SU1742732A1 - Measuring vibration converter - Google Patents

Abstract

Usage: in the field of measurements of mechanical quantities. Summary of the invention: on the base, an inertial element is mounted through an elastic suspension, on which a mechano-electric converter is fixed. On the two sides of the inertial element on the basis of installed elastic damping plates. The housing is filled with damping medium. The natural frequency of the flaps is selected 2.3 ... 2.5 times the natural frequency of the inertial element, and the total effective mass of the flaps is selected 1.1 ... 1.4 times less than the mass of the inertial element. 1 il.

Description

(L

WITH

The invention relates to the field of measurement of mechanical quantities, for example, measurements of vibration accelerations.

Vibrating transducers are known in which structural damping is absent and the required form of frequency response is provided by the natural frequency value. For these vibration transducers, the working range (with an uneven frequency response of 10%) is the frequency range up to 1/3 of the natural frequency. Any expansion of the frequency range is associated with a decrease in sensitivity, which is inversely proportional to the square of the natural frequency, which is a disadvantage of these vibration transducers.

The closest in technical essence to the proposed vibrator contains a sensitive element in the form of a cantilever beam with inertial

weight at the end. The console is fixed on the base of the device, and a mechano-electric converter is mounted on it. Symmetrically on both sides of the console on the base there are two plates with a gap between them and the console. When the sensitive element moves relative to the shields, the viscous medium (gas or liquid) in the gap creates damping, which forms the frequency response of the instrument. If the damping coefficient is close to 0.6, then the working frequency range of the vibrator is in the range of up to 0.9 natural frequency, i.e. almost three times wider than in the absence of a damper.

A disadvantage of the known construction is that it maintains the same interrelation of sensitivity and natural frequency as in the absence of a damper.

N G

g °

The aim of the invention is to expand the frequency range of the measuring vibration transducer without reducing its sensitivity.

This goal is achieved by the fact that in a vibration transducer containing a base located in a casing with a damping medium with damping plates fixed on it, between which an inertial element is placed, connected to the base by means of an elastic suspension with a mechano-electric converter fixed on it, while their own frequency is selected 2.3-2.5 times the natural frequency of the inertial element, and the total effective mass of the flaps is selected 1.1-1.4 times less than the mass of the inertia onnogo element.

The drawing shows schematically the structure of the vibration converter.

The vibration transducer contains a base 1, on which an inertial sensing element 2 is installed, consisting of a load and an elastic suspension. On the latter, a mechano-electric converter 3 is mounted to move the load relative to the base in the direction indicated by arrow a into an electrical signal. Elastic flaps 4 and 4 are also installed on the base. The base is covered by a casing 5, which is filled with a viscous medium (gas or liquid).

When the vibration acceleration is applied to the base 1 of the vibration transducer, both the inertia sensing element 2 and the flaps 4 and 4 are involved in the movement. These movements are interconnected, and the connection

through a viscous medium filling the gaps between the inertial element and the shields. In the frequency range between the natural frequencies of the inertial element and the flaps, the phases of these movements turn out to be opposite, which increases the strength of the interaction of the inertial element and the flaps, proportional to their relative speed, the flaps

t inherent inertia element, thereby aligning the frequency response of the vibrator.

When choosing the natural frequency of the flaps, 2.3-2.5 times the natural frequency of the inertial element, and the total effective mass of the flaps is 1.1-1.4 times less than the mass of the inertial element, the working frequency range is expanded by almost 4 times compared to famous vibrator.

Claims (1)

The invention includes a measuring vibration transducer comprising a base located in a housing with a damping medium with damping plates fixed to it, between which an inertial element is placed connected to the base by means of an elastic suspension on which a mechano-electric converter is fixed, characterized in that, in order to expand the frequency range while maintaining sensitivity, the plates are made elastic, while their own frequency is selected 2.3-2.5 times more the natural frequency of the inertial element, and the total effective mass of the flaps is selected 1.1-1.4 times less than the mass of the inertial element.