SU932575A1 - Electrokinetic sensor - Google Patents

Description

(5) ELECTROKINETIC SENSOR

Claims (2)

The invention relates to a measuring technique, to primary information converters, and is used to measure mechanical forces and pressures in gaseous or liquid media. Electrokinetic converters of non-electrical quantities into an electrical signal are known. The principally known sensor is made in the form of a sealed cylinder filled with working fluid, the ends of which are closed by membranes, divided into two chambers by a partition made of porous material (glass, ceramics, etc.) with current collection on both sides of it. When an external mechanical signal is applied to one of the membranes, the fluid in the cells of the cell and in the hopax partitions begins to flow through the porous partition from one chamber to another. As a result, an emf arises between current collectors proportional to an external signal. The disadvantage of the known sensor is the impossibility of measuring pressure changes and other quantities acting simultaneously and with equal intensity on both membranes. As a result, the sensor can be used to measure pressure surges in isotropic media. A sensor is known in which one of the membranes is isolated from external factors due to the presence of an additional chamber filled with gas with rigid walls 2. The disadvantage of this sensor is the low output signal power per unit volume of the converter and the relatively high internal resistance, which makes sensor matching difficult with devices connected to its output. The purpose of the invention is to increase the output power and expand the functionality without significant increases in the dimensions of the sensor. 3932 suitable for measuring pressure surges in gaseous or liquid media. This goal is achieved by the fact that, in the electrokinetic sensor of the porous partition, it is made in the form of a hollow ball, the working fluid inside which contains a gas bubble. At the same time, it is possible to reduce the internal resistance of the sensor by increasing the dimensions of the sensor by as many times as the area of the disk exceeds the area of the disk of the same diameter. At the same time, the output signal power increases. The drawing shows the device of the sensor. The sensor consists of a housing 1, inside of which a porous septum is installed in the form of a hollow ball 2. On the inner and outer surface of the porous system there are mesh current collecting electrodes 3 and. A porous partition divides the housing into two chambers 5 and 6. The outer surface of the housing is covered with flexible membranes 7 and 8 in the form of hemispheres, which are receiving elements that receive an external signal. The secondary elastic element of the sensor is a gas bubble 9 placed inside the porous sphere. Chambers 5 and 6 are filled with working fluid. When an external pressure EF is applied to the spherical surface of the sensor, due to the incompressibility and isotropy of the working fluid, the bubble decreases in size, as a result of which the liquid is filtered through a porous wall and EMF appears on the electrodes. Thus, both the increase in the output power of the signal and the sensitivity of the sensor to pressure surges in the medium are due to the implementation of a porous partition in the form of a hollow ball and the presence of a gas bubble in the fluid filling this ball. The result achieved simplifies measurement circuits with electrokinetic sensors, increasing sensitivity, accuracy and reliability. The invention The electrokinetic sensor, comprising a housing divided by a porous partition with current collectors into two chambers filled with a working fluid and provided with elastic elements, is characterized by the fact that, in order to expand the functionality and increase the output signal power, the porous partition is made in the shape of a hollow ball, the working fluid inside which contains a gas bubble. Sources of information taken into account in the examination 1. M. Kasimzade and draw Electrokinetic converters of information. M., Energie, 1973, p.39. 2. In the same place, p. 40, fig. 11 g (prototype). g