CN203849193U - Indoor rock sample heat conduction coefficient testing device - Google Patents

Abstract

The utility model relates to an indoor rock sample thermal conductivity testing device, which belongs to the category of testing instruments. The test device consists of a lower base, a cold pole cooling device, an outer heat insulation tube, an inner heat insulation tube, an inner heat insulation layer, a hot electrode electric heating plate, an upper support plate, a heat insulation layer, and a heater. The inner thermal insulation layer, inner thermal insulation tube and outer thermal insulation tube are all fixed on the lower end surface of the upper support plate, and the inner thermal insulation layer, inner thermal insulation tube and outer thermal insulation tube surround the outer side of the hot pole electric heating plate from the inside to the outside, forming a closed The test sample is placed in the insulation chamber, and the lower end of the sample is equipped with a cold pole cooling device to keep the temperature of the lower end of the sample at a constant low temperature. The utility model can measure the axial heat conduction coefficient and the radial heat conduction coefficient of the rock sample, and compare it with a reference sample to further verify the accuracy of the measurement. The utility model has reasonable design, simple structure and convenient operation and use.

Description

An indoor rock sample thermal conductivity testing device

technical field

The utility model relates to an indoor rock sample thermal conductivity testing device, which belongs to the category of testing instruments. the

Background technique

Thermal conductivity is an important thermodynamic parameter of rock. How to accurately measure the thermal conductivity of rocks is of great significance for the multi-field coupling research of rocks. However, under the action of diagenesis and long-term geological structure, rocks are heterogeneous bodies composed of various minerals. In addition, due to the influence of sedimentary layers or microcracks, the thermal conductivity of rocks often shows anisotropy. Most of the existing thermal conductivity testing instruments are mostly aimed at homogeneous materials. For example, the invention patent "A Method and Device for Measuring Thermal Conductivity" (public number: CN1601262A) can only measure average materials, but is not suitable for measuring the thermal conductivity of rocks. , there are only a few thermal conductivity test instruments, some measurement methods are more complicated, and there are large errors in the measurement results. In addition, the current testing instruments can only measure the thermal conductivity of the rock in one direction, and cannot accurately describe the thermal conductivity of the rock as a whole, and there will be large errors when performing large-scale calculations and analysis. the

Contents of the invention

In view of the above existing problems, the purpose of this utility model is to provide a device for testing the thermal conductivity of rocks with simple structure, convenient use and strong practicability, which can measure the thermal conductivity of rocks in two directions. the

In order to achieve the above object, the utility model adopts the following technical solutions:

An indoor rock sample thermal conductivity test device, the test device consists of a lower base, a cold pole cooling device, a column, an outer heat insulation tube, an inner heat insulation tube, an inner heat insulation layer, an upper reference sample, a hot electrode electric heating plate, an upper Support plate, elevator, telescopic rod, heat insulation layer, first thermocouple, second thermocouple, fixed fixture, heater, lower reference sample; the lower base is connected with the upper support plate through the column, and the cold pole cooling device is located in the lower base Above, the cold pole cooling device is in the shape of a boss, and the two sides of the lower platform of the cold pole cooling device are respectively provided with water inlets and water outlets. The lower reference sample is set above the upper platform of the cold pole cooling device, and the upper end surface of the lower reference sample is set There is a heater; there is an elevator above the upper support plate, the telescopic rod moves through the upper support plate, the upper end of the telescopic rod is fixedly connected with the elevator, the lower end of the telescopic rod is fixedly connected with the upper end surface of the heat insulation layer, and the fixing fixture is fixed on the lower end surface of the heat insulation layer. A hot electrode electric heating plate and an upper reference sample are arranged inside. The hot electrode electric heating plate is located between the heat insulating layer and the upper reference sample. The upper and lower end faces of the upper reference sample are respectively provided with a first thermocouple and a second thermocouple. ; the upper end of the outer heat insulating pipe, the inner heat insulating pipe and the inner heat insulating layer are respectively fixed on the lower end surface of the upper supporting plate, the inner heat insulating pipe surrounds the outer side of the inner heat insulating layer, the outer heat insulating pipe surrounds the outer side of the inner heat insulating pipe, and the outer insulating pipe The lower end of the heat pipe is located on the lower platform of the cold pole cooling device, the inner wall of the bottom end of the inner heat insulating tube coincides with the outer wall of the upper platform of the cold pole cooling device, the inner wall of the inner heat insulation layer coincides with the heat insulation layer, and the lower end of the inner heat insulation layer is located in the inner The upper end face of the bottom end of the heat insulating tube. the

The heater is a point tungsten wire heat source heater. the

The centers of the lower base, the cold pole cooling device, the lower reference sample, the heater, the upper reference sample, the hot pole electric heating plate, the elevator, the connecting rod, and the heat insulation layer are all located on the same center line. the

Due to the adoption of the above technical scheme, the indoor rock sample thermal conductivity testing device of the present invention has the following advantages:

The outer insulation pipe of the utility model surrounds the outer side of the inner insulation pipe, and the inner insulation pipe surrounds the outer side of the inner heat insulation layer. The inner wall of the inner heat insulation layer coincides with the heat insulation layer. The thermal insulation layer forms a closed thermal insulation chamber, which can avoid heat dissipation during the test experiment. the

Due to the heterogeneity of the rock, the test setup was compared with a reference sample of known thermal conductivity. The utility model

The test device adopts the method of heating the reference sample and the test sample at the same time. By testing the thermal conductivity of the reference sample and the test sample respectively, the thermal conductivity of the reference sample obtained is compared with its known thermal conductivity. Determine the measurement accuracy of the thermal conductivity of the test specimen. the

Considering the heterogeneity of rock, this test device can measure axial and radial thermal conductivity. The testing device of the present invention includes two kinds of heat sources, which can be disassembled. The heater adopts a tungsten wire heating source to generate heat. According to the measured parameters, the position of the hot electrode electric heating plate and the heater can be exchanged. During the test, the test There are multiple temperature-measuring thermocouples distributed on the upper and lower end faces and sides of the sample, which can accurately measure the temperature distribution of the test sample, and it is convenient to calculate the axial thermal conductivity of the test sample, and can be substituted into the numerical simulation software according to the surface temperature. Reverse analysis, the radial thermal conductivity of the test sample is obtained. the

Description of drawings

Fig. 1 is a schematic diagram of the use of the testing device of the present invention. the

Fig. 2 is a structural schematic diagram of the testing device of the present invention. the

Figure 3 shows the distribution of thermocouples for temperature measurement on the surface of the test sample. the

Figure 4 is a top view of the distribution of thermocouples for temperature measurement on the surface of the sample. the

Detailed ways

Below in conjunction with accompanying drawing, the utility model is further described. the

see Attachment. the

An indoor rock sample thermal conductivity test device, the test device consists of a lower base 1, a cold pole cooling device 2, a column 3, an outer heat insulating pipe 4, an inner heat insulating pipe 5, an inner heat insulation layer 6, and an upper reference sample 7 , hot electrode electric heating plate 8, upper support plate 9, elevator 10, telescopic rod 11, heat insulation layer 12, first thermocouple 13, second thermocouple 14, fixing fixture 15, heater 17, and lower reference sample 18;

The lower base 1 is connected with the upper support plate 9 through the column 3. The cold pole cooling device 2 is located above the lower base 1. The cold pole cooling device 2 is in the shape of a boss. The two sides of the lower platform of the cold pole cooling device 2 are respectively provided with water inlets and outlets. The nozzle, by controlling the water circulation, controls the lower end surface of the lower reference sample 18 to maintain a lower temperature, the lower reference sample 18 is arranged above the upper platform of the cold pole cooling device 2, and a heater is arranged on the upper end surface of the lower reference sample 18 17. The heater 17 can be disassembled according to different test parameters. the

An elevator 10 is arranged above the upper support plate 9. The elevator 10 can be electric, mechanical or manual. The telescopic rod 11 moves through the upper support plate 9. 12 The upper end surface is fixedly connected, and the fixing fixture 15 is fixed on the lower end surface of the heat insulating layer 12. The fixing fixture 15 is provided with a hot electrode electric heating plate 8 and an upper reference sample 7, and the hot electrode electric heating plate 8 is located on the heat insulating layer 12 and the upper reference sample 7 In between, fastening screws are arranged on the outside of the fixing fixture 15, and the hot pole electric heating plate 8 and the upper reference sample 7 are fixed in the fixing fixture 15 by fastening screws, and the hot pole electric heating plate 8 can use a heater according to the difference of test parameters 17 replacement, the upper and lower end surfaces of the upper reference sample 7 are respectively provided with a first thermocouple 13 and a second thermocouple 14. During the test, the telescopic rod 11 is extended, and the upper reference sample 7 is controlled to drop to contact with the test sample 16. , the heater 17 and the hot pole electric heating plate 8 are connected to an external power supply. the

The outer heat insulation pipe 4, the inner heat insulation pipe 5, and the heat insulation layer 12 are all hollow stainless steel materials, and the inner heat insulation layer 6 adopts asbestos board material. the

The inner thermal insulation layer 6, the inner thermal insulation tube 5, and the outer thermal insulation tube 4 surround the outer side of the thermal insulation layer 12 from inside to the outside, and the inner thermal insulation layer 6, the inner thermal insulation tube 5, and the outer thermal insulation tube 4 are fixed on the upper support plate 9 The lower end surface forms a closed heat preservation chamber, and the test sample is placed in the heat preservation chamber. The lower end of the outer heat insulating pipe 4 is located on the lower platform of the cold pole cooling device 2, and the inner wall surface of the bottom end of the inner heat insulating pipe 5 is connected to the bottom of the cold pole cooling device 2. The outer wall of the upper platform coincides, the inner wall of the inner thermal insulation layer 6 coincides with the thermal insulation layer 12, and the lower end of the inner thermal insulation layer 6 is located on the upper end surface of the inner thermal insulation pipe 5 bottom. the

The heater 17 is a point tungsten wire heat source heater. the

The centers of lower base 1, cold electrode cooling device 2, lower reference sample 18, heater 17, upper reference sample 7, hot electrode electric heating plate 8, elevator 10, connecting rod 11, and heat insulation layer 12 are all located on the same center line . the

The working principle of the utility model:

(1) Place two temperature measuring thermocouples on the upper and lower ends of the test sample 16, and place six temperature measuring thermocouples on the side according to the height gradient, see Figure 3 and Figure 4, the black semicircle in Figure 3 is the thermocouple. the

(2) If you choose to measure the axial thermal conductivity, then place the hot electrode heating plate 8 on the upper end of the upper reference sample 7; if you choose to measure the radial thermal conductivity, then install the heater 17 on the upper end of the upper reference sample 7. the

(3) The telescopic rod 11 is controlled by the elevator 10 to elongate, and the upper heat insulating layer 12, the hot electrode heating plate 8 (or the heater 17), and the upper reference sample 7 are lowered to contact the test sample 16. the

(4) According to the parameters to be measured in (2), control the hot electrode electric heating plate 8 (or heater 17) to heat, start the cold electrode cooling device 2, pass the water circulation of the water inlet and water outlet on both sides, and refer to the test under control. The lower end face of Sample 18 was kept at a lower temperature. the

(5) If the axial thermal conductivity is measured, take the quotient of the constant heating power q(W) of the hot electrode electric heating plate 8 and the surface area S(m^2) of the upper reference sample 7 as the heat flux Q(W/m^2) ,Right now

Q=q/S

The temperature measuring thermocouple installed on the surface of the sample can measure the temperature distribution of the sample surface under different height gradients, and further obtain the temperature gradient of the sample,

$<span\; class="notranslate">\; \&dtri;</span>\mathrm{<span\; class="notranslate">\; T</span>}<span\; class="notranslate">\; =</span>\mathrm{<span\; class="notranslate">\; \&Delta;T</span>}<span\; class="notranslate">\; /</span>\mathrm{<span\; class="notranslate">\; l</span>}$

ΔT is the surface temperature difference of the sample at different heights, and l is the height of the sample. the

Further, the axial thermal conductivity k

$\mathrm{<span\; class="notranslate">\; k</span>}<span\; class="notranslate">\; =</span><span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; Q</span>}<span\; class="notranslate">\; /</span><span\; class="notranslate">\; \&dtri;</span>\mathrm{<span\; class="notranslate">\; T</span>}<span\; class="notranslate">\; =</span><span\; class="notranslate">\; -</span>\frac{\mathrm{<span\; class="notranslate">\; ql</span>}}{\mathrm{<span\; class="notranslate">\; S\&Delta;T</span>}}$

If the radial thermal conductivity is measured, the surface temperature of the sample is obtained according to the temperatures of multiple temperature measuring thermocouples placed on the upper reference sample 7, the lower reference sample 18 and the test sample 16, and the temperature at each point is substituted into the value The simulation software performs back analysis to obtain the radial thermal conductivity of the sample. the

The obtained results can be compared with the reference samples, which is convenient and accurate. the

Claims (3)

1. an indoor rock sample test device of thermal conductivity coefficient, is characterized in that: described proving installation by lower bottom base (1), cold utmost point cooling device (2), column (3), outer heat-insulated pipe (4), interior heat-insulated pipe (5), in protect hot heat-insulation layer (6), upper reference coupon (7), thermoae electric hot plate (8), upper backup pad (9), lifter (10), expansion link (11), heat insulation layer (12), the first thermopair (13), the second thermopair (14), stationary fixture (15), heating element (17), lower reference coupon (18) and form, lower bottom base (1) is connected with upper backup pad (9) by column (3), cold utmost point cooling device (2) is positioned at lower bottom base (1) top, cold utmost point cooling device (2) is boss-shaped, cold utmost point cooling device (2) lower platform both sides are respectively arranged with water inlet, water delivering orifice, lower reference coupon (18) is arranged on cold utmost point cooling device (2) upper mounting plate top, and lower reference coupon (18) is provided with heating element (17) on upper surface, upper backup pad (9) top is provided with lifter (10), the movable upper backup pad (9) that connects of expansion link (11), expansion link (11) upper end is fixedly connected with lifter (10), expansion link (11) lower end is fixedly connected with heat insulation layer (12) upper surface, stationary fixture (15) is fixed on heat insulation layer (12) lower surface, in stationary fixture (15), be provided with thermoae electric hot plate (8), upper reference coupon (7), thermoae electric hot plate (8) is positioned between heat insulation layer (12) and upper reference coupon (7), upper reference coupon (7) upper, on lower surface, be respectively arranged with the first thermopair (13) and the second thermopair (14), outer heat-insulated pipe (4), interior heat-insulated pipe (5), inside protecting hot heat-insulation layer (6) upper end is separately fixed on the lower surface of upper backup pad (9), in being surrounded on, protects by interior heat-insulated pipe (5) hot heat-insulation layer (6) outside, outer heat-insulated pipe (4) is surrounded on interior heat-insulated pipe (5) outside, the lower end of outer heat-insulated pipe (4) is positioned on cold utmost point cooling device (2) lower platform table top, the upper mounting plate outer wall of interior heat-insulated pipe (5) bottom internal face and cold utmost point cooling device (2) coincide, inside protecting hot heat-insulation layer (6) inwall and heat insulation layer (12) coincide, inside protecting hot heat-insulation layer (6) lower end is positioned on the upper surface of heat-insulated pipe (5) bottom.

2. a kind of indoor rock sample test device of thermal conductivity coefficient according to claim 1, is characterized in that: described heating element (17) is a tungsten filament thermal source heating element.

3. a kind of indoor rock sample test device of thermal conductivity coefficient according to claim 1, is characterized in that: the center of lower bottom base (1), cold utmost point cooling device (2), lower reference coupon (18), heating element (17), upper reference coupon (7), thermoae electric hot plate (8), lifter (10), connecting link (11), heat insulation layer (12) is all positioned on same center line.