RU176601U1 - DEVICE FOR DETERMINING THERMAL PROPERTIES OF MATERIALS - Google Patents

Abstract

The utility model relates to measuring equipment, in particular, to devices for determining the heat, thermal diffusivity and heat capacity of materials, for example, rock samples. A device is proposed for determining the thermal properties of materials, containing two standards with a gap between them for the test sample, a flat source of thermal vibrations located at the boundary of the first standard with a gap and connected through a thermal oscillator to a control and recording unit, a differential thermocouple placed on the end face of the second standard and connected through a preliminary DC amplifier to the control and registration system. What is new is that the working junction of the differential thermocouple is placed at the end of the second standard, mating with the test sample, at a distance of 0.68 r (where r is the radius of the test sample) from the axis of the system of contacting bodies, and at the ends of the standards opposite to the ends in contact with the test sample, additionally placed temperature sensors. EFFECT: increased accuracy of measurements of thermal properties of materials. 2 ill.

Description

The utility model relates to measuring equipment, in particular, to devices for determining the thermal properties (thermal conductivity, thermal diffusivity and heat capacity) of materials, for example, rock samples.

A device for measuring thermal diffusivity, heat capacity and thermal conductivity of dielectrics and rocks by the method of plane temperature waves. (Yurchak R.P. Installation for complex measurements of the thermophysical properties of dielectrics // Factory Laboratory. - M .: Metallurgy, 1971. - T. 37. - No. 12. - S. 1514-1516.)

(

- толщина, d - диаметр). Между пластинами зажимается малоинерционный нагреватель, представляющий собой плоскую проволочную спираль. На свободных поверхностях размещаются термопары. В эксперименте из сигнала термопар с помощью потенциометра выделяется переменная составляющая, которая после усиления усилителем регистрируется на шлейфовом осциллографе. На этом же осциллографе фиксируются сигналы включения и выключения мощности нагревателя. В установке задается П-образный нагрев с помощью низкочастотного генератора и реле, мощность нагрева измеряется амперметром и вольтметром.In the setup described above, two identical flat samples are used - plates, for each of which the condition of unlimited

(

- thickness, d - diameter). A low-inertia heater, which is a flat wire spiral, is clamped between the plates. Thermocouples are placed on free surfaces. In the experiment, a variable component is extracted from the thermocouple signal using a potentiometer, which, after amplification by the amplifier, is recorded on a loop oscilloscope. On the same oscilloscope, the power on and off signals of the heater are recorded. In the installation, a U-shaped heating is set using a low-frequency generator and a relay, the heating power is measured by an ammeter and a voltmeter.

The thermal diffusivity and heat capacity are determined based on the measured values of the oscillation amplitude, the temperature on the sample surface opposite from the heater, and the phase shift between these oscillations and the heater power fluctuations.

The thermal conductivity λ is calculated from the obtained values of thermal diffusivity "α" and heat capacity "s". The measurement error "α" according to the author is 3-4%, λ - 5%.

The disadvantages of this technique in terms of petrophysical studies include the presence of two samples, which, even when sawn from one piece of sample, differ in composition and structure due to the significant heterogeneity of the rocks. In addition, the need from measurement to measurement to mount and dismantle temperature sensors on the surface of samples significantly complicates the experiment in mass determination of the thermal properties of rocks.

Closest to the proposed utility model by technical nature (prototype) is a "Device for determining the thermophysical properties of materials" (RF patent for the invention No. 1755152, CL G 01 N 25/18 of December 10, 1990), containing an external thermostat, housing a high-pressure working chamber with a cover having an opening for the piston exit, a shutter with a safety ring, a cover, a clamp, a pressure cartridge consisting of a body and a piston, a pressure gauge, an indicator, a piston (2nd standard) with a differential thermocouple placed in it, are studied the first sample, an impermeable shell, a flat source of thermal vibrations located on the end face of the first standard, (thrust bearing), a hydraulic pump of variable internal pore pressure with a supply pipe and a valve, a manometer, a direct current pre-amplifier, an analog-to-digital converter, a mini-computer, a thermal generator oscillations, a hydraulic pump of variable pressure of lateral compression with a tap, a supply pipe and a pressure gauge.

Thermophysical properties of the standards in the prototype satisfy the ratio:

,

,

where λ ₁ , α ₁ , and λ ₂ , α ₂ - respectively, the thermal conductivity and thermal diffusivity of the first and second standards.

The disadvantages of the prototype include the fact that it does not take into account heat loss from the side surfaces of the standards (with a one-dimensional thermal model) and does not control the attenuation in the standards of wave temperatures. The aforementioned leads to systematic measurement errors. Consider a system of equations that determines the temperature field in all three contacting bodies (Fig 1):

Here τ _i is the temperature in the i-th body; x, r are spatial variables; τ is the time; L is the length of the test sample; α _i , λ _i - thermal diffusivity and thermal conductivity of i - body; α is the heat transfer coefficient; r ₀ , S is the radius and cross-sectional area of the contacting bodies; τ ₀ is the ambient temperature; q (τ) is the given heat flux from heater 4, q (τ) = N / S; N is the power of the heater.

In system (1) - (9), we pass to dimensionless variables of the form

- характерная величина теплового потока; P - периметр поперечного сечения контактирующих тел. В результате получаемWhere

- the characteristic value of the heat flux; P is the perimeter of the cross section of the contacting bodies. As a result, we get

X = 1, θ ₂ = θ ₃ ,

X → ± ∞, θ ₁ → 0, θ ₃ → 0, 0 <R <1, Fо> 0.

Evaluation of the possibility of using a one-dimensional mathematical model in the system of contacting bodies to determine the thermal properties of materials shows that the temperature at different points of the cross-sections of the standards is not the same (due to the presence of lateral heat losses), and there may be situations when the temperature at some points (sections ) section significantly different from the average section. In this case, maximum deviations are observed on the axial line and on the lateral surface of the system of bodies. These deviations are greater, the greater the coefficient of heat transfer.

The aim of the proposed model is to increase the accuracy of measurements of the thermal properties of materials, such as thermal conductivity, thermal diffusivity, and heat capacity.

This goal is achieved due to the fact that the device is designed to determine the thermal properties of materials, contains:

- two standards with a gap between them for the test sample;

- a flat source of thermal vibrations located on the border of the first standard with a gap and connected through a thermal oscillator to the control and registration unit;

- a differential thermocouple placed at the end of the second standard and connected through a preliminary DC amplifier to the control and registration system.

What is new is that the working junction of the differential thermocouple is placed at the end of the second standard, mating with the test sample, at a distance of 0.68 r ₀ (where r ₀ is the radius of the test sample) from the axis of the system of contacting bodies, and at the ends of the standards opposite to the ends, in contact with the test sample, temperature sensors are additionally placed.

The described arrangement of the working junction of the differential thermocouple helps to eliminate systematic errors in the measurement of the thermal properties of materials associated with the incomplete correspondence of the physical setup of the mathematical model of heat transfer in the system of contacting bodies. The presence of additional temperature sensors allows you to choose the test mode corresponding to the mathematical model noted above.

As a result, the accuracy of measuring the heat, thermal diffusivity and heat capacity of the studied samples of materials increases.

Thus, the proposed utility model solves the problem of optimizing the placement of the temperature sensor in the standard. The inventive utility model is illustrated by drawings, where:

- in FIG. 1 presents a system of three contacting bodies (prototype);

- in FIG. 2 device for determining the thermal properties of materials. Calculations show that if we measure the temperature at a point where it coincides with the average temperature over the cross section, then we can use the solution of problem (17) - (20) to process the experimental data

- средняя по сечению температура в к-ом теле.Here s is the complex parameter of the Laplace transform and

- the average cross-sectional temperature in the body.

For standards made of polymethylmethacrylate, quartz glass, and other similar materials, the average cross-section temperature has a point corresponding to X = 1 and R = 0.68. Placing the temperature sensor at this point eliminates systematic measurement errors associated with the presence of heat loss from the side surfaces of the system of contacting bodies.

At the same time in the proposed device at the ends of the standards opposite to the ends in contact with the test sample, additional temperature sensors are placed. The purpose of this placement is to verify in experiment the sufficiency of the longitudinal dimensions of the standards for attenuation of temperature fluctuations in them with an error not exceeding the measurement error. The aforementioned conditions the strict fulfillment of the boundary conditions of the experiment.

The proposed utility model for determining the thermal properties of materials (Fig. 2) contains two standards 1 and 3 with a gap between them for the test sample 2 and temperature sensors 6 and 7 located at opposite ends of these standards. In addition, the device includes a flat source of thermal vibrations 4 , which is located on the border of the first standard 1 with a gap for the test sample 2, and connected through a thermal oscillation generator 5 with a control and registration unit (not indicated in Fig. 2), differential thermocouple 8, preliminary th DC amplifier 9, analog-to-digital converter 10, minicomputer 11. At the same time, the working junction of the differential thermocouple 8 is located at the end of the second standard 3, mating with the test sample 2, at a distance of 0.68 r ₀ (where r ₀ is the radius the test sample 2) from the axis of the system of contacting bodies.

The thermal properties of materials, including rocks, are determined on the test sample 2 of a round shape and thickness L.

The materials of standards 1 and 3 (half-bounded bodies) are polymethyl methacrylate or quartz glass of the KB brand, the length of standards 1 and 3 is chosen so that the temperature wave attenuates almost completely in them, that is, the temperature of the ends of standards 1 and 2 opposite from contact with the test sample 3 corresponded to the initial temperature with an error not exceeding the measurement error, and chromel-kopel type thermocouples serve as temperature sensors 6 and 7.

The utility model works as follows.

Before measuring thermal properties, the test sample 2 is inserted into the gap between the first 1 and second 3 standards. The entire system of contacting bodies 1, 2, 3 is clamped using a clamp (not shown in Fig. 2).

The heat oscillation generator 5 using a flat source of thermal vibrations 4, made either by spraying on the end face of the first standard 1 or from thin nichrome foil, sets the fluctuations in the heat flux of a rectangular shape of a fixed frequency and amplitude.

In this case, the frequency and amplitude values are selected based on the conditions of attenuation of temperature waves in the system of contacting bodies 1,2,3 using temperature sensors 6 and 7.

After some time, in the system of contacting bodies 1, 2, 3, periodic temperature fluctuations occur, which decay in semi-bounded bodies (standards 1 and 3). Using a differential thermocouple 8, temperature changes are converted into an electrical signal, which, after amplification by a DC pre-amplifier 9, is digitized by an analog-to-digital converter 10 and input into a mini-computer 11. The mini-computer 11 controls the thermal oscillation generator 5 and the analog- digital Converter 10, and also performs the processing of primary information and the calculation of heat, thermal diffusivity, heat capacity of the test sample 2.

A device for determining the thermal properties of materials corresponds to a mathematical model, which avoids the systematic errors of the experiment and improves the accuracy of measurements of heat, thermal diffusivity and heat capacity.

Claims (1)

A device for determining the thermal properties: thermal conductivity, thermal diffusivity and heat capacity of materials, containing two standards with a gap between them for the test sample, a flat source of thermal vibrations placed at the boundary of the first standard with a gap and connected through a thermal oscillator to the control and registration unit, differential thermocouple placed at the end of the second standard and connected through a pre-amplifier of direct current to the control and registration system, characterized in that about the working junction of the differential thermocouple is placed on the end face of the second standard, mating with the test sample at a distance of 0.68r ₀ from the axis of the contacting bodies, where r ₀ is the radius of the test sample, and sensors are additionally placed on the ends of the standards opposite to the ends in contact with the test sample temperature.

Images