KR20100069255A - A radiation detector capable of detecting the direction of radiation source - Google Patents

Abstract

PURPOSE: A radiation measuring apparatus is provided to measure the dose of radiation by rotating a radiation shielding part along the outer periphery of a radiation detector. CONSTITUTION: A radiation measuring apparatus comprises a radiation detector(100), a radiation shielding part(110), a driving part, a display part or a storage part. The radiation detector measures the dose of radiation. The radiation shielding part has a cylindrical shape. The radiation shielding part surrounds the radiation detector. An opening(112) is formed in one side of the radiation shielding part. The driving part controls the rotation of the radiation shielding part. The display part or the storage part displays or stores the dose of radiation and a direction of radiation source.

Description

A radiation detector capable of detecting the direction of radiation source

The present invention relates to a radiation measuring apparatus capable of measuring a direction of a radiation source, and more particularly, provided with a cylindrical radiation shield configured to be rotatable in a form surrounding the radiation detector outside the radiation detector, on one side of the radiation shield. A radiation measuring device capable of measuring radiation while measuring the radiation dose in the measurement zone by measuring openings by rotating the radiation shielding body by forming an opening, and measuring a direction in which a radiation source from which radiation is being emitted is measured. It is about.

As nuclear power and related industries are greatly developed, the danger of radiation such as alpha, beta, and gamma rays emitted from radioactive materials is highlighted, and safety of people working in the nuclear field and radiation safety of related facilities are becoming important.

Therefore, research and development of a measuring device for measuring and monitoring radiation accurately and precisely is necessary to secure the safety of the nuclear industry.

Numerous radiation measuring devices have been developed and marketed to measure the radiation dose and intensity of radiation in high-level radiation zones (hereinafter referred to as 'radiation zones') in hospitals, schools, and research laboratories including nuclear power plants. As the related industry continues to expand, research and development on accurate and accurate radiation measuring devices are urgently needed.

Commonly used radiation measuring apparatuses include Geiger counters and survey meters that target radiation such as alpha, beta, gamma rays, and the like.

In the case of a Geiger counter, a device is used to collect the generated ion pairs and measure the radiation dose and radiation intensity by using the point that the gas in the vicinity is ionized by the radiation emitted from the measurement object to generate the ion pair.

On the other hand, the survey meter includes scintillators that absorb radiation and generate visible light, and a photoelectric converter that converts the generated visible light into an electric signal. It is a device for measuring quantity.

However, these radiation measuring devices focus on measuring the total amount of radiation and the intensity of the radiation, and are not suitable for tracking the direction of the radiation source that leaks the radiation.

Therefore, in order to track the direction of the radiation source that leaks the radiation, a worker wearing a personal exposure dosimeter enters the radiation zone and checks the direction of the radiation source. Tracking is not only time consuming, but also requires a lot of manpower, in particular an operator may be exposed to high-level radiation.

Therefore, there is a need for a radiation measuring apparatus having a new structure that can prevent a worker from being exposed to radiation and can simultaneously measure the amount of radiation and the direction in which the radiation source is present.

The present invention is to solve the problems of the prior art, provided with a form surrounding the radiation detector outside the radiation detector for detecting radiation, provided with a cylindrical radiation shield having an opening on one side the radiation shield is radiation By being configured to be rotatable along the outer diameter of the detector, the radiation source incident to the opening can be measured as the shield rotates, and the direction of the radiation source capable of measuring the presence direction of the radiation source from which the radiation is being emitted can be measured. Its purpose is to provide this possible radiation measuring device.

The present invention as a technical concept for achieving the above object, the radiation detection unit for measuring the dose of the incident radiation, and a cylindrical radiation shielding body is formed in the form surrounding the outside of the radiation detection unit formed on one side It is configured, the radiation shield is configured to be rotatable, by measuring the dose of radiation incident through the opening in accordance with the rotation of the shield provides a radiation measuring apparatus characterized in that the direction of the radiation source can be measured. .

Radiation source direction measuring apparatus according to the present invention, by providing a rotatable radiation shield having an opening on one side outside the radiation detection unit, while measuring the radiation dose in various radiation environments, at the same time the radiation line measured through the opening formed on one side It is also possible to measure the direction of the radiation source that is emitted and leaked.

In addition, the apparatus for measuring the direction of the radiation source according to the present invention is configured to remotely monitor data on the radiation dose change and the direction of the radiation source measured from the radiation detector, thereby preventing an operator from being exposed to radiation. It also has the effect of minimizing the time and manpower required to detect the emission and leakage of radiation.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the structure of a radiation measuring apparatus capable of measuring the direction of a radiation source according to an embodiment of the present invention.

As shown in FIG. 1, a radiation measuring apparatus capable of measuring a direction of a radiation source according to the present invention includes a radiation detector 100 for measuring a dose of radiation incident from a radiation measuring zone, and an outside of the radiation detector 100. Is configured to be rotatable in the form surrounding the configuration is configured to include a cylindrical radiation shield 110 formed with an opening 112 on one side.

The radiation detector 100 may be configured with radiation measuring devices such as a Geiger counter or survey meter for detecting the total amount of radiation and the intensity of the radiation in a nuclear-related industrial environment.

An opening 112 is formed at one side of the radiation shield 110, and radiation is incident only through the opening 112, and radiation is blocked at the remaining portions except the opening 112, and radiation is incident on the radiation detector 100. It cannot be configured.

In addition, the radiation shield 110 is configured to rotate outside the radiation detection unit 100, it is possible to determine the location of the source of radiation according to the dose of radiation measured through this configuration.

In other words, when the radiation is measured while rotating the shield 110, the radiation is incident while the position of the opening 112 formed on one side is changed to measure the change in the radiation dose at the corresponding position, the radiation dose is rapidly increased The location of the opening 112 when measured to be can be estimated in the direction in which the radiation source is present.

The radiation shield 110 may be configured to connect a separate rotation means so that the operator can measure the radiation while rotating manually, and in a work environment where it is cumbersome to rotate manually by the operator to rotate the radiation shield 110 A control unit (not shown) may be further provided to measure the radiation dose and the direction of the radiation source while continuously or periodically rotating the shield 110.

In addition, the radiation measuring apparatus further includes a display unit (not shown) or a storage unit (not shown) capable of displaying or recording the measured radiation dose and the result of the measurement of the direction of the radiation source. May be facilitated.

Through such a configuration, the radiation measuring device can be fixedly installed in a radiation measuring zone of various environments, or an operator can measure and confirm the radiation dose and the direction of existence of the radiation source while moving the radiation measuring device using a moving mechanism.

2 is a view showing the configuration of a radiation measuring apparatus capable of measuring the direction of the radiation source according to the second embodiment of the present invention.

As shown in FIG. 2, the radiation measuring apparatus capable of measuring the direction of the radiation source of the present invention surrounds the radiation detector 200 and the outside of the radiation detector 200 that measure the dose of radiation incident from the radiation measurement zone. Is configured to be rotatable in the form is a cylindrical radiation shield 210 having an opening 212 formed on one side, the driving unit 220 is connected to the radiation shield 210 to rotate the radiation shield 210 continuously or periodically and The communication unit 230 receives a control signal from an external device 300 located in a space where there is no danger of radiation, controls the driving unit 220, and transmits data on the measured radiation dose and the direction of the radiation source to the external device 300. It is configured to include).

The communicator 230 receives a control signal for controlling the operation of the radiation detector 200 and the driver 220 of the apparatus from the external device 300, and measures the radiation dose and the radiation source measured through the radiation detector 200. The measurement data for the presence direction is converted into digital data and transmitted to the external device 300.

The communication unit 230 may transmit and receive the control signal and the measurement data by wire through a signal line connected to the external device 300 or wirelessly through a short range wireless communication means such as Bluetooth, Zigbee, or the like.

The external device 300 transmits a control signal for controlling the operations of the radiation detector 200 and the driver 220 of the radiation measuring apparatus installed in the measurement zone, and receives communication data from the communication unit 230. Module (not shown), a microprocessor (not shown) capable of monitoring radiation dose change and radiation source direction information, and a recording device (not shown) capable of continuously recording the information. .

The radiation measuring device having such a configuration controls the operator to measure the radiation dose and the direction of the radiation source by remote control in a safe place without directly accessing and measuring the radiation zone where the risk of overexposure to the radiation is high. It is very suitable for receiving measurement results.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

1 is a perspective view showing the structure of a radiation measuring apparatus capable of measuring the direction of a radiation source according to an embodiment of the present invention.

2 is a view showing the configuration of a radiation measuring apparatus capable of measuring the direction of the radiation source according to a second embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100, 200: radiation detector 110, 210: radiation shield

112 and 212: opening portion 220: driving portion

230: communication unit 300: external device

Claims (4)

In the radiation measuring apparatus capable of measuring the direction of the radiation source, A radiation detector for measuring a dose of incident radiation; And A cylindrical radiation shield configured to surround the outside of the radiation detector and having an opening formed at one side thereof; Consists of including The radiation shield is configured to be rotatable, the radiation measuring device characterized in that the direction of the radiation source can be measured by measuring the dose of radiation incident through the opening in accordance with the rotation of the shield. The method of claim 1, The radiation measuring device, And a driving unit for controlling the rotation of the radiation shield. The method of claim 1, The radiation measuring device, And a display unit or a storage unit which can display or record a measurement result of the radiation dose measured by the radiation detection unit and the direction of the radiation source. 3. The method of claim 2, The radiation measuring device, And a communication unit configured to receive a control signal for controlling operations of the radiation detector and the driver from the outside, and to transmit data on the radiation dose and the direction of the radiation source measured by the radiation detector to the outside. Radiation measuring device.

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