RU2725203C1 - Mechanical quantity sensor - Google Patents

Abstract

FIELD: measurement.SUBSTANCE: invention relates to measurement equipment, is intended for conversion of dynamic mechanical values, including vibration and impact acceleration into electric signal, and can be used in various industries, in particular, construction, for seismic measurements, experimental research. Mechanical values sensor consists of an L-shaped support made of an electrically insulating material, an elastic metal plate and an inertia element. Resilient metal plate is rigidly fixed to the vertical wall of the support from one end. Inertial element is attached to the other end of the plate. Both surfaces of the plate adjoining the jamming point are in contact with electrolyte of two electrochemical cells. Each cell is made in the form of a hollow quarter sphere of elastic electric insulating material, one arched flat surface of the case of which is glued to the horizontal surface of the plate, and the other one - to the vertical wall of the support. Current-collecting counter electrodes of the cells are made from metal of the plate, tightly embedded in the vertical wall of the support, some of their free ends are in contact with electrolyte of cells, and others - are withdrawn from the support wall.EFFECT: technical result is higher reliability and reliability of conversion of dynamic mechanical values to an electrical signal in a wide range of loads and frequencies.1 cl, 2 dwg

Description

The invention relates to measuring equipment, is intended for converting dynamic mechanical quantities, including vibration and shock acceleration, into an electrical signal and can be used in various industries, in particular, in construction, for seismic measurements, experimental studies.

A known sensor of mechanical quantities with a beam cantilever fixed flexural elastic element and strain gauge converters of its deformation into an electrical signal [http://tokves.ru/datchiki-balochnyie.html?yclid=1736387897797397239].

The disadvantages of such a sensor are:

a) the need for a bridge circuit power supply, which increases energy consumption;

b) the incomplete transfer of deformation from the elastic element to the strain gauge through the adhesive layer, the properties of which depend on external conditions (temperature, humidity), aging, the nature of the measured loads, is possible.

A known sensor of mechanical quantities [V.V. Yancich. Piezoelectric sensors for vibration and shock acceleration. Textbook Allowance. Rostov-on-Don, 2008, p. 49, fig. 3.4 b; http://diss.seluk.ru/m-elektrotelmika/474496-1-yanchich-pezoelektricheskie-datchiki-vibracionnogo-udarnogo-uskoreniya-uchebnoe-posobie-rostov-na-donu-2008-recenzenti-docent-ka.php] adopted for the prototype, consisting of an element of the cantilever type, a piezoelectric element and an inertial element. The cantilever is made in the form of a metal L-shaped support, in the vertical wall of which an elastic horizontal metal plate with an inertial element at the other end is rigidly pinched from one end, the piezoelectric element is glued in the zone of maximum mechanical stresses of the plate that arise when it is bent under the influence of a measured quantity. The disadvantages of such a sensor are:

a) the fragility of the piezoelectric element and the dependence of its characteristics on external conditions and operating conditions;

b) the adhesive layer, which is an intermediate element in the transfer of deformation, has low strength and reliability, and also negatively affects the temporal and temperature stability of metrological characteristics;

c) the occurrence of sensitivity to rotational vibrations caused by the fact that the centers of mass of the piezoelectric and inertial elements are spaced a certain distance and do not coincide with the center of inertia of the device;

d) high-resistance output impedance, which creates difficulties in recording the measured value and noise immunity.

A common problem in measuring non-electric quantities (forces, pressures, vibration, etc.) with sensors of this kind with a primary transducer in the form of a sensitive elastically damped element, a secondary transducer (strain gauge, piezoelectric element) and an adhesive layer between them, is a decrease in the reliability and reliability of the measured value transformations in electrical signal.

The invention is aimed at solving the problem of improving the reliability and reliability of the conversion of dynamic mechanical quantities into an electrical signal in a wide range of loads and frequencies. The technical result is a direct conversion of the deformation of a sensitive elastic element into an electrical signal.

The technical result is achieved by a mechanical quantity sensor, consisting of a cantilever type element in the form of an L-shaped support, in the vertical wall of which a horizontally located elastic metal plate with an inertial element on the other end is rigidly pinched at the other end, while the L-shaped support is made of electrical insulating material and both surfaces of the plate adjacent to the pinch point are in contact with the electrolyte of two electrochemical cells, the body of each of which is made in the form of a hollow quarter of a sphere of elastic electrical insulating material, one curved flat surface of the body is glued to the horizontal surface of the plate, and the other to the vertical wall of the support, the collector counter electrodes of the cells are made of plate metal, hermetically sealed in the vertical wall of the support, some of their free ends are in contact with the electrolyte of the cells, and others are removed from the wall of the support.

In FIG. 1 shows a general view of the sensor. In FIG. 2 - section along aa.

The mechanical quantity sensor consists of a L-shaped support 1 made of an insulating material, an elastic metal plate 2 and an inertial element 3, two electrochemical cells, each of which includes a housing 4, an electrolyte 5, a collector counter electrode 6. A horizontally positioned elastic metal plate 2 is rigidly pinched from one end to the vertical wall of the L-shaped support 1, the inertial element 3 is fixed to the other end of the metal plate 2, the housing of the electrochemical cells 4 are made of elastic electrical insulating material in the form of a hollow quarter of the spheres filled with electrolyte 5, one curved flat surface of the housing 4 is glued to the horizontal surface of the metal plate 2, and the other to the vertical wall of the L-shaped support 1, and one electrochemical cell 4 is fixed on top of the plate 2, and the other on the bottom. The collector counter electrodes of 6 cells 4 are made of metal of the plate 2, hermetically sealed in the vertical wall of the L-shaped support 1, some of their free ends are in contact with the electrolyte 5 of the cells 4, and others are removed from the wall of the L-shaped support 1.

The sensor operates as follows. When exposed to vibration, seismic vibrations, other shocks, they are perceived by an elastic metal plate 2 with an inertial element 3, while the upper and lower surfaces of the metal plate 2 are alternately stretched and compressed. The zones of maximum mechanical stresses that occur during bending of the plate and are in contact with the electrolyte are deformable electrodes. It is known [Gokhshtein A.Ya. Surface tension of solids and adsorption. Ed. A.N. Frumkina, M., Nauka, 1976, P.33], that if, when the electrode in contact with the electrolyte deforms, its area changes, then the effect of elastic charging occurs. Moreover, if the electrode charge is kept constant, for example, by introducing damping resistance into the electrode circuit, then the potential of the electrode itself changes. In the electrochemical cells 4, these changes are recorded relative to the collector counter electrodes 6. Since the change in the area of the deformable electrodes of the cells 4 are close in magnitude, but opposite in sign, the output signal is doubled. Thus, the effect of direct conversion of the mechanical deformation of the sensitive elastic element into an electrical signal is achieved.

By choosing the ratio of the length and thickness of the elastic metal plate 2 and the mass of the inertial element 3, it is possible to widely control the range of measured dynamic loads and frequencies [Yu.I. Yorkshire. Vibrometry. Second edition, revised and enlarged. M., State. scientific and technical publishing house of machine-building literature, 1963].

When removing the inertial element 3 from the elastic metal plate 2, the sensor can be used to record forces and movements by directly influencing the measured value on the free end of the plate.

The invention has the following advantages over the claimed prototype:

a) low resistance output resistance due to the low resistance of the electrolyte, provides ease of measurement and noise immunity,

b) a decrease in sensitivity to rotational vibrations caused by the low weight of the electrochemical cells and their two-sided fastening to an elastic plate and a rigid vertical wall,

c) the absence of an adhesive layer and a piezoelectric element, as intermediate deformation converters.

Thus, the problem is solved to increase the reliability and reliability of the conversion of dynamic mechanical quantities into an electrical signal in a wide range of loads and frequencies, while the technical result is achieved by directly converting the resulting deformation of a sensitive elastic element into an electrical signal.

Claims (1)

A mechanical quantity sensor, consisting of a cantilever type element in the form of a L-shaped support, in the vertical wall of which a horizontally located elastic metal plate with an inertial element on the other end is rigidly pinched at one end, characterized in that the L-shaped support is made of electrical insulating material, and both surfaces of the metal plate adjacent to the pinch point are in contact with the electrolyte of two electrochemical cells, the body of each of which is made in the form of a hollow quarter-sphere of elastic insulating material, one curved flat surface of the body is glued to the horizontal surface of the metal plate, and the other to the vertical wall of the L-shaped support, the collector counter electrodes of two electrochemical cells are made of plate metal, hermetically sealed in the vertical wall of the L-shaped support, some of their free ends are in contact with the electrolyte of the cells, and others are withdrawn from the wall of the L-shaped th support.

Images