JP2002277993A - Inspecting method for radiographic image photographing device, radiographic image photographing device, and abnormality report system for radiographic image photographing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inspecting method for a radiographic image photographing device by which abnormality of the radiographic image photographing device is easily detected, the radiographic image photographing device, and an abnormality report system for the radiographic image photographing device which can speedily report detected abnormality. SOLUTION: For example, statistical processing is performed by using an S value and abnormality of a radiation source 31 or photographing device 10b can be detected from the processing result. Consequently, the trouble of inspecting the radiographic image photographing device can be eliminated by automatically performing the inspection, for example, right after the power source is tuned on without specially taking a test photograph like before. Further, a sign for abnormality occurrence can be read by periodically performing the inspection and the abnormality occurrence to the radiographic image photographing device can be predicted and coped with in advance. Further, the detection result of an abnormality detecting means 10cc can be reported to a maintenance center D, thereby the maintenance center D grasps whether each radiographic image photographing device becomes abnormal and its trends and performs proper processing, so that centralized and efficient management can be performed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a maintenance technique for a radiographic imaging apparatus, and more particularly to a technique for detecting a malfunction of an imaging apparatus of the radiographic apparatus when the malfunction occurs.

[0002]

2. Description of the Related Art There is known a radiation image capturing apparatus having a radiation source such as an X-ray source, and an image capturing apparatus for reading out an image by emitting stimulating light from a stimulable phosphor detector excited by the radiation source. Have been. By the way, if any of these radiation sources, stimulable phosphor detectors, and photographing devices are deteriorated or some abnormality occurs in image formation, there is a problem that a normal radiation image cannot be obtained.
Therefore, conventionally, in order to detect these abnormalities, test photography is periodically performed to check whether the photographed image is normal.

[0003]

However, it is cumbersome to perform such test shooting regularly, and if the test is performed according to a schedule on the user side, the test shooting may not be possible or may be forgotten. is there. Further, even if the test imaging is determined to be normal, there is a problem that an abnormality occurring in the radiation imaging apparatus cannot be detected until the next test imaging is performed. Further, if the maintenance center is contacted after the abnormality is discovered, it takes a long time for repair, and during that time, there is a problem that the radiographic imaging apparatus cannot be used.

SUMMARY OF THE INVENTION The present invention relates to a radiographic image capturing apparatus inspection method and a radiographic image capturing apparatus capable of easily detecting an abnormality of a radiographic image capturing apparatus, and a radiation image capturing apparatus abnormality reporting system capable of promptly reporting the detected abnormality. The purpose is to provide.

[0005]

(1) An inspection method of a radiographic image capturing apparatus according to the present invention includes a radiation source and a stimulable phosphor detector on which a latent image is formed by radiation irradiated from the radiation source. In a method for inspecting a radiographic image capturing apparatus, comprising: an image capturing apparatus that obtains image information by irradiating excitation light; statistically processing an analysis value obtained from the image information obtained by the image capturing apparatus; Alternatively, since an abnormality in the imaging device is detected, statistical processing is performed using, for example, an S value as an analysis value, and an abnormality in the radiation source or the imaging device can be detected based on the processing result. Therefore, the inspection of the radiation image capturing apparatus is automatically performed, for example, before use without performing the test capturing as in the related art, thereby eliminating the labor of the inspection. Further, by performing the inspection periodically, it is possible to read the sign of the occurrence of the abnormality, to predict the occurrence of the abnormality of the radiation image capturing apparatus, and to cope with it in advance.

(2) In the inspection method of the radiographic imaging apparatus according to the present invention, the excitation light is irradiated to the radiation source and the stimulable phosphor detector on which the latent image is formed by the radiation irradiated from the radiation source. In a method of inspecting a radiographic image capturing apparatus having an image capturing apparatus for acquiring image information by statistically processing an image capturing information of the radiation source and an analysis value obtained from the image information acquired by the image capturing apparatus. ,
Since the abnormality of the radiation source or the imaging device is detected,
For example, statistically processing using the S value as the analysis value,
An abnormality in the radiation source or the imaging device can be detected based on the processing result. Therefore, the inspection of the radiation image capturing apparatus is automatically performed, for example, before use without performing the test capturing as in the related art, thereby eliminating the labor of the inspection. Further, by performing the inspection periodically, it is possible to read the sign of the occurrence of the abnormality, to predict the occurrence of the abnormality of the radiation image capturing apparatus, and to cope with it in advance.

(3) That is, it is preferable that the analysis value obtained from the image information obtained by the photographing device is an S value.

(4) The radiation image capturing apparatus of the present invention
A radiation source, a photographing device that acquires image information by irradiating excitation light to a stimulable phosphor detector on which a latent image is formed by radiation emitted from the radiation source, and a processing unit, the processing unit comprising: The unit includes a calculating means for calculating the S value, a data storing means for storing the calculated S value, and an abnormality detecting means for detecting an abnormality based on the stored S value. The means can perform, for example, statistical processing using the S value, and detect an abnormality in the radiation source or the imaging apparatus based on the processing result.
Therefore, the inspection of the radiation image capturing apparatus is automatically performed, for example, before use without performing the test capturing as in the related art, thereby eliminating the labor of the inspection. Further, by performing the inspection periodically, it is possible to read the sign of the occurrence of the abnormality, to predict the occurrence of the abnormality of the radiation image capturing apparatus, and to cope with it in advance.

(5) The radiation image capturing apparatus of the present invention
A radiation source, an imaging device for acquiring image information by irradiating excitation light to a stimulable phosphor detector on which a latent image has been formed by radiation emitted from the radiation source, and S
S value calculation data storage means for storing data necessary for calculating a value, S value calculation means for calculating an S value from the stored data, and abnormality detection for detecting an abnormality from the calculated S value Means, the abnormality detecting means can perform, for example, statistical processing using the S value, and detect an abnormality in the radiation source or the imaging apparatus based on the processing result. Therefore, the inspection of the radiation image capturing apparatus is automatically performed, for example, before use without performing the test capturing as in the related art, thereby eliminating the labor of the inspection. Also, by conducting regular inspections,
The sign of the occurrence of an abnormality can be read, and the occurrence of an abnormality in the radiographic image capturing apparatus can be predicted, so that a measure can be taken in advance.

(6) In the abnormality notification system for a radiation image capturing apparatus according to the present invention, the radiation image capturing apparatus is provided with a communication unit, and information on the abnormality detected by the abnormality detection unit is transmitted to the maintenance center via the communication unit. It is convenient because the user does not have to contact the maintenance center by phone or facsimile each time, and the maintenance center can manage the radiation image capturing apparatus intensively and efficiently. It is.

(7) An abnormality notification system for a radiation image capturing apparatus according to the present invention includes a server connected to the radiation image capturing apparatus alone or in plurality via a network, and relates to an abnormality detected by the abnormality detecting means. Since information is acquired from the radiographic image capturing apparatus to the server via the network,
If the server is managed by, for example, a maintenance center, it is not necessary for the user to contact the maintenance center one by one, and the maintenance center can manage a plurality of radiation image capturing apparatuses intensively and efficiently. So convenient.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram of an abnormality notification system of the radiation image capturing apparatus according to the present embodiment. The radiation image capturing apparatuses 10 arranged in the hospitals A to C are connected to a server 20 managed by a maintenance center D via a network N such as the Internet.

FIG. 2 is a diagram showing a network system constructed in hospital A. Note that hospitals B and C have similar systems. In the network system of FIG. 2, three radiation image capturing apparatuses 10, a CT scan 11 via a print link 11a, a history server 12 having a hard disk 12a, two imagers 13, and a data server having a hard disk 14a , The MRL 15 via the print link 15a is LA
N, and via a communication controller 16 to an external server 20. Each radiation image capturing device 10 includes a radiation source 31, a capturing device 10b, and a processing unit 10c.

FIG. 3 is a schematic configuration diagram of the radiation image photographing apparatus. As shown in FIG. 3, the imaging device 10b includes a stimulable phosphor detector 10ba and a stimulable phosphor detector 10ba that form a radiation image based on radiation emitted from the radiation source 31 and transmitted through the subject as a latent image. A scanning semiconductor laser 10bb (red, infrared) that emits excitation light to emit stimulating light in accordance with a latent image; an acrylic concentrator 10bc for condensing and guiding stimulating light; Photomultiplier tube (PMT: photomultiplier) 10bd for electrically amplifying the stimulated photostimulation and a halogen lamp 10be for erasing afterimages
And A signal (image information) from the photomultiplier 10bd of the photographing device 10b passes through a Log amplifier 10bf and an A / D converter 10bg as shown in FIG.
c.

The processing unit 10c includes, in addition to a normal control unit and an image processing unit, an S value calculating unit 10c for calculating an "S value".
a, a data storage unit 10cb for storing the calculated S value predetermined period, and an abnormality detection unit 1 for statistically processing the imaging information of the radiation source 31 and the stored S value to detect an abnormality.
0 cc is provided. The abnormality detected here is an abnormality relating to at least one of the radiation source 31 and the imaging device 10b. It should be noted that it is not possible to identify which device is abnormal in the present embodiment. It is valid. Further, it is possible to effectively estimate which device has failed by combining the rate and time of occurrence of an abnormality for each device. The abnormality detected by the abnormality detecting unit 10cc can be confirmed on the display unit 10cd, and is notified to the server 20 of the maintenance center D (FIG. 1) via the LAN and the communication control unit (communication unit) 16.

[S value] Here, the "S value" is a value indicating the density of an output image obtained as a result of normalization processing when a patient is imaged under a certain imaging condition. This is a value corresponding to the sensitivity of the film required to finish the density set by DL and DH. In this example, the S value is created based on the image of the “ROI” region in FIG. 4 showing, for example, a chest image.

[Shooting Information] In this example, the shooting information of the radiation source 31 referred to by the abnormality detecting means 10cc of the processing unit 10c is all information at the time of shooting. (Front view, etc.) ・ Imaging distance (If there is DICOM information, it is not necessary if the imaging distance is predetermined depending on the imaging part) ・ Radiation dose generated by radiation source 31 (radiation dose is predetermined・ Patient (subject) information (gender, weight (the thickness of the part to be imaged is the best, but the weight is a guide)) ・ Name of the technician ) And so on.

[Statistical processing] In this example, the statistical processing is performed as software processing of the processing unit 10c, which is a known means. For example, statistically comparing the images taken under the same conditions for one year and monitoring the state where the “S value” changes. Is detected, the abnormality detecting means 10cc
Judge. This determination can be made for each number of shots (for example, 1000 shots).

FIG. 5 is a diagram showing a modification of the present embodiment. In the above-described example, the “S value” is calculated for each photographing. However, as in the sub-processing unit 10c ′ shown in FIG. 5, data necessary for calculating the S value (for example, raw image data) Value calculating means 10ca 'for storing a predetermined number of data for a predetermined period of time, and an S value calculating means 10c for periodically calculating the S value from the stored data as necessary.
The b 'and the abnormality detecting means 10cc' are provided separately from the processing unit 10c (or integrally with the processing unit 10c), and the abnormality of the radiation image capturing apparatus can be detected here.

As described above, in this embodiment described above, for example, statistical processing is performed using the S value, and an abnormality in the radiation source 31 or the imaging device 10b can be detected based on the processing result. Therefore, the inspection of the radiation image capturing apparatus is automatically performed, for example, immediately after the power is turned on, without performing the test imaging as in the related art, thereby eliminating the labor of the inspection. Further, by performing the inspection periodically, it is possible to read the sign of the occurrence of the abnormality, to predict the occurrence of the abnormality of the radiation image capturing apparatus, and to cope with it in advance. Further, the abnormality detecting means 10
Since the detection result of cc (10 cc ′) can be notified to the maintenance center D, the maintenance center D determines whether or not each radiation image capturing apparatus has an abnormality.
Centralized and efficient management can be performed by grasping the tendency and performing appropriate processing.

FIG. 6 is a diagram showing a schematic configuration of an imaging system including a radiation image imaging apparatus according to the present embodiment.
As shown in FIG. 6, the radiation imaging apparatus 50 includes an image reading unit 103 and a controller 102.

When an X-ray is emitted from a radiation source (here, an X-ray source) 31 driven by a drive source 32, the image reading unit 103 accumulates a part of the X-ray energy, and then stores the visible light. A plate-like structure in which a stimulable phosphor is laminated on a support using a stimulable phosphor that emits stimulable light in response to accumulated X-ray energy when irradiated with excitation light such as laser light or laser light The stimulable phosphor detector 10ba temporarily stores and records radiation image (X-ray transmission plane image) information of a subject such as a human body by X-rays emitted from the X-ray irradiator 30, and scans with laser light. The stimulated emission light is sequentially emitted, and the stimulated emission light is photoelectrically sequentially read by the photoelectric reading unit 20 to obtain an image signal. Then, the image reading unit 3
Is the stimulable phosphor detector 1 after reading this image signal.
The erasing light is radiated to 0ba to emit the X-ray energy remaining in the detector 10ba to prepare for the next imaging.

The image reading unit 103 converts the radiation image information of the subject P, which is a subject, into the stimulable phosphor detector 10.
ba, a laser light source unit (semiconductor laser) 10bb including a laser diode or the like that generates laser light as excitation light for the stimulable phosphor detector 10ba, and a laser drive circuit 10 for driving the laser light source unit 10bb.
5 and an optical system 1 for scanning the stimulable phosphor detector 10ba with laser light from the laser light source unit 10bb.
07, and a photoelectric reading unit 120 that collects stimulated emission excited by the excitation laser beam, performs photoelectric conversion, and obtains an image signal. The photoelectric reading unit 120 includes a condenser 10bc for condensing stimulated emission excited by the excitation laser beam, and a condenser 1
A current signal from a photomultiplier (photomultiplier tube) 10bd that photoelectrically converts the light condensed by Obc, a high-voltage power supply 10a that applies a voltage to the photomultiplier 10bd, and a current signal from the photomultiplier (photomultiplier tube) 10bd A log amplifier 10bf for amplification, a converter 10bg for converting to a digital signal by current / voltage conversion / voltage amplification / A / D conversion, and a digital signal converted by the converter 10bg. And a processor 10c for transmitting a signal, and transmits a digital signal of the read radiation image information to the controller 102. The processing unit 10c is configured by a RISC processor, and corrects a response delay or unevenness of a digital signal.

The image reading section 103 further includes a halogen lamp 10be for irradiating an erasing light and a halogen lamp 10be for emitting the X-ray energy remaining in the stimulable phosphor detector 10ba after reading the image signal. And a driver 115 for driving. The image reading unit 1
03 denotes a laser drive circuit 105, a high voltage power supply 10a, Lo
The control unit 17 controls the g amplifier 10bf, the conversion unit 10bg, the processing unit 10c, and the driver 115, respectively. Further, the laser light source unit 10b of the image reading unit 103
b, the optical system 107, the condenser 10bc, the photomultiplier 10bd, and the halogen lamp 10be are integrally moved as a sub-scanning unit (not shown) by a ball screw mechanism (not shown) in a sub-scanning direction perpendicular to the laser scanning direction. I do. This sub-scanning unit performs sub-scanning by moving when reading an image, and the halogen lamp 1 while moving back.
The light is erased by emitting 0be.

The controller 102 is a personal computer 2
5, a keyboard 26, and a monitor display unit 27,
The digital signal of the radiation image information received from the image reading unit 103 is temporarily stored in a memory, subjected to image processing, and displayed on the monitor display unit 27 and image processing is controlled in accordance with an operation input from the keyboard 26, The radiographic image information that has been subjected to the image processing is output.

Although the present invention has been described with reference to the embodiments, it should be understood that the present invention should not be construed as being limited to the above-described embodiments, and that modifications and improvements can be made as appropriate. is there. Radiation refers to, for example, X-rays, but is not limited thereto.

[0027]

According to the present invention, there is provided an inspection method for a radiographic image capturing apparatus and a radiographic image capturing apparatus capable of easily detecting an abnormality of the radiographic image capturing apparatus, and a radiographic image capturing apparatus capable of promptly reporting the detected abnormality. An abnormality notification system can be provided.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of an abnormality notification system of a radiation image capturing apparatus according to the present embodiment.

FIG. 2 is a diagram showing a network system constructed in hospital A.

FIG. 3 is a schematic configuration diagram of a radiographic image capturing apparatus.

FIG. 4 is a diagram illustrating an example of a chest image.

FIG. 5 is a diagram showing a modification of the present embodiment.

FIG. 6 is a diagram illustrating a schematic configuration of an imaging system including a radiation image imaging apparatus according to the present embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Radiation imaging apparatus 31 Radiation source 10b Imaging apparatus 10c Processing unit 16 Communication control unit 20 Server

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Claims (7)

[Claims] 1. A radiation system comprising: a radiation source; and an imaging device that acquires image information by irradiating excitation light to a stimulable phosphor detector on which a latent image is formed by the radiation emitted from the radiation source. In the inspection method of the image capturing apparatus, a radiation image capturing apparatus that statistically processes an analysis value obtained from the image information acquired by the image capturing apparatus, and detects an abnormality of the radiation source or the image capturing apparatus. Inspection methods. 2. A radiation system comprising: a radiation source; and an imaging device configured to acquire image information by irradiating excitation light to a stimulable phosphor detector on which a latent image is formed by the radiation emitted from the radiation source. In the inspection method for an image capturing apparatus, statistically processing imaging information of the radiation source and an analysis value obtained from the image information acquired by the imaging apparatus, and detecting an abnormality of the radiation source or the imaging apparatus. A method for inspecting a radiographic image capturing apparatus, comprising: 3. The method according to claim 1, wherein the analysis value obtained from the image information acquired by the imaging device is an S value. 4. A radiation source, a photographing device for acquiring image information by irradiating excitation light to a stimulable phosphor detector on which a latent image is formed by radiation irradiated from the radiation source, and a processing unit. Wherein the processing unit includes: a calculating means for calculating an S value; a data storing means for storing the calculated S value; and an abnormality detecting means for detecting an abnormality based on the stored S value. A radiographic imaging device characterized by the above-mentioned. 5. A radiation source, a photographing device for acquiring image information by irradiating excitation light to a stimulable phosphor detector on which a latent image is formed by radiation radiated from the radiation source; S value calculation data storage means for storing data required for calculation, S value calculation means for calculating an S value from the stored data, and abnormality detection means for detecting an abnormality from the calculated S value. A radiographic imaging apparatus comprising: 6. A radiation image capturing apparatus according to claim 4, further comprising a communication unit, wherein information relating to the abnormality detected by said abnormality detection unit is transmitted to a maintenance center via said communication unit. Abnormality notification system of the radiation image capturing apparatus. 7. A radiation image capturing apparatus according to claim 4 or 5, comprising a server connected alone or in plurals via a network, wherein information on the abnormality detected by said abnormality detecting means is transmitted via said network. An abnormality notification system for a radiation image capturing apparatus, wherein the abnormality notification system is obtained from the radiation image capturing apparatus by the server.