SU1007020A1 - Vibration parameter electrokinetic pickup - Google Patents

Description

This invention relates to electrokinetic converters that can be used to measure vibrations. The known electrokinetic linear acceleration meter is a body with rigid end walls, inside of which a conversion wall is placed, dividing the body cavity into two chambers, each of which has electrodes, working fluid, gas volumes, gas volume transfer limiters, made in the form of porous partitions , while the liquid-gas interface is located in the pores of the displacement limiters Ci The disadvantage of such a linear acceleration gauge is the complexity of and the limited application due to the narrow frequency range of the measured accelerations. Electrokinetic vibration meters are known in which an electrical signal arises when a fluid moves relative to a porous transducer. The septum is due to the mass inertia of the fluid itself, which is located between the conversion partition and the elastic membrane. In a number of cases, the latter is rigidly connected to an additional inertial mass In this case, the electrokinetic cell either vibrates with the housing or is stationary and the pressure drop on the conversion partition is created by the vibration of the inertial mass, which is rigidly connected Noel with an elastic membrane. The closest in technical essence and the achieved effect to the proposed is an electrokinetic sensor containing a housing filled with a working fluid, equipped with electrodes transforming a partition rigidly fixed in the housing and dividing its cavity into two chambers, and an inertial element connected by elastic elements with a housing t l The constructions considered have a significant general disadvantage due to the fact that with increasing linear accelerations the shock guide significantly increases An automatic load on the conversion wall, may cause its mechanical destruction, since it is most often made of fragile glass, ceramic, etc. materials. The deficiency noted reduces the reliability of such sensors when they are used to measure increased vibrations and limits the upper range of measured accelerations. The purpose of the invention is to increase the reliability of the sensor by reducing the shock load on the conversion wall. This goal is achieved by the fact that in an electrokinetic sensor containing a housing filled with working fluid, equipped with electrodes, a conversion barrier rigidly fixed in the housing and dividing its cavity into two chambers, and an inertial element connected with elastic elements to the housing, an inertial element. It is made with a variable cross section, is located in one of the sections and through the working fluid is communicated with its largest and smallest sections with opposite sides of the transforming partition. In this case, the inner surface of the inertia element is made in the form of a funnel tapering from the porous partition, the smallest section of which is communicated by an isolated channel one of the sides of the conversion partition. In addition, the inertial element is made in the form of a body expanding from the transforming partition, the largest cross section of which is connected by an isolated channel on one side of the porous partition. FIG. 1 shows a sensor with one embodiment of an inertial element; in fig. 2 shows another embodiment of the inertia element. Electrokinetic vibration sensor contains a sealed housing 1 with rigid walls, filled with a working fluid, such as acetone. Inside the case, a transforming porous partition 2 with electrodes 3 is rigidly fixed. Partition 2 divides the cavity of the case into two chambers 4 and 5. In chamber 5 an inertial element b of the variable internal ((rig 1) and external (Fig. 2) cross section is placed, st 7. One side of the transforming partition is connected with a wide section, and the other with a narrow one, moreover, when a narrow section is located inside the inertial element Dfig 1), the message is made by means of a pipe 8. A narrow section of the working fluid in tchike (FIG. 2) is formed by the inner surface of the housing 1 and the largest external cross section of the inertial element. It communicates with the side of the septum cylindrical channel 9. The proposed sensor works as follows. Vibration accelerations directed along the sensor axis cause

Claims (3)

Ϊ. ELECTROKINETIC SENSOR OF VIBRATION PARAMETERS, comprising a housing filled with working fluid, equipped with electrodes, a conversion wall, rigidly fixed in the housing and dividing its cavity into two chambers, and an inertial element connected by elastic elements to the housing, characterized in that, in order to increase the reliability of the sensor by reducing the shock load on the converting partition inertial element is made with a variable cross-section, is located in one of the chambers and through the working fluid is communicated with its most the smallest and smallest sections with opposite sides of the converting cross section. birthmarks. 2. The sensor according to claim 1, which is related to the fact that the inner surface of the inertial element is made in the form of a funnel tapering from the porous septum, the smallest neck of which is communicated by an isolated channel from one of the sides of the converting partition. 3. Sensor pop. 1, characterized in that the inertial element is made in the form of a body expanding from the transforming partition, the largest section of which is communicated by an isolated channel from one side of the porous partition. Fig!