SU1286981A1 - Device for measuring conductance of specimens from solid particulate materials - Google Patents

Abstract

The invention relates to a technique for measuring the electrical conductivity of solid dispersed materials consisting of components with pronounced differences in the electrical conductivity of the filler and the binder. The purpose of the invention is to increase the measurement accuracy. The device is designed as electrically insulated and uniformly distributed across the cross section of potential electrodes embedded in current-carrying electrodes. The current-carrying electrodes clamp the ends of the sample under test. A constant current is applied from the source of the bison. A potential electrodes uniformly distributed over the ends are connected in pairs to the potentiometer by a switch. The apparent values of the voltage drop are averaged. The device allows one to take into account the current distribution over the cross section and eliminates the voltage drop in the contact areas of the current-carrying electrodes with the sample surfaces, which improves the measurement accuracy. 3 Il. (L

Description

The invention relates to a technique for measuring the electrical conductivity of solid particulate materials consisting of components with pronounced differences in the electrical conductivity of the filler and the binder.

The aim of the invention is to improve the accuracy of measuring the electrical conductivity of solid particulate materials.

Fig. 1 shows the constructive arrangement of the current-carrying electrode in the potential electrode; Fig. 2 shows the measuring circuit of the device; Fig. 3 shows section A-A in Fig. 2.

The device contains sample 1, electrical insulation 2, current-carrying electrode 3, potential electrode 4, spring device 5, housing 6, flexible wire 7, switch 8,

tensiometer 9, rheostat 10, ammeter 11.LD-.

In the current lead electrode 3, the holes for the potential electrodes are uniformly distributed. Dp eliminating the electrical contact of the potential electrode 4 with the electrode 3, the surface of the hole is electrically insulated 2. The potential electrodes 4 are placed in the electrically insulating housing 6 and equipped with a spring device 5 to ensure reliable contact with the sample surface. connected to switch 8 connected to potentiometer 9.

The device works as follows. .

A sample of 30 mm length is clamped at the ends between the current-carrying electrodes with a diameter of 15 mm and 0.8 mm holes for potential electrons. The constant current from the power supply is regulated by a rheostat 10 and

ten

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measured by ammeter 11. Switch 8 is connected in pairs to potentiometer 9 by potential electrodes uniformly distributed over the surfaces. The apparent values of the voltage drop are averaged. The number of measurement points can be increased by rotating the sample around its axis. The device is designed to measure the electrical conductivity of samples of solid dispersed materials. In such materials, the distribution of the current lines has an irregular, random character; therefore, the error due to the holes in the current-carrying electrodes is insignificant. Essential for such structures is the averaging of effective current lines due to the uniform distribution of potential electrodes over the sample cross section and orientation along these current lines.

The use of a special tokopod of the auxiliary electrode ensures high accuracy in measuring the electrical conductivity of dispersed materials.

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Claims (1)

Invention Formula A device for measuring the electrical conductivity of samples from solid dispersed materials, containing two pairs of electrodes connected to the recording circuit, each pair made as insulated electrodes embedded into each other, and the working surfaces of one pair relative to the other lie in parallel planes that differ - with the fact that, in order to improve the measurement accuracy, potential electrodes are built into the current electrode and are evenly distributed over its voltage.  / / - /., J: LJ -,. /  V u ii / f. FIG. 2 Aa