CN201803966U - Low-temperature physical property measuring device of solid material - Google Patents
Low-temperature physical property measuring device of solid material Download PDFInfo
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- CN201803966U CN201803966U CN2010205419409U CN201020541940U CN201803966U CN 201803966 U CN201803966 U CN 201803966U CN 2010205419409 U CN2010205419409 U CN 2010205419409U CN 201020541940 U CN201020541940 U CN 201020541940U CN 201803966 U CN201803966 U CN 201803966U
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Abstract
A low-temperature physical property measuring device of solid material is used for measuring the following parameters of the solid material under low temperature: specific heat, AC/DC resistivity, heat conductivity coefficient and thermoelectric potential rate. The physical property measuring device is composed of a sample bearing part and a refrigeration part. The refrigeration part comprises the following components: a Dewar flask, a Dewar sleeve, a Dewar cover, a low-temperature chamber, a vacuum pumping module and an air leakage prevention module. The Dewar flash is placed in the Dewar sleeve which is fastened with the Dewar cover through a flange structure. The central part of the Dewar cover is provided with an opening for the insertion of the low-temperature chamber. The central part of the low-temperature chamber is sleeved by a prevention sleeve for fixing the low-temperature chamber. The flange structure is provided at the joint between a sample rod and the low-temperature chamber. The air leakage prevention module and the vacuum pumping module are clamped therebetween from bottom to top. Furthermore the joint is sealed by an O-shaped ring. An upper end of the sample rod is provided with an aviation plug. An inner lead wire is connected with the aviation plug along a rod body of the sample rod. The low-temperature physical property measuring device of the solid material has the following advantages: small consumption amount of liquid nitrogen, no consumption of indium wire, short thermal relaxation time, stable low-temperature environment, relatively simple structure, low cost, suitability for application in physical property measurement of various solid materials in teaching and scientific researching processes, etc.
Description
Technical field
The utility model relates to the device of measuring the solid material rerum natura under a kind of low temperature, is used to measure specific heat, alternating current-direct current resistance rate, coefficient of heat conductivity and the thermoelectrical potential rate of solid material under the low temperature, belongs to the Physical Properties of Low Temperature fields of measurement.
Background technology
The specific heat of solid material, alternating current-direct current resistance rate, coefficient of heat conductivity and thermoelectrical potential rate are crucial physical parameters under the low temperature, accurately fast and obtain above-mentioned parameter with a kind of low cost method very important meaning is arranged.
In the past, measure above parameter needs separately the design measurement scheme and builds metering circuit, and efficient is low, lose time and also process loaded down with trivial details.Afterwards, some systematized products have appearred in succession on the market, as the alternating temperature varying magnetic field electronic transport character measuring system of Dong Fangchenjing company, the PPMS of Quantum Design company etc.
But, the circulating refrigerating plant of the general employing of these products, being about to sample is placed in the environment that is surrounded by heat pipe, liquid nitrogen or liquid helium are extracted in heat pipe from Dewar and circulate, and finally return in the Dewar, and the shortcoming of this method is that the liquid nitrogen consumption is big, quality requirements height for conduit, the low temperature lower seal needs the noble metal indium, complex structure, and cost is too high.
And the measuring method of these products is too complicated, thereby support equipment is required height, and is inapplicable in the occasion of some low precision requirement.For example, what the specific heat measurement option of PPMS adopted is the thermal relaxation method, needs fabulous high vacuum environment, and sample size has strict demand, and loading and unloading also are careful.
Summary of the invention
Technical matters: the defective that the utility model exists at prior art provide a kind of liquid nitrogen consumption little, do not consume the indium silk, thermal relaxation time is short, low temperature environment is stable, structure solid material Physical Properties of Low Temperature measurement mechanism simple, with low cost relatively.
Technical scheme: solid material Physical Properties of Low Temperature measurement mechanism of the present utility model is made up of refrigerating part and sample bearing part; Refrigerating part is promptly kept the assembly of low temperature environment, by Dewar flask, Dewar cover, Dewar lid, low temperature chamber, vacuumize module and the anti-gas-leak module is formed; Vacuumize module and be flange arrangement up and down, its side mouth of bleeding is to connect vacuum pump; The anti-gas-leak module is the disk of rubber material, the centre has closure seam and passes through for specimen holder and sample strip, Dewar flask is positioned in the Dewar cover, Dewar lid and Dewar cover are fastening with flange arrangement, have the hole consistent with the low temperature chamber external diameter in the middle of the Dewar lid, insert for low temperature chamber, middle part, low temperature chamber periphery is with and stops cover, the degree of depth of its insertion stops the cover side to have screw by stoping cover control, allows the pointed screw riveting go into fixing low temperature chamber; The sample bearing part is comprehensive for the assembly of loading and unloading sample and carrying metering circuit, fixes with screw between specimen holder lower end and the sample strip, and specimen holder is sent into sample strip in the low temperature chamber.
The joint of specimen holder and low temperature chamber is a flange arrangement, accompanies the anti-gas-leak module therebetween from bottom to up and vacuumizes module, and seal with O type circle; The specimen holder upper end is equipped with aviation plug, and inner lead is connected on the aviation plug along the body of rod of specimen holder.
Sample strip is fixed on the specimen holder lower end, hangs to be placed on the low temperature chamber bottom, and low temperature chamber is immersed in the liquid nitrogen environment, and low temperature chamber adopts thermal conductivity preferred metal material, effectively heat is conducted; Be fixed with the anti-gas-leak module of rubber system on the low temperature chamber, there is superfine closure seam the centre, and length just allows specimen holder and sample strip pass through, when the replacing sample is extracted specimen holder, the anti-gas-leak module is in closure state, stops air further to enter low temperature chamber, keeps the low temperature environment in the low temperature chamber; Simultaneously, low temperature chamber and specimen holder and vacuumize module and the joint of anti-gas-leak module outside low temperature environment, carry out O type circle sealing herein, remove the noble metal indium that the low temperature lower seal will consume from.
All carry corresponding metering circuit on each sheet sample strip, only need to change the measurement that sample strip just can be finished different parameters.Have of the measurement of three kinds of sample strip corresponding to specific heat, alternating current-direct current resistance rate, coefficient of heat conductivity and thermoelectrical potential rate.Adopt four leads method metering circuits on the alternating current-direct current resistance rate sample strip, peripheral two lead-in wires are responsible for introducing electric current, the electric potential difference of sample between two middle lead-in wires are responsible for measuring, other pure resistance well heater and the thermal resistance thermometer of posting of sample.The specific heat sample strip adopts adiabatic impulse method metering circuit, and the sample attach area is the copper sheets of center, and thin slice is affixed on the sample strip with the good glass fibre of heat-insulating property on four angles, has pure resistance well heater and thermal resistance thermometer on thin slice.Coefficient of heat conductivity and thermoelectrical potential rate sample strip adopt unidirectional steady flow of heat method metering circuit, the sample upper end connects the pure resistance well heater, the lower end is fixed on the sample strip, and 2 of the segment distance of being separated by on the sample connect a copper constantan thermal resistance thermometer and No. two copper constantan thermal resistance thermometers.
Beneficial effect: the utility model provide a kind of liquid nitrogen consumption little, do not consume that indium silk, thermal relaxation time are short, low temperature environment is stable, structure is simple relatively, have the device that low temperature environment is stablized lasting, simple in structure, convenient disassembly and advantage such as with low cost, the rerum natura that can be applied to the various solid materials in the teaching and scientific research process is measured.
Description of drawings
Fig. 1 is a solid material Physical Properties of Low Temperature measurement mechanism structure,
Have among the figure: 1 is specimen holder, and 2 is low temperature chamber, and 3 is sample strip, and 4 are the Dewar lid, and 5 is the Dewar cover, and 6 for stoping cover, and 7 for vacuumizing module, and 8 is the anti-gas-leak module, and 9 is Dewar flask;
Fig. 2 is an alternating current-direct current resistance rate sample strip,
Have among the figure: 10 are alternating current-direct current resistance rate sample strip, and 11 is sample, and 12 is well heater, and 13 is thermal resistance thermometer;
Fig. 3 is the specific heat sample strip,
Have among the figure: 14 are the specific heat sample strip, and 15 is sample, and 16 is well heater, and 17 is thermal resistance thermometer,
Fig. 4 is coefficient of heat conductivity and thermoelectrical potential rate sample strip,
Have among the figure: 18 are coefficient of heat conductivity and thermoelectrical potential rate sample strip, and 19 is sample, and 20 is well heater, and 21 is a copper constantan thermal resistance thermometer, and 22 is No. two copper constantan thermal resistance thermometers.
Embodiment
This describes preferred embodiment of the present utility model in detail below with reference to accompanying drawing.
As shown in Figure 1, refrigerating part comprises Dewar flask 9, Dewar cover 5, Dewar lid 4, low temperature chamber 2, vacuumizes module 7 and anti-gas-leak module 8.The liquid nitrogen of 2/3rds degree of depth is housed in the Dewar flask 9, is placed in the Dewar cover 5, Dewar cover 5 is fastening with flange arrangement with Dewar lid 4, to reduce leaking of liquid nitrogen.Have the hole consistent with the low temperature chamber external diameter in the middle of the Dewar lid 4, insert for low temperature chamber 2, low temperature chamber 2 middle parts are with and stop cover 6, with fixing low temperature chamber 2 and control its insertion depth.Fix with screw between specimen holder 1 lower end and the sample strip 3, specimen holder 1 is sent into sample strip 3 in the low temperature chamber 2.The joint of specimen holder 1 and low temperature chamber 2 is a flange arrangement, accompanies anti-gas-leak module 8 therebetween from bottom to up and vacuumizes module 7, and seal with O type circle.Specimen holder 1 upper end is equipped with aviation plug, and inner lead is connected on the aviation plug along the body of rod of specimen holder 1.
As shown in Figure 2, adopt four leads method on the alternating current-direct current resistance rate sample strip 10, the responsible electric current I of introducing of peripheral two lead-in wires, two middle lead-in wires are responsible for the electric potential difference U of sample between the measurement at a distance of L.During operation sample 11 is processed as cross-sectional area S, the strip of moderate length is attached on four lead-in wires.The electricalresistivity that can obtain specimen material is:
Cooperate pure resistance well heater 12 and thermal resistance thermometer 13 simultaneously, can record the resistivity under the different temperatures T, final deal with data obtains the ρ-T curve of institute's test sample product material.
Specific heat sample strip 14 adopts adiabatic impulse method, the sample attach area is the copper sheets of center, thin slice is affixed on the sample strip with the good glass fibre of heat-insulating property on four angles, has pure resistance well heater 16 (heating power is P) and thermal resistance thermometer 17 on thin slice.During operation, will be evacuated in the low temperature chamber 2 with air pump earlier, quality is that the sample 15 of m is attached to measured zone, and in the Δ t time, thermometer records sample temperature from T
1Change to T
2, temperature variation Δ T should be controlled at 1% T
1In, can be approximately and trend towards 0.At this moment, the mean specific heat C of derived sample material in Δ T is:
Coefficient of heat conductivity and thermoelectrical potential rate sample strip 18 adopt unidirectional steady flow of heat method, sample 19 upper ends connect pure resistance well heater 20 (heating power is P), the lower end is fixed on the sample strip, the heat of well heater 20 can not axially transmit, can only transmit downwards by sample 19, form unidirectional hot-fluid, hot-fluid is after after a while, the each point temperature no longer changes on the sample 19, forms stable unidirectional hot-fluid.During operation, to be evacuated in the low temperature chamber 2 with air pump earlier, sample 19 is processed into the strip that cross-sectional area is S, and two of standoff distance L connect two copper-constantan thermocouple thermometers 21,22 on the sample, after time, recording 2 stable temperature respectively is T through Δ t
1, T
2At this moment, the coefficient of heat conductivity λ of derived sample material is:
In two copper-constantan thermocouple thermometers 21,22, recording electromotive force between two copper leads is V
a, be all that electromotive force is V between two leads of constantan
b, the temperature difference heat electromotive force rate of copper and constantan is respectively S
a, S
bAccording to Seebeck effect, have:
V
a=(S
a-S)(T
1-T
2)
V
b=(S
b-S)(T
1-T
2)
Then the thermoelectrical potential rate of derived sample material is that S is:
Claims (3)
1. solid material Physical Properties of Low Temperature measurement mechanism is characterized in that this detection device of physical property is made up of refrigerating part and sample bearing part; It is comprehensive that refrigerating part is promptly kept the assembly of low temperature environment, by Dewar flask (9), Dewar cover (5), Dewar lid (4), low temperature chamber (2), vacuumize module (7) and anti-gas-leak module (8) is formed; Vacuumize module (7) and be flange arrangement up and down, its side mouth of bleeding; Anti-gas-leak module (8) is the disk of rubber material, the centre has closure seam and passes through for specimen holder (1) and sample strip (3), Dewar flask (9) is positioned in the Dewar cover (5), Dewar lid (4) and Dewar cover (5) are fastening with flange arrangement, have the hole consistent with the low temperature chamber external diameter in the middle of the Dewar lid (4), insert for low temperature chamber (2), the peripheral middle part of low temperature chamber (2) is with and stops cover (6), stop cover (6) side to have screw, allow the pointed screw riveting go into fixedly low temperature chamber (2); The sample bearing part is comprehensive for the assembly of loading and unloading sample and carrying metering circuit, fix with screw between specimen holder (1) lower end and the sample strip (3), specimen holder (1) is sent into sample strip (3) in the low temperature chamber (2), the joint of specimen holder (1) and low temperature chamber (2) is a flange arrangement, accompany anti-gas-leak module (8) therebetween from bottom to up and vacuumize module (7), and seal with O type circle; Specimen holder (1) upper end is equipped with aviation plug, and inner lead is connected on the aviation plug along the body of rod of specimen holder (1).
2. solid material Physical Properties of Low Temperature measurement mechanism according to claim 1, it is characterized in that: sample strip (3) is fixed on specimen holder (1) lower end, suspension is placed on low temperature chamber (2) bottom, and low temperature chamber (2) is immersed in the liquid nitrogen environment, and low temperature chamber (2) adopts metal material; Be fixed with the anti-gas-leak module (8) of rubber system on the low temperature chamber (2), there is superfine closure seam the centre, and length just allows specimen holder (1) and sample strip (3) pass through; Simultaneously, low temperature chamber (2) and specimen holder (1) and vacuumize module (7) and the joint of anti-gas-leak module (8) is provided with O type circle and seals.
3. solid material Physical Properties of Low Temperature measurement mechanism according to claim 1 is characterized in that carrying on the described sample strip corresponding metering circuit, only needs to change the measurement that sample strip just can be finished different parameters; Have of the measurement of three kinds of sample strip corresponding to specific heat, alternating current-direct current resistance rate, coefficient of heat conductivity and thermoelectrical potential rate; Alternating current-direct current resistance rate sample strip (10) goes up and adopts four leads method metering circuits, and peripheral two lead-in wires are introduced electric current, the electric potential difference of sample between two middle lead-in wires are measured, other pure resistance well heater (12) and the thermal resistance thermometer (13) of posting of sample; Specific heat sample strip (14) adopts adiabatic impulse method metering circuit, the sample attach area is the copper sheets of center, thin slice is affixed on the sample strip with glass fibre on four angles, has pure resistance well heater (16) and thermal resistance thermometer (17) on thin slice; Coefficient of heat conductivity and thermoelectrical potential rate sample strip (18) adopt unidirectional steady flow of heat method metering circuit, the sample upper end connects pure resistance well heater (20), the lower end is fixed on the sample strip, and 2 of the sample two ends connect a copper constantan thermal resistance thermometer (21) and No. two copper constantan thermal resistance thermometers (22).
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Cited By (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101957334A (en) * | 2010-09-26 | 2011-01-26 | 东南大学 | Low-temperature physical property measuring device of solid material |
CN104635054A (en) * | 2015-02-11 | 2015-05-20 | 华北电力大学 | Closed-type temperature control solid medium electrical resistivity measurement device |
CN106018695A (en) * | 2016-06-22 | 2016-10-12 | 中国人民解放军95989部队 | High-pressure nitrogen contamination warning device |
CN106442619A (en) * | 2016-10-31 | 2017-02-22 | 华南理工大学 | Dual-channel room-temperature direct measuring instrument and method for magnetocaloric effect |
CN106918748A (en) * | 2017-03-29 | 2017-07-04 | 上海交通大学 | For the electrode system of the following solid dielectric space charge measurement of zero degrees celsius |
CN107664678A (en) * | 2017-09-12 | 2018-02-06 | 北京大学 | A kind of low vibrations ultrahigh vacuum low-temperature physical property measuring device |
CN109991271A (en) * | 2019-04-08 | 2019-07-09 | 包头稀土研究院 | Specimen holder, the magnetothermal effect measuring instrument with reference temperature and measurement method |
CN110320389A (en) * | 2019-08-02 | 2019-10-11 | 中国科学院苏州纳米技术与纳米仿生研究所 | A kind of original position property test system and sample mounting procedure |
CN116466276A (en) * | 2023-06-20 | 2023-07-21 | 中国科学院合肥物质科学研究院 | Vibration sample rod and vibration sample magnetometer |
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2010
- 2010-09-26 CN CN2010205419409U patent/CN201803966U/en not_active Expired - Lifetime
Cited By (13)
Publication number | Priority date | Publication date | Assignee | Title |
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CN101957334B (en) * | 2010-09-26 | 2012-06-27 | 东南大学 | Low-temperature physical property measuring device of solid material |
CN101957334A (en) * | 2010-09-26 | 2011-01-26 | 东南大学 | Low-temperature physical property measuring device of solid material |
CN104635054A (en) * | 2015-02-11 | 2015-05-20 | 华北电力大学 | Closed-type temperature control solid medium electrical resistivity measurement device |
CN106018695A (en) * | 2016-06-22 | 2016-10-12 | 中国人民解放军95989部队 | High-pressure nitrogen contamination warning device |
CN106442619B (en) * | 2016-10-31 | 2023-03-21 | 华南理工大学 | Double-channel room-temperature magnetocaloric effect direct measuring instrument and method |
CN106442619A (en) * | 2016-10-31 | 2017-02-22 | 华南理工大学 | Dual-channel room-temperature direct measuring instrument and method for magnetocaloric effect |
CN106918748A (en) * | 2017-03-29 | 2017-07-04 | 上海交通大学 | For the electrode system of the following solid dielectric space charge measurement of zero degrees celsius |
CN107664678A (en) * | 2017-09-12 | 2018-02-06 | 北京大学 | A kind of low vibrations ultrahigh vacuum low-temperature physical property measuring device |
CN107664678B (en) * | 2017-09-12 | 2019-12-13 | 北京大学 | Low-vibration ultrahigh-vacuum low-temperature physical property measuring device |
CN109991271A (en) * | 2019-04-08 | 2019-07-09 | 包头稀土研究院 | Specimen holder, the magnetothermal effect measuring instrument with reference temperature and measurement method |
CN110320389A (en) * | 2019-08-02 | 2019-10-11 | 中国科学院苏州纳米技术与纳米仿生研究所 | A kind of original position property test system and sample mounting procedure |
CN116466276A (en) * | 2023-06-20 | 2023-07-21 | 中国科学院合肥物质科学研究院 | Vibration sample rod and vibration sample magnetometer |
CN116466276B (en) * | 2023-06-20 | 2023-09-08 | 中国科学院合肥物质科学研究院 | Vibration sample rod and vibration sample magnetometer |
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Granted publication date: 20110420 Effective date of abandoning: 20120627 |