologist can select the controller 2 according to the usage status of the plurality of controllers 2 when a communication failure occurs.

  Further, if the specific controller 2 also functions as the server 4, even if the server 4 breaks down, since all the records of the photographing database are stored in the controller 2, the photographing work is not hindered. It is further preferable that all the controllers 2 have the function of the server 4.

  Next, in the case of an emergency, a case will be described in which the registration of a patient or radiographing is postponed and the radiographic image is read first.

  (1) The radiologist positions a portion of the subject M to be radiographed between the radiation tube 9 and the cassette 6 and operates the radiation generation control device 10 of the radiation tube 9 to irradiate the radiation. Then, a part of the radiation energy irradiated from the radiation tube 9 and transmitted through the subject M is temporarily accumulated in the photostimulable phosphor sheet 8 incorporated in the cassette 6.

  (2) When the radiography of the patient is completed, the assistant sets the cassette 6 for which radiography has been completed in the radiographic image reading apparatus 1. When the cassette 6 is set, the radiation image reading apparatus 1 reads the sheet ID number from the barcode 62 of the cassette 6 and searches the imaging database of the server 4 with this sheet ID number.

  The server 4 searches the shooting database with the sent sheet ID number, but cannot obtain the latest record among the matching records. Accordingly, a reply that there is no matching record is returned to the radiation image reading apparatus 1. The radiation image reading apparatus 1 reads image data under default reading conditions, and temporarily stores the read image data in the radiation image reading apparatus 1.

  Next, it is desired to specify the controller 2 that transmits the image, but it is unclear to which controller 2 the image can be transmitted. In this case, the solution is similar to that in the case of the communication failure described above. These may be appropriately selected depending on hospital circumstances.

  The first solution is a method of designating a destination controller 2 from the controller 2 side. That is, the controller 2 directly sends the controller ID number of the return destination to the radiation image reading apparatus 1 holding the image data to be received, and requests the return of the image data.

  Upon receiving this request, the radiation image reading apparatus 1 transmits all the image data held together with additional information such as the read sheet ID number and reading conditions to the controller 2 having the designated controller ID number.

  The advantage of this solution is that the control form on both the controller 2 side and the radiation image reading apparatus 1 side is the simplest, the development cost of control software is low, and stable operation is easy.

  The second solution is that the radiation image reading device 1 forces image data to all the controllers 2 together with information indicating post-registration data, additional information such as the read sheet ID number and reading conditions. It is a method to transmit automatically. The controller 2 that has received the image data and the additional information temporarily stores the received image data and the additional information, and deletes them when they are no longer needed.

  For example, when the user selects another controller 2, a confirmation declaration is made to confirm that the temporarily stored image data and additional information are own. By transmitting this declaration to the other controller 2, the other controller 2 can erase the temporarily stored image data and additional information.

  The advantage of this solution is that when the user selects another controller 2, image data has already been received (since it is highly likely that it has been received), so any controller 2 can immediately check the image. It is.

  In the third solution, the server 4 has an image storage function, and the radiographic image reading apparatus 1 includes an image together with information indicating that the server 4 is post-registration data, additional information such as a read sheet ID number and reading conditions. In this method, data is transmitted and the server 4 temporarily stores the transmitted image data and additional information.

  When the user requests transmission of registered image data after being temporarily stored from the controller 2 to the server 4, the server 4 transmits the image data temporarily stored and its additional information to the controller 2 that made the request.

  The advantage of this solution is that the transmission destination of the image data from the radiation image reading apparatus 1 is always fixed to the server, so that the development of control software on the radiation image reading apparatus 1 side is simple and the development cost is low. In addition, the system operates stably with simple control.

  In the fourth solution, the order of the controller 2 to be transmitted in the case of post-registration data is determined in advance, and information indicating the post-registration data, the read sheet ID number, the reading condition, etc. are added according to the order. In this method, image data is transmitted to the controller 2 together with information. In this case, it is preferable that the user knows in advance the controller 2 to go in the case of post-registration data.

  The advantage of this solution is that the image data is automatically transmitted to another predetermined controller 2 without any operation by the user.

  A fifth solution is a method in which the radiation image reading apparatus 1 is provided with a function capable of designating a controller 2 for returning image data, and a user designates a controller 2 to which image data is returned using this function. It is. When the user designates the controller 2, image data is transmitted to the controller 2 together with additional information such as information indicating post-registration data, a read sheet ID number, and reading conditions. Further, it is more convenient to configure so that a plurality of controllers 2 and servers 4 can be specified at the same time.

  The advantage of this solution is that the control forms on both the controller 2 side and the radiation image reading apparatus 1 side are simple, the development cost of control software is low, and stable operation is easy. Further, since a plurality of controllers 2 and servers 3 can be designated as transmission destinations, a highly secure system can be constructed.

  The sixth solution is that any radiation image reading device 1 is provided with a portable storage medium writing device, and any controller 2 is provided with this portable storage medium reading device to read image data. In this method, the portable storage medium is stored together with additional information such as a sheet ID number and reading conditions, the portable storage medium is set in a desired controller 2, and image data and additional information are transferred to the controller 2.

  The merit of this solution is that it can cope with a communication failure in the entire network 3. As described above, in the case of an emergency, the image data read can be transmitted to the controller 2 even in the case where the registration regarding the patient and the imaging is postponed and the reading is performed first.

  (3) The radiologist inputs incidental information such as patient information and imaging information when imaging with the cassette 6 from the input unit 22 of the controller 2. When the patient information and the imaging information are confirmed, the controller 2 performs image processing on the received image data under image processing conditions determined by the imaging information, and displays the image data subjected to this image processing on the screen 21. Thereafter, the radiologist can change the image processing conditions as necessary. When the change of the image processing condition is input, the controller 2 performs image processing on the image data under the changed image processing condition and displays the image data on the screen 21 again. The controller 2 temporarily stores the sheet ID number received together with the image data, the accompanying information such as the input patient information and imaging information, and the operator ID number together with the reading conditions.

  If there is an error in the information displayed on the screen 21, the radiologist can input a re-input instruction from the input unit 22 and correct it. When these inputs are completed for all received image data, an input for instructing the end of input is performed.

  When a series of processes and input operations are completed and the image data and accompanying information are determined, the sheet ID number, operator ID number, reading conditions, and accompanying information that are temporarily stored are stored in the controller 2 ID number (hereinafter referred to as controller ID number). And is transmitted to the server 4.

  The server 4 attaches a unique captured image unique ID number to each captured image to the received sheet ID number, operator ID number, reading condition, and accompanying information, and registers this record in the captured database. .

Embodiment 2
The present embodiment is a modification of the first embodiment and is an embodiment in which no function is used for the server 4 of the first embodiment (it functions even without the server 4).

  The controller 2 registers the sheet ID number and reading conditions (reading sensitivity, reading resolution, etc.). When this is confirmed, the controller ID number (normal sheet ID number) of the controller 2 that is the return destination is stored in the information including at least the sheet ID number. And the controller ID number of the controller 2 in which the reading condition is registered) and all or a predetermined specific radiographic image reading apparatus 1. In other words, before the cassette 6 in which the sheet ID number is registered is set in any of the radiographic image reading apparatuses 1, a plurality of radiographic image reading apparatuses 1 are requested to transmit image data in advance.

  In this embodiment, an image data transfer request notification in which information such as a sheet ID number, a reading condition, and a return destination controller ID number is written is formed, and the image data transfer request notification is transmitted to all the radiation image reading apparatuses 1. .

  The radiation image reading apparatus 1 that has received the image data transfer request notification temporarily stores the received image data transfer request notification.

  When the cassette 6 is set in the radiographic image reading device 1 at an arbitrary timing and the sheet ID number is read from the barcode 62 of the cassette 6, all image data transfer requests temporarily stored in the radiographic image reading device 1 are requested. In the notification, it is searched whether or not the same sheet ID number as the sheet ID number read from the barcode 62 by the radiation image reading apparatus 1 exists. When the corresponding sheet ID number is detected, the controller ID number of the return destination is acquired from the image data transfer request notification, and the cassette 6 having the desired sheet ID number is attached to the controller 2 having this controller ID number. Notify that it has been detected.

  In this embodiment, an ID detection notification in which the detected sheet ID number and its own apparatus ID number are written is formed, and this ID detection notification is transmitted to the controller 2 as a return destination.

  Further, the radiation image reading apparatus 1 reads image data from the photostimulable phosphor sheet 8 included in the cassette 6 according to the reading conditions specified in the corresponding image data transfer request notification, and the read image data Is transmitted to the controller 2 as a return destination.

  If the corresponding sheet ID number could not be found, the coping method similar to the above-described “when urgent, postponing registration related to the patient and imaging and reading first” may be performed. .

  When the controller 2 receives the ID detection notification, the controller 2 temporarily stores it in the controller 2 and examines the sheet ID number described in the received ID detection notification to determine which image data transfer request notification corresponds to the sheet. Check if the ID number is detected.

  Next, a request to discard the image data transfer request notification corresponding to the detected sheet ID number is transmitted to at least the radiation image reading apparatus 1 that has not transmitted the ID detection notification. In this embodiment, the discard request notification in which the detected sheet ID number is written is transmitted to all the radiation image reading apparatuses 1 that have not transmitted the ID detection notification.

  The radiation image reading apparatus 1 that has received the discard request notification has an image having the same sheet ID number as the sheet ID number described in the discard request notification from among all temporarily stored image data transfer request notifications. Search for a data transfer request notification and discard (delete) it.

  The timing at which the controller 2 transmits the discard request notification to the radiation image reading apparatus 1 may be before or after receiving the image data. In the present embodiment, when the sheet ID number corresponding to the image data transfer request notification is detected in the radiation image reading apparatus 1, an ID detection notification is transmitted from the radiation image reading apparatus 1 to the controller 2, In response to this, the controller 2 is configured to discard the unnecessary image data transfer request notification by transmitting a discard request notification to the radiation image reading apparatus 1 that has not transmitted the ID detection notification. Other means may be used to discard the unnecessary image data transfer request notification.

  For example, a request for discarding the image data transfer request notification having the detected sheet ID number is sent from the radiation image reading apparatus 1 that has detected the sheet ID number to the other radiation image reading apparatuses 1. Also good.

Embodiment 3
This embodiment is a modification of the second embodiment.

  When a sheet ID number and reading conditions (such as reading sensitivity and reading resolution) are registered by the controller 2, these pieces of information are temporarily stored in the controller 2. However, unlike the second embodiment, at this time, an image data transfer request notification in which information such as a sheet ID number, a reading condition, and a return destination controller ID number is written is not transmitted to the radiation image reading apparatus 1.

  When the cassette 6 is set in the radiation image reading apparatus 1 and the sheet ID number is read from the barcode 62 of the cassette 6, at least the read sheet ID number and its own apparatus ID are notified to all the controllers 2. In this embodiment, an ID detection notification in which the read sheet ID number and its own apparatus ID number are written is formed, and this ID detection notification is transmitted to all the controllers 2.

  When the controller 2 receives the ID detection notification, the controller 2 temporarily stores it in the controller 2 and also stores the sheet ID described in the ID detection notification in the information temporarily stored in the controller 2. Whether or not a sheet ID number identical to the number exists is searched. When the corresponding sheet ID number is detected, the image data is requested to be transferred to the radiation image reading apparatus 1 that has transmitted the ID detection notification.

  In this embodiment, the controller 2 generates an image data transfer request notification in which information such as a sheet ID number, a reading condition, and a return destination controller ID number is written, and this is the radiation image reading apparatus that has transmitted the ID detection notification. 1 is transmitted.

  If the corresponding sheet ID number cannot be found in the information temporarily stored in the controller 2, the above-described “in case of an emergency, postponing registration related to the patient and imaging and reading first. It is only necessary to implement the same coping method as “if you do”.

  Next, a request to discard the image data transfer request notification corresponding to the detected sheet ID number is transmitted to at least the radiation image reading apparatus 1 that has not transmitted the ID detection notification. In this embodiment, the discard request notification in which the detected sheet ID number is written is transmitted to all the radiation image reading apparatuses 1 that have not transmitted the ID detection notification.

  The radiation image reading apparatus 1 that has received the discard request notification has an image having the same sheet ID number as the sheet ID number described in the discard request notification from among all temporarily stored image data transfer request notifications. Search for a data transfer request notification and discard (delete) it.

  When the radiation image reading apparatus 1 receives the image data transfer request notification, the image data is read and read from the photostimulable phosphor sheet 8 included in the cassette 6 according to the reading conditions specified in the packet. The image data is transmitted to the controller 2 indicated by the controller ID number of the return destination in the image data transfer request notification.

  The timing at which the controller 2 transmits the discard request notification to the radiation image reading apparatus 1 may be before or after receiving the image data.

  As described above, as described in the second and third embodiments, a radiographic imaging system that can obtain the same effect as that of the first embodiment can be constructed without using the function of the server 4.

  Also in the second and third embodiments, when the radiation image reading device 1 attempts to transmit the radiation image read from the photostimulable phosphor sheet 8 of the cassette 6 to the specified controller 2, the controller 2 receives the radiation image. May not be transmitted. In this case, this problem can be avoided by a solution that does not use the server 4 among the solutions described in the first embodiment.

  Also in the second and third embodiments, there are cases in which it is necessary to read a radiation image first in the case of an emergency by postponing registration related to a patient or imaging. In this case as well, this problem can be avoided with a solution that does not use the server 4 or the operator ID number among the solutions described in the first embodiment.

  Furthermore, in this embodiment, any controller 6 in which the sheet ID number is registered in any controller 2 can be set in a distributed manner in any radiation image reading apparatus 1 and any radiation image reading apparatus. The function for realizing that the image data read in 1 is automatically returned to the controller 2 in which the sheet ID number of the photostimulable phosphor sheet 8 corresponding to the image data is registered. Since the controller 2 and the radiation image reading apparatus 1 are provided and this function can be realized without using the specific server 4, there is no danger that the entire system will not function when the function of the server 4 is down. . Further, even if any controller 2 or radiation image reading apparatus 1 fails, the image data automatic return function is not lost.

  Further modifications of the three embodiments of the present invention described above will be described below.

  In general, the radiographic image reading apparatus is a radiographic image reading apparatus 1 that uses a cassette 6 as shown in FIG. 5 (hereinafter, this type radiographic image reading apparatus will be appropriately referred to as a cassette type radiographic image reading apparatus). There is also a dedicated type radiation image reading apparatus as shown in FIGS. The dedicated type radiological image reading apparatus is a radiographic image reading apparatus in which the detection means (detector unit) for detecting X-rays is fixed or built in the imaging apparatus, so that the user cannot easily carry the detection means. is there. In addition to the photostimulable phosphor sheet 8, a solid flat detector or the like can be used as the detection means.

  FIG. 7 is a diagram showing a standing-type radiological image reading apparatus 1a, which includes an elevator 100 and the radiographic image reading apparatus 1a.

  FIG. 8 is a diagram showing a recumbent type radiation image reading apparatus 1b, which includes a plate-like member 101, a bed 102, and a radiation image reading apparatus 1b.

  The radiographic image reading apparatus 1a and the radiographic image reading apparatus 1b are each configured by a reading unit 110, a signal processing unit 120, a primary storage unit 130, and a communication unit 140. Both functions and operations are described with reference to FIG. This is the same as the radiation image reading apparatus 1 described above. The reading unit 110 includes an excitation light generation unit, a photoelectric reading unit, and an A / D converter (none of which are shown). The radiographic image described in FIG. This is the same as the reading device 1.

  The main differences between the radiation image reading device 1a and the radiation image reading device 1b from the radiation image reading device 1 are the following three points.

  1) Reading of the photostimulable phosphor sheet 8 is started in synchronization with the generation of radiation from the radiation tube 9.

  2) In order to achieve this synchronization, the controllers 2a and 2b are in communication with the radiation generation control device 10 regarding the radiation irradiation synchronization signal.

  3) Registration of the sheet ID number of the photostimulable phosphor sheet 8 is unnecessary.

  Next, the operation when the radiation image reading apparatus 1a and the radiation image reading apparatus 1b are used will be described.

  The radiologist registers the patient information with the controllers 2a and 2b, and then sets the subject M at a predetermined position of the radiation image reading device 1a and the radiation image reading device 1b. 10 is operated to emit radiation. Then, a part of the X-ray energy irradiated from the X-ray tube 9 and transmitted through the subject M is temporarily stored in the photostimulable phosphor sheet 8 incorporated in the cassette 6.

  In synchronization with this irradiation, the reading unit 110 reads image information from the photostimulable phosphor sheet 8, and the image data is transmitted to the controllers 2a and 2b via the signal processing unit 120, the primary storage unit 130, and the communication unit 140. Is done.

  Until now, these dedicated type radiographic image reading apparatuses and cassette type radiographic image reading apparatuses have been controlled by individual controllers. However, if a dedicated type radiographic image reader and a cassette type radiographic image reader are placed in the same imaging room, they must be controlled by different controllers, increasing the number of controllers installed, installation area, and equipment cost. The fault of doing is pointed out. In addition, when imaging the same patient with a dedicated type radiographic image reader and a cassette type radiographic image reader, registration of patient information and imaging information and image confirmation must be performed by different controllers, resulting in a significant reduction in work efficiency. This has led to an increase in operational errors.

  In the embodiment of the present invention, in order to solve these problems, the cassette type controller 2 can control the dedicated type radiation image reading apparatuses 1a and 1b.

  FIG. 9 is a diagram showing an example of this actual form, which is a modification of the first, second, and third embodiments. Dedicated type radiation image reading apparatuses 1a and 1b are connected to a controller 2 indicated by an arrow A by dedicated lines 3a and 3b, respectively. The other controllers 2 can be connected to the dedicated type radiation image reading apparatuses 1a and 1b in the same manner. In this embodiment, it is assumed that the dedicated type radiological image reading apparatuses 1a and 1b and the cassette type radiographic image reading apparatus 1 indicated by the arrow B are installed in the same radiographing room. Usually, these radiation image reading apparatuses are used in the controller 2 indicated by the arrow A.

  In this case, since the dedicated type radiographic image reading apparatuses 1a and 1b are connected to the controller 2 indicated by the arrow A by the dedicated lines 3a and 3b, the images transmitted from the dedicated type radiographic image reading apparatuses 1a and 1b. Data can be received only by the controller 2 indicated by the arrow A. However, the controller 2 indicated by the arrow A can receive image data not only from the cassette type radiation image reading apparatus 1 indicated by the arrow B but also from other cassette type radiation image reading apparatuses 1.

  As a result, when a dedicated type radiographic image reading apparatus and a cassette type radiographic image reading apparatus are arranged in the same imaging room, there is no need to control them with different controllers, and the number of installed controllers, installation area, and apparatus cost are reduced. be able to. In addition, when imaging the same patient with a dedicated type radiographic image reader and a cassette type radiographic image reader, it is possible to register patient information and imaging information and confirm images with the same controller. Can be improved and operational errors can be reduced.

  FIG. 10 is a modification of the embodiment of FIG. 9, and dedicated type radiation image reading apparatuses 1 a and 1 b are connected to an arbitrary controller 2 via a network 3. Therefore, an arbitrary controller 2 can receive image data from the dedicated type radiation image reading apparatuses 1a and 1b. FIG. 10 assumes a case where a device surrounded by a dotted line indicated by an arrow C is installed in one photographing room.

  When using the radiographic image reading apparatuses 1a and 1b, the radiographer usually registers patient information and imaging information and confirms an image with the controller 2 indicated by the arrow D, but is indicated by the arrow C due to some trouble. When the controller 2 cannot receive the image data transmitted from the radiation image reading apparatuses 1a and 1b, the other controller can receive the image data. For this reason, a highly reliable system can be constructed.

  FIG. 11 is a modification of the embodiment of FIG. 10, and dedicated type radiation image reading apparatuses 1 a and 1 b, a cassette type radiation image reading apparatus 1, and a controller 2 are connected by a switching hub 80. Although the server 4 is connected to the switching hub indicated by the arrow E, it goes without saying that even if the server 4 does not exist, it operates without any problem as in the embodiments described above.

  The network 3 and the DICOM network 90 are connected by a gateway 81. The image data output by the controller 2 is output to the DICOM network 90 via the switching hub 80 and the gateway 81. In this embodiment, since the dedicated type radiographic image reading apparatuses 1a and 1b, the cassette type radiographic image reading apparatus 1 and the controller 2 are dispersedly connected by the switching hub 80, the radiographic image reading apparatuses 1, 1a and 1b are connected. When the image data transfer between the controller 2 and the controller 2 occurs at the same time, the image data transfer time is improved. Since a large amount of image data flows in the network 3 connecting the switching hubs 80, it is preferable to use a cable having a large transfer capability.

  FIG. 12 is a variation of the embodiment of FIG. Local image filing devices 82 and 83 that also serve as DICOM gateways file image data generated in portions surrounded by dotted lines G and H, respectively. The server 4 is a server that supervises the information generated in the part surrounded by the dotted lines of the arrows G and H. Even when the server 4 does not exist, the server 4 operates without any problem as in the embodiments described so far. Needless to say. A database in the local image filing devices 82 and 83 is managed by an image filing device 93.

  The image recording apparatus 91, the image diagnostic apparatus 92, the image filing apparatus 93, and the like described in the first embodiment can be connected to the DICOM network 90 in FIGS. 9, 10, 11, and 12.

It is a figure which shows the structural example of the conventional cassette type radiographic imaging system. It is a figure which shows another example of a structure of the conventional cassette type radiographic imaging system. It is a figure which shows the structural example of the radiographic imaging system of Embodiment 1. FIG. It is a figure which shows operation | movement of the radiographic imaging system of Embodiment 1. It is a figure which shows the radiographic image reading apparatus of the radiographic imaging system of Embodiment 1. It is a figure which shows the structural example of the radiographic imaging system of Embodiment 2, 3. FIG. It is a figure which shows the structural example of a radiographic imaging system of a dedicated type (standing position type). It is a figure which shows the structural example of a radiographic imaging system of a dedicated type (suppression type). It is a figure which shows the structural example of the radiographic imaging system which is a deformation | transformation form of Embodiment 1. FIG. It is a figure which shows the structural example of the radiographic imaging system which is a modification of embodiment shown by FIG. It is a figure which shows the structural example of the radiographic imaging system which is a modification of embodiment shown by FIG. It is a figure which shows the structural example of the radiographic imaging system which is a modification of embodiment shown by FIG.

Explanation of symbols

1 Radiation image reader (cassette type)
1a Radiation image reader (standing position type)
1b Radiation image reader (recumbent type)
2 Controller 3 Network 4 Server 5 Information input terminal 6 Cassette 7 Image confirmation device 8 Stimulable phosphor sheet 9 Radiation tube 10 Radiation generation control device 21 Display unit 22 Input unit 23 Operator ID number input unit 24 Bar code reader 62 Barcode 80 Switching hub 81 Local image filing device 82 Local image filing device 91 Image recording device 92 Image diagnostic device 93 Image filing device 110 Reading unit 120 Signal processing unit 130 Primary storage unit 140 Communication unit 150 Barcode reader 160 Transport mechanism

Claims (15)

A plurality of controllers for registering shooting information;
A radiographic imaging system in which radiographic image data is read using a detection unit that detects X-rays and a plurality of radiographic image reading devices that output the read radiographic image data are arranged on the same network,
The controller and the radiographic image reading device are connected to a network so that the radiographic image data is transmitted to the controller in which the imaging information corresponding to the radiographic image data is registered,
The controller is
An image display means for the operator to confirm the radiation image data;
After the confirmation, an image confirmation input means for inputting that the operator has confirmed the radiation image data;
Radiographic imaging, comprising: registration means for registering the confirmed radiographic image data and the imaging information in association with each other when radiographic image data confirmation is input to the image confirmation input means system. The controller has image processing means for performing image processing on the received radiation image data,
The registration means is means for registering radiographic image data after image processing or radiographic image data before image processing to which image processing conditions are added in association with the imaging information. Item 2. The radiographic image capturing system according to Item 1. The radiographic imaging system according to claim 1, wherein the detection unit is a solid flat panel detector. The radiographic image capturing system according to claim 1, wherein the detection unit is a radiographic image accumulating sheet body. A plurality of controllers for registering identification information of the radiation image storage sheet member and a plurality of radiation image reading devices that read the radiation image stored in the radiation image storage sheet member and output image data are on the same network. The radiographic imaging system arranged in the radiography system, wherein the controller can display the image for confirmation when receiving the image read from the radiographic image storage sheet by the radiographic image reading device, The radiation image accumulating sheet whose identification information is registered by any of the controllers can be set in any of the plurality of radiation image reading devices, and the radiation image reading device Reads the identification information of the set radiation image storage sheet body, and the plurality of radiation Regardless of the radiation image reading device of the image reading device, the controller which registered the identification information of the radiation image accumulating sheet body is specified based on the identification information read by the radiation image reading device, and the radiation A radiographic imaging system, wherein the radiographic image read from the radiographic image storage sheet by the image reading device is transmitted to a specified controller. When transmitting the radiation image read from the radiation image accumulating sheet by the radiation image reading device to the specified controller, if the transmission to the controller is not possible, the radiation image is transmitted to another controller. The radiographic imaging system according to claim 5. Each of the plurality of controllers has means for obtaining identification information specific to the operator of the controller, and when the controller registers the identification information of the radiation image storage sheet body, the controller is specific to the operator of the controller. If the radiographic image read by the radiographic image reading apparatus is transmitted to the specified controller and cannot be transmitted to the controller, the registration is performed together with the identification information. The radiographic imaging system according to claim 6, wherein the radiographic image is transmitted to a controller having the same identification information unique to the operator. The controller is capable of registering identification information specific to a subject when registering identification information of a plurality of radiation image storage sheets relating to one subject, and a plurality of radiation image storage sheets relating to one subject. When registering body identification information together with identification information unique to the subject, a predetermined display is displayed when all the images read from the plurality of radiation image storage sheet bodies relating to the one subject are received. The radiographic image capturing system according to claim 5, wherein the radiographic image capturing system is used. The radiographic image according to any one of claims 5 to 8, wherein the controller can output images read from a plurality of radiographic image accumulation sheet bodies related to one subject in a predetermined order. Shooting system. On the same network, there is a database means for storing a database of records including at least identification information of the radiation image accumulating sheet registered by the plurality of controllers and identification information of the controller that has registered the identification information. The database means can search from any of the plurality of radiographic image reading devices by the identification information of the radiographic image storage sheet body, and returns a corresponding record, and any of the plurality of radiographic image reading devices. Based on the identification information of the controller in the returned record, the controller registered for the radiation image storage sheet is specified, and the radiation image read from the radiation image storage sheet by the radiation image storage sheet is stored in the specified controller. Any one of claims 5 to 9, wherein the transmission is performed. Radiographic imaging system according to item 1. Each of the plurality of controllers transmits a record including the identification information of the radiation image accumulating sheet member registered by the controller and the identification information of the controller to all of the plurality of radiation image reading apparatuses. Each of the radiographic image reading apparatuses stores the received record, and attempts to transmit the read image based on the identification information of the controller of the record that matches the identification information of the read radiographic image storage sheet body. The radiographic imaging system according to any one of claims 5 to 9. Any of the plurality of radiation image reading devices searches for a record that matches all of the plurality of controllers with the identification information of the read radiation image storage sheet body, and reads the image to the controller that has the matching record. The radiographic image capturing system according to claim 5, wherein: When registering the identification information of the radiographic image storage sheet body with the controller, the radiographic image storage sheet body is also registered together with imaging information regarding the imaging part, imaging direction, imaging conditions, etc. of the subject to be imaged, The controller determines reading conditions for the radiation image accumulating sheet body from the registered imaging information, and the radiological image reading apparatus is configured to read the reading based on identification information of the read radiation image accumulating sheet body. The radiographic imaging system according to any one of claims 5 to 12, wherein conditions are obtained, and image data is read from the radiation image accumulating sheet based on the obtained reading conditions. When registering the identification information of the radiographic image storage sheet body with the controller, the radiographic image storage sheet body is also registered together with imaging information regarding the imaging part, imaging direction, imaging conditions, etc. of the subject to be imaged, The controller performs image processing on image data received together with the identification information of the radiation image storage sheet body based on imaging information that matches the identification information of the radiation image storage sheet body, and outputs the processed image data. The radiographic imaging system in any one of 5-13. The controller can control a dedicated type radiological image reading apparatus, and the image data output from the dedicated type radiographic image reading apparatus is synchronized with radiation imaging by the dedicated type radiographic image reading apparatus. The radiographic image capturing system according to claim 5, wherein the radiographic image capturing system can receive the image.

Images