KR20180099156A - X-ray spatial dose distribution measurement apparatus - Google Patents

Abstract

The present invention relates to an X-ray spatial dose distribution measurement apparatus capable of measuring a spatial dose distribution of a radiation radiated from an X-ray generator according to a distance from the X-ray generator. The apparatus includes: an upper frame extending in a horizontal direction; first and second side frames extending downward from both ends of the upper frame; a frame body having a lower frame coupling the first and second side frames at lower portions of the first and second side frames; a sliding panel extending along the direction parallel to the upper frame and installed and supported on the first and second side frames of the frame body to move up and down; an up and down driving unit for moving the sliding panel up and down relative to the first and second side frames; a radiation detection module arrayed thereon with radiation detection elements for detecting radiation along the direction parallel to the upper frame in the sliding panel; and a signal processing unit for calculating radiation spatial dose distribution information from the signal outputted from the radiation detection module while controlling the up and down driving unit. According to the X-ray spatial dose distribution measurement apparatus, the X-ray spatial dose distribution is measured in the field.

Description

[0001] The present invention relates to an X-ray spatial dose distribution measurement apparatus,

The present invention relates to an X-ray space dose distribution measuring instrument, and more particularly, to an X-ray space dose distribution measuring instrument capable of measuring an air dose distribution of radiation emitted from a radiation source.

The image acquisition method using X-ray is utilized in various fields such as medical field.

On the other hand, in recent years, a method of acquiring images by irradiating an X-ray to containers in order to acquire information on the internal loading of a container moved to a vehicle is disclosed in various publications such as Korean Patent Publication No. 2004-0034481.

However, in the case of installing an X-ray inspection apparatus for container inspection, it is necessary to precisely grasp the intensity and distribution information of the X-ray emitted from the X-ray generator to be installed at the site.

Therefore, there is a demand for a device capable of measuring the spatial dose distribution of the radiation generated from the X-ray generator in the field.

It is an object of the present invention to provide an X-ray spatial dose distribution meter capable of measuring the spatial dose distribution of radiation generated from an X-ray generator in the field, which is designed to solve the above-mentioned problems.

In order to achieve the above object, an X-ray space dose distribution measuring instrument according to the present invention is an X-ray space dose distribution measuring instrument capable of measuring a spatial dose distribution of a radiation radiated from an X-ray generator according to a distance from an X- And first and second side frames extending downwardly from opposite ends of the upper frame; and first and second side frames at the bottom of the first and second side frames, A frame body having a lower frame to be coupled therewith; A sliding panel extending along a direction parallel to the upper frame and installed to be vertically movable up and down on the first and second side frames of the frame body; An up-down driving part for moving the sliding panel up and down relative to the first and second side frames; A radiation detection module in which a radiation detection element for detecting radiation along a direction parallel to the upper frame is arrayed in the sliding panel; And a signal processing unit for calculating the radiation dose distribution information from the signal output from the radiation detection module while controlling the up / down driving unit.

According to an aspect of the present invention, a diode is applied to the radiation detecting element.

Preferably, the radiation detection module is constructed so as to be controllably moved to the signal processing section in the sliding panel.

The radiation detection module may further comprise: a detection bar having the diodes arrayed to be spaced apart from each other and having a rack gear formed on one side along the longitudinal direction; A pinion provided so as to engage with the rack gear of the detection bar; And a movement adjusting motor for rotating the pinion in the forward and reverse directions in accordance with the control signal of the signal processing unit.

Preferably, the sliding panel is coupled to one end of a wire installed to be supported through a rotary roller rotatably installed in the upper frame, and the other end of the wire, Up and down drive motor for rotating the roller is installed to be driven and controlled by the signal processing unit.

The X-ray spatial dose distribution measuring instrument according to the present invention provides an advantage of measuring the X-ray spatial dose distribution in the field.

FIG. 1 is a perspective view showing an X-ray spatial dose distribution measuring instrument according to the present invention,
Figure 2 is a diagram showing the control system for some of the elements of Figure 1;

Hereinafter, an X-ray spatial dose distribution measuring instrument according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing an X-ray space dose distribution measuring instrument according to the present invention, and FIG. 2 is a view showing a control system for some elements of FIG.

1 and 2, an X-ray spatial dose distribution measuring instrument 100 according to the present invention includes a frame body 110, a sliding panel 130, an elevating and lowering driving unit 150, a radiation detecting module 160, (180).

The frame body 110 is provided with a sliding panel 130 (not shown) in which a radiation detection module 160, which will be described later, is accommodated so as to measure the spatial dose distribution of the radiation radiated from the X-ray generator 10 according to the distance from the X- And is formed in the shape of a sideview frame.

When the frame body 110 is divided, the upper frame 111 extending in the horizontal direction, the first and second side frames 112 and 113 extending downward from both ends of the upper frame 111, The first and second side frames 112 and 113 are coupled to each other at a lower portion of the first and second side frames 112 and 113 to form a lower frame 114 have.

The first and second side frames 112 and 113 are formed with guide rails 112a and 113a extending vertically to guide the sliding of the sliding panel 130 to be described later.

Of course, the lower frame 114 can be mounted with wheels to provide ease of movement.

The sliding panel 130 is provided to extend along a direction parallel to the upper frame 111 and to be supported by the first and second side frames 12 and 113 of the frame body 110 so as to be elevated and lowered.

The sliding panel 130 is formed in a 'C' shape so as to surround the first and second side frames 12 and 113 so that the sliding panel 130 can be vertically moved up and down while being separated from the frame body 110 .

The sliding panel 130 is formed with a restraining groove 133 for guiding the guide rails 112a and 113a.

The sliding panel 130 is formed therein with a receiving space for receiving the radiation detecting module 160 to be described later and has an opening 132 opened to expose the radiation detecting module 160 along the longitudinal direction .

The lifting and lowering driving part 150 is capable of lifting or lowering the sliding panel 130 with respect to the first and second side frames 112 and 113.

The raising and lowering driving unit 150 includes a rotating roller 152, a wire 154, a winding roller 156, and a raising and lowering driving motor 158.

The rotary roller 152 is rotatably mounted on a bracket 151 provided at the center of the upper frame 111.

One end of the wire 154 is coupled to a ring provided on the upper surface of the sliding panel 130, and the other end is coupled to the winding roller 156.

The outer ring 154 extends upward from the ring 137 of the sliding panel 130 and is supported by the rotary roller 152 and then downwardly wound and unwound through the winding roller 156.

The winding roller 156 is rotatably installed to wind or unwind the wire 154 to the lower frame 114.

The up / down driving motor 158 is controlled by the signal processing unit 180 to drive the winding roller 156 in the forward and reverse directions.

The radiation detection module 160 has the radiation detection elements 162 arrayed at regular intervals in the sliding panel 130 to detect radiation along a direction parallel to the upper frame 111.

Here, the radiation detecting element 162 is a diode to which a current flows by an X-ray.

It goes without saying that the ion detection chamber 162 may be an ion chamber different from the illustrated example.

The radiation detection module 160 is constructed so as to be controlled by the signal processing unit 180 in the sliding panel 130 so as to be moved in the horizontal direction.

In this case, horizontal measurement points can be expanded by movement of the radiation detection module 160 while reducing the number of arrays of the radiation detection elements 162, An air dose distribution measurement can be performed.

The radiation detection module includes a detection bar 161, a pinion 167, and a movement adjustment motor 168.

The detection bars 161 are arranged such that the diodes applied to the radiation detection elements 162 are spaced apart from each other and a rack gear 166 is formed on one side of the bottom surface along the longitudinal direction.

The detection bar 161 is supported at both ends thereof by a movement guide member 139 provided in the sliding panel 130 so as to allow the movement of the detection bar 161 in the horizontal direction so that the detection bar 161 can be moved in the restrained state in the horizontal direction.

The pinion 167 is provided inside the sliding panel 130 so as to engage with the rack gear 166 of the detection bar 161.

The movement adjustment motor 168 rotates the pinion 167 in the forward and reverse directions in accordance with the control signal of the signal processing unit 180.

Here, the minimum movement adjustment distance of the rack gear 166 is shorter than the separation distance of the radiation detection element 162. [

The operating portion 182 is provided with a key for supporting the measurement of the radiation spatial dose distribution.

The signal processing unit 180 receives the signal for instructing the radiation spatial dose distribution measurement from the operation unit 182 and outputs the radiation dose distribution measurement signal to the up / Calculates the radiation spatial dose distribution information from the signal output from each radiation detection element 162 of the radiation detection module 160 while controlling the drive and outputs the calculated radiation spatial dose distribution information to the output unit 184, To be displayed through the device.

Here, the signal processor 180 controls the sliding panel 130 to be moved by a vertical interval set in the vertical direction, and then, from the radiation detecting element 162, in a state where the radiation detecting module 160 is disposed at the left reference end The received signal is mapped to correspond to the position corresponding to the memory (not shown), and the radiation detection module 160 is moved so that the separation distance between the radiation detection elements 162 is shifted by a set sub- Processes the received signal from the detector element 162 and proceeds this horizontal movement and detection process by the number of divisional measurements divided by the separation distance between the room event detection elements 162. [

Thereafter, the signal processing unit 180 moves the sliding panel 130 by a vertical interval set in the vertical direction, moves the radiation detection module 160 to the set left reference end, and then performs the horizontal movement measurement process described above .

This process proceeds to the set vertical scan range, and as a result, the radiation distribution information can be measured two-dimensionally.

In addition, by performing the measurement process at a different distance from the X-ray generator 10, the three-dimensional X-ray space dose distribution information can be grasped.

According to the X-ray spatial dose distribution measuring apparatus described above, the X-ray spatial dose distribution can be measured at various sites such as the construction site of the X-ray detection facility.

110: frame body 130: sliding panel
150: raising and lowering driving part 160: radiation detecting module
180: Signal processing section

Claims (5)

An X-ray spatial dose distribution measuring instrument capable of measuring a spatial dose distribution of radiation emitted from an X-ray generator according to a distance from an X-ray generator,
A first side frame extending downward from both ends of the upper frame and a second side frame extending downward from the lower side of the first and second side frames, A frame body having a lower frame;
A sliding panel extending along a direction parallel to the upper frame and installed to be vertically movable up and down on the first and second side frames of the frame body;
An up-down driving part for moving the sliding panel up and down relative to the first and second side frames;
A radiation detection module in which a radiation detection element for detecting radiation along a direction parallel to the upper frame is arrayed in the sliding panel;
And a signal processing unit for calculating the radiation spatial dose distribution information from the signal output from the radiation detection module while controlling the up / down driving unit. 2. The X-ray spatial dose distribution measuring apparatus according to claim 1, wherein a diode is applied to the radiation detecting element. 3. The X-ray spatial dose distribution measuring instrument according to claim 2, wherein the radiation detection module is constructed so as to be controllably moved to the signal processing unit in the sliding panel. 4. The apparatus of claim 3, wherein the radiation detection module
A detection bar in which the diodes are arrayed so as to be spaced apart from each other, and a rack gear is formed on one side along the longitudinal direction;
A pinion provided so as to engage with the rack gear of the detection bar;
And a movement adjusting motor for rotating the pinion in the forward and reverse directions in accordance with a control signal of the signal processing unit. The sliding panel as claimed in claim 4, wherein the sliding panel is coupled to one end of a wire supported by a rotary roller rotatably installed in the upper frame,
And an up-down driving motor for rotating the winding roller coupled with the other end of the wire installed to wind or unwind the wire to the lower frame is controlled by the signal processor to be driven.

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