SU781602A1 - Vibration batch meter - Google Patents

Description

The invention relates to measuring equipment and can be used to control vibrations. ,

Known vibration diodemeter containing a vibration sensor having a housing and a membrane fixed in it, and a recording system [1].

A disadvantage of the known device is the design complexity and its relatively large size, due to the design features and the presence of external power sources.

The purpose of the invention is to reduce the size and simplify the design.

This is achieved by the fact that the vibration sensor includes a grid system located between the housing and the membrane connected to the housing by mesh electrodes, a porous glass partition and a capillary filled with a polar liquid having a mercury drop and whose cavities are interconnected through a partition.

The drawing schematically depicts the described vibrodosimeter.

- The vibration meter contains a vibration sensor • with a housing 1 and a membrane 2, - fixed in it, and registering 3 ((system. A vibro sensor includes an electret 3 located between the housing 1 and the membrane 2). The recording system is designed as connected to the housing 1 and an electret 3 of mesh electrodes 4 and 5, separating them with a porous glass partition 6 and a capillary 7 filled with a polar liquid, having a mercury drop 8 and cavities 9 and 10 of which are interconnected through a partition 6. The vibrodoemometer works as follows.

The housing 1 of the vibration sensor is rigidly connected15 with the object subject to vibration control, and vibrates with it. The membrane 2 moves relative to the electret 3, which is always surrounded by an electric field. As a result of this, an electric current flows in an external circuit formed by electret 3 and membrane 2, whose amplitude is proportional to the intensity of vibrations.

When voltage is applied proportionally to the intense intensity of the detected vibrations of membrane 2 to the mesh electrodes 4 and 5 as a result of electroosmotic phenomena associated with the flow of the polar fluid through: ts ·. ''Risto partition 6 in the presence raznostipotentsialov the electrodes 4 and 5 is observed movement mercury drop 8 together with a polar liquid in the capillary 7. Since the speed of the working fluid and the mercury drop in the capillary 8 7 _n pro- 5rts _{ionalna magnitude} of the voltage applied to the electrodes 4 and 5, and the magnitude of the voltage is proportional to the intensity of the vibrations of the membrane 2 relative to the electret 3, the position of the mercury drop 8 in the capillary 7 will determine the integral value of the results of the recorded vibrations.

The high surface tension of the mercury droplet 8 and the large hydrodynamic resistance of the entire recording system (capillary 7, cavities 9 and 10) determine the constancy of the surface tension of the mercury droplet during vibrations. It depends only on the voltage applied to the electrodes 4 and 5.

This will make it possible, by the position of mercury drop 8, to perform continuous ‘visual reading of the integral results of vibration measurements, when V'REQUIRED voltage on electrodes 4 and 5 returns the measuring system to its original state, which ensures operation for an unlimited time.

The presence of an electret in the vibration sensor eliminates the need for external power sources.

The main advantage of vibrodoei 5 meters - its miniature and ease of execution.

Claims (1)

Claim 1Q Vibrodosimeter containing a vibration sensor having a housing and a membrane. fixed in it, and a recording system, characterized in that, in order to reduce the size and 15 to simplify the design, the vibration sensor includes an electret located between the housing and the membrane, and the recording system is made in the form of mesh electrodes connected to the housing and the electret, separating them porous 20 by a glass partition and a capillary filled with a polar liquid having a mercury drop and whose cavities are interconnected through a partition. 25 Sources of information taken into account during the examination 1. Mikhlin B.Z. High-frequency capacitive and inductive sensors, M.-L., Gosenergoizdat, 1960, p. 6830 69 (prototype). IT.TX?