KR200431207Y1 - An automatic apparatus for detecting radioactive - Google Patents

Abstract

The present invention relates to an automatic radiation measuring apparatus, the main body 10, the upper and lower guide rails 11, 12 are installed to be spaced apart in the horizontal direction therein; Upper and lower horizontal moving parts 21 and 22 moving along upper and lower guide rails 11 and 12; Shaft portion 30 is installed between the upper and lower horizontal moving parts (21, 22); A rotating part 40 installed on the upper horizontal moving part 22 or the lower horizontal moving part 21 to rotate the shaft part 30 in the left and right directions; A support follower 50 extending forward as being elevated along the shaft portion 30; A cylinder 60 installed at an end of the support follower 50; It is installed on the cylinder rod 61 of the cylinder 60, the detection unit 70 for measuring the surface dose rate; characterized in that it comprises a.

Description

An automatic apparatus for detecting radioactive

1 is a perspective view of an automatic radiation measuring apparatus according to the present invention.

<Description of Signs of Major Parts of Drawings>

10 ... main body 11, 12 ... upper and lower guide rails

13 ... Enter key 14 ... Distance display

15 ... radiation dose display 16 ... wheels

21, 22 ... horizontal moving part

30 ... shaft 31 ... guide groove

40 ... The Society 50 ... Supporters

51 ... Main Supporters 52 ... Sub Supporters

53 ... cylinder support follower 55 ... water gauge

60 ... cylinder 61 ... cylinder rod

70 ... detector 80 ... transmitter

The present invention relates to an automatic radiation measuring apparatus for automatically measuring the surface dose rate of the surface of the water.

In nuclear power plants, nuclear fission reactions produce electricity, and the fission-producing material is used in nuclear fuel assemblies. The spent nuclear fuel assembly then generates a high level of radiation, and the spent nuclear fuel assembly is typically stored and stored in water so that the high level radiation does not leak to the outside. The place where the spent fuel assembly is stored and stored is called a spent fuel pool (SFP).

The legislation requires that the surface dose rate (radiation rate at a distance of 10 cm from the surface) of the surface of the SFP cannot exceed 0.25 mrem per hour. Therefore, the surface dose rate is periodically measured so that the surface dose does not exceed 0.25 mrem. After the detection part of the radiometer is estimated at about 10 cm from the water surface, the surface dose rate is measured.

By the way, it was very difficult to visually identify the height of about 10 cm from the surface of the water, and thus the reliability of the measurement was deteriorated because the measurement was made by guesswork.

In addition, if a mistake is made, the detector of the radiometer may come into contact with water, which may contaminate the radiometer and cause the detector, which is a precision instrument, to fail.

And since the radiation dose rate of SFP changes for various reasons, it is necessary to monitor whether the reference value is exceeded in real time, but now it is monitored daily, so if it is exceeded, it takes at least one day to recognize it. there was.

The present invention was created to solve the above problems, to provide an automatic radiation measuring device that can automatically measure the surface dose rate at exactly 10 cm from the surface of the SFP.

Another object of the present invention is to provide an automatic radiation measuring apparatus capable of fundamentally eliminating contamination as well as the cause of failure by preventing the detection portion from contacting water.

Still another object of the present invention is to provide an automatic radiation measuring apparatus that can provide information for prompt response when the surface dose rate is exceeded in real time by measuring the surface dose rate in real time.

In order to achieve the above object, the automatic radiation measuring apparatus according to the present invention,

A main body 10 provided with upper and lower guide rails 11 and 12 spaced apart from each other in a horizontal direction; Upper and lower horizontal moving parts 21 and 22 moving along the upper and lower guide rails 11 and 12; A shaft portion 30 installed between the upper and lower horizontal moving portions 21 and 22; A rotating part (40) installed in the upper horizontal moving part (22) or the lower horizontal moving part (21), for rotating the shaft part in the left and right directions; A support follower 50 extending forward as being elevated along the shaft portion 30; A cylinder (60) installed at an end of the support follower (50); And a detection unit 70 installed on the cylinder rod 61 of the cylinder 60 to measure a surface dose rate. At this time, it is installed in the main body 10, and further includes a transmitter 80 for transmitting the surface dose rate data measured by the detector 70 to the outside.

In the present invention, the support follower 50, the main support follower 51 which is installed to be elevated along the shaft portion 30, and is protruded from the main support follower 51 by extending forward A sub support follower 52 and a cylinder support follower 53 which extends forward by being released from the sub support follower 52 and supports the cylinder 60 on which the detection unit 70 is installed.

In the present invention, the main body 10 is provided with a distance display unit 14 for displaying the moving distance or the distance from the water surface of the detection unit 70 moved forward by the support follower 50.

In the present invention, the main body 10 is provided with a radiation dose display unit 15 for displaying the surface dose rate measured by the detection unit 70.

In the present invention, the support follower 50 is provided with a water level meter 55 for measuring the distance between the detection unit 70 and the water surface to generate a related signal. In this case, the water level meter 55 is implemented using a laser generating element and a sensor.

In the present invention, the wheel 16 for the movement of the main body 10 is installed below the main body 10.

Hereinafter, with reference to the accompanying drawings, an automatic radiation measuring apparatus according to the present invention with reference to the accompanying drawings will be described in detail.

1 is a perspective view of an automatic radiation measuring apparatus according to the present invention.

As shown, the radiometer according to the present invention, the main body 10 is installed in the upper and lower guide rails (11, 12) spaced apart in the horizontal direction therein; Upper and lower horizontal moving parts 21 and 22 moving along upper and lower guide rails 11 and 12; A shaft portion 30 installed between the upper and lower horizontal moving portions 21 and 22; Rotating portion 40 for rotating the shaft portion 30 in the left and right direction, which is installed in the upper horizontal moving portion 22 or the lower horizontal moving portion 21, in the present embodiment, the lower horizontal moving portion 21. ; A support follower 50 extending forward as being elevated along the shaft portion 30; A cylinder 60 installed at an end of the support follower 50; A detection unit (70) installed on the cylinder rod (61) of the cylinder (60) for measuring the surface dose rate at the surface of the SFP; It includes a transmitter 80 for transmitting data corresponding to the surface dose rate measured to the outside.

At this time, it is preferable that the support follower 50 has a structure that can be extended to move the cylinder 60 in which the detector 70 is installed forward. There are various methods for implementing this, in the present embodiment, the main support follower 51 which is installed to move up and down along the shaft portion 30, and the sub support follower extending forward by being protruded from the main support follower 51. It is explained by way of example that it is composed of a 52 and a cylinder support follower 53 which extends forward by coming out of the sub support follower 52 and supports the cylinder 60 on which the detection unit 70 is installed.

A predetermined portion of the main body 10 has a power switch S1 for applying power, the upper and lower horizontal moving parts 21 and 22, the rotating part 40, the support follower 50, and the cylinder ( 60, various switches S2 are organically connected to the detector 70 and the transmitter 80 to control them.

In addition, the upper portion of the main body 10 is a command for causing the support follower 50 to move up and down along the shaft portion 30 to move the detector 70 from the surface to a predetermined height, or to move the detector 70 forward. An input key 13 for inputting a command for extending the support follower 50 or a command for driving the pivoting unit 40 to rotate the support follower 70 is installed.

In addition, in front of the main body 10, as the support follower 50 extends, when the detector 70 moves forward or the height changes from the water surface, a distance display unit for displaying the height of the detector 70 from the water surface ( 14) is installed.

In addition, the support follower 50 is provided with a detector 70 and a water gauge 55 for measuring the distance from the water surface. The water level gauge 50 automatically measures the distance to the water surface and generates a related signal, and this signal is used as a signal for causing the support follower 50 for supporting the detector 70 to be elevated along the shaft 30. . The water level gauge 55 may be implemented in various ways. In the present embodiment, the water level gauge 55 is implemented by installing a laser generating element and a sensor in the level gauge. The laser generated from the laser generating element is reflected by the water and then received by the sensor. At this time, the distance from the laser to the received light after being reflected from the water can be used to find out the moving distance. The distance between the detector 70 and the water surface may be measured. As such, the technique of measuring the distance using a laser is a well-known technique, and thus, further description thereof will be omitted.

Further, in front of the main body 10, a radiation dose display section 15 for displaying the surface dose rate (radiation dose rate at a distance of 10 cm from the water surface) measured by the detection unit 70 is provided. It is possible to check whether the surface dose rate measured by the radiation dose display unit 15 exceeds the reference value (0.25 mrem).

In addition, a wheel 16 for moving the main body 10 is installed below the main body 10.

The upper and lower horizontal moving parts 21 and 22 are moved along the upper and lower guide rails 11 and 12 and have a structure in which a linear motor (not shown) is built therein. However, the means for moving the upper and lower horizontal moving parts 21 and 22 may be implemented in various structures such as a hydraulic cylinder as well as a linear motor.

Guide shaft 31 is formed in the longitudinal direction in the shaft portion 30, the support follower 50 is elevated along the guide groove (31). There are various ways to implement this, in this embodiment, the motor and the gear is installed in the shaft portion 30, the gear lifts the support follower 50.

The rotating unit 40 rotates the shaft unit 30 in the left and right directions. There are various methods for implementing such a rotating part 40, for example, may use a hydraulic motor. As the rotating unit 40 rotates the support follower 50 in the left and right directions, the detection unit 70 installed at the end of the support follower 50 increases the surface dose rate in a wide area in the left and right directions. It can be measured.

The cylinder 60 is provided at the end of the support follower 50 to elevate the detection unit 70. In this embodiment, an air cylinder operated by air is employed. The cylinder 60 is used to raise and lower the detector 70 in a fine range.

The transmitter 80 is provided in the main body 10, and transmits the surface dose rate data measured by the detector 70 to the outside, so that the surface dose rate can be confirmed in real time from the outside.

Next, the operation of the radiometer having the above structure will be described.

In order to measure the radiation dose at the surface of the SFP, the detector 70 is placed 10 cm in front of the surface of the water. To this end, by inputting a command to the input key 13, the support follower 50 along the shaft portion 30 is lowered to a specific position so that the detector 70 is located 10cm above the water surface.

Then, when the water level of the SFP is slightly lowered, the cylinder rod 61 protrudes from the cylinder 60 to lower the detection unit 70. And when the water level is sharply lowered support follower 50 is lowered along the shaft portion (30).

If the radiation dose is measured in a distant part, the support follower 50 may be extended by inputting a specific command to the input key 13, in which case the sub support is supported by the main support follower 51. The follower 52 protrudes, and then the cylinder support follower 53 protrudes from the sub support follower 52. Accordingly, the detector 70 may be moved far forward in relation to the main body 10.

On the other hand, when measuring the surface dose rate of a large area, the rotating part 40 rotates the shaft part 30 to the left and right directions, and measures the area | region where the detection part 70 installed in the edge part of the support follower 50 is large. Do it.

In addition, when setting the moving distance of the detection unit 70 or the height value from the water surface through the input unit 13, when the water level fluctuates frequently, the distance between the detection unit 70 and the water surface is automatically adjusted by the input value to measure the surface dose rate. Done.

In addition, the surface dose rate value measured in real time is transmitted to the outside where the person always resides, for example, the computer (C) of the health physics room through the transmitting unit 80 so as to immediately check whether the standard value prescribed by the related laws and regulations is exceeded. .

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible.

As described above, according to the automatic radiation measuring apparatus according to the present invention, it is possible to automatically measure the surface dose rate at exactly 10 cm from the water surface of the SFP, and furthermore to measure the radiation dose at a constant height from the water surface even if the water level is changed. This ensures standardization and accuracy of measurements.

In addition, since the detector is extended from the support follower, the measurement can be performed out of reach of humans.

In addition, since the measurement is made in real time and the measured value is transmitted to the outside, it is possible to check in real time whether the surface dose rate reference value prescribed by the relevant laws and regulations is exceeded, and if the reference value is exceeded, immediate action is possible.

In addition, since the movement of the detection unit is precisely controlled, it is possible to prevent the possibility of contact with water and thus eliminate the possibility of contamination and failure.

And because it is mobile, the user can move wherever he wants. For example, it is possible to measure the radiation dose of nuclear power plant reactor tank.

Claims (8)

A main body 10 provided with upper and lower guide rails 11 and 12 spaced apart from each other in a horizontal direction; Upper and lower horizontal moving parts 21 and 22 moving along the upper and lower guide rails 11 and 12; A shaft portion 30 installed between the upper and lower horizontal moving portions 21 and 22; A rotating part 40 installed on the upper horizontal moving part 22 or the lower horizontal moving part 21 to rotate the shaft part in the left and right directions; A support follower 50 extending forward as being elevated along the shaft portion 30; A cylinder (60) installed at an end of the support follower (50); And a detection unit (70) installed on the cylinder rod (61) of the cylinder (60) for measuring surface dose rate. The method of claim 1, An automatic radiation measuring apparatus installed on the main body (10), further comprising a transmitter (80) for transmitting the surface dose rate data measured by the detector (70) to the outside. The method of claim 1, The support follower 50 includes a main support follower 51 which is installed to be elevated along the shaft portion 30, and a sub support follower extending forward by being protruded from the main support follower 51. 52) and a cylinder support follower 53 which extends forward by coming out of the sub support follower 52 and supports the cylinder 60 on which the detection unit 70 is installed. Measuring device. The method of claim 1, The main body 10 has an automatic radiation measuring device, characterized in that the distance display unit 14 for displaying the moving distance or the distance from the water surface of the detection unit 70 moved forward by the support follower 50 is installed. . The method of claim 1, The radiation dose display unit (15) for displaying the surface dose rate measured by the detection unit 70 is installed in the main body (10). The method of claim 1, The support follower (50) is an automatic radiation measuring device, characterized in that the water level measuring unit 55 for measuring the distance between the detection unit 70 and the water surface to generate an associated signal. The method of claim 6, The water level meter 55 is an automatic radiation measuring apparatus, characterized in that implemented using a laser generating element and a sensor. The method of claim 1, The lower portion of the main body 10 is an automatic radiation measuring device, characterized in that the wheel 16 for the movement of the main body 10 is installed.

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