RU2653114C1 - Device for measurement of surface tension and metal viscosity factor - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to means for determining the physicochemical constants of a substance, namely its surface tension and the viscosity coefficient. Device comprises an electric resistance furnace mounted vertically with a movable holder, measuring and regulating thermocouples, a gas supply system, a loading system for a sample of metallic material, comprising a cooled sealed unit with a chamber for housing a test piece in the form of a sleeve therein, and with a weight sensor mounted on a fixed base. Device is further provided with additional chambers for placing in each of them a test sample in an inverted form, and additional weight sensors, each of which is connected by means of a suspension with the corresponding sample. Cooling sealed unit is provided with a central opening for mounting said thermocouples into it, and each test sample is mounted on a quartz rod, in the lower part of which a micrometric head is fixed.

EFFECT: technical result: providing the possibility of increasing the accuracy and speed of measurement and providing the possibility of measuring the zero creep load, starting from zero values.

1 cl, 6 dwg

Description

The invention relates to means for determining the physicochemical constants of a substance, namely its surface tension and viscosity coefficient.

The closest solution to the claimed solution is a device for determining the zero creep load described in a scientific article Gershman EI, Zhevnenko SN, “Method for measuring the surface tension of the solid-gas interface“ insitu ”, Physics of metals and metal science , 2010, according to which the device comprises an electric resistance furnace - 10 installed in a movable holder of the furnace - 11, thermocouples - 12, a gas supply system, a sample loading system, which is a mobile carriage - 1, which can be moved around in the vertical direction with the help of micro and macro displacement screws - 2, 3, this carriage allows you to move the camera - 5 and, accordingly, the sample - 6 relative to the weight sensor - 8, which is rigidly fixed on a fixed base - 9, and thus load or unload it, elastic corrugation - 4, allowing you to move the camera and the sample relative to the sensor without depressurization of the entire system, and the transmission of force from the weight sensor to the sample is carried out through the alundum rod - 7.

The device for measuring the load of zero creep, described above, uses one camera with one sample. The intrinsic mass of the foil and the mass of the hitch (suspensions: loops on the foil and the connecting rod) create a constant load on the foil, which is taken into account when calculating the zero creep load. At the same time, this leads to a drawback of such a device, namely, a zero creep load less than these constant weights (suspensions, dead weight foil) cannot be measured in principle. As a result, surface energy can be measured if it has a value above a certain positive level.

Thus, the disadvantages of the known device is the inability to measure the load of zero creep less than constant weights (suspensions, dead weight of the foil), a high error and the ability to measure surface energy only if it has a value above a certain positive level.

The main objective of the invention is to find a load of zero creep, i.e. load at which neither elongation nor contraction of the sample in the form of foil or wire occurs.

The technical result is to increase the accuracy and speed of measurement, and providing the ability to measure the load of zero creep, starting from zero values.

The technical result is achieved by the fact that the device for measuring the load of zero creep of metallic materials, contains an electric resistance furnace installed with the possibility of vertical movement by means of a movable holder, measuring and regulating thermocouples, a gas supply system, a loading system for a sample of metallic material, including a carriage moving in a vertical direction, located on a fixed support and cooled sealed unit with a chamber for placement of the test subject of nitrogen in the form of a sleeve, and with a weight sensor mounted on a fixed base, and is additionally equipped with cameras for placing the test sample in each of them inverted, and additional weight sensors, each of which is suspended by a suspension with a corresponding sample, while the cooling is sealed the block is made with a central hole for installing the indicated thermocouples, and each test sample is mounted on a quartz rod, in the lower part of which a micrometer head is fixed.

Brief List of Drawings

In FIG. 1 presents a General setup for measuring the load of zero creep described in the prototype.

In FIG. 2 presents a General diagram of the claimed device.

In FIG. 3 is a diagram of a cooled unit with sensors.

In FIG. 4 shows a sample for measuring the load of zero creep (25 - thick-walled sleeve, 26 - metal foil).

In FIG. Figure 5 shows the curves of the load on the sample versus time. The dashed line indicates the load P ₀ , which corresponds to the absence of deformation (zero creep).

In FIG. 6 presents examples of the description by computer of the experimental data, a) the tension of the sample; b) reduction.

In the proposed installation, the method of finding the load of zero creep "in-situ" was implemented. This is achieved by using a weight sensor, which was both a loading element and a force measurement sensor created by the surface tension in the sample.

The essence of the invention lies in the fact that the claimed device (Fig. 2) contains as a heating element an electrical resistance furnace - 13 with two independent windings of nichrome. The inner winding is used to control the temperature in the working part of the furnace, the outer winding is used to maintain a constant temperature 100 ° C below the operating temperature, thereby reducing the absolute value of the regulated power. This winding is under constant voltage. The accuracy of temperature maintenance is 0.5. In this case, the furnace is installed in a movable holder - 14, which ensures the movement of the furnace in the vertical direction. Temperature regulation and control is carried out using the control and regulating chromel-alumel thermocouples 15, the hot junction of which is in the immediate vicinity of the samples, and the cold junction of the thermocouples is maintained at a constant temperature using the thermostat.

To create an inert or reducing atmosphere in the chambers, an argon and hydrogen supply system was created - 16, which includes a hydrogen generator, an argon cylinder, gas supply tubes, gas flow regulators, and a liquid shutter. During operation, the reactor is constantly purged with hydrogen or a mixture of hydrogen and argon at a low speed (5-10 cm ³ / min).

The cooled block - 17 of the system for loading a sample of metallic material contains up to six separate chambers - 19 with samples - 18 made in the form of foil (18-30 microns thick) rolled into a cylinder with a diameter of 4-8 mm. Thus, measurements can be carried out on six different compositions (if it is required to measure isotherms of surface energy, i.e., the dependence of surface energy on the concentration of the second component in a solid solution).

To create an equilibrium atmosphere, smooth the temperature field in the furnace chamber and compensate for the thermal expansion of the foil - 26 was welded with its upper end to the thick-walled sleeve - 25 (Fig. 4).

In this case, the samples are installed (Fig. 3) upside down in the chambers, the sample is turned upside down, i.e. turn the sleeve with its foil welded in to measure the load of zero creep, starting from zero values. For this, the sample is placed on a quartz rod - 24, in the lower part of which a micrometer head is fixed - 21, and weight sensors - 20, which are both a loading element and a force measurement sensor, are placed above the samples, each sensor is connected to the sample by suspension - 23. To regulate and control the temperature of this cooling unit, a central opening was created - 22, in which thermocouples are installed.

The sensor was calibrated using standard weights from 1 to 50 grams. At the same time, the magnitude of the deflection of the sensor was monitored depending on the load in order to compare, during the experiment, the magnitude of the deformation of the sample as a function of the load.

If the load created by the sensor on the sample is less than the zero creep load, then the foil is compressed and the sensor readings will gradually increase; if the load is greater than the zero creep load, the foil is stretched and the sensor will gradually decrease (Fig. 5). Regardless of the selected load value, after some time, the system should come to an equilibrium value corresponding to the absence of deformation of the sample, that is, to the state when the surface tension force balances the force created by the sensor.

Deformation under experimental conditions proceeds according to the Nabaro-Hering mechanism, which establishes a linear relationship between the strain rate of the sample and the voltage at the sensor, the proportionality coefficient is equal to the inverse viscosity.

where η is the viscosity coefficient

where B is a constant of the Nabarro-Herring theory, Ω is the atomic volume, D is the coefficient of volume diffusion, V is the average volume of grain.

The voltage σ ^/ sum of the voltage generated by the sensor and the voltage generated by surface tension:

where, σ is the voltage specified by the sensor,

σ ₀ - zero creep stress, including the weight of the thrust and half the weight of the foil;

On the other hand, since the sensor is an elastic beam, we can write:

The proportionality coefficient A is determined by the deflection of the sensor under various standard weights, and the coefficient “A”, which is the tangent of the angle of inclination, was determined from the obtained graph “deflection value - applied load”.

Substituting (3) in (1) and (4), we obtain the system of equations:

Having done the substitution, we get:

Separating the variables, we come to the equation:

Integrating equation (7), we obtain:

Equation (8) is the kinetic dependence of the voltage on the sensor versus time for a sample at a certain temperature. If the samples have the same dimensions, instead of stress it is convenient to use a load in the form of a weight P ₀ . Selecting the parameters of equation (8) using a computer that give the best agreement between the experimental curve and the theoretical one, one can find the stress (load) of zero creep σ ₀ (P ₀ ) and viscosity coefficient η.

, где w - толщина фольги, a h - ширина. Истинная нагрузка нулевой ползучести связана с поверхностными энергиями в соответствии с соотношением:The load P is related to the voltage according to the equation

where w is the thickness of the foil, ah is the width. The true load of zero creep is associated with surface energies in accordance with the ratio:

- общая площадь границ зерен, при цилиндрической форме зерна.

- длина фольги, γ_СП поверхностная энергия свободной поверхности (СП, поверхности «твердое-газ»), γ_ГЗ - поверхностная энергия границ зерен, с хорошей точностью можно считать

.Where

- the total area of grain boundaries, with a cylindrical shape of the grain.

is the foil length, γ _{SP is the} surface energy of the free surface (SP, solid-gas surface), γ _GB is the surface energy of grain boundaries, we can assume with good accuracy

.

In this case, the true load of zero creep and measured by the above method differ by the value of the constant loads associated with suspensions and dead weight of the foil:

In the case of an inverted arrangement of the sample and the sensor, constant weights can be included in the dead weight of the sensor and programmed to zero.

In addition, it is possible to determine the load of zero creep according to the dependence of the strain rate on stress. Based on equations (1) and (3) we can write:

Or considering (4)

от σ или

от σ будут линейными, поскольку η не зависит от напряжения в условиях диффузионной ползучести. По отсекаемому отрезку на оси ординат можно определить отношение напряжения нулевой ползучести к вязкости, а тангенс угла наклона этой прямой будет давать величину обратную вязкости. Отношение отсекаемого отрезка (коэффициент D) к тангенсу угла наклона (коэффициент С) позволит определить напряжение нулевой ползучести.Comparing equations (11) and (12) with the equation of the line: y = G⋅x + D, it is easy to see that the graphs in coordinates

from σ or

will be linear on σ, since η is independent of stress under diffusion creep conditions. Using the cut-off line on the ordinate axis, the ratio of zero creep stress to viscosity can be determined, and the slope of this straight line will give the inverse viscosity. The ratio of the cut-off segment (coefficient D) to the tangent of the angle of inclination (coefficient C) will determine the zero creep stress.

Thus, the claimed device allows you to measure the load of zero creep, starting from zero values, as well as significantly speed up the process of obtaining data on surface energy and will lead to a decrease in random errors and the number of emissions.

Claims (1)

A device for measuring the load of zero creep of metallic materials, containing an electric resistance furnace installed with the possibility of vertical movement by means of a movable holder, measuring and regulating thermocouples, a gas supply system, a loading system for a sample of metallic material, including a cooled sealed unit with a chamber for placing the test sample in it in the form of a sleeve, and with a weight sensor mounted on a fixed base, characterized in that it is equipped with an additional cameras to place the test sample upside down in each of them, and additional weight sensors, each of which is connected to the corresponding sample by means of a suspension, and the cooling sealed unit is made with a central hole for installing the indicated thermocouples, and each test sample is installed on a quartz stock, in the lower part of which a micrometer head is fixed.

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