JP2004188094A - Radiographic apparatus and radiographic system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radiographic apparatus capable of properly setting a photographing condition on the basis of the photographing condition set when photographing is performed in the past and, a radiographic system. <P>SOLUTION: The radiographic device is provided with a storage device for storing photographing condition necessary for taking a radiation image containing at least a tube voltage value and a tube current value used when the radiation image is taken, a display device for displaying the photographing condition stored in the storage device when a same subject is again photographed and a control unit for storing the photographing condition and controlling the display of the photographing condition. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a radiographic image capturing apparatus and a radiographic image capturing system, and more particularly, to a radiographic image capturing apparatus and a radiographic image capturing system that can appropriately set capturing conditions based on capturing conditions at the time of capturing in the past. About.
[0002]
[Prior art]
Conventionally, radiation images represented by X-ray images have been widely used for diagnosis of diseases and the like. In order to obtain a good radiation image, in the radiation image capturing apparatus, imaging conditions necessary for capturing a radiation image such as a tube voltage and a tube current are appropriately set according to a subject such as a patient's chest, for example. You need to shoot. Conventionally, the setting of the imaging conditions is performed by a radiologist inputting the imaging conditions from an input operation unit such as a keyboard (for example, see Patent Document 1).
[0003]
In addition, conventionally, an imaging condition is automatically set based on a part of a patient to be imaged or the like. In this automatic setting, since the imaging conditions are determined uniformly from the part to be imaged, the dose is appropriately set in the automatically set tube voltage and tube current due to differences in individual patient's body shape and the like. In some cases, a clear radiographic image cannot be obtained, or a part to be diagnosed is not included in the imaging range with the automatically set irradiation field aperture value. Therefore, the radiologist performs input for adjusting the imaging condition automatically set from the input operation unit according to the height and weight of the patient, the imaging region, the result of actually seeing the patient's body shape, and the like.
[0004]
[Patent Document 1]
JP-A-10-201750
[0005]
[Problems to be solved by the invention]
However, in the conventional radiation image capturing apparatus (Patent Document 1), a radiologist predicts the amount of transmitted radiation, the size of a captured region, and the like to set the capturing conditions. Since the calculation is performed based on external factors such as the weight, the imaging region, and the result of actually observing the body shape of the subject, the actual amount of transmitted radiation and the size of the imaging region may be contrary to the prediction. In this case, there is a problem that a clear radiation image cannot be obtained, for example, a clear radiation image cannot be obtained, or a part to be diagnosed is not included in an imaging range.
[0006]
Incidentally, radiographic images are often taken a plurality of times in order to observe changes over time in the affected part. Since the amount of transmitted radiation and the size of the imaging region do not change so much, the amount of transmitted radiation, the size of the imaging region, and the like can be reduced by taking into account imaging conditions used in the past imaging. Prediction can be made more easily and accurately, and photographing conditions can be set appropriately.
[0007]
Therefore, the present invention provides a radiographic image capturing apparatus and a radiographic image capturing system that can appropriately set radiographic conditions based on radiographing conditions at the time of radiographing in the past and can obtain a good radiological image. The purpose is to provide.
[0008]
[Means for Solving the Problems]
In order to solve the above-described problems, a radiation image capturing apparatus according to the present invention includes a radiation tube device that generates radiation, and connects a high-voltage generator that applies a high voltage to the radiation tube device. In a radiation image capturing apparatus provided with a diaphragm device for adjusting a radiation irradiation field on the front surface, image capturing conditions necessary for capturing a radiation image including at least a tube voltage value and a tube current value used when capturing a radiation image are stored. A storage device, a display device that displays the shooting conditions stored in the storage device when the same subject is shot again, and controls the storage of the shooting conditions by the storage device, and displays the shooting conditions by the display device. And a control device for controlling.
[0009]
According to the present invention, when the same subject is imaged again, a display device for displaying imaging conditions used for past imaging stored in the storage device is provided. By taking into account the past imaging conditions that have been set, the radiation transmission amount, the size of the imaging region, and the like are predicted, and the imaging conditions are set.
[0010]
According to a second aspect of the present invention, in the radiation image capturing apparatus according to the first aspect, the storage device stores the captured radiation image, and the display device re-displays the same subject. A radiographic image stored in the storage device is displayed at the time of imaging.
[0011]
According to the present invention, the radiation image information is displayed on the display device together with the past imaging conditions stored in the storage device when the same subject is imaged again, so that the radiologist is displayed on the display device. In consideration of the past radiation image and the imaging conditions, the amount of transmitted radiation, the size of the imaging region, and the like are predicted, and the imaging conditions are set.
[0012]
A radiation image capturing apparatus according to a third aspect of the present invention includes a radiation tube device that generates radiation, and connects a high voltage generator that applies a high voltage to the radiation tube device. In a radiation image capturing apparatus provided with a diaphragm device for adjusting a radiation irradiation field on the front surface, image capturing conditions necessary for capturing a radiation image including at least a tube voltage value and a tube current value used when capturing a radiation image are stored. A storage device, and at least one of a tube voltage value and a tube current value of the high-voltage generation device and an irradiation field aperture value of the diaphragm device based on imaging conditions stored in the storage device when the same subject is imaged again. And a control device for controlling one of them.
[0013]
According to the present invention, when the same subject is photographed again, the tube voltage value and the tube current value of the high-voltage generator and the irradiation field diaphragm value of the diaphragm device are determined based on the past photographing conditions stored in the storage device. Since the control device for controlling at least one of them is provided, the photographing conditions are automatically set based on the past photographing conditions.
[0014]
Further, the radiographic image capturing system according to the invention of claim 4 connects an ordering server that manages information related to radiographic image capturing and a radiographic image capturing device that captures a radiographic image via a network. In the radiographic image capturing system that performs capturing by the radiographic image capturing apparatus, based on the capturing information, the subject information regarding the subject and the capturing information necessary for capturing the radiation image are registered as the capturing reservation information. At least a storage device for storing imaging conditions necessary for imaging a radiation image including a tube voltage value and a tube current value used at the time of imaging the radiation image is provided, and is stored in the storage device when the same subject is imaged again. Display device that displays the current shooting conditions together with shooting reservation information And it features.
[0015]
According to the present invention, imaging conditions necessary for imaging a radiation image including a tube voltage value and a tube current value used when the radiation image is imaged are stored in the storage device of the ordering server. When the same subject is imaged again, the imaging conditions are displayed together with the imaging reservation information on the display device provided in the radiographic imaging apparatus. The amount of transmission, the size of the imaging site, and the like are predicted, and imaging conditions are set.
[0016]
According to a fifth aspect of the present invention, in the radiation image capturing system according to the fourth aspect, the storage device stores the captured radiation image, and the display device displays the same subject again. A radiographic image stored in the storage device is displayed at the time of imaging.
[0017]
According to the present invention, the captured radiation image is stored in the storage device of the ordering server. Then, when the same subject is imaged again, the radiation image is displayed on the display device provided in the radiographic image imaging device together with the imaging reservation information and the imaging conditions. In consideration of the above, the radiation transmission amount, the size of the imaging region, and the like are predicted, and the imaging conditions are set.
[0018]
Further, the radiation image capturing system according to the invention of claim 6 connects an ordering server that manages information related to radiation image capturing and a radiation image capturing apparatus that captures a radiation image via a network, and the ordering server has In the radiation image capturing system that performs capturing by the radiation image capturing apparatus, based on the image capturing information, based on the capturing information, the subject information regarding the subject and the capturing information regarding the conditions for capturing the radiation image are registered as the capturing reservation information. At least a storage device for storing imaging conditions necessary for imaging of a radiation image including a tube voltage value and a tube current value used at the time of imaging the radiation image is provided. The tube voltage value based on the photographing conditions stored in the storage device Characterized in that a control device for controlling at least one of the tube current value and the irradiation field aperture.
[0019]
According to the present invention, the imaging conditions used when imaging the radiation image are stored in the storage device of the ordering server. When the same subject is photographed again, at least one of the tube voltage value, the tube current value, and the irradiation field aperture value is controlled based on the photographing conditions. The photographing conditions are set as desired.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
[0021]
As shown in FIG. 1, a radiographic image capturing system according to the present invention includes an ordering server 1 that manages information related to radiographic image capturing, a radiographing operation terminal 2 that performs an operation related to radiographic image capturing, and an image reading process of a captured radiographic image. And an image reading processing operation terminal 3 for performing operations relating to the image reading processing. The imaging operation terminal 2 includes a radiation tube device 5 that generates radiation via the cable 4, a high voltage generator 6 that applies a high voltage to the radiation tube device 5, and a diaphragm device 7 that adjusts a radiation irradiation field. A phototimer 8 for detecting the amount of radiation transmitted through the patient A is connected. An image reading processing device 9 is connected to the image reading processing operation terminal 3 via a cable 4. Note that the radiographing operation terminal 2, the high-voltage generator 6, the aperture device 7, and the phototimer 8 constitute a radiation image radiographing device.
[0022]
The ordering server 1 is composed of a computer. As shown in FIG. 2, the ordering server 1 includes a CPU (Central Processing Unit) 11, a ROM (Read Only Memory) 12, a RAM (Random Access Memory) 13, and an external storage. A device 14, an input operation device 15 such as a keyboard and a mouse, a display device 16 such as a CRT display and a liquid crystal display, and an interface 17 are provided.
[0023]
The ROM 12 stores various control programs related to management of information related to radiographic imaging. The RAM 13 is provided with a work area and the like by the CPU 11, and the CPU 11 develops a specified program from various programs stored in the ROM 12 into a work area in the RAM 13, and performs various processes according to the programs. It is supposed to run.
[0024]
The imaging operation terminal 2 and the image reading processing operation terminal 3 are electrically connected to the interface 17.
[0025]
The CPU 11 associates the patient information, imaging information, and read information input from the input operation device 15 with the external storage device 14 as imaging reservation information for instructing a radiologist to perform radiographic image imaging in a state where the information is associated with each other. Is to be stored. The patient information is information about the patient such as the patient's name, age, gender, date of birth, and patient ID number for identifying the patient. The photographing information is information necessary for photographing, such as a photographing part (a part to be photographed on the body of the photographed person), a photographing direction and a photographing method. The read information is information relating to read conditions such as read sensitivity and read resolution of the radiation image reading apparatus according to the imaging information.
[0026]
The ROM 12 stores, for each imaging region, an imaging condition table that defines an average tube voltage value, a tube current value, a dose, and an irradiation field aperture value that can obtain a good radiation image for the region. The CPU 11 selects a tube voltage value, a tube current value, a dose, and an irradiation field aperture value corresponding to the imaging region input from the input operation device 15 based on the imaging condition table stored in the ROM 12 and obtains imaging information. Is added.
[0027]
In addition, when the tube voltage value, the tube current value, the dose, and the irradiation field aperture value selected based on the imaging condition table are corrected at the time of capturing the radiation image, the CPU 11 corrects the correction value used for the actual imaging. Is received from the imaging operation terminal 2 and stored in the external storage device 14 as a correction value. Further, the CPU 11 receives the captured radiation image from the image reading processing operation terminal 3 and stores the radiation image in the external storage device 14.
[0028]
The photographing operation terminal 2 is constituted by a computer. As shown in FIG. 2, the photographing operation terminal 2 includes a CPU 21 as a control device, a ROM 22, a RAM 23, an input operation device 24 such as a keyboard and a mouse, a CRT display, A display device 25 such as a liquid crystal display and an interface 26 are provided.
[0029]
The ROM 22 stores various control programs for controlling radiographic image capturing. The RAM 23 is provided with a work area and the like by the CPU 21. The CPU 21 develops a designated program from various programs stored in the ROM 22 into a work area in the RAM 23, and performs various processes according to the programs. It is supposed to run.
[0030]
The ordering server 1, the high voltage generator 6, the aperture device 7, and the photo timer 8 are electrically connected to the interface 26.
[0031]
Here, as shown in FIG. 1, a radiation tube device 5 is connected to the high-voltage generator 6, and by applying a tube voltage and a tube current from the high-voltage generator 6 to the radiation tube device 5, Radiation is applied. At a radiation irradiation port 51 of the radiation tube device 5, a diaphragm port 71 of a diaphragm device 7 for adjusting a radiation irradiation field is provided so as to be freely opened and closed. A bed B on which the patient A is placed is provided below the radiation tube device 5 and in the radiation irradiation range. Below the bed B, a radiation image capturing cassette C containing a stimulable phosphor sheet is provided. Is provided with a cassette mounting port (not shown). A phototimer 8 is provided between the bed B and the cassette mounting opening. The phototimer 8 detects a radiation dose transmitted through the patient A, and the radiation dose transmitted through the patient A reaches a predetermined dose. When this is done, a signal is transmitted to the photographing operation terminal 2.
[0032]
The CPU 21 provided in the photographing operation terminal 2 receives the photographing reservation information from the ordering server 1 via the interface 26 in accordance with the signal from the input operation device 23, displays the photographing reservation information on the display device 25, and displays the photographing reservation information. The medium tube voltage value and the tube current value are output to the high voltage generator 6, the dose is output to the phototimer 8, and the irradiation field aperture value is output to the aperture device 7.
[0033]
Further, upon receiving the imaging reservation information, the CPU 21 determines whether the correction value and the radiation image are stored in the external storage device 14 of the ordering server 1 for the imaging region of the patient, that is, the subject indicated in the received imaging reservation information. It is designed to search. If stored, the correction value and the radiation image are received from the ordering server 1 and displayed on the display device 25, and the correction values are output to the high-voltage generator 6, the phototimer 8, and the aperture device 7, respectively. It is supposed to.
[0034]
When an input for correcting the tube voltage value, the tube current value, the dose, and the irradiation field aperture value is input from the input operation device 24, the CPU 21 changes the corrected values to the high voltage generator 6, the photo timer 8, and the aperture. The signals are output to the devices 7 respectively.
[0035]
In addition, the CPU 21 controls the operation of applying the tube voltage and the tube current by the high-voltage generator 6 and the operation of detecting the transmitted dose by the phototimer 8 in accordance with a signal from the input operation device 23. ing. The CPU 21 controls the operation of stopping the tube voltage and the tube current by the high-voltage generator 6 in accordance with a signal from the photo timer 8.
[0036]
In addition, the CPU 21 performs imaging using the tube voltage value, the tube current value, the dose, and the irradiation field aperture value at the time of imaging in the past, or performing imaging using the value input from the input operation device 24. , A difference between a value used for actual photographing and a value selected based on the photographing condition table is transmitted to the ordering server 1.
[0037]
The radiation image reading device 3 is configured by a computer, and the radiation image reading device 3 is provided with a CPU 31, an input operation device 32, a ROM 33, a RAM 34, and an interface 35, as shown in FIG.
[0038]
The ROM 33 stores various control programs for controlling an image reading process of a captured radiation image. The RAM 34 is provided with a work area and the like by the CPU 31. The CPU 31 develops a designated program from various programs stored in the ROM 33 into a work area in the RAM 34, and performs various processes according to the programs. It is supposed to run.
[0039]
The ordering server 1 and the image reading device 9 are electrically connected to the interface 35.
[0040]
The CPU 31 receives the imaging reservation information from the ordering server 1 via the interface 35 in response to a signal from the input operation device 32, and based on the image reading information in the received imaging reservation information, the radiation image reading processing device 9 is controlled. In the image reading processing by the radiation image reading processing device 9, the stimulable phosphor sheet on which the radiation image has been taken is irradiated with excitation light, and the radiation energy stored and recorded in the stimulable phosphor sheet is stimulated to emit light. This is performed by converting the intensity of the stimulated emission light into an electric signal.
[0041]
The CPU 31 receives the radiation image on which the image reading processing has been performed by the radiation image reading processing device 9 and transmits the radiation image to the ordering server 1.
[0042]
Next, the operation of the present embodiment will be described.
[0043]
Based on the judgment of the doctor, the patient information, imaging information, and reading information input from the input operation device 15 of the ordering server 1 are correlated by the doctor to the radiologist by the CPU 11 in a state where the information is associated with each other by the CPU 11. Is stored in the external storage device 14 as the photographing reservation information instructing the user. When an imaging region is input, the CPU 11 selects a tube voltage value, a tube current value, a dose, and an irradiation field aperture value based on an imaging condition table stored in the ROM 12, and adds the selected value to the imaging information.
[0044]
When the radiologist operates the imaging operation terminal 2, the imaging reservation information registered in the ordering server 1 is received by the CPU 21 of the imaging operation terminal 2 and displayed on the display device 25 of the imaging operation terminal 2. At this time, the tube voltage value and the tube current value in the imaging reservation information are output to the high voltage generator 6, the dose is output to the phototimer 8, and the irradiation field aperture value is output to the aperture device 7.
[0045]
Further, when the imaging reservation information is received by the imaging operation terminal 2, the CPU 21 of the imaging operation terminal 2 transmits the correction value and the radiation image for the same imaging region of the same patient indicated in the received imaging reservation information to the ordering server. A search is made to determine whether the data is stored in the first external storage device 14. If the correction value and the radiation image are stored, the correction value and the radiation image are received from the ordering server 1 and displayed on the display device 25, and the correction value is transmitted to the high-voltage generator 6, the photo timer 8, and the aperture device 7. Each is output.
[0046]
The radiologist inputs a value to be corrected from the input operation device 24 of the imaging operation terminal 2 when it is necessary to correct the tube voltage value or the like in consideration of the content displayed on the display device 25 and the patient's body shape and the like. . When the correction is performed, the corrected value is output to the high voltage generator 6, the photo timer 8, and the aperture device 7 by the CPU 21 of the photographing operation terminal 2.
[0047]
The tube voltage value and the tube current value are input to the high voltage generator 6 and set as values to be applied to the radiation tube device 5. The dose is input to the photo timer 8 and is set as a transmitted dose to be transmitted to the photographing operation terminal 2 to signal that the predetermined dose has been reached. The aperture value of the irradiation field is input to the aperture device 7, and based on this, the opening and closing operation of the aperture 71 is performed, and the radiation field is adjusted.
[0048]
The radiologist applies the radiation image capturing cassette C to the body of the patient A to be imaged, and arranges the radiation tube device 5 at a position where the radiation image capturing cassette C can be irradiated with radiation from above the patient's body. . Thereafter, when the radiologist operates the input operation device 24 of the imaging operation terminal 2, the application of the tube voltage and the tube current from the high voltage generator 6 is started under the control of the CPU 21, and the radiation from the radiation tube device 5 is transmitted to the patient A. Irradiated against At the same time, under the control of the CPU 21, the detection of the transmitted dose by the photo timer 8 is started. When the transmitted dose detected by the photo timer 8 reaches the set dose, a signal is transmitted to the CPU 21 of the photographing operation terminal 2, and under the control of the CPU 21 having received the signal, the control of the high voltage generator 6 The application of the voltage and the tube current is stopped, and the irradiation of the radiation from the radiation tube device 5 is also stopped.
[0049]
Thereafter, when imaging was performed with the tube voltage value, tube current value, dose, and irradiation field aperture value at the time of imaging in the past, or when imaging was performed with the value input from the input operation device 24, The difference between the value used for actual imaging and the value selected based on the imaging condition table is transmitted by the CPU 21 to the ordering server 1 and stored in the external storage device 14 of the ordering server 1 as a correction value. .
[0050]
Thereafter, when the radiologist operates the input operation device 32 of the image reading processing operation terminal 3, the CPU 31 receives the imaging reservation information from the ordering server 1, and performs radiation based on the image reading information in the received imaging reservation information. The image reading processing device 9 irradiates the stimulable phosphor sheet with the radiation image with excitation light to emit excitation light, and the radiation energy recorded and accumulated in the stimulable phosphor sheet is stimulated to emit light. Is converted into an electric signal.
[0051]
The radiation image subjected to the image reading processing by the radiation image reading processing device 9 is received by the CPU 31 of the image reading processing operation terminal 3 and transmitted to the ordering server 1, and is stored in the external storage device 14 of the ordering server 1. You.
[0052]
The radiation image on which the image reading process has been performed is displayed on the display device 16 of the ordering server 1 or output by an image output device (not shown) such as a printer, so as to be used for diagnosis by a doctor. The Rukoto.
[0053]
As described above, according to the embodiment of the present invention, when the same part of the same patient is to be imaged again, the imaging reservation information, the past imaging conditions, and the radiation image managed by the ordering server 1 The display conditions are displayed on the display device 25 provided in the device 2 and the shooting conditions are automatically set based on the past shooting conditions. Therefore, the radiological technologist can more easily and accurately consider the displayed radiographing reservation information, past radiographing conditions, the radiographic image, the patient's body shape, and the like, and more easily and accurately transmit the radiation and the size of the radiographic part. Can be predicted, so that it can be easily determined whether or not a good radiation image can be obtained under the past imaging conditions.
[0054]
Then, when it is determined that a good radiation image can be obtained under the past imaging conditions, the imaging can be performed under the past imaging conditions that have been automatically set. In addition to this, a good radiation image can be obtained based on the past imaging conditions.
[0055]
On the other hand, if it is determined that a better radiation image can be obtained by correcting the past imaging conditions, the imaging conditions are determined based on the correspondence between the displayed past radiation images and the imaging conditions. Correction can be made, and a better radiation image can be obtained.
[0056]
In addition, since the past imaging conditions, radiation images, and imaging reservation information are collectively managed by the ordering server, the imaging information in the imaging reservation information, the past imaging conditions, and the radiation image are displayed in association with each other, It is possible to appropriately set the imaging conditions in consideration of the imaging information, the past imaging conditions, and the radiation image without error.
[0057]
In the embodiment of the present invention, the tube voltage value, the tube current value, the dose, and the irradiation field aperture value at the time of photographing in the past are displayed on the display device 25 of the photographing operation terminal 2 and the photographing conditions are automatically set. However, only the tube voltage value and the tube current value may be displayed and automatically set as the photographing conditions.
[0058]
Further, in the embodiment of the present invention, the radiographing conditions and radiographic images obtained when radiographing was performed in the past are displayed on the display device 25 of the radiographing operation terminal 2 and the past radiographing conditions are automatically set as radiographing conditions. However, only the past imaging conditions and radiation images, or only the past imaging conditions may be displayed. In this case, the radiologist inputs the imaging conditions from the input operation device 25 of the imaging operation terminal 2. When determining the imaging conditions, the radiation transmission amount is determined in consideration of past imaging conditions and radiation images. Since it is possible to predict the size of a radiographed part and the like, radiographing conditions can be appropriately set, and a good radiation image can be obtained.
[0059]
Further, in the embodiment of the present invention, a difference between a tube voltage value, a tube current value, or the like used in actual imaging and a value selected based on the imaging condition table is managed as a correction value in the ordering server 1, and With this correction value, the value automatically set based on the imaging condition table is corrected when the same imaging region of the same patient is imaged again. The current value and the like may be managed by the ordering server. In this case, when the imaging reservation information is received by the imaging operation terminal 2, the CPU 21 of the imaging operation terminal 2 determines the tube voltage value, tube current value, and the like used in the past imaging for the same imaging region of the same patient. It is searched whether it is stored in the ordering server 1, and if it is stored, it is received and the past tube voltage value, tube current value, etc. are output to the high voltage generator 6 or the like. In this case, it is not necessary to automatically set the shooting conditions based on the shooting condition table.
[0060]
Further, in the embodiment of the present invention, the ordering server 1 manages all of the differences between the tube voltage values, tube current values, and the like used for actual imaging and the values selected based on the imaging condition table, and all the radiation images. However, only the difference between the tube voltage value, tube current value, and the like used for imaging in which a good image was obtained and the value selected based on the imaging condition table and the radiation image are managed. You may.
[0061]
Further, in the embodiment of the present invention, the radiation image capturing system has been described. However, an external storage device that stores a tube voltage value, a tube current value, and the like used in actual capturing and a radiation image is provided in the capturing operation terminal 2. For example, a radiographic image capturing apparatus can be configured by the capturing operation terminal 2, the high-voltage generating device 6, the aperture device 7, and the photo timer 8 to perform capturing processing. According to this radiographic image capturing apparatus, when a radiologist inputs, for example, a patient ID number or the like from the input operating device 24 of the image capturing operating terminal 2, the CPU 21 of the image capturing operating terminal 2 uses the external storage provided in the image capturing operating terminal 2. It is searched whether or not a tube voltage value, a tube current value, and the like and a radiation image used in the past imaging are stored in the apparatus, and if stored, read out and displayed on the display device 25. At this time, the past tube voltage value and tube current value are output to the high voltage generator 6, the dose is output to the phototimer 8, and the irradiation field aperture value is output to the aperture device 7. Therefore, according to this radiographic image capturing apparatus, when capturing the same part of the same patient again, the past capturing conditions and the radiation image stored in the external storage device are displayed on the display device 25, The photographing conditions are automatically set based on the past photographing conditions. Therefore, the radiologist can easily and accurately predict the amount of transmitted radiation and the size of the imaging region by considering the displayed past imaging conditions and the radiographic image and the patient's body shape and the like. Therefore, a better radiation image can be obtained. In addition, when a good radiographic image can be obtained under past imaging conditions, radiographing can be performed under automatically set past imaging conditions. Can be.
[0062]
【The invention's effect】
According to the first aspect of the present invention, when the same subject is photographed again, the display device for displaying the photographing conditions stored in the storage device when the photographing was performed in the past is provided. The technician can predict the amount of transmitted radiation, the size of the imaging site, and the like in consideration of past imaging conditions. Therefore, it is possible to more easily and accurately predict the amount of transmitted radiation, the size of the imaging region, and the like, so that a radiologist can appropriately set imaging conditions and obtain a good radiation image. .
[0063]
According to the second aspect of the present invention, the radiographic image is displayed on the display device together with the past imaging conditions stored in the storage device when the same subject is imaged again. The imaging conditions can be adjusted based on the correspondence between the radiation images, and a better radiation image can be obtained.
[0064]
According to the third aspect of the present invention, when the same subject is photographed again, the photographing conditions are automatically set based on the photographing conditions stored in the storage device. Appropriate imaging conditions are set automatically without predicting the amount of radiation transmission or the size of the imaging region from external factors such as the body weight, the imaging area, and the results of actually viewing the patient's body shape. A good radiation image can be obtained. In addition, since the imaging may be performed according to the automatically set imaging conditions, it is possible to prevent an input error of the imaging conditions by the radiologist.
[0065]
According to the fourth aspect of the present invention, the past imaging conditions managed by the ordering server are displayed on the display device provided in the radiation image capturing apparatus when the same subject is captured again, so that the radiation The technician can appropriately set the imaging conditions and obtain a good radiation image. In addition, past imaging conditions and imaging reservation information are collectively managed by the ordering server, and are displayed together on a display device provided in the radiation image capturing apparatus when the same subject is captured again. Therefore, since the shooting information in the shooting reservation information and the past shooting conditions are displayed in association with each other, the shooting conditions are appropriately set without error and easily considering the shooting information and the past shooting conditions. be able to.
[0066]
According to the invention described in claim 5, the past imaging conditions and the radiation image managed by the ordering server are displayed on the display device provided in the radiation image capturing apparatus when the same subject is captured again. . Therefore, the radiographing conditions can be adjusted based on the correspondence between the radiographing conditions and the radiographic images, and better radiographic images can be obtained. In addition, past imaging conditions, radiation images, and imaging reservation information are collectively managed by the ordering server, and are simultaneously displayed on a display device provided in the radiation imaging apparatus when the same subject is imaged again. Therefore, since the imaging information in the imaging reservation information and the past imaging conditions and the radiation image are displayed in association with each other, the imaging is performed without error and easily taking the imaging information and the past imaging conditions and the radiation image into consideration. Conditions can be set appropriately.
[0067]
According to the sixth aspect of the present invention, appropriate imaging conditions are automatically set based on past imaging conditions managed by the ordering server, and a good radiation image can be obtained. In addition, since the imaging may be performed according to the automatically set imaging conditions, it is possible to prevent an input error of the imaging conditions by the radiologist.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an embodiment of a radiographic image capturing system according to the present invention.
FIG. 2 is a block diagram showing a configuration of an embodiment of a radiographic image capturing system according to the present invention.
[Explanation of symbols]
1 ordering server
2 Shooting operation terminal
4 Image reading processing device
5 Radiation tube device
6 High voltage generator
7 Aperture device
8 Photo timer
9 Image processing unit

Claims (6)

Radiation image capturing having a radiation tube device for generating radiation, connecting a high voltage generator for applying a high voltage to the radiation tube device, and providing a diaphragm device for adjusting a radiation irradiation field in front of the radiation tube device In the apparatus, at least a storage device for storing imaging conditions necessary for imaging of a radiation image including a tube voltage value and a tube current value used when imaging a radiation image, and the storage device when imaging the same subject again. A radiographic imaging apparatus comprising: a display device that displays stored imaging conditions; and a control device that controls storage of the imaging conditions by the storage device and controls display of the imaging conditions by the display device. apparatus. 2. The storage device according to claim 1, wherein the storage device stores the captured radiation image, and the display device displays the radiation image stored in the storage device when the same subject is captured again. 3. Radiation imaging device. Radiation image capturing having a radiation tube device for generating radiation, connecting a high voltage generator for applying a high voltage to the radiation tube device, and providing a diaphragm device for adjusting a radiation irradiation field in front of the radiation tube device In the apparatus, at least a storage device for storing imaging conditions necessary for imaging of a radiation image including a tube voltage value and a tube current value used when imaging a radiation image, and the storage device when imaging the same subject again. A control device for controlling at least one of a tube voltage value and a tube current value of the high-voltage generating device and an irradiation field diaphragm value of the diaphragm device based on the stored imaging conditions. Radiation imaging device. An ordering server that manages information related to radiographic image capturing is connected to a radiographic image capturing apparatus that captures a radiographic image via a network, and the ordering server captures in advance subject information about a subject and capturing information necessary for capturing a radiographic image. Registered as reservation information, and in the radiographic image capturing system for performing radiography using the radiographic image capturing apparatus based on the radiographic reservation information, the ordering server includes at least a tube voltage value and a tube current used when the radiographic image was captured. A storage device for storing imaging conditions necessary for imaging a radiation image including a value, and a display device for displaying imaging conditions stored in the storage device together with imaging reservation information when imaging the same subject again. A radiographic imaging system, characterized in that: The storage device according to claim 4, wherein the storage device stores the captured radiation image, and the display device displays the radiation image stored in the storage device when the same subject is captured again. Radiation imaging system. An ordering server that manages information related to radiographic image capturing is connected to a radiographic image capturing apparatus that captures a radiographic image via a network, and the ordering server captures in advance subject information about a subject and capturing information about conditions for capturing a radiographic image. Registered as reservation information, and in the radiographic image capturing system for performing radiography using the radiographic image capturing apparatus based on the radiographic reservation information, the ordering server includes at least a tube voltage value and a tube current used when the radiographic image was captured. A storage device for storing imaging conditions necessary for imaging a radiation image including a value, wherein the radiation image imaging device uses a tube voltage based on the imaging conditions stored in the storage device when the same subject is imaged again. Value, tube current value, and / or irradiation field aperture value. Radiographic imaging system characterized in that a control device.

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