WO2014061069A1 - 極低温用測温抵抗体素子 - Google Patents
極低温用測温抵抗体素子 Download PDFInfo
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- WO2014061069A1 WO2014061069A1 PCT/JP2012/006718 JP2012006718W WO2014061069A1 WO 2014061069 A1 WO2014061069 A1 WO 2014061069A1 JP 2012006718 W JP2012006718 W JP 2012006718W WO 2014061069 A1 WO2014061069 A1 WO 2014061069A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K13/00—Thermometers specially adapted for specific purposes
- G01K13/006—Thermometers specially adapted for specific purposes for cryogenic purposes
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- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B19/00—Other methods of shaping glass
- C03B19/09—Other methods of shaping glass by fusing powdered glass in a shaping mould
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K7/00—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements
- G01K7/02—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using thermoelectric elements, e.g. thermocouples
- G01K7/04—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using thermoelectric elements, e.g. thermocouples the object to be measured not forming one of the thermoelectric materials
- G01K7/06—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using thermoelectric elements, e.g. thermocouples the object to be measured not forming one of the thermoelectric materials the thermoelectric materials being arranged one within the other with the junction at one end exposed to the object, e.g. sheathed type
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K7/00—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements
- G01K7/16—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using resistive elements
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K7/00—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements
- G01K7/16—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using resistive elements
- G01K7/18—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using resistive elements the element being a linear resistance, e.g. platinum resistance thermometer
- G01K7/183—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using resistive elements the element being a linear resistance, e.g. platinum resistance thermometer characterised by the use of the resistive element
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01C—RESISTORS
- H01C7/00—Non-adjustable resistors formed as one or more layers or coatings; Non-adjustable resistors made from powdered conducting material or powdered semi-conducting material with or without insulating material
- H01C7/04—Non-adjustable resistors formed as one or more layers or coatings; Non-adjustable resistors made from powdered conducting material or powdered semi-conducting material with or without insulating material having negative temperature coefficient
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K2203/00—Application of thermometers in cryogenics
Definitions
- the present invention relates to a resistance temperature detector element for measuring a temperature in a very low temperature range from 4K (K: unit of absolute temperature) to 90K.
- the temperature measurement by the resistance thermometer element is performed by utilizing the property that the electric resistance of the resistance thermometer wire accommodated in the resistance thermometer element changes depending on the temperature.
- the temperature becomes the temperature output of the resistance temperature detector element.
- a constant current is passed through the lead wires connected to both ends of the resistance temperature detector wire, the electric resistance value is obtained from the voltage drop, and the electric resistance value is converted into temperature.
- the structure of the resistance temperature detector element a structure in which a coiled resistance temperature detector wire is installed with an inorganic insulating material powder interposed in the outer frame is generally used.
- the reason why the RTD element having such a configuration is generally used is that it is easy to manufacture and inexpensive.
- the electrical resistance changes due to changes in the length and cross-sectional area of the RTD wire.
- a coiled resistance thermometer wire is installed in the inorganic insulating material powder, the force applied to the resistance thermometer wire is small and a temperature measurement error occurs. The difficulty is also cited as a reason why it is generally used.
- FIG. 1 and Fig. 2 show typical structures of resistance temperature detector elements that are generally widely used. 1 is a longitudinal sectional view, and FIG. 2 is a II-II sectional view of FIG. However, the coil portion of the resistance temperature detector wire 4 in FIG. 1 is shown in an external view.
- the resistance temperature detector element 1 has a coil-shaped resistance temperature detector wire 4 having lead wires 5 connected to both ends, and a columnar insulation having a substantially circular cross section as an outer frame.
- Two lead wires 5 connected to both ends are reciprocally inserted into two longitudinal through holes 3 provided in the insulator 2 so as to be exposed from the same end of each through hole 3.
- the resistance temperature detector wire 4 is installed in the through hole 3 with a filler 6 that is an inorganic insulating material powder filled in the gap in the through hole 3. It has a structure sealed with a sealing material 7 so that the internal filling material 6 does not fall off.
- the inorganic insulating material powder as the filler 6 a polycrystalline powder made of alumina, magnesia, silica, or a mixture thereof is used.
- a ceramic formed from a polycrystalline body made of alumina, magnesia, silica, or a mixture thereof is exclusively used.
- sealing material 7 a polycrystalline adhesive mainly composed of alumina, magnesia, silica, zircon, or a mixture thereof is usually used, and an enamel such as an epoxy resin may be used. Furthermore, as shown in FIG. 1 (a) of Patent Document 2, the resistance thermometer element used in a state in which the inorganic insulating material powder does not fall off is provided with a sealing material 7. Some are not.
- platinum is usually used as shown in JIS C1604 "resistance temperature detector".
- the measurement temperature is 73 K ( ⁇ 200 ° C.) or less
- the change rate of the electrical resistance of platinum with respect to the temperature change decreases, and the measurement sensitivity decreases, so that the temperature measurement error increases and measurement becomes impossible.
- platinum and cobalt alloys as shown in Patent Document 1 and Non-Patent Document 1 are usually used as the material of the resistance thermometer wire 4.
- the platinum-cobalt alloy has little decrease in measurement sensitivity even in a low temperature range, and as shown in Non-Patent Document 1, the temperature can be accurately measured in the temperature range of 4K to at least 325K.
- the lower limit is 4K because 4K is the boiling point of helium, and temperature calibration at temperatures below this is difficult.
- a conventional resistance thermometer element using a resistance thermometer wire for low temperature made of an alloy of platinum and cobalt and containing the resistance thermometer wire by interposing an inorganic insulating powder in the outer frame At a temperature of about 90K or less, there is a problem that the temperature measurement error increases to the plus side as the temperature decreases, and that the increase becomes abrupt when the temperature becomes 10K or less.
- the resistance temperature detector element shown in FIGS. 1 and 2 which uses a resistance temperature sensor wire for low temperature made of an alloy of platinum and cobalt, the current that is passed to measure the electrical resistance is standard. Table 1 shows temperature measurement errors in the low temperature range of 4K to 10K when 0.2 mA, 1 mA, and 2 mA.
- FIG. 7 is a graph of Table 1.
- the temperature measurement error in Table 1 and FIG. 7 indicates that increasing the measurement current to reduce the influence of noise in a noisy environment also causes a problem of increasing the error.
- the temperature measurement error on the plus side becomes large in a temperature of about 90K or less, particularly in the temperature range from 10K to 4K, and the error increases the SN ratio.
- the error increases the SN ratio.
- the temperature of the resistance thermometer wire becomes higher than the external temperature due to a decrease in the function as a heat medium, a decrease in heat conduction, and a decrease in the ability to dissipate Joule heat generated by the measurement current. It was.
- the Joule heat generated in the resistance thermometer wire by the measured current is the heat transmitted through the inorganic insulating powder and the heat transferred by the molecular motion of the air existing between the inorganic insulating powder. 1 is discharged to the outside through the insulator 2 in the structure of FIG. 1, and the temperature difference between the external temperature and the resistance thermometer wire is very small.
- the temperature difference between the external temperature and the resistance thermometer wire is very small.
- the Joule heat generated in the resistance temperature detector wire is transmitted only through the inorganic insulating material powder and is released to the outside via the insulator. Due to the deterioration of the heat dissipation performance, the Joule heat discharge becomes insufficient, and the temperature of the resistance temperature detector wire starts to become higher than the external temperature at 90K or less, as shown in Table 1 and FIG. Since the temperature rises and the Joule heat is proportional to the square of the measured current, the Joule heat increases as the measured current increases, and the temperature rise of the RTD wire due to insufficient discharge of Joule heat is promoted. It is thought to be done.
- the present invention has been made in view of the above-described errors, and an object of the present invention is to provide a temperature resistor element that can accurately measure a temperature in a cryogenic temperature range of 90K to 4K.
- the present inventor has found that the temperature measurement error increases to the plus side as the temperature decreases at a temperature of 90K or less, and the error is particularly large in the low temperature range of 10K to 4K.
- the following resistance thermometer element is used.
- a resistance thermometer for cryogenic temperature comprising a resistance temperature detector wire, an outer frame that accommodates the resistance temperature detector wire, and a filler filled between the outer frame and the resistance temperature detector wire.
- the filler is a polycrystalline inorganic insulating material powder and an amorphous insulating material having a softening point lower than the melting temperature of the inorganic insulating material powder, the resistance temperature detector wire, and the outer frame.
- the temperature measuring resistor wire, the outer frame and the inorganic insulation are at a temperature higher than the softening point of the glass powder.
- a resistance thermometer element for cryogenic temperature was obtained by heating at a temperature lower than the melting temperature of the material powder to melt only the glass powder, and then cooling and solidifying.
- the conventional filler was only a polycrystalline inorganic insulating material powder, whereas in the present invention, a polycrystalline inorganic insulating material powder and an amorphous insulating material glass powder were mixed.
- the mixture is filled between the outer frame and the resistance thermometer wire as a filler, and this is heated at a heating temperature set higher than the softening point of the glass powder to melt the glass powder in the outer frame. After that, the temperature is lowered and solidified.
- amorphous glass starts to melt when the temperature exceeds the transition point, and the glass that is in a solid state begins to have liquid properties.
- the temperature is further raised and the temperature reaches the softening point, also called the Rilton point, the glass melts to its deformed state due to its own weight. Therefore, when heated to the softening point or higher, the glass powder in the filler spreads into the gaps between the inorganic insulating powders, and when the temperature is lowered, most of the inorganic insulating powders are connected to the glass.
- the heating temperature is set to a temperature not higher than the melting point of the inorganic insulating material powder and the melting point or transition point of the resistance temperature detector wire and outer frame, and not lower than the softening point of the glass powder.
- the glass powder mixed with the inorganic insulating material powder is melted, so that many particles of the inorganic insulating material powder are connected to each other by glass. Due to this connection, it has high thermal conductivity, and even in the low temperature range of 90K or less, the gas such as air existing in the gaps of the inorganic insulating material powder is low temperature, so even if it becomes liquid droplets and solidifies, it is seen in the conventional one In this mode, the heat generation of the Joule heat generated by the measured current is hindered and a positive temperature measurement error does not occur, and accurate temperature measurement that is not affected by Joule heat is possible up to a low temperature of 4K. .
- the inorganic insulating material powder in the filler can be a polycrystalline powder made of alumina, magnesia, silica or a mixture thereof, as in the conventional case, and the outer frame is made of alumina as in the conventional case. Further, a ceramic formed from a polycrystalline body made of magnesia, silica, or a mixture thereof can be used. The melting point of these materials is 1500 ° C. or higher, and the softening point of amorphous glass is at most 800 ° C. except for special high-temperature glass.
- the resistance temperature detector wire As the resistance temperature detector wire, the one made of a platinum and cobalt alloy having a high measurement accuracy in the low temperature range shown in Patent Document 1 and Non-Patent Document 1 can be used as in the past.
- the melting point of platinum and cobalt alloys is much higher than the softening point of glass except for special high temperature ones.
- the inorganic insulating powder, outer frame, and resistance temperature detector wire can be kept in shape and heated to melt only the glass powder.
- the platinum-cobalt alloy has an electrical resistance value that changes depending on the amount of internal strain. Therefore, if the internal strain changes, the temperature measurement value changes, resulting in an error.
- the degree of annealing of the resistance temperature detector wire made of an alloy of platinum and cobalt changes depending on the heating temperature at which the glass powder is melted, and the amount of internal strain changes. It is desirable to set the temperature so that the strain is an amount that reduces the temperature measurement error. From this point of view, it is preferable that the material of the resistance thermometer wire is an alloy containing 0.5 mol% of cobalt in platinum, and the heating temperature is preferably 460 ° C. or more and 520 ° C. or less. As shown in the results of our test to be described, the temperature measurement error in the low temperature region of the resistance element for cryogenic temperature according to the present invention can be kept small.
- the glass powder in the filler by heating the glass powder in the filler to a temperature above the softening point, the glass powder melts and spreads in the gaps between the inorganic insulating powders, and when cooled, most of the inorganic insulating powders are connected to the glass.
- the heating temperature is 50 ° C. higher than the softening point.
- glass powder having a softening point of 410 ° C. or lower and a heating temperature of 460 ° C. or higher and 520 ° C. or lower.
- the inorganic insulating powder is made of alumina powder, which has relatively good thermal conductivity and is inexpensive among inorganic insulating materials. Glass powder is chemically stable and easy to handle, and does not contain toxic substances such as lead.
- the mixing ratio of the glass powder to the inorganic insulating powder in the filler if the mixing ratio is small, the glass particles are not sufficiently connected between the particles of the inorganic insulating powder and the improvement in heat conduction is limited. This causes a temperature measurement error on the plus side due to Joule heat. Also, if the mixing ratio is too large, the glass property becomes dominant and the force to restrain the RTD wire becomes strong, and the RTD wire due to the difference in thermal expansion between the RTD wire and the filler. The change in the length and cross-sectional area of the wire and the change in the internal strain of the resistance thermometer wire due to the difference in thermal expansion cause a change in electrical resistance, which causes an increase in temperature measurement error.
- the mixing ratio of the glass powder to be mixed with the inorganic insulating powder is small, it causes an increase in temperature measurement error in both cases, but the inorganic insulating powder is alumina powder, and the glass powder is mainly composed of bismuth oxide.
- the inorganic insulating powder is alumina powder, and the glass powder is mainly composed of bismuth oxide.
- the numerical value of the mixing ratio of the glass powder is the ratio of the glass powder weight to the total weight of the inorganic insulating material powder and the glass powder (hereinafter, wt% indicating the amount of the glass powder in the filler indicates the ratio to the total weight).
- the specific gravity of the above glass powder is 7.4.
- the internal strain of a resistance temperature detector wire made of an alloy containing 0.5 mol% of cobalt in platinum is set to an appropriate strain amount by setting the heating temperature for melting glass powder to 460 ° C. or more and 520 ° C. or less.
- the temperature measurement error becomes smaller, but it is possible to achieve an appropriate internal strain by the restraining force of the filler with a high mixing ratio of the glass powder to the resistance temperature detector wire. Since it is caused by the difference in thermal expansion between the resistor wire and the filler, it changes depending on the temperature, and also causes a temperature measurement error due to the change in the length and cross-sectional area of the resistance thermometer wire due to the difference in thermal expansion. Therefore, it is not preferable. Therefore, in the present invention, the internal strain is adjusted by the heating temperature for melting the glass powder, and the restraining force by the filler is suppressed.
- making the resistance thermometer wire into a coil shape means that the resistance thermometer wire is caused by the difference in thermal expansion between the resistance thermometer wire and the filler. This has the effect of further reducing changes in line length and cross-sectional area, and changes in internal strain, and reducing measurement errors.
- the above-described aspect of the present invention has no problem in applying to the structure of the resistance thermometer element widely used conventionally shown in FIGS.
- An inexpensive resistance temperature detector element can be obtained.
- the resistance temperature detector element of the conventional structure was sealed with a sealing material made of an insulating material on both side ends of the through hole so that the inorganic insulating material powder in the through hole did not fall off,
- the inorganic insulating material powder is connected by the glass powder, so there is no fear of dropping off, and the sealing material is not essential.
- an adhesive mainly composed of a polycrystalline body of alumina, magnesia, silica, zircon or a mixture thereof can be used as in the conventional materials. These adhesives have a heat-resistant temperature of 1000 ° C. or higher, and are generally high enough that the softening point of general glass is 800 ° C., so that they are not damaged by heating for melting the glass powder.
- the inorganic insulating material powder filled in the gap between the outer frame and the resistance temperature detector wire is changed to a mixture of the inorganic insulating material powder and the glass powder, which is equal to or higher than the melting temperature of the glass powder.
- the temperature measurement error increases to the plus side as the temperature decreases at a temperature of 90K or less, which has been seen in the conventional resistance thermometer element, by heating to a high temperature, and particularly from 10K to 4K.
- the error increases rapidly in the low temperature range, and the error does not increase when the measurement current is increased to increase the S / N ratio, and is not affected by the measurement current value even in the extremely low temperature range of 90K to 4K.
- a resistance temperature detector element capable of accurately measuring the temperature was obtained.
- FIG. 2 is a cross-sectional view taken along the line II-II of the resistance temperature detector element for cryogenic temperature of FIG. 1. It is a graph which shows the result of having tested the relationship between the heating temperature for glass powder melting
- FIG. 1 and FIG. 2 show a specific structure of a resistance temperature detector element according to an embodiment of the present invention.
- the structure is the same as the conventional one.
- the filler 6 was conventionally a polycrystalline inorganic insulating material powder
- a mixture of a polycrystalline inorganic insulating material powder and a glass powder which is an amorphous insulating material is used as a glass.
- the difference is that the glass powder is melted by heating at a heating temperature higher than the softening point of the powder and then cooled and solidified.
- FIG. 1 is a longitudinal sectional view
- FIG. 2 is a sectional view taken along the line II-II in FIG.
- the coil part of the resistance temperature detector wire 4 in FIG. 1 is shown in an external view.
- a resistance temperature detector element 1 includes an insulator 2 constituting an outer shell, a resistance temperature detector wire 4 accommodated in the insulator 2, and an insulator 2.
- a filling material 6 is provided between the resistance temperature detector wire 4.
- the insulator 2 is a ceramic made of polycrystalline alumina, magnesia, silica, or a mixture thereof, and has a columnar shape with a substantially circular cross section having two through holes in the axial direction.
- an insulator having an outer diameter of 1.4 mm and a length of 10.5 mm made of ceramic made of a mixture of alumina and silica is a suitable example.
- the diameter of the two through holes 3 is, for example, ⁇ 0.4 mm.
- a single through hole formed in a cylindrical shape may be adopted. In that case, the resistance temperature detector wire 4 may be accommodated in a state of being folded back in the through hole, or may be accommodated in a state of not being folded back.
- Resistance thermometer wires 4 are accommodated in the respective through holes 3 of the insulator 2.
- the resistance temperature detector wire 4 is a coiled platinum-cobalt alloy.
- the resistance thermometer wire 4 is reciprocated into the through hole 3 so that one end and the other end of the resistance thermometer wire 4 protrude from the same side of each through hole 3 of the insulator 2.
- a wire having an outer diameter of ⁇ 20 ⁇ m made of an alloy of platinum and cobalt containing 0.5 mol% of cobalt is a suitable example.
- the cobalt content may be, for example, 0.05 mol% to 2.0 mol%.
- other resistor wires used in a cryogenic temperature region for example, an alloy of rhodium and iron may be employed.
- a lead wire 5 is connected to one end and the other end of the resistance temperature detector wire 4, respectively.
- a suitable example of the lead wire 5 is an alloy of platinum and rhodium that has a small electrical resistance and has little influence on the measured value of the electrical resistance of the resistance temperature detector wire.
- the inside of the through hole 3 is filled with a filler 6.
- the filler 6 is filled between the insulator 2 and the resistance thermometer wire 4 to mechanically hold the resistance thermometer wire 4 and to generate Joule heat generated by the measurement current. It functions as a heat medium for radiating heat to the outside via the.
- the filler 6 is an inorganic insulating material powder made of a polycrystalline material such as alumina, magnesia, silica, or a mixture thereof, and an amorphous insulating material mixed with the inorganic insulating material powder. It consists of some glass.
- the filler 6 is obtained by uniformly mixing a glass powder with an inorganic insulating material powder, heating it at a predetermined temperature or higher to melt the glass powder, and then lowering the temperature to solidify. Most of the inorganic insulating material powder is connected by solidified glass. By this connection, the filler 6 has high thermal conductivity even in the extremely low temperature range, and maintains the function of releasing the Joule heat generated by the measurement current. Therefore, the effect of reducing the temperature measurement error in the very low temperature range is achieved. is there.
- an inexpensive alumina powder having a relatively high thermal conductivity is a suitable example.
- Sealing material 7 is provided at both ends of the insulator 2.
- the sealing material 7 is provided at both ends of the insulator 2 so that the filler 6 filled in the through hole 3 does not fall off, and seals both side ends of the through hole 3. Sealing is performed with an adhesive mainly composed of a polycrystalline body of alumina, silica, zircon, or a mixture thereof. In the present invention, the sealing material 7 is not essential and may be omitted.
- the resistance temperature sensor wire 4 is arranged inside the insulator 2 so that both ends thereof are aligned with one end side of the insulator 2 as shown in FIG. Insert it back and forth.
- the inorganic insulating material powder was uniformly mixed with the insulator 2, the resistance temperature detector wire 4, and the glass powder which is an amorphous insulating material whose softening point is lower than the melting point of the inorganic insulating material powder.
- a thing is filled in the through-hole 3 and sealed with a sealing material 7 if necessary. Then, this assembly is put in an electric furnace and heated at a preset heating temperature, for example, for 2 hours.
- the heating temperature is a temperature equal to or higher than the softening point of the glass powder.
- a temperature of 460 ° C. or more and 520 ° C. or less at which the internal strain due to annealing of the temperature resistor wire 4 is appropriate is suitable.
- the resistance temperature detector element 1 thus heat-treated changes into a solidified state in which the glass powder in the filler 6 is melted inside and the melted glass powder is connected with particles of the inorganic insulating powder.
- the internal strain of the resistance thermometer wire 4 is an appropriate amount. The effect of reducing the height is enhanced.
- the glass powder melts and spreads in the gaps between the inorganic insulating powders when heated above its softening point.
- the glass powder in order to melt more reliably at the heating temperature of 460 ° C. or higher and 520 ° C. or lower, the glass powder has a relatively softening point.
- Low material is preferred.
- a glass powder having a softening point of about 405 ° C. mainly composed of bismuth oxide is a suitable example. Even if the heating temperature is the lower limit of 460 ° C., the glass powder melts more reliably because the temperature is higher than the softening point by 50 ° C., and this glass is made of lead-free glass powder that is substantially free of harmful lead components. There are also advantages that can be generated.
- the inorganic insulating material powder is alumina powder
- the glass powder is mainly composed of bismuth oxide
- the specific gravity is obtained by adding zinc oxide and boron oxide.
- the mixing ratio of the glass powder in the filler 6 is preferably in the range of 3.5 wt% to 10.0 wt%. By setting the mixing ratio within this range, it is possible to connect the inorganic insulating material powder with glass sufficient to maintain high heat conduction in the cryogenic temperature range, and the force to restrain the resistance temperature detector wire 4 is suppressed. Since the deformation caused by the thermal expansion to the resistance temperature detector wire 4 and the change in the internal strain can be made minute, the resistance temperature detector element 1 having a small temperature measurement error can be obtained even in the extremely low temperature range.
- Test 1 The test was performed by the following three tests: Test 1 to Test 3. Items common to the test specimens and test contents of each test are as follows.
- the configuration of the test body is the same as that shown in FIGS.
- the RTD wire 4 is a wire having an outer diameter of ⁇ 20 ⁇ m made of an alloy containing 0.5 mol% of cobalt in platinum, and the lead wire 5 is an alloy of platinum and rhodium having an outer diameter of ⁇ 0.2 mm. used.
- the insulator 2 is made of a ceramic formed by mixing a mixture of alumina and silica, and has an outer diameter of 1.4 mm and a length of 10.5 mm.
- the diameter of the two through holes 3 provided in the longitudinal direction is as follows. ⁇ 0.4 mm.
- As the sealing material 7, a heat-resistant adhesive mainly composed of alumina was used.
- the filler 6 used was a mixture of alumina powder and glass powder having bismuth oxide as a main component, zinc oxide and boron oxide added thereto, a specific gravity of 7.4, and a softening point temperature of 405 ° C.
- Test 1 Test related to heating temperature for melting glass powder
- a resistance temperature sensor wire made of an alloy of platinum and cobalt changes in electrical resistance value depending on the amount of internal strain, but the degree of annealing changes depending on the heating temperature at which the glass powder is melted, and the amount of internal strain changes.
- the temperature measurement error increases or decreases depending on the heating temperature at which the glass powder is melted.
- the cryogenic temperature measurement according to the present invention in which the mixing ratio of the glass powder mixed with the alumina powder in the filler 6 is 4.2 wt%. Five temperature resistance elements were made, and the heating temperature for melting the glass powder of each body was set to different temperatures in the range of 455 ° C. to 540 ° C., and temperature measurement errors at 90K and 10K were tested. These heating temperatures are higher than the softening point temperature 405 ° C. of the used glass powder by 50 ° C. or more.
- the current for measuring the electrical resistance value was 2 mA, and the temperature measurement error was measured using a germanium thermometer calibrated by a public institution as a reference thermometer.
- the test was performed using a meter that outputs a high temperature and a meter that outputs a low temperature because of the relationship between the electrical resistance value set in the meter and the temperature.
- the test results are shown in Table 2, and Table 2 is shown in FIG. 3 and FIG.
- the meter 1 in Table 2 refers to a meter that outputs a high temperature from the relationship between the electrical resistance value set in the meter and the temperature, and the test results using this meter are as shown in FIG. It refers to a meter that outputs a low temperature, and the test results using this meter are as shown in FIG. From FIG. 3, if the heating temperature for melting the glass powder is in the range of 490 ° C. to 520 ° C., a temperature measurement error within about 1 ° C. occurs. Further, from FIG. 4, the temperature measurement error is within about 1 ° C. within the range of 460 ° C. to 490 ° C.
- the heating temperature for melting the glass powder is 460 ° C. or more and 520 ° C. or less, and 50 ° C. or more than the softening point temperature of the glass powder. If the temperature is high, by using either a meter that outputs a high temperature, a meter that outputs a low temperature, or a meter that outputs an intermediate temperature from the setting of the relationship between the electrical resistance value and the temperature, It shows that a temperature measurement error within about 1 ° C. can be obtained from 90K to 10K.
- the result of FIG. 3 also shows that if the heating temperature for melting the glass powder is set to 503 ° C. and an instrument that outputs a high temperature from the setting of the relationship between the electrical resistance value and the temperature is used, the temperature measurement error becomes almost zero. Is shown. In the following tests, the heating temperature for melting the glass powder was set to 503 ° C., and the measurement was performed using an instrument that outputs a high temperature from the setting of the relationship between the electrical resistance value and the temperature.
- Test 2 Test for verifying relationship between glass powder mixing ratio and error due to Joule heat
- the temperature measurement error in the test results of FIGS. 3 and 4 includes an error due to Joule heat that generates a current for measuring the electrical resistance value flowing through the resistance temperature detector wire 4.
- a test for verifying that the alumina powder particles were connected by glass in the filler 6 and that Joule heat was sufficiently discharged was performed.
- Test 3 Test to verify temperature measurement error in low temperature range from 10K to 4K
- the temperature measurement error was measured using a germanium thermometer calibrated by a public institution as a reference thermometer.
- the conventional resistance temperature detector element shown in Table 1 and FIG. 7 shows the resistance temperature detector element used in Test 3 and the heating for melting the glass powder without mixing the glass powder with the filler 6. The only difference is that it is not done, and the other structures, dimensions, and materials are the same.
- the dimensions and materials of the insulator and the resistance temperature detector wire are shown, and the lead wire, the sealing material, the inorganic insulating material powder, and the material of the glass powder are shown.
- the dimensions and materials of the resistance element for cryogenic temperature according to the invention are not limited thereto.
- the insulator 2 may be made of a ceramic obtained by molding a boron nitride polycrystal, or an inorganic insulating powder made of polycrystal boron nitride may be used.
- the outer diameter of the resistance temperature detector wire is not limited to 20 ⁇ m, and a low electrical resistance material other than an alloy of platinum and rhodium may be used as the lead wire, and the glass powder is melted as a sealing material. Any insulating adhesive that can withstand this heating temperature can be used.
- the material of the glass powder is applicable as long as the softening point is other than a high temperature that greatly changes the internal strain of the resistance temperature detector wire.
- the cryogenic resistance element for cryogenic use of the present invention is suitable for a temperature sensor element for measuring a temperature in a cryogenic temperature range of 4K to 90K in measuring a temperature in a cryopump, measuring a temperature in a hydrogen station, or the like.
- the method of mixing the glass powder with the inorganic insulating material powder according to the present invention and melting the glass powder is the heat generated when the gas such as air existing in the through hole is formed into droplets and solidified when used in a low temperature range. A decrease in conduction can be prevented. When the heat conduction is reduced, the amount of heat transfer is reduced, so that the temperature follow-up of the resistance thermometer wire with respect to the temperature change of the measurement target is deteriorated, and the adverse effect that the response speed of the temperature measurement is slowed.
- the method of mixing the glass powder with the inorganic insulating material powder according to the present invention and melting the glass powder does not cause such an adverse effect because the heat conduction does not decrease due to droplet formation or solidification.
- thermocouple in which a thermocouple element is housed by interposing an inorganic insulating material powder in a metal sheath with a thermocouple element is sometimes used as a temperature sensor in a cryogenic region.
- a sheathed thermocouple no current is required to measure the electrical resistance value, so that when used in a cryogenic temperature range, gas such as air present in the gaps of the inorganic insulating material powder becomes droplets and solidifies to conduct heat. Even if it decreases, temperature measurement error due to Joule heat that generates measurement current does not occur like a resistance temperature detector element, but there is a problem that the response speed of temperature measurement becomes slow due to decrease in heat conduction .
- a method for preventing a decrease in heat conduction by mixing glass powder into the inorganic insulating material according to the present invention and melting the glass powder is a method for measuring the temperature of a sheath thermocouple (bonding a plus thermocouple wire and a minus thermocouple wire).
- Point A sheath that does not reduce the response speed of temperature measurement even when used in a cryogenic temperature range by applying it to the surrounding inorganic insulating powder to eliminate the drop in heat conduction due to the formation of air droplets inside the sheath and solidification. It can be a thermocouple.
- the resistance temperature detector element is used as a resistance temperature detector element for cryogenic temperature according to the present invention in a low temperature range.
- the sheath thermocouple glass powder is mixed with the inorganic insulating material powder around the RTD element, and the glass powder is melted to add to the inside of the RTD for cryogenic temperature and measure the sheath. Even if it is used in a cryogenic temperature range without causing thermal drop due to air droplets and solidification with the temperature resistor element, the response speed of temperature measurement is fast and a measurement current is generated. A sheath resistance thermometer with a small temperature measurement error due to Joule heat can be obtained.
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Abstract
Description
このため、測温抵抗体線に生じたジュール熱は無機絶縁材粉末のみを伝わって、絶縁碍子経由で外部に放出されることとなる。この放熱性能の低下により、ジュール熱の排出が不十分となり、測温抵抗体線の温度が90K以下で外部温度より高くなり始め、10Kから4Kの低温域では表1、図7に示すような温度まで高くなり、かつ、ジュール熱は測定電流の2乗に比例するので、測定電流が大きい程、ジュール熱が増加し、ジュール熱の不十分な排出よる測温抵抗体線の温度上昇が助長されると考えられるのである。
したがって、加熱温度は、無機絶縁材粉末の融点、並びに測温抵抗体線及び外枠の融点または転移点以下の温度で、かつガラス粉末の軟化点以上の温度に設定される。
この連結により充填材6は、極低温域においても高い熱伝導性を有し、測定電流が発生するジュール熱を放出する機能を維持するので、極低温域での温度測定誤差を小さくする効果がある。
このように加熱処理された測温抵抗体素子1は、充填材6中のガラス粉末が内部で溶融し、溶融したガラス粉末が無機絶縁材粉末の粒子を連結した状態で固化したものに変化して極低温域でも測定電流が発生するジュール熱を放出する機能を維持することに加え、測温抵抗体線4の内部歪が適切な量となっていることから、極低温域において温度測定誤差を小さくする効果が高められたものとなる。
測温抵抗体線4には、白金にコバルトが0.5mol%含まれた合金を材料とする外径φ20μmの線を使用し、リード線5は外径φ0.2mmの白金とロジウムの合金を使用した。
また、絶縁碍子2は、アルミナとシリカの混合物を成形したセラミックで作られた、外径φ1.4mm、長さ10.5mmのもので、長手方向に設けられた2つの貫通孔3の径はφ0.4mmである。封止材7には、アルミナを主成分とする耐熱性接着剤を使用した。
充填材6は、アルミナ粉末に、酸化ビスマスが主成分でこれに酸化亜鉛と酸化ボロンを加えた比重が7.4で軟化点温度が405℃のガラス粉末を混合したものを用いた。
白金とコバルトの合金を材料とする測温抵抗体線は内部歪の量により電気抵抗値が変化するが、ガラス粉末を溶融させる加熱温度よってその焼鈍度合いが変わり、内部歪の量が変化するので、ガラス粉末を溶融させる加熱温度によって温度測定誤差が増減する。
図3及び図4の試験結果の温度測定誤差には、測温抵抗体線4に流されている電気抵抗値測定のための電流が発生するジュール熱に起因する誤差が含まれている。充填材6においてアルミナ粉末粒子がガラスにより連結され、ジュール熱の排出が十分に行われていることを検証するための試験を次に実施した。
充填材6のアルミナ粉末に混合するガラス粉末の混合比率を7.7wt%とした本発明による極低温用測温抵抗体素子を作り、4Kから10Kの低温域における温度測定誤差を試験した。温度測定誤差は、公的機関で校正されたゲルマニュウム温度計を規準温度計として計測した。
熱伝導が低下すると、熱の移動量が少なくなるために、測定対象の温度変化に対する測温抵抗体線の温度追従が悪くなり、温度測定の応答速度が遅くなるという弊害も発生する。本発明による無機絶縁材粉末にガラス粉末を混合し、ガラス粉末を溶融させる方法は、液滴化、固体化による熱伝導の低下が生じないため、このような弊害は生じない。
2 絶縁碍子
3 貫通孔
4 測温抵抗体線
5 リード線
6 充填材
7 封止材
Claims (6)
- 測温抵抗体線と、この測温抵抗体線を内部に収容する外枠と、当該外枠と前記測温抵抗体線との間に充填される充填材とを備えた極低温用測温抵抗体素子において、
前記充填材は、多結晶体の無機絶縁材粉末と、当該無機絶縁材粉末、前記測温抵抗体線及び前記外枠の溶融する温度よりも軟化点が低い非晶質体の絶縁材であるガラス粉末との混合物であって、
当該混合物を前記外枠と前記測温抵抗体線との間に充填した後、前記ガラス粉末の軟化点よりも高く、かつ前記測温抵抗体線、前記外枠及び前記無機絶縁材粉末の溶融する温度より低い温度で加熱して当該ガラス粉末のみを溶融させ、その後降温して固化させた
ことを特徴とする極低温用測温抵抗体素子。 - 請求項1に記載の極低温用測温抵抗体素子において、前記測温抵抗体線は、白金とコバルトの合金を材料とし、これをコイル状に形成したものである
ことを特徴とする極低温用測温抵抗体素子。 - 請求項2に記載の極低温用測温抵抗体素子において、
前記白金とコバルトの合金は、白金にコバルトが0.5mol%含まれた合金であり、
前記ガラス粉末溶融のための加熱温度は、460℃以上520℃以下であり、かつ、前記ガラス粉末の軟化点より50℃以上高い温度である
ことを特徴とする極低温用測温抵抗体素子。 - 請求項3に記載の極低温用測温抵抗体素子において、
前記無機絶縁材粉末は、アルミナ粉末であり、
前記ガラス粉末は、酸化ビスマスが主成分で、これに酸化亜鉛及び酸化ボロンを加えたものであり、
前記ガラス粉末の前記充填材に対する混合比率は、3.5wt%から10.0wt%の範囲である
ことを特徴とする極低温用測温抵抗体素子。 - 請求項1から4の何れか1項に記載の極低温用測温抵抗体素子において、
前記測温抵抗体線の両端に接続されるリード線をさらに備え、
前記外枠は、軸方向に二つの貫通孔を有する略円形断面の柱状をした絶縁碍子であり、
前記測温抵抗体線は、その両端部が前記各貫通孔の同側端部から露出するように往復して挿入されており、
前記充填材は、前記貫通孔の内壁と前記測温抵抗体線との隙間に充填されている
ことを特徴とする極低温用測温抵抗体素子。 - 請求項5の極低温用測温抵抗体素子において、
前記各貫通孔の両側端部を封止する、絶縁材を材料とする封止材をさらに備えている
ことを特徴とする極低温用測温抵抗体素子。
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