KR20160038635A - Phantom system for detetecting radiation dose - Google Patents

Abstract

According to the present invention, a phantom system to detect a radiation dosage comprises: a phantom body which has an upper surface of an open box shape and a water storing part; and a detector holder combined with the phantom body, has one end part dipped in water stored in the water storing part, and accommodates one end of the detector measuring radiation dosage irradiated to the water storing part. The phantom system comprises a drainage storage part arranged in the phantom body, is between the water storing part and a partition wall to form a separation space, and has an open upper part; and a water level limiting drain which limits a water level of the water storing part to maintain a volume of water stored in the water storing part in an upper part of the partition wall which distinguishes the water storing part from the drainage storage part. As such, the installation process of the detector is able to easily be carried out.

Description

[0001] The present invention relates to a phantom system for detecting radiation dose,

The present invention relates to a phantom system for measuring radiation dose, and more particularly to a phantom system for measuring the amount of radiation incident into water.

Generally, a phantom for radiation dose measurement is a human body which can precisely measure the amount of radiation to be irradiated for the purpose of radiation therapy or radiation use, and to optimally control the radiation dose applied to the human body or object during the actual treatment or experiment Or a substitute for an object to be tested. Generally, water has an effective atomic number similar to that of human tissue and is readily available anywhere, with the same compositional ratio and homogeneous density. Therefore, water is used as a radiation-absorbing dose measurement material in place of the human body. The water-absorbed dose can be obtained by measuring the amount of radiation incident on a detector installed in a water-filled phantom device having a predetermined size of receptacle as proposed by the International Atomic Energy Agency (IAEA).

The amount of radiation varies from the distance from the radiation source to the extent to which it deviates from the beam center axis. Therefore, in order to accurately measure the radiation dose, it is important to align the center of the beam of radiation and the ionizer precisely at a point on the straight line and at a distance from the source, and repeatability and reproducibility should be ensured for each measurement. In particular, such precision measurement is important in the field of calibration of a secondary standard body by the National Standard Act.

An example of a phantom for radiation measurement is disclosed in Korean Patent Laid-Open Publication No. 2013-0059087. In such a conventional phantom device, it is difficult to always set the ionizer (detector) for measuring the radiation dose at a constant position. More specifically, in a conventional phantom structure, an auxiliary device such as a laser, telescope or the like is used to install the ionizer at a specific position, or the ionizer is aligned with the central axis of the radiation beam depending on the operator's subjective judgment. Further, since the conventional phantom device is difficult to accurately control the amount of water that is always filled when water is filled, there is a problem that an error occurs every measurement, and water may overflow in the preparation process.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to improve the structure of a phantom so that the ionization chamber for measuring the radiation dose can be constantly installed at a desired position, And to provide a phantom system for measuring the amount.

According to an aspect of the present invention, there is provided a phantom system for measuring a radiation dose, the phantom system comprising: a phantom body having a box-like shape with an opened upper surface and a water receiving part inside; And

A phantom body having a box-like shape with an opened upper surface and a water receiving portion inside; And

A bucket holder which is coupled to the phantom body and is installed at one end thereof in the water accommodated in the water accommodating portion and accommodates one end of a detector for measuring an amount of radiation incident on the water accommodating portion; The phantom system comprising:

A drain disposed in the phantom body and formed as a separated space with the water receiving portion and the partition wall interposed therebetween and having an open top; And

And a water level restricting drain for restricting a water level of the water containing part so that the volume of the water contained in the water containing part can be kept constant at the upper part of the partition wall separating the water containing part and the water discharge storage part have.

Preferably, the ionizer holder is movably installed with respect to the phantom body.

The ionizer holder may be installed movably in a direction parallel to the ground.

The ionizer holder may be movably installed in a direction perpendicular to the paper surface.

A screw member disposed on the phantom body and rotatably installed on a side wall of the phantom body, the screw member having an externally threaded portion; And

Wherein the screw member is provided with a female threaded portion which is engaged with a male threaded portion of the screw member, the screwed member being installed to move forward or backward in the longitudinal direction of the screw member when the screw member rotates, Member.

It is preferable that the screw members are provided with a pair arranged in parallel so as to be spaced apart from each other.

A first port for supplying or discharging water to the water receiving portion, and a second port for discharging the water introduced into the drain storage portion through the water level limiting drain port.

And a pump device connected to the first port or the second port and supplying or discharging water from the outside to the water receiving portion.

A guide member disposed on one side wall of the phantom body and elongated in a direction perpendicular to the ground; And

And a vertical moving member that is slidably installed in a direction perpendicular to the paper surface with respect to the guide member and is detachably fixed so that the ionizer holder is disposed in a horizontal direction with respect to the paper.

And a portable drain which is detachably coupled to the drainage storage unit and temporarily stores the water introduced into the drainage storage unit from the water storage unit through the water level limiting drainage port.

And a computer device for receiving a measured value from the ionizer accommodated in the ionizer holder and automatically calculating a calibrated value,

The computer device comprising:

An information input unit receiving information of a detector accommodated in the ionizer holder and a measurement condition of the ionizer;

 An information processing unit for calculating a correction factor using the values input from the information input unit and calculating a corrected value based on the measured values from the ionizer (detector);

A storage unit for storing values processed by the information input unit and the information processing unit; And

And an output unit for outputting a value calculated by the information input unit or the information processing unit.

The phantom system for measuring the radiation dose according to the present invention can maintain the water level of the water receiving part constant by connecting the water receiving part and the drain water storage part to the water level limiting drain hole, Since the installation position of the ionizer can be easily and precisely adjusted by installing the ionizer in a movable and detachable ionizer holder, the measurement error of the radiation amount can be remarkably reduced and the accurate radiation amount can be measured. Also, in the case where a computer apparatus is provided which calculates the correction value based on the measured value from the ionizer and receives the information of the ionizer and the measurement condition as in the preferred embodiment of the present invention, and calculates and outputs the corrected value automatically There is an advantage that accurate measurement values can be checked and used in real time.

FIG. 1 is a view showing major components of a phantom system for measuring a radiation dose according to an embodiment of the present invention.
2 is a plan view of Fig.
FIG. 3 is an exploded perspective view of the major components shown in FIG. 1 from another direction; FIG.
4 is a sectional view taken along the line IV-IV shown in Fig.
5 is a perspective view of a phantom system for measuring a radiation dose according to another embodiment of the present invention.
6 is a plan view of Fig.
Figure 7 is a side view of Figure 4;
8 is a sectional view taken along line VIII-VIII shown in FIG.
9 is a sectional view taken along line IX-IX shown in Fig.
10 is a block diagram of the computer apparatus shown in FIG.

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

FIG. 1 is a view showing major components of a phantom system for measuring a radiation dose according to an embodiment of the present invention. 2 is a plan view of Fig. FIG. 3 is an exploded perspective view of the major components shown in FIG. 1 from another direction; FIG. 4 is a sectional view taken along the line IV-IV shown in Fig. 5 is a perspective view of a phantom system for measuring a radiation dose according to another embodiment of the present invention. 6 is a plan view of Fig. Figure 7 is a side view of Figure 4; 8 is a sectional view taken along line VIII-VIII shown in FIG. 9 is a sectional view taken along line IX-IX shown in Fig. 10 is a block diagram of the computer apparatus shown in FIG.

1 to 10, a phantom system 10 for measuring a radiation dose according to a preferred embodiment of the present invention includes a phantom body 20, a water receiving portion 30, a water level limiting drain port 32, A drainage storage section 40, a portable drainage box 44, an ionizer holder 50, a pump device 60, and a computer device 90.

The phantom body 20 is formed in a box shape whose upper surface is opened. The phantom body 20 may be made of a material such as acrylic resin or aluminum which is a material through which radiation is easily transmitted. In the present embodiment, the phantom body 20 is formed in a cuboid shape having an open top. The phantom body 20 may be mounted on a support 22.

The phantom body 20 includes a water receiving portion 30 and a drain storage portion 40 separated by a partition wall.

The water receiving portion 30 is a space formed in the internal space of the phantom body 20 to receive water. The drainage storage unit 40 is a space that receives water discharged from the water storage unit 30 when the water storage unit 30 is filled with a predetermined amount of water. The water storage part (30) and the water discharge storage part (40) are separated by a partition wall. The drainage storage unit 40 is formed as a space having an open upper part like the water storage unit.

A water level limiting drain port 32 is provided to allow water to flow in and out between the water containing section 30 and the drainage storage section 40. The water level limiting drain port 32 is a passage disposed above the partitions between the water storage part 30 and the drainage storage part 40. The water level limiting drain 32 includes a plurality of lattice-shaped passageways. Since the water level limiting drain port 32 is provided, the water receiving portion 30 can always maintain a constant water level.

The water receiving portion 30 is provided with a first port 34. The first port 34 is provided for supplying water to the water receiving portion 30 or discharging water from the water receiving portion 30. [ The first port (34) is a passage formed on the lower side of the water receiving portion (30). A pump device 60, which will be described later, may be coupled to the first port 34. The first port 34 may be provided with a filter for removing foreign substances.

Meanwhile, the drainage storage unit 40 is provided with a second port 42. The second port 42 is provided for discharging the water introduced into the drainage storage unit 40 through the water level limiting drainage port 32 to the outside. The second port (42) is a passage provided on the lower side of the drainage storage part (40). A pump device 60, which will be described later, may be coupled to the second port 42.

The pump device 60 is connected to the first port 34 or the second port 42. The pump device 60 supplies water to the water receiving portion 30 from the outside or drains the water. Meanwhile, the pump unit 60 may discharge water from the drainage storage unit 40 to the outside. The pump device 60 can be constructed by employing a pump device of a known structure.

The portable drain box 44 may be detachably coupled to the drainage storage unit 40 in a sliding structure. The portable drain box 44 is a box-shaped structure having an open top. The portable drain box 44 may be useful when the pump unit 60 is not connected to the drainage storage unit 40. The portable drain box 44 temporarily stores the water flowing into the drainage storage unit 40 from the water storage unit 30 through the water level limiting drainage port 32. That is, the water contained in the portable drain box 44 can be separated from the drainage storage unit 40 and discharged to the outside. The handle 46 is provided on the upper portion of the portable drain box 44, thereby enhancing the user's convenience.

The ionizer holder (50) is coupled to the phantom body (20). The ionizer holder 50 is installed so that one end of the ionizer holder 50 is immersed in the water contained in the water receiver 30. The ionizer holder 50 may be fully immersed in the water contained in the water receiving part 30 as the case may be. The ionizer holder 50 receives and fixes one end of the ionizer. The ionizer (detector) is a kind of sensor for measuring the amount of radiation incident on the water receiving part (30). The ionizer (detector) is a sensor for measuring a change in the amount of charge according to the radiation dose. Substantially the ionizer (the detector) outputs a current value. The ionizer (detector) is detachably fixed to the ionizer holder 50.

Preferably, the ionizer holder 50 is movably installed with respect to the phantom body 20. When the ionizer holder 50 is movably installed with respect to the phantom body 20, the ionizer can be easily and precisely installed at various positions of the water receiver 30. [

In the present embodiment, the ionizer holder 50 is installed to be movable only in one direction with respect to the phantom body 20. More specifically, the ionizer holder 50 is installed to be movable in a direction parallel to the ground surface or perpendicular to the ground surface with respect to the phantom body 20. 1 to 4 show a structure in which the ionizer holder 50 is movably installed in a direction parallel to the ground. 5 to 9 show a structure in which the ionizer holder 50 is movably installed in a direction perpendicular to the paper surface.

Hereinafter, the installation structure of the ionizer holder 50 will be described in more detail.

First, referring to FIGS. 1 to 4, a structure in which the ionizer holder 50 is installed so as to move in a horizontal direction on the ground will be described.

The ionizer holder 50 is detachably attached to the horizontal moving member 74. The horizontal moving member 74 is coupled to the screw member 70. The horizontal moving member 74 is a bar-shaped structure. The screw member 70 is disposed on the upper portion of the phantom body 20. The screw member 70 is rotatably installed on a side wall of the phantom body 20. The screw member 70 is a rod-like member. A male screw portion is provided on the outer peripheral surface of the screw member 70. Both ends of the screw member (70) are rotatably supported on the side wall of the phantom body (20). A first adjustment member (72) is provided to rotate the screw member (70). The first adjustment member 72 is disposed orthogonal to the screw member 70. The first adjustment member 72 is rotatably mounted on the phantom body 20. The first adjusting member 72 and the screw member 70 are coupled to each other by a coupling structure such as a helical gear or a bevel gear to rotate the first adjusting member 72 to rotate the first adjusting member 72 So that the screw member 70 can be rotated. The first adjusting member 72 may be automatically rotated by engaging a power source such as a stepping motor. Alternatively, the screw member 70 may be directly coupled to the stepping motor without the first adjusting member 72. In this embodiment, the first adjusting member 72 is manually rotated.

The screw members 70 are provided with a pair arranged in parallel so as to be spaced apart from each other. The horizontally moving member 74 is screwed to the pair of screw members 70. More specifically, both ends of the horizontal moving member 74 are provided with a female screw portion which is engaged with the male screw portion of the screw member 70. As a result, when the screw member 70 rotates, the horizontal moving member 74 is installed to move forward or backward in the longitudinal direction of the screw member 70.

The Ionizer holder 50 is fixed to the horizontal moving member 74 by being fitted into an installation hole 75 provided at the center of the horizontal moving member 74. A plurality of the ionizer holder 50 may be prepared and installed in various lengths depending on the type of the ionizer. The ionizer holder 50 and the ionizer may be coupled to each other to allow the free end of the ionizer to be positioned at a predetermined position in a direction perpendicular to the paper surface from the horizontal moving member 74 . In addition, since the position of the installation hole 75 provided at the center of the horizontal moving member 74 does not change in the longitudinal direction of the horizontal moving member 74, the position in the direction is fixed. As the screw member 70 is rotated, the horizontal moving member 74 is moved forward or backward along the longitudinal direction of the screw member 70 so that the screw member 70 moves only in the longitudinal direction of the screw member 70 . For convenience of description, the longitudinal direction of the screw member 70 will be defined as the forward and backward directions. Therefore, the lighter holder 50 can move only in the forward and backward directions, and can not move in the other direction. 1, when radiation is incident on the front of the phantom body 20, the radiation incident on the water receiving portion 30 passes through the water accommodated in the water receiving portion 30, Different amounts of absorption are measured in the ionizer (detector). Therefore, the measurement position adjustment in the incident direction of the radiation is performed by moving the ionizer holder 50 in the forward and backward directions to repeatedly set the ionizer (detector) at a predetermined position. Accordingly, there is an advantage that an error due to the change of the position of the ionizer (detector) can be minimized. The horizontal moving member 74 may be provided with a water temperature meter 76 for measuring the temperature of water contained in the water receiving portion 30. [

5 to 9, a structure in which the ionizer holder 50 is installed so as to move in a direction perpendicular to the paper will be described.

The phantom body 20 is provided with a guide member 80 and a vertically movable member 82.

The guide member (80) is disposed on one side wall of the phantom body (20). More specifically, the guide member (80) is fixed to the inner wall of the water receiving portion (30). The guide member 80 is a bar-shaped structure. The guide member (80) is fixed to the phantom body (20). The guide member 80 is elongated in a direction perpendicular to the paper surface. The guide member 80 may be formed integrally with the phantom body 20.

The vertically moving member 82 is slidably installed in a direction perpendicular to the paper surface with respect to the guide member 80. The vertical moving member 82 is detachably fixed so that the ionizer holder 50 is disposed in a horizontal direction with respect to the ground. The vertically moving member 82 is provided with an engagement groove 83 having a female screw so that the bolt-like coupling means can be engaged with the ionizer holder 50 in a direction parallel to the paper. In the present embodiment, two coupling groove portions 83 are provided. The vertically-moving member 82 is installed so that it can be raised or lowered in the longitudinal direction of the guide member 80 by the second adjusting member 84. More specifically, the second adjustment member 84 is a structure similar to the screw member 70. The second adjusting member 84 is disposed long in a direction perpendicular to the paper surface. The lower end of the second adjusting member 84 is rotatably fixed to the phantom body 20. An upper end of the second adjusting member 84 protrudes upward from the phantom body 20, and a rotary knob is provided. The second adjusting member 84 has a male screw portion on an outer circumferential surface thereof and the vertical moving member 82 has a female screw portion engaged with a male screw portion of the second adjusting member 84. Accordingly, when the second adjusting member 84 is rotated, the vertical moving member 82 is moved up or down along the guide member 80. The second adjusting member 84 may be connected to a power source such as a stepping motor and rotated automatically.

FIG. 5 shows a state in which the ionizer holder 50 is installed on the vertically moving member 82. The battery holder 50 is coupled to the vertically movable member 82 by two bolts. The ionizer holder 50 installed in the vertically moving member 82 may be useful when the radiation is incident in a direction perpendicular to the paper surface. By providing the water level limiting drain port 32, the user can always maintain a constant water level in the water containing portion 30. [ Accordingly, the ionizer holder 50 coupled to the vertically moving member 82 can be lowered by a required depth based on the water surface of the water receiving portion 30. [ Since the vertically movable member 82 can move only in the direction perpendicular to the paper surface with respect to the phantom body 20, when the radiation is incident from above the water receiving portion 30 downward, It is possible to accurately position and move the position of the ionizer holder 50 as much as necessary in the incidence direction.

Now, a description will be made of a computer device 90 that receives a measured value from the ionizer (detector) accommodated in the ionizer holder 50 and automatically calculates a calibrated value.

The computer device 90 includes an information input unit 92, an information processing unit 94, a storage unit 96, and an output unit 98.

The information input unit 92 may employ a keyboard or a barcode scanner. In the case of employing the barcode scanner, there is an advantage that a mistake of the user can be minimized in the process of inputting the ionizer information.

The information input unit 92 reads the specifications of the ionizer (detector) and makes it possible to process the measured data easily and quickly. The information input unit 92 can easily input and set measurement conditions such as a measurement time, a measurement count, a measurement wait time, an applied voltage, and a measurement range, as well as the specification of the ionizer (detector). Such measurement conditions can be easily set by inputting a value through the keyboard to the input format displayed on the screen.

The information processing unit 94 calculates a correction factor using the values input from the information input unit 92 based on the measured values from the ionizer (detector), and calculates the corrected values. The information processing unit 94 is coupled to the computer device 90 in the form of computer programmed software to calculate a substantially useful calibration value. For example, it is possible to calibrate the air density from the measured temperature in real time and the measured air pressure value separately using the temperature gauge 76 mounted on the horizontally moving member 74. Therefore, it is possible to minimize the human errors that may occur in the measurement of the radiation dose and the calculation of the correction factor. Accordingly, there is an advantage that the time for measuring and calibrating the radiation dose is remarkably shortened compared to the conventional case.

The storage unit 96 stores values processed by the information input unit 92 and the information processing unit 94. [ The storage unit 96 may be constructed using a hard disk or a semiconductor memory device which is generally used.

The output unit 98 employs a known component such as a display or a printer and outputs a value calculated by the information input unit 92 or the information processing unit 94. [

The current value measured by the ionizer (detector) is processed by the information processing unit 94 through an analogue digital converter, so that the user can accurately use the radiation amount measured in real time.

Hereinafter, a process of measuring the radiation dose using the phantom system 10 for measuring a radiation dose according to the present invention will be described in detail.

First, with reference to Figs. 1 to 4, a case where radiation is incident in a horizontal direction on the paper will be described.

Water is supplied to the water receiving portion (30) by using the pump device (60). The water supplied to the water storage part 30 increases the water level of the water storage part 30 so that when the water level reaches the water level limiting drainage port 32, . A water level sensor may be provided near the water level limiting drain port 32 to automatically stop the operation of the pump device 60. On the other hand, the operation and stop of the pump device 60 may be manually performed by a person. Now, the ionizer (detector) is installed at the position to be measured. It is not necessary to uniformly define the process of installing the ionizer (detector), and will be described below by way of example. And the ionizer holder 50 is coupled to the horizontally moving member 74. And connects the ionizer (detector) to the ionizer holder 50. The ionizer holder 50 is fitted to the installation hole 75 from the upper side to the lower side of the horizontal moving member 74. The detector is slidably coupled from the upper side of the lighter holder 50 to the lower side. Now, the free end of the ionizer (detector) is moved to the position to be measured. In this case, the position of the ionizer holder 50 can be changed only in the direction in which the radiation is incident. The depth of the water accommodating portion 30 is determined to be constant according to the length of the ionizer holder 50. In addition, since the unit holder 50 can not move in the longitudinal direction of the horizontal moving member 74, it is not allowed to change the position of the unit. Accordingly, the positional error does not occur except for the incident direction of the radiation. Now adjust the position of the radiation in the direction of incidence. The first adjusting member 72 is rotated. As the first adjusting member 72 rotates, the screw member 70 rotates. As the screw member 70 rotates, the horizontal moving member 74 moves in the longitudinal direction of the screw member 70 (same as the incident direction of the radiation). When the ionizer is positioned at a desired position, the rotation of the first adjusting member 72 is stopped. Now, the specification and measurement conditions of the ionizer (detector) are input to the information input unit 92 of the computer device 90. Now, when the radiation is incident on the water receiving portion 30, measurement is started. The computer device 90 is connected to the ionizer in a wired or wireless manner and combines the measured values with the calibration conditions in the ionizer to calculate substantially available calibration values in real time and store and output the calibrated values.

Now, with reference to Figs. 5 to 9, the case where the radiation is incident in a direction perpendicular to the paper will be described.

The water level is maintained at a constant level by supplying water to the water receiving portion 30, which is the same as the case where the radiation is incident in a horizontal direction to the paper surface with reference to FIGS. 1 to 4. Therefore, do.

Now, the ionizer (detector) is installed at the position to be measured. It is not necessary to uniformly define the process of installing the ionizer (detector), and will be described below by way of example. And the ionizer holder 50 is coupled to the vertically movable member 82. And connects the ionizer (detector) to the ionizer holder 50. The bucket holder (50) is fixed to the vertically movable member (82) using two bolts. The detector is slidably coupled to the longitudinal direction of the ionizer holder 50. Now, the free end of the ionizer (detector) is moved to the position to be measured. In this case, the position of the ionizer holder 50 can be changed only in the direction in which the radiation is incident. The length protruding from the side wall of the water receiving portion 30 is determined to be constant according to the length of the ionizer holder 50. Also, since the ionizer holder 50 can not move in the width direction of the guide member 80, it is not allowed to change the position of the ionizer holder 50 in that direction. Accordingly, the positional error does not occur except for the incident direction of the radiation. Now adjust the position of the radiation in the direction of incidence. The second adjusting member 84 is rotated so that the ionizer (detector) is positioned on the water surface of the water receiving portion 30. [ In this state, the first adjusting member 72 is rotated to lower the vertical moving member 82 to a desired position. As the second adjusting member 84 rotates, the vertical moving member 82 moves in the longitudinal direction of the guide member 80 (same as the direction of incidence of radiation). When the ionizer is located at a desired position, the rotation of the second adjusting member 84 is stopped. Now, the specification and measurement conditions of the ionizer (detector) are input to the information input unit 92 of the computer device 90. Now, when the radiation is incident on the water receiving portion 30, measurement is started. The computer device 90 is connected to the ionizer in a wired or wireless manner and combines the measured values with the calibration conditions in the ionizer to calculate substantially available calibration values in real time and store and output the calibrated values.

On the other hand, when the radiation dose measurement is completed, the pump device 60 is operated to discharge the water in the water storage portion 30 and the drainage storage portion 40 to the outside. On the other hand, the pump device 60 If the first port 34 and the second port 42 are closed, water is poured from above the water receiving portion 30 to prepare for measurement, and when the measurement is completed, The water can be drained by connecting the drain hose to the one port 34. [ When the portable drain box 44 is installed in the drainage storage unit 40, the portable drainage box 44 is separated from the drainage storage unit 40 and the water contained in the portable drainage box 44 is drained Can be removed.

As described above, the phantom system for measuring the radiation dose according to the present invention can maintain the water level of the water receiving part constantly by connecting the water receiving part and the drain water storage part to the water level limiting drain hole, It is possible to easily and precisely adjust the installation position of the ionization chamber, so that the measurement error of the radiation dose can be remarkably reduced and the accurate radiation dose can be measured. Also, in the case where a computer apparatus is provided which calculates the correction value based on the measured value from the ionizer and receives the information of the ionizer and the measurement condition as in the preferred embodiment of the present invention, and calculates and outputs the corrected value automatically There is an advantage that accurate measurement values can be checked and used in real time. That is, in the phantom system for measuring the radiation dose according to the present invention, it is possible to perform the measurement operation in a state in which the constant volume of water is always filled in the water accommodating portion, thereby making it possible to eliminate an error in the volume change of the water, Alignment of the ionizer (detector) is very easy, and excellent repeatability with respect to the location of the ionizer (detector) can be expected when measuring the radiation dose. Therefore, there is an advantage that it can be usefully used in a secondary standard laboratory or in an institution requiring precise measurement of the radiation dose.

While the present invention has been described with reference to the preferred embodiments, it is to be understood that the invention is not to be limited by the example, and various changes and modifications may be made without departing from the spirit and scope of the invention.

10: Phantom system for radiation dose measurement
20: phantom body
22: Support
30: water receiving portion
32: Water level limiting drain
34: First port
40:
42: second port
44: Portable drain
46: Handle
50: Ion Holder
60: Pump device
70: Screw member
72: first adjusting member
74: Horizontal moving member
75: Installation ball
76: Thermometer
80: Guide member
82: vertically movable member
83: Coupling groove
84: second adjusting member
90: Computer device

Claims (11)

A phantom body having a box-like shape with an opened upper surface and a water receiving portion inside; And
A bucket holder which is coupled to the phantom body and is installed at one end thereof in the water accommodated in the water accommodating portion and accommodates one end of a detector for measuring an amount of radiation incident on the water accommodating portion; The phantom system comprising:
A drain disposed in the phantom body and formed as a separated space with the water receiving portion and the partition wall interposed therebetween and having an open top; And
And a water level restricting drain for restricting a water level of the water accommodating part so that the volume of the water contained in the water accommodating part can be kept constant on the upper part of the partition wall separating the water accommodating part and the drain water storage part Phantom system for radiation dose measurement. The method according to claim 1,
Wherein the ionizer holder is movably installed with respect to the phantom body. The method according to claim 1,
Wherein the ionizer holder is installed movably in a direction parallel to the ground. The method according to claim 1,
Wherein the ionizer holder is mounted movably in a direction perpendicular to the ground. 3. The method of claim 2,
A screw member disposed on the phantom body and rotatably installed on a side wall of the phantom body, the screw member having an externally threaded portion; And
Wherein the screw member is provided with a female threaded portion which is engaged with a male threaded portion of the screw member, the screwed member being installed to move forward or backward in the longitudinal direction of the screw member when the screw member rotates, And a phantom system for measuring a radiation dose. 6. The method of claim 5,
Wherein the screw members are provided with a pair of spaced apart spaced apart phantom members. The method according to claim 1,
A first port for supplying or discharging water to the water containing portion and a second port for discharging the water introduced into the drain storage portion through the water level limiting draining port to the outside, system. 8. The method of claim 7,
And a pump device connected to the first port or the second port and supplying or discharging water from the outside to the water receiving part. The method of claim 3,
A guide member disposed on one side wall of the phantom body and elongated in a direction perpendicular to the ground; And
And a vertically moving member slidably mounted on the guide member in a direction perpendicular to the paper surface and detachably fixed so that the ionizer holder is disposed in a horizontal direction with respect to the paper surface. system. The method according to claim 1,
And a portable drain box detachably connected to the drainage storage unit and temporarily storing the water introduced into the drainage storage unit from the water storage unit through the water level limiting drainage port. The method according to claim 1,
And a computer device for receiving a measured value from the ionizer accommodated in the ionizer holder and automatically calculating a calibrated value,
The computer device comprising:
An information input unit receiving information of a detector accommodated in the ionizer holder and a measurement condition of the ionizer;
An information processing unit for calculating a correction factor using the values input from the information input unit and calculating a corrected value based on the measured values from the ionizer (detector);
A storage unit for storing values processed by the information input unit and the information processing unit; And
And an output unit for outputting a value calculated by the information input unit or the information processing unit.

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