JP2014077677A - Thermoluminescence dosimeter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thermoluminescence dosimeter capable of precisely measuring a dose equivalent even when, for example, skin is extremely thin by forming a base tape to be thinner while maintaining the strength, the durability and the heat resistance.SOLUTION: The thermoluminescence dosimeter includes: a base tape 8 that holds fluorescent substance 7 for radiation dosimetry; a cover which covers the fluorescent substance 7 side of the base tape 8; and a fixing member for sandwiching and fixing the periphery area of the base tape 8 and a transparent cover 9. The base tape 8 has a concave portion 8a for making the base tape 8 thinner in a generally central area to place the fluorescent substance 7 in the concave portion 8a.

Description

  The present invention relates to a thermofluorescence dosimeter used for detection of radiation.

  Conventionally, there are various methods for detecting radiation, and one of them is a thermofluorescence dosimeter using a phenomenon in which light is emitted by applying heat after irradiation. In the thermofluorescence dosimeter, the radiation dose can be obtained based on a glow curve indicating the relationship between the heating temperature of the thermoluminescent material and the emission intensity. In addition, by selecting a luminescent material, it can be applied to various types of radiation (β rays, γ rays, neutron rays, etc.), and can be used repeatedly by returning to the state before irradiation again after heating. Some of the above-mentioned thermofluorescence dosimeters are composed of a phosphor, a substrate and a cover for holding the phosphor, and a holder (card) for housing them (for example, see Patent Document 1).

JP-A-53-77576

  In the thermofluorescence dosimeter as described above, it is a problem to measure the dose equivalent of the skin (for example, “70 μm dose equivalent” which is the dose equivalent of the tissue having a depth of 70 μm from the body surface). That is, in order to correspond to a depth of 70 μm from the body surface of the skin having a specific gravity of approximately 1, generally a base tape made of a resin having a specific gravity greater than 1 is made thin to about 40 to 60 μm. Must be formed. That is, it can be said that the phosphor placed on the base tape of about 40 to 60 μm absorbs the same amount of radiation as the tissue having a depth of 70 μm from the body surface.

  However, if the base tape is thinly formed, the strength and durability of the base tape are reduced, and it becomes difficult to hold the phosphor.

  The present invention has been devised to solve such problems of the prior art, and the main purpose thereof is a base tape capable of measuring the dose equivalent of the skin so as to be closer to the accuracy. It is in providing the thermofluorescence dosimeter provided with.

  The thermofluorescence dosimeter of the present invention includes a base tape that holds a phosphor for measuring radiation dose, a cover that covers the phosphor side of the base tape, and a fixing member that sandwiches and fixes each outer peripheral portion of the base tape and the cover. And a concave portion for thinning the base tape is provided at a substantially central portion of the base tape, and a phosphor is placed in the concave portion.

  According to the present invention, the base tape can be thinned while maintaining strength, durability, and heat resistance. For example, even a dose equivalent of a very thin skin can be measured more accurately.

Whole perspective view which shows the example of TL badge using the thermofluorescence dosimeter in embodiment of this invention 1 is an exploded perspective view showing a configuration of a phosphor unit in an embodiment of the present invention. Sectional drawing of the principal part which shows the assembly state of the fluorescent substance unit in embodiment of this invention The principal part sectional side view in the use condition of the TL badge in embodiment of this invention The schematic diagram which shows the measuring point of the fluorescent substance unit in embodiment of this invention The perspective view of the base tape in embodiment of this invention Sectional drawing of the fluorescent substance unit in embodiment of this invention Sectional drawing of the base tape and fluorescent substance in embodiment of this invention

  A first invention made to solve the above problems is a base tape that holds a phosphor for measuring radiation dose, a cover that covers the phosphor side of the base tape, and each outer periphery of the base tape and the cover. A fixing member for sandwiching and fixing the portion, a recess for thinning the base tape is provided at a substantially central portion of the base tape, and the phosphor is placed in the recess.

  According to this, the base tape can be thinned while maintaining the strength, durability, and heat resistance. For example, even a dose equivalent of a very thin skin can be measured more accurately.

  According to a second aspect of the present invention, in the base tape, the thickness of the concave portion forming portion is 70 μm or less, and the outer peripheral portion of the concave portion is 70 μm or more.

  According to this, the dose equivalent of the skin can be measured more accurately. That is, the thickness of the skin is generally about 70 μm. Since a general base tape material (resin) has a specific gravity higher than that of the skin, the thickness of the recessed portion forming portion can be made to be 70 μm or less, thereby making it closer to a more accurate value. Moreover, an outer peripheral part can maintain intensity | strength by making an outer peripheral part 70 micrometers or more.

  According to a third aspect of the present invention, the fixing member includes a frame body having a step portion on which an outer peripheral portion of the base tape can be placed, and each outer peripheral portion of the base tape and the cover. A ring sandwiched therebetween, wherein the annular frame and the ring are made of the same metal and fixed.

  According to this, the influence on radiation becomes the same, and the measured value can be stabilized. That is, by making the annular frame and the ring the same metal, the type and amount of radiation transmitted through the annular frame and the ring are the same, so the amount of radiation absorbed by the phosphor from an oblique direction is made constant. be able to. Furthermore, the coefficient of thermal expansion can be made closer (same). Further, since the annular frame 6 and the ring 10 have the same degree of thermal expansion, even when heated and cooled, the ring frame 6 and the ring 10 can expand and contract in the same manner, and can maintain a sealed state.

According to a fourth aspect of the present invention, the annular frame body and the ring are made of an aluminum material when the phosphor is Li ₂ B ₄ O ₇ (hereinafter referred to as LiB) (lithium borate). It is characterized by.

  According to this, in the measurement with the LiB phosphor, there is no influence by the material of the annular frame and the ring, and accurate measurement can be performed.

  According to a fifth aspect of the present invention, the annular frame and the ring are made of a brass material when the phosphor is CaS, and the holder that supports the annular frame has an axial direction of the annular frame. A lead plate is provided so as to be sandwiched between both sides.

According to this, in the case of a phosphor of CaSO ₄ (hereinafter referred to as “CaS”) (calcium sulfate), the sensitivity to X-rays is too high, and therefore, before and after the annular frame (on both sides in the axial direction of the annular frame). By providing a lead plate and further making the material of the annular frame brass, X-rays not only from the front and rear but also from an oblique direction are shielded, thereby reducing the dependence of the X-rays on the phosphor irradiation direction. Measurement stability can be achieved.

(Embodiment)
Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an overall perspective view showing an example of a TL (thermoluminescence) badge using a thermofluorescence dosimeter according to an embodiment of the present invention. The illustrated TL badge 1 is a rectangular flat box-shaped case 2 (holder), an elongated flat plate 3 that can be inserted and removed in the longitudinal direction of the case 2, and a plate 3 that is arranged in the longitudinal direction thereof. It is comprised by the fluorescent substance unit 5 which can be attached or detached freely.

  The plate 3 is provided with four circular holding holes 4 arranged in the longitudinal direction. A disc-shaped phosphor unit 5 is mounted in the holding hole 4. The holding hole 4 is formed in a shape having an inner diameter that can accommodate the phosphor unit 5 with a little play, and an inward flange portion 4a that can support the outer peripheral portion of the phosphor unit 5 in a mounted state. Yes. Although only one phosphor unit 5 is illustrated in FIG. 1, the phosphor unit 5 is inserted into each of the four holding holes 4 and the plate is immersed (inserted) into the case 2. Of course, the shape of the phosphor unit 5 is not limited to a disk shape (circular shape), and may be an ellipse, a polygon, or the like.

  FIG. 2 is an exploded perspective view showing the configuration of the phosphor unit 5 in the embodiment of the present invention. The phosphor unit 5 includes a circular annular frame 6 having a size to be placed on the inward flange portion 4 a of the holding hole 4 and a phosphor 7 integrally mounted on the upper surface and is accommodated in the annular frame 6. The base tape 8 includes a transparent cover 9 that covers the entire top surface of the base tape 8 including the phosphor 7, and a ring 10 that fixes the base tape 8 and the transparent cover 9 to the annular frame 6. Although the outer shape of the annular frame 6, the base tape 8, and the transparent cover 9 is circular in this embodiment, it may be oval or polygonal as described above. At this time, the fixing members that sandwich and fix the outer peripheral portions of the base tape 8 and the transparent cover 9 are the annular frame 6 and the ring 10. However, the plate 3 may be clamped and fixed between the inward flange portion 4a of the holding hole 4 and the ring 10, or may be clamped between the inward flange portion 4a by caulking the upper portion of the plate 3 (ring 10 side). It may be fixed. Even if the shape of the base tape 8 is a flat plate shape, the recessed part demonstrated later may be formed.

  FIG. 3 is a cross-sectional view of the main part showing the assembled state of phosphor unit 5 in the embodiment of the present invention. The annular frame 6 is formed in a flat dish shape by a peripheral wall portion 6a that forms the outer periphery thereof and a step portion 6b that is molded inward in the radial direction from a base portion inside the peripheral wall portion 6a. The step portion 6b that forms the bottom wall of the annular frame 6 extends from the peripheral wall portion 6a by a predetermined length, and an opening formed in a circular shape by the inner peripheral portion of the step portion 6b in the center portion of the bottom wall. 6c is provided. The peripheral wall portion 6a and the step portion 6b are preferably the same thickness. However, since the peripheral wall portion 6a may be finally caulked, the peripheral wall portion 6a may be formed thinner than the step portion 6b.

  The base tape 8 may be formed of, for example, polyimide resin mixed with carbon powder, thereby ensuring high heat resistance and light shielding properties. Moreover, the transparent cover 9 is good to be formed, for example by Teflon (trademark), and, thereby, transparency and heat resistance are ensured. The outer diameters of the base tape 8 and the transparent cover 9 are the same as or substantially smaller than the inner diameter of the peripheral wall 6 a of the annular frame 6. The outer peripheral portion of the base tape 8 and the outer peripheral portion of the transparent cover 9 are laminated in this order on the upper surface of the stepped portion 6b in FIG.

  An annular ring 10 is further stacked on the outer peripheral portion of the transparent cover 9 in a state where the outer peripheral portion of the transparent cover 9 is stacked on the outer peripheral portion of the base tape 8 placed on the stepped portion 6b. The ring 10 is molded to have a size with an outer diameter that is substantially in close contact with the inner peripheral surface of the peripheral wall portion 6a, and has a width that is substantially the same as the inwardly extending length of the step portion 6b and a thickness that is lower than the height of the peripheral wall portion 6a. It is formed in a rectangular cross-sectional shape.

  By laminating the ring 10 as described above and bonding the outer peripheral surface of the ring 10 and the inner peripheral surface of the peripheral wall 6a, the outer periphery of the base tape 8 and the transparent cover 9 is provided between the step 6b and the ring 10. Part is pinched. In this way, the base tape 8 and the transparent cover 9 are integrally fixed to the annular frame 6 together with the ring 10, and the phosphor unit is unitized by the annular frame 6, the base tape 8, the transparent cover 9, and the ring 10. 5 is formed. Note that the method of fixing the ring 10 to the annular frame 6 is not limited to adhesion. For example, as shown by the arrow A in FIG. 3, the ring 10 is fixed by caulking the appropriate portion of the peripheral wall portion 6a. You may make it do.

  A dome portion 9a bulging in a dome shape is formed on the side opposite to the base tape 8 as shown in FIG. . The phosphor 7 disposed (held) on the upper surface of the base tape 8 is received (accommodated) in the space 11 between the dome portion 9a and the base tape 8, and the space 11 is externally fixed by fixing the ring 10 described above. Sealed against.

As a material of the phosphor 7, for example, as a lithium borate phosphor having a body substantially equivalent effective atomic number (7.26), natural ⁿ Li, ⁶ Li of the ⁿ B was isotopically enriched, ⁷ Li And ⁶ Li ₂ ¹⁰ B ₄ O ₇ (Cu) and ⁷ Li ₂ ¹¹ B ₄ O ₇ (Cu) in combination with ¹⁰ B and ¹¹ B, and non-concentrated ⁿ Li ₂ ⁿ B ₄ O ₇ (Cu) And the calcium sulfate phosphor CaSO ₄ (Tm) having high sensitivity, and these four types of phosphors may be used according to the purpose of measurement.

^{_{Incidentally, n Li 2 n B 4 O}} 7 (Cu) is the biological equivalent LiB by adding Cu as activator is obtained by a phosphor, gamma, X, other β-rays, with respect to thermal neutrons Has sensitivity. ⁷ Li ₂ ¹¹ B ₄ O ₇ (Cu) uses an isotope-enriched material ⁷ Li ₂ ¹¹ B ₄ instead of ⁿ Li ₂ ⁿ B ₄ and has almost no sensitivity to neutrons. , X, and β-ray characteristics are equivalent to ⁿ Li ₂ ⁿ B ₄ O ₇ (Cu). ⁶ Li ₂ ¹⁰ B ₄ O ₇ (Cu) uses an isotope enriched material ⁶ Li ₂ ¹⁰ B ₄ O ₇ instead of ⁿ Li ₂ ⁿ B ₄ O ₇ and has high sensitivity to thermal neutrons. The characteristics for γ, X, and β rays are equivalent to ⁿ Li ₂ ⁿ B ₄ O ₇ (Cu).

CaSO ₄ (Tm) is a phosphor obtained by adding Tm as an activator to non-biologically equivalent CaS, and is highly sensitive to γ · X rays. Used for line measurement. In addition, since there is an excessive response to low-energy γ · X-rays without a metal shield, a LiB phosphor is combined and used for γ · X-ray energy evaluation. Note that neutron beams have little sensitivity.

Moreover, in the thermofluorescence dosimeter, when using LiB system that may use various shielding materials corresponding to the measurement purpose and line type, for example, for the evaluation of the deep dose equivalent (1 cm under the skin), When the phosphor unit 5 has a thickness of 160 mg / cm ² , a 1000 mg / cm ² resin shield is used in combination with a 840 mg / cm ² ABS hanger. A 50 mg / cm ² shield is used to measure the skin surface dose (7 mg / cm ² β-absorbed dose under the skin), and a Cd (cadmium) shield is used to measure the neutron dose using an isotope-enriched phosphor. Thermal neutron absorption and Sn (tin) shield are used for gamma ray compensation. In the case of the CaS system, a resin shield and a Pb (lead) shield are used for γ · X-ray energy evaluation and low-dose measurement evaluation, respectively.

  In the case of the present TL badge 1, the material of the case 2 is ABS resin, and the material of the plate 3 is Noryl resin. As shown in FIG. 1, there are cases where six rectangular depressions 2a are provided on the upper and lower surfaces of the case 2 (only the upper surface is shown in the figure), and each of the depressions 2a has a flat plate-like shield body 12. Are pasted together. In addition, there are a two-window shape in which the ring 10 and the light-shielding film 13a are provided in two places, and a windowless shape in which eight shield bodies 12 are attached to all (four places on the front and back), which can be used properly according to the measurement purpose.

  FIG. 4 is a side cross-sectional view of the main part of the TL badge 1 in use according to the embodiment of the present invention. The upper side of the figure is the surface side in the wearing state, and the lower side of the figure is the human body side. As shown in the figure, the phosphor unit 5 is disposed with the transparent cover 9 side facing down.

The base tape 8 in the phosphor unit 5 is made of a carbon-containing high heat-resistant polyimide film having a thickness of about 100 μm, the phosphor 7 having an average particle diameter of about 90 μm is formed in almost one layer, and the transparent cover 9 is made of Teflon (registered trademark). ) It may consist of materials. As described above, the phosphor 7 is shielded from the outside by the base tape 8 and the transparent cover 9, so that dust, dust, and the like are prevented from adhering to the phosphor 7. The phosphor 7 having a layer thickness of 15 mg / cm ² is covered with 11 mg / cm ² (base tape 8) and 3 mg / cm ² (transparent cover 9). In the present embodiment, the carbon content of the base tape 8 is about 2% of the whole.

  FIG. 5 is a schematic diagram showing a measurement procedure of the phosphor unit 5 in the embodiment of the present invention. The detector may be a light heating system, a tungsten lamp 14 that emits infrared rays is disposed on the base tape 8 side, a Si filter 15 is disposed on the phosphor unit 5 side of the tungsten lamp 14, and the Si filter A condensing tube 16 is disposed between 15 and the phosphor unit 5. A PM tube 18 is disposed on the transparent cover 9 side of the phosphor unit 5 via an optical filter 17.

  Visible light having a wavelength of 1.2 μm or less is removed from the light from the tungsten lamp 14 by the Si filter 15. The infrared light that has passed through the Si filter 15 is condensed on the base tape 8 of the phosphor unit 5 by the condenser tube 16. The base tape 8 is formed of the carbon-containing high heat-resistant polyimide film as described above, and absorbs infrared light in the light that has passed through the Si filter 15 to increase the temperature and heat the phosphor 7. .

  The phosphor 7 is heated to about 350 ° C., and the time required for the temperature increase is within one second. The tungsten lamp 14 is turned on three times. Pre-annealing is performed at the first lighting, measurement is performed at the second lighting, and residual dose is erased at the third lighting. Thus, the phosphor unit 5 can be measured, and the time required for the measurement and annealing of one phosphor unit 5 is about 3 seconds.

  As described above, according to the present invention, since an element provided with one kind of phosphor 7 is made one phosphor unit 5, it can be handled for each unit. When the TL badge 1 arranged on the plate 3 is prepared, the unit can be measured and selected so that the sensitivity of the phosphors 7 of the same type falls within the allowable value, so that the yield is good.

  Further, since the ring 10 is fixed to the annular frame 6 and the base tape 8 and the transparent cover 9 are sandwiched, the sealing performance of the space for receiving and accommodating the phosphor 7 can be easily ensured. For example, by making the flatness of the ring 10 to a certain degree of accuracy, the base tape 8 and the transparent cover 9 that are sandwiched between the ring 10 and the stepped portion 6 b only by caulking the peripheral wall portion 6 a of the annular frame 6. It is possible to ensure a high degree of adhesion of the outer peripheral portion. This makes it easy to assemble the phosphor unit 5 that can ensure protection of the phosphor 7 from moisture, dust, dust, etc., and there is no problem in handling the phosphor 7 in units of the phosphor unit 5. It does not occur.

  Further, the annular frame 6 and the ring 10 may be formed of a material that does not adversely affect the measurement sensitivity in accordance with each material of the phosphor 7. For example, when the annular frame 6 and the ring 10 are formed of the same metal. Good. Thus, by making the annular frame 6 and the ring 10 the same metal, the influence on radiation becomes the same, and the measurement value can be stabilized. That is, by making the annular frame 6 and the ring the same metal, the type and amount of radiation transmitted through the annular frame 6 and the ring 10 are the same, so the radiation dose absorbed by the phosphor 7 from an oblique direction. Can be made constant. Note that the same metal does not have to be exactly the same type of metal, and metals having a specific gravity close to each other (within about plus or minus 10%) are sufficient. Moreover, for example, one may be an alloy like a combination of aluminum and an aluminum alloy.

  Furthermore, by making the annular frame 6 and the ring 10 the same metal, the coefficient of thermal expansion can be made closer (same). In the present invention, since the degree of thermal expansion of the annular frame 6 and the ring 10 is the same, even when heated and cooled, the ring frame 6 and the ring 10 can expand and contract in the same manner, and maintain a sealed state. Further, even if the annular frame 6 and the ring 10 are not strictly the same metal, it is sufficient if the metals have similar coefficients of thermal expansion (within plus or minus 10%). Moreover, in order to obtain said effect, resin of the same material may be sufficient. Of course, the resin of the same material here does not need to be exactly the same type, and it is sufficient if the specific gravity and the coefficient of thermal expansion are substantially the same. However, the same metal is most preferable.

  Further, when the phosphor 7 is LiB, the annular frame 6 and the ring 10 may be formed of an aluminum material. In this case, in the measurement by the phosphor 7 of LiB, there is no influence by the material of the annular frame 6 and the ring 10, and an accurate measurement can be performed.

  When the phosphor 7 is CaS, the annular frame 6 and the ring 10 are preferably made of brass material, and lead plates are preferably provided before and after the annular frame 6. In the case of the CaS phosphor 7, since sensitivity to X-rays is too high, it reacts with X-rays from the oblique direction of the annular frame 6. By selecting a large brass material, the X-ray from such an oblique direction is shielded, so that the dependency of the X-ray on the phosphor 7 irradiation direction can be reduced, and the measurement can be stabilized. obtain.

  In addition, the above-mentioned base tape 8 in Panasonic SN Kyushu Co., Ltd., 2826, Shimodajima, Sadohara-cho, Miyazaki-shi, Miyazaki Prefecture, described above may be a flat plate shape as described above, or a shape in which a concave portion to be described below is formed. good.

  6A and 6B are perspective views of the base tape according to the embodiment of the present invention. FIG. 6A shows a case where only the base tape is used, and FIG. 6B shows a case where a phosphor is placed. FIG. 7 is a cross-sectional view of the phosphor unit in the embodiment of the present invention. FIG. 8 is a cross-sectional view of the base tape and the phosphor according to the embodiment of the present invention. FIG. 8A shows a case where a recess is formed as in this embodiment, and FIG. Therefore, the case where a concave portion as described in the embodiment is not formed is shown.

  6-8, the circular recessed part 8a is formed in the approximate center of the base tape 8, and the fluorescent substance 7 is arrange | positioned in the recessed part 8a. Since the particle size of the phosphor 7 may be larger than the depth of the concave portion 8a, the phosphor 7 is not necessarily contained below the surface of the outer peripheral portion 8b.

  The size of the recess 8a is as follows in FIG. That is, the outer diameter D of the base tape 8 is 7 mm (may be about 5 to 10 mm, but is not limited to this range), and the outer diameter d of the recess 8 a is 4 mm (about 3 to 6 mm. It is not limited to the range and is always smaller than D). The area of the recess 8a is preferably about 25 to 40% of the area of the base tape 8. The phosphor 7 is mounted in a substantially circular shape, and the diameter of the mounting region is approximately 3 mm (may be approximately 1 to 5 mm, but is not limited to this range and is always smaller than d). The concave portion 8a is formed to have a margin of about 0.5 mm (which is preferably about 0.3 to 1 mm, but not limited to this range) around the area where the phosphor 7 is placed. Further, the thickness H of the outer peripheral portion 8b of the base tape 8 is 80 μm (preferably about 70 to 100 μm, but is not limited to this range), and the thickness h of the recessed portion 8a forming portion is 50 μm (about 40 to 60 μm). However, it is not limited to this range and is always smaller than H). That is, a hole of about 20 to 40 μm is formed. The depth of the recess 8a is 30 μm (may be about 20 to 50 μm, but is not limited to this range), and h is preferably about 30 to 60% of H.

  The shape of the recess 8a is not limited to a circle, and may be another shape such as an ellipse or a polygon. Similarly, the outer shape of the base tape 8 may be another shape such as an ellipse or a polygon, and the outer shape of the base tape 8 and the outer shape of the recess 8a are not necessarily the same. However, by making the outer shape of the base tape 8 and the outer shape of the recess 8a the same, the strength of the base tape 8 can be maintained in a balanced manner. Further, by making the outer shape of the base tape 8 and the outer shape of the concave portion 8a the same, the width of the outer peripheral portion 8b of the base tape 8 (the region of height H not provided with the concave portion 8a) is made constant. The radiation absorption is not greatly biased depending on the direction. Further, by making both outer shapes circular, in the entire circumferential direction of the phosphor 7, the direction of the width of the outer peripheral portion 8b, the thickness of the base tape 8, etc. is lost, and the radiation absorption of the phosphor 7 is biased by the direction. It becomes difficult. Further, the outer shape of the recess 8a is preferably the same as the outer shape of the stepped portion 6b of the annular frame 6, the transparent cover 9, and the ring 10. Thereby, the directionality in the radiation absorption of the fluorescent substance 7 is further relaxed, and it can approach a more accurate value.

  Moreover, it is preferable that the width of the outer peripheral portion 8 b of the base tape 8 is larger than the width of the fixing member such as the step portion 6 b of the annular frame 6 and the ring 10. Thereby, since fixing members, such as the step part 6b of the annular frame 6, and the ring 10, can clamp the outer peripheral part 8b among the base tapes 8, the base tape 8 can be firmly clamped by the fixing members.

  With the above-described configuration, in the base tape 8, the region on which the phosphor 7 is placed is formed thin to have a thickness h, and at the same time, the periphery thereof is set to a thickness H (H> h). The base tape 8 can be both strong and thin.

  By making the phosphor 7 mounting area thinner, a value closer to the dose equivalent of radiation hitting human skin can be measured. Human skin generally has a specific gravity of about 1 and a thickness of about 70 μm. On the other hand, since the specific gravity of the resin constituting the base tape 8 is generally 1 or more, the thickness needs to be 70 μm or less. Further, since the base tape 8 is also required to have heat resistance, strength, and durability, a certain thickness or more is required. That is, as described above, the phosphor unit 5 is heated to about 350 degrees during radiation dose measurement, and therefore, in this embodiment, the base tape 8 is made of a high heat resistant polyimide film. Since the specific gravity of the polyimide film is about 1.4, the thickness h of the recessed portion forming portion is 50 μm. Although depending on the specific gravity of the material of the base tape 8, since the specific gravity of the resin is generally larger than h, h is preferably 70 μm or less, particularly 40 to 60 μm. When h is 40 μm or less, it is difficult to ensure the strength of the base tape 8. Of course, if the material of the base tape 8 is changed, the thickness H of the outer periphery and the thickness h of the recessed portion forming portion also change, but the region where the phosphor 7 is placed by forming the recessed portion 8a is formed thinner than the outer periphery. By doing so, the same effect can be obtained.

  The recess 8a forming process on the base tape 8 is easily performed by laser processing. Therefore, although the surface of the concave portion 8a may be somewhat uneven, the thickness h of the concave portion 8a may be set within about 40 to 60 μm.

  Further, as shown in FIG. 8A, the step between the concave portion 8a and the outer peripheral portion 8b does not need to be a right angle, and may be an inclined surface or a curved line.

  In addition, a water resistant material may be coated on the back side of the base tape 8 in order to improve the water resistance of the base tape 8 and prevent water vapor or moisture in the air from entering the phosphor unit 5. The back side of the base tape 8 is the back side with the surface on which the phosphor is placed as the front side. In particular, when the phosphor 7 mounting region of the base tape 8 is thinly formed as described above, the possibility of moisture and the like entering is increased as compared with the case where the phosphor 7 is formed thick. Can be prevented. The thickness of the water-resistant layer is thinner than that of the base tape 8, and is preferably about 5 to 30 μm.

  The preferred embodiments of the present invention have been described above. However, as those skilled in the art can easily understand, the present invention is not limited to such portable implementations, and the gist of the present invention is not limited. Changes can be made as appropriate without departing from the scope. Further, all the components shown in the above embodiment are not necessarily essential, and can be appropriately selected without departing from the gist of the present invention.

  The thermofluorescence dosimeter according to the present invention ensures the hermeticity of the space that accommodates the phosphor, and is easily adjusted when two or more phosphors of the same type are disposed because they are handled in units. It is useful as a fluorescence dosimeter because it can ensure measurement accuracy.

DESCRIPTION OF SYMBOLS 1 TL badge 5 Phosphor unit 6 Annular frame 6a Peripheral wall part 6b Step part 7 Phosphor 8 Base tape 8a Recessed part 8b Outer part 9 Transparent cover 10 Ring

Claims (5)

A base tape that holds a phosphor for measuring radiation dose; a cover that covers the phosphor side of the base tape; and a fixing member that sandwiches and fixes each outer peripheral portion of the base tape and the cover,
A thermofluorescence dosimeter characterized in that a recess for thinning the base tape is provided in a substantially central portion of the base tape, and the phosphor is placed in the recess. 2. The thermofluorescence dosimeter according to claim 1, wherein the concave portion forming portion has a thickness of 70 μm or less and an outer peripheral portion of the concave portion is 70 μm or more. The fixing member includes a frame body provided with a step portion on which an outer peripheral portion of the base tape can be placed inside, and a ring for sandwiching each outer peripheral portion of the base tape and the cover between the step portion. The thermoluminescent dosimeter according to claim 1, wherein the annular frame body and the ring are formed of the same metal and are fixed to each other. The thermoluminescent dosimeter according to any one of claims 1 to 3, wherein the annular frame and the ring are made of an aluminum material when the phosphor is LiB. The annular frame and the ring are made of brass when the phosphor is CaS, and lead plates are sandwiched between holders that support the annular frame on both sides in the axial direction of the annular frame. The thermofluorescence dosimeter according to any one of claims 1 to 3, wherein the thermofluorescence dosimeter is provided.