SU855579A1 - Capacitive seismic pickup - Google Patents

Description

one

The invention relates to electromechanical transducers and can be used in acoustic non-destructive testing methods for recording (receiving) wave processes in solids, the shock pulses of which have a frequency spectrum up to 100-200 kHz.

A seismic sensor is known with a capacitive transducer made in the form of two metal cylinders, one of which is located inside the other, and gaskets between cylinders made of elastic insulating material tlj. The disadvantage of this device is the limited frequency range of the recorded signals.

The closest technical solution to the present invention is a capacitive vibration and displacement sensor, comprising a housing, elastically using springs connected to it a cylindrical inertial mass and a sensing element consisting of moving and stationary electrodes, which are respectively mounted on an inertial mass and on a moving body along with measured object of the sensor housing. Amplitude sensor action. vibrations and displacements are based on

property of the inertial mass, suspended on the springs to the body, remain motionless when the body oscillates at a frequency exceeding the frequency

5 natural inertial oscillations

masses

The disadvantage of this device is that the sensor has a limited frequency range and when

10 of the registration of shock pulses with frequency spectral composition up to 100-200 kHz, the signal is greatly distorted due to the higher resonances of the springs.

The purpose of the invention is the elimination of

15 occurrences when registering shock pulses.

The goal is achieved by the fact that in a known capacitive seismic sensor comprising a body, an inertial mass elastically connected to the body with a fixed electrode fixed to it and a fixed electrode fixed to the body, the inertial mass is made in the form of two truncated

25 cones, facing large bases to each other and swept along the line of connection with a collar, clamped between the rubber rings attached to the body.

thirty

The drawing shows the device, a general view with a partial cut.

The capacitive sensor consists of a housing 1 made of a lightweight high-strength metal, in which an inertial mass 2 is installed, consisting of two truncated cones facing large bases to each other and spanned along the connection line by a shoulder 3 clamped between rubber rings fixed to the housing 1 4, and is provided on the smaller base of one of the truncated cones. A movable electrode 5, in parallel with which a fixed electrode 6 is attached to the housing 1 through an insulator 7.

When registering wave processes, the housing 1 and the fixed electrode 6 mounted on it move with the measured object, and the inertial mass moves. 2, carrying the movable electrode 5, due to pinching of its bead 3 between rubber rings 4 that do not have higher re-resonances, remains stationary due to inertial forces, as a result of which the gap and, accordingly, the electrical capacitance between the electrodes 1 and 5 and 6 changes. proportional to the sensor output.

Performing the inertial mass in the form of two truncated cones, facing large bases to each other, makes it more rigid, and the natural frequencies are more pronounced. In addition, bevels of inertial mass exclude lateral friction of it on the rubber rings. The elimination of higher resonances of the springs is possible when the elastic suspension is made of a material with high internal damping. One of these materials is porous rubber. Elastic suspension of seismic mass in the proposed sensor

can also be carried out using a corrugated membrane with a hard one. center. However, sensors with a fixed inertial mass in rubber rings are more economical.

The use of the proposed capacitive sensor in acoustic nondestructive testing methods for registering shock wave processes in solids eliminates distortion of the useful signal, since with this design of seismic mass and elastic suspension, the upper frequency limit of AitanaaoHa is limited only by the resonant frequency of the sensor body, which depends 5 from the body material and increases with a decrease in its geometric dimensions.

Claims (2)

1. USSR author's certificate 177104, cl. S 01 V 1/16, 1964. 0 2. Agey D.I. and others. Sensors, control and {Egulyirovanie. M., Mechanical Engineering, 1965, p. 546 (prototype)