KR20170111675A - An apparatus for radiation dose measurement of examinee and method managing radiation dose - Google Patents

Abstract

The present invention relates to an apparatus for measuring X-ray exposure of a subject and a method of managing the same, which comprises an X-ray generator 1, a detector 2 for detecting an X-ray amount transmitted from the X- And a comparator 30 for filtering the signal output from the scintillator amplifiers 10 and 20 to a predetermined intensity or more. The scintillator 10 and 20 detect the X- ), Counts pulses of the X-rays filtered by the comparator 30 and integrates them as an X-ray dose, subtracts the X-ray amount detected by the detector 2 with respect to the total X-ray dose generated by the X-ray generator 1 A processor 40 for calculating the X-ray dose of the subject by calculating the X-ray dose of the subject, and an X-ray exposure dose calculation unit 40 for calculating the X- Seconds The amount of exposure when the subject undergoes various X-ray inspections can be accurately measured, and the X-ray dose measurement value is cumulatively managed The annual cumulative X-ray exposure dose and the cumulative dose amount over a five-year period of time that each person undergoes during the various examinations are calculated and managed, thereby effectively preventing the problem caused by the excessive amount of radiation exposure of the subject.

Description

TECHNICAL FIELD [0001] The present invention relates to an X-ray exposure measuring apparatus and a method for managing an X-

The present invention relates to an apparatus for measuring X-ray dose of a subject and an exposure control method thereof, and more particularly to an X-ray exposure measuring apparatus and an exposure control method for accurately measuring a radiation exposure amount to be received by an examinee during an X-ray examination and cumulatively managing the measured exposure amount, And more particularly, to an apparatus and method for managing X-ray exposure dose of a subject to prevent the occurrence of an excessive amount of trouble.

Generally, radioactive contamination is caused by contamination by radioactive waste flowing from a nuclear facility or radioactive material handling workshop or a laboratory, and alpha (alpha), beta, gamma rays emitted from radioactive material are excessively exposed to human body The tissue can be damaged or altered, and the damage is most severe in tissues or organs with intense cell division. It is especially affected by germ cells and can cause genetic modification. Therefore, there is a risk that a deformed child is born and causes cancer.

In particular, X-ray inspection, which is an indispensable element in modern medical fields among various radiations, is a method of transmitting X-rays through a human body, a photographic action of delamination of a film, a fluorescence function of emitting fluorescence corresponding to a fluorescent substance, The X-ray inspection makes it possible to accurately determine the internal structure and the lesion formed thereon without damaging the human body by X-ray inspection.

Depending on the purpose of the diagnosis, there are various methods of taking an X-ray. In the simple imaging method, the X-ray differs depending on the kind and density of the material constituting the human body. As a difference in concentration. As another example, there is a tomographic method in which a plurality of shadows overlap each other to constitute one image because the X-ray image is in the form of a transmission line, and a computerized tomography (CT examination) in which a tomographic image of a human body tomography, and PET-CT.

These X-ray examinations are widely used in the medical field for various diagnostic purposes, so one person may be subjected to multiple X-ray examinations.

However, this X-ray is also one of the strictly regulated radiations. Especially in the chest x-ray examination, the dose is 0.02 mSv. However, in the chest CT examination, the dose is 8 mSv, the head and neck CT is 2 mSv, , Coronary angiography (18 mSv), whole-body screening CT, radiation dose from 12 mSv up to 25 mSv, and so on.

The natural radiation dose to humans in the natural environment is 2.4 mSv per year on average worldwide. The effect of such a small amount of radiation on the human body is negligible, but a large amount of radiation is harmful to the human body and cumulative exposure dose can cause serious problems such as lymphocyte reduction, leukocytosis, increased cancer incidence, and infertility. As a result, people who work in the environment handling radiation materials need to strictly control their exposure levels, so that the radiation exposure limit for one year is 50 mSv and the exposure limit for 5 years is 100 mSv .

The amount of radiation that biologically affects the body is caused by radiation systemic exposure, 1 Sv causes some blood changes, 2-5 Sv causes nausea, hair loss, bleeding and, in many cases, death. More than 80% of deaths in 6 months or more within 2 months, and the lowest level of carcinogenicity is known to be 100 mSv / year.

Accordingly, in domestic registered patent No. 10-1574076 (registered on Nov. 27, 2015), it is judged whether a worker carrying out the work of radiation material compares the radiation safety equipment with the work clothes and the wrist as prescribed, A safety and radiation exposure management system of a radiation worker is provided, which can monitor and monitor a worker in a safe state, and can transmit and manage various signals to a worker.

However, there is no control on the general subject or patient radiation dose under X-ray inspection, and there are no specific rules governing the assessment of radiation dose, but the monitoring equipment is very expensive, There is no need to manage cumulative radiation dose during the diagnosis process.

Domestic Registration No. 10-1574076 (registered on Nov. 27, 2015)

An object of the present invention is to provide an X-ray dose measuring device for measuring an accurate exposure amount in an X-ray inspection in order to solve the problem of the X-ray exposure amount of the prior art.

Another object of the present invention is to provide a database (DB) for the amount of exposure of a subject at the time of examination at various hospitals using the X-ray exposure measuring apparatus described above, cumulatively managing the same, And to provide a method for managing exposure dose.

According to an aspect of the present invention, there is provided an apparatus for measuring X-

An X-ray generator, and flash detection devices for detecting X-rays and outputting a signal, the X-ray generator being disposed adjacent to a detector for detecting an X-ray dose transmitted to the subject by the X-

A comparator for filtering the signal outputted from the flash detection device to a predetermined intensity or more,

 A processor for counting X-ray pulses filtered by the comparator and accumulating the X-ray dose as an X-ray dose and calculating an X-ray dose of the subject by subtracting the X-ray dose detected by the detector with respect to the total X-ray dose generated by the X- .

The first flash detection device among the flash detection devices is disposed in front of the X-ray generator and measures the total X-ray dose generated. The second flash detection device is disposed immediately in front of the dry plate as the detection section, and measures the X- do.

The scintillation amplifying apparatus comprises a scintillator panel formed in a plate shape having a predetermined thickness to minimize absorption of X-rays in the scintillator, and a scintillator panel having a plurality of scintillator panels, each scintillator panel including a plurality of scintillator panels for detecting the number and intensity of visible light generated in the scintillator, And the like.

And an exposure amount management unit for receiving the X-ray exposure data calculated by the processor and cumulatively adding the individual X-ray exposure amounts of the subject for a preset period of time and managing the individual X-ray exposure tolerance limits.

Wherein the processor counts pulses by the X-ray filtered by the comparator and accumulates the X-ray dose as an X-ray dose, and calculates an X-ray dose in a second flash detector on a dry plate side at a total X-ray dose (SC1) SC2) is calculated as the X-ray exposure amount of the subject.

The method for managing X-ray exposure of a subject according to the present invention comprises the steps of (S1) measuring X-ray dose at the photoexhausts of the flash multiplication devices installed in the X-ray inspection apparatus,

(S2) of removing noise due to natural radiation from the signal of the photoacoustic exhaustes measured in the step (S1)

A step (S3) of calculating a net exposure amount of the X-ray to be exposed by the subject by subtracting an X-ray dose (SC2) obtained by measuring the X-ray dose passed through the human body from the total X-ray dose (SC1) emitted from the X-

(S4) accumulating the X-ray dose and the past exposure amount cumulatively in the individual radiation exposure history calculated in the step (S3)

(S5) of summing the individual X-ray exposure amounts calculated in the step (S4) and transmitted from the individual hospitals and managing whether or not the X-ray exposure amount exceeds a preset cumulative dose reference value.

The X-ray exposure measuring apparatus of the present invention has an effect of accurately measuring the amount of exposure when the subject receives various X-ray inspections. The cumulative X-ray exposure measurement values are cumulatively managed, and the annual radiation accumulation The amount of exposure and the cumulative amount of exposure for 5 years are calculated and managed, thereby effectively preventing the problem caused by the excessive amount of radiation exposure of the subject.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the arrangement of a flash detector of an X-ray exposure measuring apparatus according to the present invention; FIG.
2 is a schematic configuration diagram of an X-ray dose measuring apparatus according to the present invention.
FIG. 3 is a schematic block diagram of a method for managing cumulative X-ray exposure dose using the X-ray dose measuring apparatus of FIG. 2;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown.

1, an X-ray exposure measuring apparatus according to the present invention comprises an X-ray generator 1, a flash (not shown) disposed adjacently to a detector 2 for detecting an X-ray amount transmitted from the X- (10, 20). The detection unit 2 may be a dry plate on which X-rays transmitted through the subject are photographed. The flash multiplication device 10 measures the total amount of X-rays generated in front of the X-ray generator 1, while the flash multiplication device 20 is disposed immediately in front of the dry plate to measure the X- .

In some cases, the flash detection device 10 may be placed closer to the X-ray generator than the subject, and the flash detection device 20 may be disposed on the dry plate side closer to the subject to measure the X-ray amount transmitted through the subject.

The total X-ray dose detected by the flash multiplication device 10 means the total X-ray dose generated by the X-ray generator 20. When the X-ray dose transmitted through the subject detected by the flash multiplication device 20 is subtracted, Refers to the amount of X-rays absorbed or reflected from the body and repelled or refracted, that is, interacting with the human body. Since such an exposure dose may be more harmful to the human body than it is transmitted through the human body, To measure the total exposure dose.

The scintillation multiplication devices include a scintillator panel formed in a plate shape having a predetermined thickness, for example, 2 to 4 mm in thickness to minimize X-ray absorption in the scintillator, and a scintillator panel in which the number and intensity of visible light generated in the scintillator For example, an SIPM or a PMT, as the light emitters 11 and 21 connected to the scintillator panel for detection.

2, the number and intensity of the X-rays emitted from the X-ray generator 1 are detected and amplified by the photodiode 11 of the flash multiplication apparatus 10 and then converted into an electrical signal, The number and intensity of the X-ray transmitted through the human body are detected and amplified in the photo-exhaust 21 of the flash multiplication device 20 disposed in front of the human body 2.

The signals output from the photo-exhaust devices 11 and 21 of the flash multiplication device are filtered by the comparator 30 to a predetermined intensity or more. This eliminates the signal as a noise that detects scintillation in the scintillator by natural radiation, And outputs the detected signal as a pulse signal.

The signal of each of the photo-evacuators 11 and 21 filtered by the comparator 30 is obtained by counting pulses by the X-ray filtered by the processor 40 and integrating them as an X-ray dose, The amount of exposure calculated for the subject is stored in the database DB in correspondence with the ID of the subject that has been input in advance, and the dose is calculated by subtracting the X-ray dose SC2 from the SCR1 from the SCR1 Then, the dose is transferred to the exposure control unit 50.

The X-ray dose management method of the subject using the X-ray exposure dose measuring apparatus will be described with reference to FIG.

First, in step S1, the X-ray dose is measured by the photodiodes 11 and 21 of the flash multiplication apparatuses 1 and 2 provided in the X-ray inspection apparatus. In step S2, noise due to natural radiation is removed from the signals of the flash detectors measured in step S1, and the X-ray amount generated in the pure X-ray inspection apparatus is measured.

In step S3, the X-ray dose SC2 obtained by measuring the X-ray dose passed through the human body is subtracted from the total X-ray dose SC1 radiated from the X-ray generator in the processor 40 to calculate the exposed X-ray dose of the subject , And the cumulative sum of the amount of exposure and the amount of exposure in the past in individual histories of the subject are cumulatively stored in DB (step S4). It is preferable that the DB is managed by each hospital and each individual is informed of the amount of exposure by X-ray inspection.

It is preferable that the X-ray dose measuring device is installed in X-ray examination devices installed in each hospital, and each hospital can manage the X-ray dose measured by a plurality of X-ray examination devices to each patient And transmits the dose data to the radiation dose management unit 50, which is managed by an authorized institution outside the hospital, for the patients measured by the X-ray examination apparatuses of the respective hospitals.

In the individual hospital, the dose data by the X-ray inspection of individual subjects who have undergone X-ray inspection at the hospital is transmitted to the management unit 50.

Then, in step S5, the management unit 50 sums individual X-ray exposure amounts transmitted from the individual hospitals and manages whether or not the X-ray exposure amount exceeds a preset cumulative dose amount reference value. The management unit, as an authorized institution, It may be a health insurance management corporation that carries out public health management, or it may be a separate exposure management institution.

The dose management unit 50 accumulates the X-ray dose in the diagnosis process in various hospitals to the subjects transmitted from various hospitals and accumulates the X-ray dose in the diagnosis process for a preset period of time, for example, The radiation dose can be calculated and notified so as to be efficiently managed so as to prevent the individual subject from being exposed to excessive radiation exposure.

The present invention can be used to prevent exposure to excessive radiation exposure of the subject by measuring and cumulatively managing the individual X-ray dose of the subject for X-ray examination accompanying various medical diagnosis processes.

1: X-ray generator 2: detector
10, 20: flash detector 11, 21:
30: comparator 40: processor
50: Exposure management

Claims (7)

An X-ray generator (1) is provided, which is disposed adjacent to a detection unit (2) for detecting an X-ray amount transmitted from an X-ray generator to an examinee, and outputs X- (10, 20)
A comparator 30 for filtering the signal outputted from the scintillation amplifiers 10 and 20 to a predetermined intensity or more,
The pulses from the X-ray filtered by the comparator 30 are counted and accumulated as an X-ray dose. The X-ray dose detected by the detector 2 is subtracted from the total X-ray dose generated by the X-ray generator 1, And a processor (40) for calculating an X-ray dose of the subject.
The method according to claim 1,
The flash multiplication device 10 measures the total amount of X-rays generated by the X-ray generator 1, and the flash multiplication device 20 is disposed immediately in front of the dry plate as a detection part, Wherein the X-ray dose measuring unit measures the X-ray dose of the subject.
3. The method of claim 2,
Each of the scintillation amplifiers 10 and 20 includes a scintillator panel formed in a plate shape having a predetermined thickness so as to minimize X-ray absorption in the scintillator, and a scintillator panel in which the number and intensity of visible light generated in the scintillator are detected Ray detector (11, 21) connected to the scintillator panel to measure the X-ray dose of the subject.
The method according to claim 1,
An exposure amount management unit 50 that receives the X-ray exposure data calculated by the processor 40 and cumulatively adds an X-ray exposure amount for each subject for a preset period of time and manages the individual X- Further comprising an X-ray detector for measuring X-ray dose of the subject.
The method of claim 3, wherein
The processor 40 counts pulses of the X-ray filtered by the comparator 30 and integrates them as an X-ray dose and calculates X And the dose (SC2) is subtracted from the X-ray dose (SC2).
The method according to claim 1,
The flash detection device 10 measures the X-ray dose irradiated to the subject placed close to the subject between the X-ray generator 1 and the subject, while the flash detection device 20 measures the amount of X- And the X-ray dose transmitted through the subject is measured.
(S1) of measuring the X-ray dose in the photo-evacuating apparatuses 11 and 21 of the flash multiplication apparatuses 1 and 2 installed in the X-ray inspection apparatus,
(S2) of removing noise due to natural radiation from the signal of the photoacoustic exhaustes measured in the step (S1)
A step (S3) of calculating an X-ray dose to be exposed by the subject by subtracting an X-ray dose (SC2) obtained by measuring the X-ray dose passed through the human body from the total X-ray dose SC1 emitted from the X-
(S4) accumulating the X-ray dose and the past dose by cumulatively accumulating in the individual history of the subject calculated in the step (S3)
(S5) managing whether or not an individual X-ray exposure amount calculated in the step (S4) and transmitted from individual hospitals is added and exceeds a preset cumulative dose amount reference value.

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