RU2788562C1 - Method for determining the complex of thermophysical characteristics of solid construction materials - Google Patents

Abstract

FIELD: construction materials.

SUBSTANCE: invention relates to the determination of the thermophysical characteristics of solid construction materials and can be widely used in various fields of technology, for example in thermal power engineering, construction, etc. A method for determining the complex of thermophysical characteristics of solid construction materials includes a test sample, on the middle of the surface of which temperature sensors are installed on the side of the refrigerator and heater. The sample is placed in a device for implementing the method between the heater and the refrigerator, the ends are closed with sealed lids to stabilize the temperature and heat flow passing through the sample under study. The temperature of the heater, the temperature of the refrigerator, the thickness of the sample are set in the electronic control unit and the device is switched on. The thermocouples of the heater and refrigerator are connected to the electronic control unit, as well as a heat flux sensor mounted on the refrigerator to measure the stationary heat flux density, which is recorded in the memory unit of the electronic control unit. The surface temperature of the test sample measured using an additional thermocouple from the refrigerator side, as well as the measured surface temperature of the test sample from the heater side, are entered into the computer device and the control unit, with the necessary data to determine the thermal resistance coefficient in the control unit’s computing device. The computer device, using the experimental data obtained, calculates the desired thermophysical characteristics of the sample under study, and, in addition, additionally calculates thermal conductivity and thermal insulation.

EFFECT: increase in the accuracy of determining the thermophysical characteristics of construction materials while simultaneously expanding the functionality.

1 cl, 2 dwg

Description

The invention relates to the determination of thermophysical characteristics of solid building materials and products, and can be widely used in the field of thermal power engineering, construction and others.

A technical solution is known in which thermophysical characteristics are determined - thermal conductivity and thermal diffusivity of solid materials, when finding which a reference sample is used to determine the wave number, which complicates the method and allows you to determine only thermal conductivity and thermal diffusivity [Patent SU 1770872, - analogue].

A known method for determining the thermal activity of materials, which consists in thermal heating of the test sample, recording the temperature change of the sample and calculating the thermal activity of the test material [Patent RU 2462703, analog].

The disadvantage of the known method for determining thermal activity is that the wave number is determined only using a reference sample, which complicates the method.

Also, the disadvantage of this method is that it allows you to determine only the thermal activity of the material under study, the determination of other thermophysical characteristics is impossible.

A known method for non-destructive testing of a complex of thermophysical characteristics of solid building materials, consisting in heating the test sample in the form of a rectangular prism, supplying heat to its surface, determining the desired thermophysical characteristics from the corresponding dependencies, measuring the temperature of the middle of the face of the investigated prism in time, the test sample is placed between a flat heater and cooled from below with a refrigerator and from all sides the sample is closed with sealed covers to stabilize the temperature and heat flux on the surface of the test material from the side of the heater, in the electronic timer control unit, the observation time is set, using the control panel, the heater temperature, refrigerator temperature, sample thickness are set using the buttons , enter the temperature values of the heater, refrigerator and stationary heat flux density in the memory block of the electronic control unit, using them to determine the calculator the values of the thermal conductivity coefficient and the thermal resistance coefficient in the electronic control unit, and the temperature values of the sample surface from the heater side, characterizing the temperature wave on the indicated sample surface, are entered into the computer and used together with the data obtained in the computing device of the electronic control unit, while to determine the desired thermophysical characteristics, the stationary heat flux density is used [RF Patent No. 2530441, - prototype].

The disadvantage of the known method when determining the complex of thermophysical characteristics is that when calculating the thermophysical characteristics, only the value of the sample surface temperature from the heater side is taken into account, without taking into account the value of the sample surface temperature from the cooler side, which reduces the accuracy of determining the thermophysical characteristics.

Also, the disadvantage is that the method does not allow to determine the wave temperature number at the time of the onset of a stationary thermal regime, which is used in determining additional thermophysical characteristics, which reduces the functionality of the known method.

The technical result is an increase in the accuracy of determining the complex of thermophysical characteristics.

The technical task is to increase the accuracy of determining the complex of thermophysical characteristics of solid materials, by determining additional thermophysical characteristics, while expanding the functionality of the method.

Solving a technical problem.

A method for determining the complex of thermophysical characteristics of solid building materials, which consists in heating the test sample by supplying heat to its surface, determining the desired thermophysical characteristics from the corresponding dependencies, measuring the temperature of the test sample in time, placed between a flat heater and a refrigerator cooled from below, from all sides the test sample is closed sealed covers to stabilize the temperature and heat flow, detect a temperature wave on the surface of the test sample from the side of the heater, set the time of the study in the electronic timer control unit, use the control panel on the buttons to set the heater temperature, refrigerator temperature, sample thickness, enter the heater temperature and temperature of the refrigerator, the density of the stationary heat flux into the memory block of the electronic control unit, using them to determine in the computing device of the control unit values of the thermal conductivity coefficient and the thermal resistance coefficient, the temperature values of the sample surface from the heater side, characterizing the temperature wave on the sample surface from the heater side, are entered into the computer and the data control unit to determine the desired thermophysical characteristics, in which the surface temperature of the sample, made in in the form of a plate, from the side of the refrigerator by means of a thermocouple installed in the middle of the plane of the sample surface for taking and recording the temperature and test time at a given interval, taking temperature readings from the start of heating the sample until the onset of a stationary thermal regime, when the temperature of the sample from the side of the refrigerator stops changing with time heating, the temperature change data from the time of heating the sample is entered into the memory block of the electronic control unit to determine the temperature wave in the computing device of the control unit according to the surface of the sample from the side of the refrigerator, which are then entered into the computer together with the data obtained in the computing device of the control unit to determine the thermal conductivity coefficient and thermal insulation coefficient according to mathematical dependencies, respectively:

where: 0.434 is a mathematical constant equal to log(2.718);

- волновое температурное число образца в виде пластины, вычисленное в момент времени наступления стационарного теплового режима;

- wave temperature number of the sample in the form of a plate, calculated at the time of the onset of a stationary thermal regime;

δ is the sample thickness;

where: 4.34 is a mathematical constant equal to 10⋅log(2.718);

- волновое температурное число образца в виде пластины, вычисленное в момент времени наступления стационарного теплового режима;

- wave temperature number of the sample in the form of a plate, calculated at the time of the onset of a stationary thermal regime;

δ is the sample thickness.

Essence.

The proposed method allows you to calculate additional thermophysical characteristics of the test sample:

thermal conductivity and thermal insulation, with the help of which the strength and sound-physical properties of solid materials are further determined, for example, such as Young's modulus of elasticity and the speed of sound in solid materials.

The essence of the method for determining the complex of thermophysical characteristics of solid building materials lies in the fact that in order to increase the accuracy of determining the thermophysical characteristics of the test sample, made in the form of a plate located between a flat heater located on top of the sample and a flat refrigerator located at the bottom of the sample, the surface temperature of the sample is additionally determined with side of the refrigerator using a thermocouple installed in the middle of the sample surface plane from the side of the refrigerator and connected to a computer device for taking and recording readings and time from the start of heating the test sample and until the onset of a stationary thermal regime, which occurs when the temperature of the sample from the side of the refrigerator stops change in time. Before the onset of the stationary thermal regime, the temperatures of the interfaces of the sample and the cooler will be different. Also, by means of a thermocouple connected to the computer device and installed in the middle of the sample plane from the side of the heater, readings are taken and the temperature and time are recorded from the start of sample heating to the onset of a stationary thermal regime with data entered into the computer device by means of a thermocouple installed in the middle of the plane. sample from the side of the heater.

For clarity, in accordance with the data obtained from experimental studies, the change in the temperature of the sample surface from the side of the refrigerator, as well as the change in the surface temperature of the sample from the side of the heater and the time of the study, graphs are plotted (Fig. 1, curve 1 and curve 2). According to curves 1 and 2, changes in the temperature of the sample surface from the side of the heater and refrigerator, respectively, and the moment when the temperatures stop changing, the heat flux passing through the sample stabilizes and becomes constant, this corresponds to the time of onset of the stationary thermal regime.

When conducting a study of a sample of textolite with a size of 250 × 250 × 20 mm, the initial temperature of the sample surface from the side of the refrigerator is T ₀ =22 ° C, and after turning on the installation, the temperature values of the sample surface from the side of the refrigerator, characterizing the temperature wave on the specified surface of the sample, begin change and when reaching the desired temperature in the control unit T _x =19.1°C are maintained constant (Fig. 1. curve I). The initial temperature of the sample surface from the heater side is also equal to T ₀ =22°C, and after turning on the setting, the temperature values of the sample surface from the heater side, characterizing the temperature wave on the indicated surface, begin to change and when the preset temperature of the heater T _P1 =34°C is reached, they are maintained constant (Fig. 1, curve II). After the temperature of the sample surface on the side of the refrigerator and the heater has ceased to change, that is, the heat flow has stabilized, the stationary thermal regime is reached, and the time of its onset is τ=36 min. (Fig. 1, position III).

The complex of thermophysical characteristics in accordance with experimental data is determined by mathematical dependencies.

The amplitude of oscillations of the temperature half-wave is determined by the formula:

where: T _P1 - temperature of the sample surface from the side of the heater at the moment of onset of the stationary thermal regime, °C;

T ₀ is the initial temperature of the sample surface.

The heat absorption coefficient is determined by the formula:

where: q _p - heat flux density, at the moment of onset of a stationary thermal regime, W/m;

- амплитуда колебаний температурной полуволны, °С.

- amplitude of fluctuations of a temperature half-wave, °C.

The thermal resistance of thermal conductivity is determined by the formula:

where: q _p - heat flux density, at the moment of onset of a stationary thermal regime, W / m ² ;

T _P1 - temperature of the sample surface from the side of the heater, at the moment of onset of the stationary thermal regime, °C;

T _P2 - temperature of the sample surface from the side of the refrigerator, at the time of the onset of the stationary thermal regime, °C.

The wave temperature number is determined at the time of the onset of a stationary thermal regime, according to the formula:

where: H - dimensionless wave number, determined by calculation at the time of the onset of a stationary thermal regime, equal to 1.414;

δ - sample thickness, m.

The thermal conductivity coefficient is determined by the formula:

where: B - heat absorption coefficient, W / (m ² ⋅K);

H - dimensionless wave number, determined by calculation at the time of the onset of a stationary thermal regime, equal to 1.414;

- волновое температурное число образца в момент времени наступления стационарного теплового режима, м^-1.

- wave temperature number of the sample at the moment of onset of the stationary thermal regime, m ^-1 .

Volumetric heat capacity is determined by the formula:

where: B - heat absorption coefficient, W / (m ² ⋅K);

τ is the time of onset of the stationary thermal regime, s;

λ - coefficient of thermal conductivity, W/(m⋅K);

π is a mathematical constant, equal to 3.14.

Thermal diffusivity is determined by the formula:

where: τ is the time of onset of the stationary thermal regime, s;

- волновое температурное число образца в момент времени наступления стационарного теплового режима, м^-1;

- wave temperature number of the sample at the moment of onset of the stationary thermal regime, m ^-1 ;

Thermal inertia is determined by the formula:

where: λ - coefficient of thermal conductivity, W/(m⋅K);

(сρ) - volumetric heat capacity, J / (m ³ ⋅K).

Thermal activity is determined by the formula:

where: b - thermal inertia, J ² / (s⋅m ⁴ ⋅K ² ).

образца в момент времени наступления стационарного теплового режима определяют дополнительные теплофизические характеристики исследуемого образца: термопроводность и термоизоляцию.Having determined the wave temperature number

sample at the moment of onset of the stationary thermal regime determine additional thermophysical characteristics of the sample under study: thermal conductivity and thermal insulation.

Thermal conductivity is a dimensionless coefficient that characterizes the proportion of the ratio of the energy of the temperature wave (J) passed through the sample to the energy supplied to the sample, determined by the formula:

where: 0.434 is a mathematical constant equal to log(2.718);

- волновое температурное число образца, вычисленное в момент времени наступления стационарного теплового режима, м^-1;

- wave temperature number of the sample, calculated at the moment of onset of the stationary thermal regime, m ^-1 ;

δ - sample thickness, m.

Thermal insulation is determined by the formula:

where: 4.34 is a mathematical constant equal to 10⋅log(2.718).

- волновое температурное число образца, вычисленное в момент времени наступления стационарного теплового режима, м^-1;

- wave temperature number of the sample, calculated at the moment of onset of the stationary thermal regime, m ^-1 ;

δ - sample thickness, m.

Determination of the wave temperature number of the sample, at the time of the onset of a stationary thermal regime, allows you to determine additional thermophysical characteristics of the sample under study - thermal conductivity and thermal insulation, expanding the functionality of the method, which is a new technical result.

In addition, the measurement of the sample surface temperature by means of an additional thermocouple installed on the side of the refrigerator and the time of onset of the stationary thermal regime allow, in comparison with the prototype, to improve the accuracy of determining the thermophysical characteristics.

The implementation of the method.

The investigated sample made in the form of a plate, for example, from textolite, with dimensions of 250×250×5÷45 mm is placed in a device for implementing the method between the heater and the refrigerator. A thermocouple is installed to measure the temperature on the outer surface of the test sample from the side of the refrigerator, a thermocouple is installed to measure the temperature on the outer surface of the test sample from the side of the heater, and a computer connected to the instrument. The test sample is closed from the ends with sealed covers to stabilize the temperature and heat flux passing through the test sample. In the electronic control unit set the temperature of the heater, the temperature of the refrigerator, the thickness of the sample and turn on the device. The electronic control unit maintains the set temperatures of the heater and refrigerator and controls them with the given accuracy. The change in temperature on the outer surface of the test sample from the side of the refrigerator and the temperature on the outer surface of the test sample from the side of the heater with a given time interval is recorded by a computer device. Next, graphs of the dependence of temperatures on the measurement time are plotted, a temperature wave on the outer surface of the test sample from the side of the refrigerator, a temperature wave on the outer surface of the test sample from the side of the heater, and when the temperatures stop changing, the time of onset of the stationary thermal regime is determined.

The computer device, using the obtained experimental data on the temperatures of the surface of the test sample from the side of the refrigerator, from the side of the heater, the stationary density of the heat flux and the time of onset of the stationary thermal regime, calculates a complex of thermophysical characteristics of the test sample.

The invention is illustrated by graphic material. In FIG. Figure 1 shows the temperature distribution over the sample thickness versus the measurement time. Curve I - change in the temperature of the surface of the test sample from the side of the refrigerator from the test time. Curve II - change in the temperature of the surface of the test sample from the side of the heater from the test time. Position III - the time of onset of the stationary thermal regime. Curve IV - heater temperature. Curve V - refrigerator temperature. In FIG. 2 schematically shows a device for implementing the method with the accepted notation.

An example of a specific implementation.

As a test sample 1, to determine the complex of thermophysical characteristics, a textolite sample was used, made in the form of a plate with dimensions of 250 × 250 × 20 mm. Temperature sensors 4 and 5 were installed in the middle of the sample 1 surface plane on the side of the refrigerator 2 and in the middle of the sample 1 surface plane on the heater 3 side, respectively. Sample 1 was placed in a device for implementing the method between heater 3 and refrigerator 2, the ends were closed with hermetic covers 6.

In the electronic control unit 7, using the control panel 8, the heater temperature was set to 34°C, the refrigerator temperature was 19.1°C, the sample thickness was set to 20 mm, and the device was connected to an alternating current source 9. Next, the heater 3 and refrigerator 2 began to reach their setpoints. temperatures. By means of the electronic control unit 7, the set temperatures of the heater 3 and the refrigerator 2 were maintained at the set values. In addition, a thermocouple 10 installed on the heater 3, a thermocouple 11 installed on the refrigerator 2, and a heat flux sensor 12 installed on the refrigerator 2 are connected to the electronic control unit 7 to measure the stationary heat flux density. The temperatures of the heater 3, refrigerator 2, and the stationary heat flux density were recorded in the memory block 13 of the electronic control unit 7. The surface temperatures of the test sample 1 from the refrigerator 2 side and the surface temperatures of the test sample 1 from the heater 3 side with an interval of 1 min. entered into the computer 14.

Before the onset of a stationary thermal regime, the temperatures of the interfaces of sample 1 with cooler 2 and heater 3 will be different. To find the surface temperature of sample 1 from the side of refrigerator 2, an additional thermocouple 4 was installed on its surface to measure the temperature over time. When the surface temperatures of sample 1 on the side of heater 3 and on the side of cooler 2 stop changing and the heat flux stabilizes, a stationary thermal regime will begin.

To determine the amplitude of oscillations of the temperature half-wave, the coefficient of heat absorption - B, the coefficient of thermal resistance of thermal conductivity, the wave temperature number, the coefficient of thermal conductivity, volumetric heat capacity - (сρ), thermal diffusivity - a, as well as thermal conductivity and thermal insulation of the test sample, we plotted the temperature distribution from the test time of the sample under study and determined the temperature of the sample surface from the side of the refrigerator, the temperature of the surface of the sample from the side of the heater, and the time of onset of the stationary thermal regime. The temperature of the test sample before testing was T ₀ =22°C, the surface temperature of the sample from the side of the refrigerator was T _P2 - 19.1°C, the surface temperature of the sample from the side of the heater was T _P1 =34°C. The value of the stationary heat flux density was q _p =195 W/m ² through τ _p =36 minutes from the start of measurements.

Further, according to the obtained value of the temperature of the sample surface from the side of the refrigerator, the value of the surface temperature of the sample from the side of the heater, the density of the stationary heat flux, as well as the time of onset of the stationary thermal regime, previously entered into the computer device that performed the calculations.

The amplitude of oscillations of the temperature half-wave was determined by the formula:

where: T _P1 - the temperature of the sample surface from the side of the heater, at the time of the onset of the stationary thermal regime, is equal to 34°C;

T _P2 - the temperature of the surface of the sample from the side of the refrigerator, at the time of the onset of a stationary thermal regime, is equal to 19.1°C. The heat absorption coefficient was determined by the formula:

where: q _p - heat flux density, at the moment of onset of the stationary thermal regime, amounted to 194 W/m ² ;

- амплитуда колебаний температурной полуволны, равна 7,45°С.

- amplitude of oscillations of the temperature half-wave, equal to 7.45°C.

The thermal resistance of thermal conductivity was determined by the formula:

where: T _P1 - the temperature of the sample surface from the side of the heater, at the time of the onset of the stationary thermal regime, is equal to 34°C;

T _P2 - the temperature of the surface of the sample from the side of the refrigerator, at the time of the onset of a stationary thermal regime, is equal to 19.1°C.

The wave temperature number was determined at the time of the onset of the stationary thermal regime, according to the formula:

where: H - dimensionless wave number, determined by calculation at the time of the onset of a stationary thermal regime, equal to 1.414;

δ - sample thickness, equal to 0.02 m.

The thermal conductivity coefficient was determined by the formula:

where: B - heat absorption coefficient, amounted to 26.04 W / (m ² ⋅K);

H - dimensionless wave number, determined by calculation at the time of the onset of a stationary thermal regime, equal to 1.414;

- волновое температурное число образца, вычисленное в момент времени наступления стационарного теплового режима, равное 70,7 м^-1.

- wave temperature number of the sample, calculated at the moment of onset of the stationary thermal regime, equal to 70.7 m ^-1 .

Volumetric heat capacity was determined by the formula:

(сρ)=В ² ⋅τ/(π⋅λ)=(26.04 ² ⋅2160)/(3.14⋅0.26)=1794⋅10 ³ , kJ/(m ³ ⋅K),

where: B - heat absorption coefficient, amounted to 26.04 W / (m ² ⋅K);

τ - the time of onset of the stationary thermal regime, determined from the schedule, amounted to 2160 s;

λ - coefficient of thermal conductivity, amounted to 0.26 W/(m⋅K);

π is a mathematical constant equal to 3.14.

Thermal diffusivity was determined by the formula:

where: τ - the time of onset of the stationary thermal regime, determined according to the schedule, was 2160 s;

- волновое температурное число, вычисленное в момент времени наступления стационарного теплового режима, составило 70,7 м^-1;

- wave temperature number, calculated at the moment of onset of the stationary thermal regime, amounted to 70.7 m ^-1 ;

π is a mathematical constant equal to 3.14.

Thermal inertia was determined by the formula:

b=λ⋅(сρ)=0.26⋅(1794⋅10 ³ )=0.466⋅10 ⁶ , J ² /(s⋅m ⁴ ⋅K ² ),

where: λ - coefficient of thermal conductivity, amounted to 0.26 W / (m⋅K); (сρ) - volumetric heat capacity, amounted to 1794⋅10 ³ J/(m ³ ⋅K).

Thermal activity was determined by the formula:

where: b - thermal inertia, amounted to 0.466⋅10 ⁶ J ² /(s⋅m ⁴ ⋅K ² ).

Having determined the wave temperature number of the sample, in the form of a plate, at the time of the onset of the stationary thermal regime, additional thermophysical characteristics of the test sample are determined: thermal conductivity and thermal insulation.

In this case, the thermal conductivity was determined by the formula:

where: 0.434 is a mathematical constant equal to log(2.718);

- волновое температурное число образца в виде пластины, вычисленное в момент времени наступления стационарного теплового режима, равное 70,7 м^-1;

- wave temperature number of the sample in the form of a plate, calculated at the time of onset of a stationary thermal regime, equal to 70.7 m ^-1 ;

δ - sample thickness, equal to 0.02 m.

Thermal insulation was determined by the formula:

where: 4.34 is a mathematical constant equal to 10⋅log(2.718);

- волновое температурное число образца в виде пластины, вычисленное в момент времени наступления стационарного теплового режима, равное 70,7 м^-1;

- wave temperature number of the sample in the form of a plate, calculated at the time of onset of a stationary thermal regime, equal to 70.7 m ^-1 ;

δ - sample thickness, equal to 0.02 m.

The proposed method for determining the complex of thermophysical characteristics of solid building materials using the wave temperature number makes it possible to determine additional thermophysical characteristics of the test sample - thermal conductivity and thermal insulation. Using thermal conductivity and thermal insulation, it is possible to determine the strength and sound-physical properties of solid materials, such as Young's modulus of elasticity and the speed of sound in solid materials, expanding the functionality of the method, which is a new technical result.

In addition, the measurement of the sample surface temperature by means of an additional thermocouple installed on the side of the refrigerator and the time of onset of the stationary thermal regime allow, in comparison with the prototype, to improve the accuracy of determining the thermophysical characteristics.

The proposed method makes it possible to determine a set of thermophysical characteristics for various solid building materials, such as brick, glass, and others.

Claims (9)

A method for determining the complex of thermophysical characteristics of solid building materials, which consists in heating the test sample by supplying heat to its surface, determining the desired thermophysical characteristics from the corresponding dependencies, measuring the temperature of the test sample in time, placed between a flat heater and a refrigerator cooled from below, from all sides the test sample is closed sealed covers to stabilize the temperature and heat flow, detect a temperature wave on the surface of the test sample from the side of the heater, set the time of the study in the electronic timer control unit, use the control panel on the buttons to set the heater temperature, refrigerator temperature, sample thickness, enter the heater temperature and temperature of the refrigerator, the density of the stationary heat flux into the memory block of the electronic control unit, using them to determine in the computing device of the control unit evaluating the values of the thermal conductivity coefficient and the thermal resistance coefficient, the temperature values of the sample surface from the heater side, characterizing the temperature wave on the sample surface from the heater side, are entered into the computer and the data control unit to determine the desired thermophysical characteristics, characterized in that they additionally determine the temperature of the sample surface, made in the form of a plate, from the side of the refrigerator by means of a thermocouple installed in the middle of the surface of the sample for taking and recording the temperature and test time at a given interval, taking temperature readings from the start of sample heating until the onset of a stationary thermal regime, when the temperature of the sample from the side of the refrigerator stops changing from the heating time, data on temperature changes from the heating time of the sample are entered into the memory block of the electronic control unit to determine the temperatures in the computing device of the control unit of the surface wave of the sample from the side of the refrigerator, which are then entered into the computer together with the data obtained in the computing device of the control unit to determine the thermal conductivity coefficient and the thermal insulation coefficient according to mathematical dependencies, respectively

where 0.434 is a mathematical constant equal to log(2.718);

- wave temperature number of the sample in the form of a plate, calculated at the time of the onset of a stationary thermal regime; δ is the sample thickness;

where 4.34 is a mathematical constant equal to 10⋅log(2.718);

- wave temperature number of the sample in the form of a plate, calculated at the time of the onset of a stationary thermal regime; δ is the sample thickness.

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