KR101814092B1 - Wide sensitivity-range tissue equivalent proportional counter apparatus and detecting method thereof - Google Patents

Abstract

A broadband tissue equivalent proportional counter is disclosed that can be miniaturized without requiring a plurality of gas chambers while implementing a wide bandwidth to accommodate both low sensitivity and high sensitivity bands.
The broadband tissue equivalent proportion counter according to one aspect includes a first sensing unit having a first sensitivity band and a second sensing unit having a second sensitivity band that is more sensitive than the first sensitivity band; A first preamplifier for amplifying a signal detected by the first sensing unit and a second preamplifier for amplifying a signal detected by the second sensing unit; A switch unit for selecting either the first signal from the first preamplifier unit or the second signal from the second preamplifier unit; A signal amplifier amplifying a signal selected from the switch; And a signal analyzer for analyzing the signal amplified by the signal amplifying unit, wherein the first sensing unit and the second sensing unit are housed in the same gas chamber.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wideband tissue equivalent proportion counter and a counting method using the ratio equalizer.

The present invention relates to a broadband tissue equivalent proportion counter and a counting method using the same, and more particularly, to a broadband tissue equivalent proportion counter which does not require a plurality of gas chambers while realizing a wide band so as to correspond to both a low sensitivity band and a high sensitivity band, A proportional counter and a counting method using the same.

Radiation (radiation, English: radiation) is a light or matter that originates from an atom with radioactivity. Transmitting the body resonates with the molecule, destroying the cell, or breaking the hydrogen bond of DNA or RNA to destroy or transform the gene. Common exposure is harmful to the human body, but concentrating it can be a means of destroying tumors and transforming genes. The weak interactions lead to the collapse of the atoms.

After the Fukushima Nuclear Power Plant accident in 2011, the general public's interest in radiation exposure has become higher than ever before. In addition to the space development, there are increasing concerns about cosmic radiation exposure in the course of various missions of crew members. And there is a growing demand for technology to evaluate the degree of radiation exposure because there is a high possibility that air crews are exposed to radiation even in the living environment.

In order to evaluate the biological effect of such radiation exposure, the equivalent dose, which is the product of the absorbed dose and the radiation load factor, should be applied and the radiation load factor is determined by the LET of the radiation (ICRP 60 1009) The evaluation of LET is very important in monitoring.

To this end, various types of detectors such as Bonner sphere, sievert counter, TLD (Thermo Luminescence Dosimetry) and SSNTD (solid state nuclear track detector) have been used to evaluate equivalent dose in space Among them, the tissue equivalent proportional counter (TEPC) (Rossi et al, 1955) has various types of detectors.

On the other hand, a tissue proportional counter used in an environment with relatively low radiation dose, such as live radiation, can be used only when the sensitivity is high. On the other hand, in an environment where radiation exposure is large, such as a nuclear power plant, a nuclear fusion research institute, a CT, or an MRI imaging site, the sensitivity can be used only if the sensitivity is relatively low. If the sensitivity of the tissue-proportional proportional counter is not too low and too high in accordance with the use environment, it becomes saturated and a detection phenomenon is caused.

To cope with both low-sensitivity and high-sensitivity bands, ie, to easily measure radiation exposure in both the low-sensitivity and high-sensitivity bands, a tissue-equivalent proportional counter corresponding to a high sensitivity range and a low- sensitivity range corresponding to tissue-equivalent proportional counter. In this case, since the high-sensitivity tissue equivalent proportion counter and the low-sensitivity tissue equivalent proportion counter have to be housed in the respective gas chambers having different pressures, there has been a problem that the equipment becomes large.

Utility Model Registration No. 0238890 (Jul. 2001), 2π proportional counter for measuring α, β radioactivity.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a broadband tissue equivalent proportion counter which can realize miniaturization without requiring a plurality of gas chambers while realizing a wide band to correspond to both low- And to provide a counting method using the same.

A broadband tissue equivalent proportion counter according to an aspect of the invention includes a first sensing unit having a first sensitivity band and a second sensing unit having a second sensitivity band that is more sensitive than the first sensitivity band; A first preamplifier for amplifying a signal detected by the first sensing unit and a second preamplifier for amplifying a signal detected by the second sensing unit; A switch unit for selecting either the first signal from the first preamplifier unit or the second signal from the second preamplifier unit; A signal amplifier amplifying a signal selected from the switch; And a signal analyzer for analyzing the signal amplified by the signal amplifying unit, wherein the first sensing unit and the second sensing unit are housed in the same gas chamber.

In this case, when the second signal is saturated, the switch unit may transmit the first signal to the signal amplifying unit.

Alternatively, the switch unit may transmit the second signal to the signal amplifying unit when the first signal is not detected.

In addition, the first sensing unit and the second sensing unit may be arranged in the same manner as the number of required unit-tissue equivalent proportional counters derived based on the sensitivity of the unit-of-tissue-equivalent proportional counter and the sensitivity required by the tissue- The unit-structure-equivalent proportional counter of the unit-structure-equivalent proportional counter.

The unit-tissue-equivalent proportional counter may have the same structure as the chamber in which the gas is enclosed and the incident radiation forms a chamber for causing an ionizing action in the gas, The first and second chamber hemispheres having the same number of chambers.

In addition, one unitary tissue equivalent proportion counter can be coupled to the other unit tissue equivalent proportion counter through the second coupling structure.

On the other hand, the second coupling structure is seated on the inner surface of the coupling portion when the coupling portions formed on the first chamber hemisphere and the second chamber hemisphere of mutually adjacent unitary structure equivalent proportion counters are engaged with each other, and the central portion thereof is connected to the anode support and an anode support through-hole structure that can be coupled by inserting an annoy support into the anode support, wherein the anode support through- insulator); And an anode support inserted into the anode support through structure of the anode insulator.

The second coupling structure includes a first chamber half of the unit proportional counter and a second chamber half of the unit salient proportional counter adjacent to each other, As shown in FIG.

In addition, an anode insulator is mounted on the inner surface of the coupling portion formed in the first chamber hemisphere and the second chamber hemisphere, which are located at both ends of the plurality of unit structure equivalent proportion counters, and the anode support penetration structure of the central portion of the anode A wire support may be coupled to the anode insulator by inserting an anode support into the anode support and providing a structure in which the anode wire is soldered to both end PCBs and the PCB is seated.

In addition, in at least one of the two ends of the plurality of unit tissue equivalent proportional counters, a spring is provided between the anode insulator and the wire support so as to provide tension to the anode wire by pushing the PCB with a restoring force. As shown in FIG.

In addition, it is preferable to further include a common anode wire penetrating between the plurality of unitary tissue equivalent proportional counters, wherein a tube having an anode wire in advance and an outer diameter smaller than the inner diameter of the anode support is provided between the plurality of anode supports The anode wire is passed through between the plurality of anode supports or the anode wire is thicker than the diameter of the anode wire and thinner than the inner diameter of the anode support, The anode can be formed by hooking it so that the medium passes through the plurality of anode supports.

According to another aspect of the present invention, there is provided a counting method using a broadband tissue equivalent proportion counter, comprising the steps of: detecting a first signal detected by a first sensing unit having a first sensitivity band and a second signal having a second sensitivity band more sensitive than the first sensitivity band; Receiving a second signal detected by the switch unit (the first sensing unit and the second sensing unit are housed in the same gas chamber); Selecting and transmitting the first signal and the second signal to the signal analyzer, wherein the signal is not saturated while the first signal and the second signal are detectable; Amplifying the signal selected and transmitted from the switch unit among the first signal and the second signal; And analyzing a signal analyzed by the signal amplified by the signal amplification unit.

In this case, when the second signal is saturated, the switch unit transmits only the first signal to the signal amplifying unit, and when the first signal is not detected, the switch unit can transmit only the second signal to the signal amplifying unit .

The first sensitivity band and the second sensitivity band are set by combining a required number of unit tissue equivalent proportional counting devices in the gas sensing chamber in the first sensitivity band and the second sensitivity band, respectively ; ≪ / RTI >

The preamplifier may further amplify the first signal and the second signal before the switch unit receives the first signal and the second signal.

By using the present invention, it is possible to realize a broadband tissue equivalent proportion counter which can realize miniaturization because it does not require a plurality of gas chambers while realizing a wide band.

In addition, it is possible to implement a broadband tissue equivalent proportion counter using only one gas chamber.

In addition, since a broadband tissue equivalent proportional radar can be implemented using only one gas chamber, the size of the equipment can be reduced.

Also, it is possible to easily and quickly manufacture a tissue-equivalent proportional counter capable of measuring the radiation exposure amount corresponding to the environment even in environments where the required sensitivity is different from each other.

In addition, since it is a spherical tissue equivalent proportional counter, it has an advantage that there is no direction dependency.

In addition, since a plurality of unit pieces of the same shape are laminated and manufactured, it is possible to manufacture a high-sensitivity tissue equivalent proportion counter which can be easily manufactured and assembled, thereby reducing the production cost.

FIG. 1 is an exploded perspective view of a tissue equivalent proportion counter coupled with two different unit tissue equivalent proportion counters,
FIG. 2 is a view showing a chamber hemisphere and a first chamber hemisphere and a second chamber hemisphere of the same type assembled into a spherical chamber through a first coupling structure to make a unit-tissue equivalent proportional counter;
FIG. 3 is a view showing a state in which the first chamber hemispheres and the second chamber hemispheres of the two unitary tissue equivalent proportion counters, which are respectively made, are coupled through the second coupling structure so that the respective proportional counters, such as two different unit structures,
4 shows an anode support through-hole structure and an anode insulator having an epoxy insertion hole into which a conductive epoxy can be inserted by a syringe, an anode support penetrating through the anode insulator,
5 is a view showing a structure equivalent proportional counter in which two unit tissue equivalent proportion counters are assembled,
6 shows a view of a tissue equivalent proportion counter in which eight unit tissue equivalent proportion counters are assembled;
7 is a view showing an elongated rectangular unit body,
8 is a block diagram showing an example of a broadband tissue equivalent proportion counter;
9 is a block diagram showing another example of a broadband tissue equivalent proportion counter;
10 shows a flow in which a signal from the low-sensitivity sensing unit and a signal from the high-sensitivity sensing unit are selected in the switch unit of the broadband tissue equivalent proportion counter,
11 is a flowchart showing an example of a counting method using a broadband tissue equivalent proportional radix.
For reference, the drawings shown in Figs. 2 to 6 are transparent perspective views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

(Embodiment 1)

Tissue-equivalent proportional counter is the unit of tissue equivalence derived from the sensitivity of unit proportional counter to be manufactured, based on the sensitivity of the unit proportional counter and the unit of tissue equivalent proportional counter required by the proportional counter to be manufactured. .

FIG. 1 is an exploded perspective view of a tissue equivalent proportion counter coupled with two different unit tissue equivalent proportion counters. FIG.

Here, the first chamber hemisphere 10 and the second chamber hemisphere 10, each having the same structure as the chamber in which the gas is enclosed and the incident radiation forms a chamber for causing the ionizing action in the gas, are prepared. Tissue equivalent proportional counter is a system in which a gas is sealed in a certain volume and a voltage is applied to both ends of the ion pair to generate an ion pair (positive ion and negative ion) The absorbed dose equivalent to the human tissue is measured by collection. At this time, the electrode is made of an anode wire 100 such as gold-coated tungsten wire or SUS wire having a diameter of 10 mu m. The absorbed dose measured by the tissue equivalent proportion detector 110 is used as information for evaluating the equivalent dose of the human body.

The inventors of the present invention designed a spherical tissue-equivalent proportional counter, which is a tissue-equivalent proportional counter having the advantage of being free from orientation dependency, and designed in the same manner as each other so that the first chamber hemisphere and the second chamber hemisphere, When two are combined, they form one whole sphere.

That is, the first chamber hemisphere and the second chamber hemisphere are formed with a first coupling structure (20) on the opposed surfaces of the outer circumferential rings joined to each other, so that the first chamber hemisphere and the second chamber hemisphere A spherical chamber is assembled through the coupling structure (20).

Assembling the unit-tissue equivalent proportion counter; And unit structurally equivalent proportional counters corresponding to the number of unit tissue equivalent proportional counters required to form the first unit hemispherical unit and the second hemispherical unit of the second chamber hemispherical unit, Through which different proportional counter units are combined. That is, the two first chamber hemispheres and the two second chamber hemispheres are combined to form two unit tissue equivalent proportion counters, and the first chamber hemisphere and the second chamber hemisphere of the unit-structure equivalent proportional counter, respectively, And as a result, each proportional counter, such as two different unit structures, will be combined. 3 shows that the first chamber hemispheres and the second chamber hemispheres of each of the two unitary tissue equivalent proportion counters made are coupled through the second coupling structure 30, 40, 70 to form two different unit tissues, Each proportional counter is shown combined.

By doing so, it becomes possible to overcome the disadvantage that the volume becomes very large since the sensitivity required in the related art increases as the surface area (in the case of a sphere, is proportional to the surface area of the sphere of 4 pi r ² .

For example, to obtain a sensitivity equivalent to a diameter of 125 mm, a sensitivity of 1.12 times can be made with nine pieces of 15.56 mm diameter, while the volume is proportional to (4π / 3) r ³ , We can conclude that we can reduce the number of ships.

Thus, when a tissue-equivalent proportional counter is manufactured in this manner, it is possible to manufacture a detector of very small volume while achieving the same sensitivity. As a result, it is possible to substitute bulky detectors in an environment that was usable only if the volume is small.

Furthermore, it is possible to easily and quickly manufacture a tissue-equivalent proportional counter capable of measuring the radiation dose corresponding to the environment even in environments where the required sensitivities are different from each other. In other words, the tissue-equivalent proportional counter used in an environment where the relative radiation dose is relatively small, such as a living radiation, can be used only when the sensitivity is high. In an environment where radiation exposure is large, such as a nuclear power plant, Can be used only if the sensitivity is relatively low and it is possible to prevent the phenomenon that the detection is not performed due to the saturation state. In this way, the tissue equivalent proportion counter having high sensitivity for different environments, as well as the low sensitivity tissue equivalent proportion counter Can be manufactured easily and quickly.

The first coupling structure 20 may have a coupling groove 21 at a position corresponding to the opposing face of the first chamber hemisphere 10 and the second chamber hemisphere 10, (For example, a connecting pin or the like) 20 inserted into the first chamber hemisphere 21 and the second chamber hemisphere 20, respectively. 2, a first chamber hemisphere and a second chamber hemisphere of the same type and the same view of the chamber hemisphere are assembled into a spherical chamber through the first coupling structure to form a unit-tissue equivalent proportional counter .

In addition, the second coupling structure may be configured such that the first chamber hemisphere and the second chamber hemisphere of the unit proportional counter, which are adjacent to each other, are seated on the inner surface of the coupling portion when the coupling portions are engaged with each other, and an anode support through-hole structure that can be coupled by inserting an annode support 40 thereinto, which has an epoxy insertion hole for inserting a conductive epoxy into a syringe so as to be fixed to the anode support 40, An anode insulator 30 and an anode support 40 inserted into and coupled to the anode support through structure of the anode insulator 30. 4, FIG. 4 shows an anode support penetrating structure 31, an anode insulator 30 having an epoxy insertion hole 32 into which a conductive epoxy can be inserted by a syringe, and an anode Support 40 is shown.

1, the second coupling structure is formed by surrounding the anode insulator 30 and the anode support 40, and connecting the anode chamber 30 and the anode support 40 to each other, And a connection ring (70) for fixing the coupling portion formed in the hemisphere and the second chamber hemisphere.

 The first and second chamber hemispheres positioned at both ends of the plurality of unitary tissue equivalent proportional counters, and the anode insulator 30 is seated on the inner surface of the coupling part formed on the hemisphere of the second chamber, respectively; Inserting and joining the anode support (40) through the anode support through structure (31) at the center of the anode insulator; The anode wire 100 is soldered to both end PCBs 50; And a wire support 80 providing a structure in which the PCB 50 is seated is coupled with the anode insulator 30.

In addition, in order to provide a tension to the anode wire 100 by pushing the PCB with a restoring force, at least one of both ends of the plurality of unitary tissue equivalent proportional counters, And interposing a spring (60) between the wire support (30) and the wire support (40).

And forming an anode through the plurality of unit structure equivalent proportional counters through one common anode wire 100, wherein the step of forming the anode includes the steps of: A tube having an outer diameter smaller than the inner diameter of the anode support is passed through the plurality of anode supports and then the tube is removed to allow the anode wire to pass between the plurality of anode supports, (30 micrometers in diameter) rather than the diameter of the anode support (for example, 10 micrometers in diameter) and the inner diameter of the anode support is used to hook the anode wire with the medium, It can also be penetrated.

As shown in Fig. 5, it is also possible to manufacture a tissue equivalent proportion counter having a relatively low sensitivity by assembling two unit tissue equivalent proportion counters according to the above-described manufacturing method of the tissue equivalent proportion counter, It is also possible to fabricate a tissue equivalent proportion counter by assembling eight unit tissue equivalent proportion counters having a relatively high sensitivity, i. E. A sensitivity four times higher than the tissue equivalent proportion counter shown in Fig. 5. Since a plurality of unit pieces of the same shape are laminated and manufactured in this way, it is easy to manufacture and assemble, and the production cost can be reduced.

(Second Embodiment)

On the other hand, combining the required n pieces (n pieces, where n is a natural number of 2 or more) of tissue-equivalent proportional counters derived based on the sensitivity and the unit texture equivalent proportional counter required by the tissue- (N-1) long rectangular unit pieces, a first chamber hemisphere and a second chamber hemisphere may be combined to produce a tissue equivalent proportion counter.

Here, the elongated rectangular unit body may be formed as shown in Fig.

That is, the first chamber hemispheres and the second chamber hemispheres, which have the same structure as each other, constitute a part of the chamber in which the gas is enclosed and the incident radiation causes the ionizing action in the gas, Preparing a combined long rectangular unit body; (N-1) long rectangular unit pieces are assembled, wherein the first chamber hemispheres and the second chamber hemispheres, which are opened in the long rectangular unit pieces (n-1) Wherein a corresponding second chamber hemisphere of the adjacent elongated rectangular unit pieces and the first chamber hemisphere are assembled through the first coupling structure into a spherical chamber; And the first chamber hemisphere and the second chamber hemisphere opened at both ends of the long rectangular unit pieces (n-1) are provided with a first coupling structure on the opposed surfaces of the outer peripheral rings respectively coupled to each other, The corresponding second chamber hemisphere and the first chamber hemisphere assembling the spherical chamber through the first coupling structure. As described above, the long rectangular unit body actually helps to improve the speed of the assembly when manufacturing a plurality of tissue equivalent proportional counters.

The first coupling structure may have a coupling groove formed at a position corresponding to the opposing face of the first chamber hemisphere and the second chamber hemisphere and the first chamber hemisphere and the second chamber hemisphere through a coupling member inserted into the coupling groove. The coupling of the second chamber hemisphere is achieved.

The long rectangular unit body is integrally coupled to the first chamber hemisphere and the second chamber hemisphere constituting the long rectangular unit body through a second coupling structure.

The second coupling structure may include a first chamber hemisphere constituting the elongated rectangular unit body and an engaging portion formed in the second chamber hemisphere, the first chamber hemispherical member and the second chamber hemisphere being seated on the inner surface of the coupling portion, An anode insulator having an anode support through-hole structure that can be inserted and bonded, has an epoxy insertion hole for inserting a conductive epoxy into a syringe to be fixed to the anode support and for energizing the anode support; And an anode support inserted into the anode support through structure of the anode insulator.

The second coupling structure may further include a connection ring for fixing the first chamber hemisphere constituting the long rectangular unit body and the coupling section formed in the second chamber hemisphere while enclosing the anode insulator and the anode support therein .

Further, the long rectangular unit body is manufactured in a state in which it is integrally assembled up to the anode support, the anode insulator, and the connection ring, which actually helps to improve the speed of the assembly when manufacturing a plurality of tissue equivalent proportion counters.

Further comprising the steps of: placing a first chamber hemisphere at both ends of the tissue equivalent proportion counter and an anode insulator at an inner surface of a coupling portion formed in the second chamber hemisphere; Inserting and joining an anode support through an anode support through structure at the center of the anode insulator; The anode wire being soldered to both end PCBs; And a wire support providing a structure in which the PCB is seated is coupled to the anode insulator.

In addition, a spring may be provided between the anode insulator and the wire support so as to provide a tension to the anode wire by pushing the PCB with a restoring force in at least one of both ends of the tissue equivalent proportion counter Intervening steps.

And forming the anode by passing the entire tissue equivalent proportion counter through a common anode wire, wherein the step of forming the anode comprises the steps of: pre-penetrating the anode wire, The anode wire is passed through a plurality of anode supports, and then the anode wire is passed through the plurality of anode supports, or the anode wire is thicker than the anode wire and the inner diameter of the anode support The anode wire can be hooked to allow the medium to penetrate the plurality of anode supports using a thinner medium than the anode.

8 is a block diagram showing an example of a broadband tissue equivalent proportion counter.

8, the broadband tissue equivalent proportion counter 100 includes a first sensing unit 110, a second sensing unit 120, a first preamplifier 210, a second preamplifier 220, A signal amplifying unit 400, a signal analyzing unit 500, and a gas chamber 600. The signal amplifying unit 400 includes a signal analyzing unit 500,

In this case, the first sensing unit 110 and the second sensing unit 120 are housed in the same gas chamber 600.

Since the sensing units 110 and 120, which are responsible for different sensing bands, are housed in the same gas chamber 600, each gas chamber managed with different gas pressures is not required for each of the sensing units 110 and 120. Therefore, the overall size of the broadband tissue equivalent proportional counter 100 can be remarkably miniaturized.

When the signal from the high-sensitivity band is saturated, the switch unit 300 transmits a signal from the low-sensitivity band to the signal amplification unit 400. When the signal from the high-sensitivity band is not saturated, the signal from the high-sensitivity band is transmitted to the signal amplification unit 400.

Therefore, it is possible to measure radiation in both the low-sensitivity band and the high-sensitivity band without fail.

The first sensing unit 110 and the second sensing unit 120 are connected to each other through a sensing unit 120. The first sensing unit 110 and the second sensing unit 120 are connected to a sensing unit And the number of unit-tissue-equivalent proportional counters.

For example, when the first sensing unit 110 corresponding to a relatively low sensitivity band is composed of one unitary tissue equivalent proportion counter and the second sensing unit 120 corresponding to a relatively high sensitivity band is composed of eight unit tissue equivalent proportions And a combination of counters.

The signal analyzer (MCA) analyzes the signal amplified by the signal amplifier 400 and counts the radiation dose.

9 is a block diagram showing another example of a broadband tissue equivalent proportion counter.

The difference from the embodiment of FIG. 8 is that the broadband tissue equivalent proportion counter 102 of FIG. 9 separates the low-sensitivity band and the high-sensitivity band from the block after the switch unit 300 as well.

9, the broadband tissue equivalent proportion counter 102 according to another embodiment includes a low sensitivity sensing unit 110, a high sensitivity sensing unit 120, a first preamplifier 210, a second preamplifier A switch unit 302, a high gain 410, a low gain 420, a first MCA 510, a second MCA 520, and a gas chamber 600.

The switch unit 302 in FIG. 9 also transmits one signal from the signal of the high sensitivity band and the signal of the low sensitivity band to the signal amplification unit 400 circuit, the switch unit 302 in the embodiment of FIG. 300). In the embodiment of FIG. 9, the switch unit 302 includes a signal amplifying unit 420 for processing a signal of a high sensitivity band, a signal amplifying unit 420 for processing a signal of a low sensitivity band, (410), respectively.

Accordingly, the broadband tissue equivalent proportion counter 102 of FIG. 9 analyzes the signals through the plurality of signal analyzers 510 and 5210.

10 is a view showing a flow in which a signal from the low-sensitivity sensing unit and a signal from the high-sensitivity sensing unit are selected in the broadband tissue equivalent proportion counter.

10, the switching unit of the broadband tissue equivalent proportion counter switches between a state (S10) of transmitting a signal of a high sensitivity band to the signal amplification unit and a state (S20) of transmitting a signal of a low sensitivity band to the signal amplification unit Switch.

If it is found that the signal is saturated in the state (S10) of transmitting the signal of the high sensitivity band to the signal amplification unit ("YES"), the signal of the low sensitivity band which is not saturated is transmitted to the signal amplification unit ) Operation state (S12). If the signal is not saturated ("No"), the state (S10) of continuing to transmit the signal of the high sensitivity band to the signal amplification unit is maintained.

If it is found that the signal is not detected in the state S20 in which the signal of the low sensitivity band is transmitted to the signal amplification unit (in case of "NO"), the signal of the high sensitivity band which can detect the signal is transmitted to the signal amplification unit The operation state is switched (S22). If the signal is detected (in the case of "YES"), the state (S20) of continuing to transmit the signal of the low sensitivity band to the signal amplification unit is maintained.

In this example, a broadband tissue equivalent proportion counter, which is two bands of high sensitivity band / low sensitivity band, is described as an example, but a broadband tissue equivalent proportion counter having a detection band of 3 or more is also possible. In this case, the switch unit is operated to switch the operation state between three or more operation states.

11 is a flowchart showing an example of a counting method using a broadband tissue equivalent proportional radix.

As shown in Fig. 11, an example of a counting method using a broadband tissue equivalent proportion counter is a method of counting a first signal having a first sensitivity band (e.g., a low sensitivity band) and a second signal having a first sensitivity band (S100) of receiving a second signal detected in a second sensing unit (the first sensing unit and the second sensing unit are housed in the same gas chamber) having a sensitive second sensitivity band, Selecting one of the first signal and the second signal and transmitting the selected signal to the signal analyzer (S120); amplifying the signal selected from the switch part of the signal amplifying part, the first signal and the second signal and transmitting the signal; And analyzing the signal amplified by the signal amplification unit (S140).

Between step S100 and step S120, it is preferable that the preamplifier further comprises a preprocessing step (S110) of amplifying the first signal and the second signal, respectively. Also, the first signal and the second signal may be amplified by different preamplifiers, respectively.

As described above with reference to FIG. 10, in step S120, when the first signal, which is a signal sensed in the high-sensitivity band, is saturated, only the second signal, which is a relatively low- . When the second signal is not detected in the low-sensitivity band, only the first signal, which is a relatively high-sensitivity band signal, is transmitted to the signal amplification unit.

This adjustment of the sensitivity band is preset by combining the required number of unit tissue equivalent proportional counters in the first sensitivity band and the second sensitivity band, respectively, in the gas chamber as described above. Since the sensitivity can be controlled in proportion to the number of unit proportional counter, the sensitivity can be easily controlled by controlling the number of units of the unit proportional equalizer.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various modifications and changes may be made without departing from the scope of the appended claims.

10 ... first chamber hemisphere or second chamber hemisphere
20 ... first coupling structure
30 ... anode insulator
31 ... Anode support through structure
32 ... epoxy insertion hole
40 ... Anode support
50 ... Anode Wire PCB
60 ... spring
70 ... connecting ring
80 ... wire support
100 ... anode wire

Claims (15)

A first sensing unit having a first sensitivity band and a second sensing unit having a second sensitivity band that is more sensitive than the first sensitivity band;
A first preamplifier for amplifying a signal detected by the first sensing unit and a second preamplifier for amplifying a signal detected by the second sensing unit;
A switch unit for selecting either the first signal from the first preamplifier unit or the second signal from the second preamplifier unit;
A signal amplifier amplifying a signal selected from the switch; And
And a signal analyzer for analyzing the signal amplified by the signal amplifier,
Wherein the first sensing unit and the second sensing unit are housed in the same gas chamber,
Wherein the first sensing unit and the second sensing unit are units based on the sensitivity and the sensitivity of the unit proportional counter which is required by the tissue equivalent proportional counter to be manufactured, Tissue-proportional proportional counter,
Wherein the unitary tissue equivalent proportion counter comprises:
The same number of first chamber hemispheres having the same structure in which the gas is enclosed and the incident radiation forms a chamber for causing an ionizing action in the gas and the first coupling structure is formed on the opposite surface of the outer ring to be coupled to each other, A second chamber hemisphere,
One unitary tissue equivalent proportion counter is coupled to the other unit tissue equivalent proportion counter through the second coupling structure,
The second engagement structure includes:
When the first chamber hemisphere of the unit proportional counter and the second chamber hemisphere of the second unit hemispherical unit which are adjacent to each other are engaged with each other, they are seated on the inner surface of the coupling portion and the central portion thereof can be joined by inserting an anode support An anode insulator having an anode support through-hole structure, an anode insulator having an epoxy insertion hole for inserting a conductive epoxy into a syringe to be fixed to the anode support and for energizing the anode support; And
And an anode support inserted into the anode support through structure of the anode insulator.
The method according to claim 1,
Wherein the switch unit transmits the first signal to the signal amplification unit when the second signal is saturated.
The method according to claim 1,
Wherein the switch unit transmits the second signal to the signal amplifying unit when the first signal is not detected.
delete delete delete delete The method according to claim 1,
The second engagement structure includes:
Further comprising a connection ring enclosing the anode insulator and the anode support and fixing a coupling portion formed in the first chamber hemisphere and the second chamber hemisphere of different unit tissue equivalent proportion counters adjacent to each other, counter.
9. The method of claim 8,
Wherein the first and second chamber hemispheres are disposed at both ends of the plurality of unitary tissue equivalent proportion counters, and the anode insulator is seated on the inner surface of the coupling part formed in the second chamber hemisphere,
And an anode support through the anode support through structure at the center of the anode insulator. The anode wire is soldered to both end PCBs,
Wherein a wire support providing a structure in which the PCB is seated is coupled with the anode insulator.
10. The method of claim 9,
A spring is interposed between the anode insulator and the wire support so as to provide a tension to the anode wire by pushing the PCB with a restoring force in at least one of both ends of the plurality of unit tissue equivalent proportional counters, / RTI > further comprising: a broadband tissue equivalent proportional counter.
11. The method of claim 10,
Further comprising one common anode wire passing between the plurality of unitary tissue equivalent proportional counters,
A tube having an outer diameter smaller than the inner diameter of the anode support while passing through the anode wire is passed through the plurality of anode supports, and then the tube is removed so that the anode wire passes through the plurality of anode supports Or
Wherein an anode is formed by hooking the anode wire with a thinner medium than the diameter of the anode wire and using a thinner medium than the inside diameter of the anode support so that the medium passes through the plurality of anode supports.
A second sensing unit having a first signal detected by the first sensing unit having the first sensitivity band and a second sensitivity band that is more sensitive than the first sensitivity band, the first sensing unit and the second sensing unit being connected to the same gas chamber Receiving the second signal detected by the switch unit;
Selecting and transmitting the first signal and the second signal to the signal analyzer, wherein the signal is not saturated while the first signal and the second signal are detectable;
Amplifying a signal selected and transmitted from the switch unit among the first signal and the second signal; And
And analyzing a signal analyzed by the signal amplified by the signal amplifying unit, the method comprising:
Wherein the first sensing unit and the second sensing unit are housed in the same gas chamber,
Wherein the first sensing unit and the second sensing unit are units based on the sensitivity and the sensitivity of the unit proportional counter which is required by the tissue equivalent proportional counter to be manufactured, Tissue-proportional proportional counter,
Wherein the unitary tissue equivalent proportion counter comprises:
The same number of first chamber hemispheres having the same structure in which the gas is enclosed and the incident radiation forms a chamber for causing an ionizing action in the gas and the first coupling structure is formed on the opposite surface of the outer ring to be coupled to each other, A second chamber hemisphere,
One unitary tissue equivalent proportion counter is coupled to the other unit tissue equivalent proportion counter through the second coupling structure,
The second engagement structure includes:
When the first chamber hemisphere of the unit proportional counter and the second chamber hemisphere of the second unit hemispherical unit which are adjacent to each other are engaged with each other, they are seated on the inner surface of the coupling portion and the central portion thereof can be joined by inserting an anode support An anode insulator having an anode support through-hole structure, an anode insulator having an epoxy insertion hole for inserting a conductive epoxy into a syringe to be fixed to the anode support and for energizing the anode support; And
And an anode support inserted into the anode support through structure of the anode insulator. A Method of Counting Using Broadband Tissue Equivalent Proportional Counter.
13. The method of claim 12,
Wherein,
Wherein the second signal is transmitted only to the signal amplification unit when the second signal is saturated and the second signal is transmitted to the signal amplification unit when the first signal is not detected, Counting method.
13. The method of claim 12,
Wherein the first sensitivity band and the second sensitivity band are set and combined in the gas chamber with a required number of unit tissue equivalent proportional counters respectively in the first sensitivity band and the second sensitivity band, Further comprising: a counting method using a broadband tissue equivalent proportional counter.
13. The method of claim 12,
Before receiving the first signal and the second signal,
And a pre-amplifying step of amplifying the first signal and the second signal, respectively, by a preamplifier unit.

Images