SU597955A1 - Moisture sensor - Google Patents

Description

one

The invention relates to a technique for measuring the viscosity of gases and can be used on radiosondes and other aircraft to measure relative humidity of the air.

A device for measuring the relative humidity of gases is known, containing — as a sensitive element — a quartz resonator equipped with a transducer into an electrical signal of any parameter of this resonator, depending on the humidity of the ambient air lj.

However, the pressure and ambient gas temperature changes indicated by the device influence the sensor readings, which results in less accurate measurements.

The closest technical solution to this invention is a moisture sensor comprising a sensitive element made in the form of a quartz resonator connected to an equivalent resistance-to-electrical conversion unit L23.

However, this sensor does not have sufficient measurement accuracy.

The purpose of the invention is to improve the measurement accuracy.

To do this, in the proposed humidity sensor, the radiating faces of the quartz resonator are placed in dampers made in the form of hollow glasses.

The drawing shows a structural diagram of the proposed device.

The humidity sensor contains a sensing element, made in the form of a quartz crystal I, connected to the unit 2 converting the equivalent resistance into an electrical signal, while the radiating faces 3, 4 of the quartz resonator 1 are placed in dampers 5,6, made in the form of Hollow glasses 7, 8.

The humidity sensor works as follows.

When excited in the quartz resonator of oscillations, its acoustic field is concentrated inside small volumes of gas, bounded by the surfaces of hollow glasses 7, 8 and radiating faces 3, 4 and

is a standing acoustic wave.

In the standing wave, in contrast to the traveling wave emitted by the quartz resonator 1 without dampers 5, b, there is no energy transfer, this ensures minimal energy losses by the quartz resonator 1, which are mainly determined by acoustic radiation from the gaps between the radiating edges 3, 4 and the inner surface of the hollow glasses 7, 8. When introducing the radiating faces 3, 4 into the cavities of the dampers 5, b without contact with their inner surface and decreasing the thickness of the gaps, the magnitude of the losses also decreases, which increases t measurement accuracy.

Claims (2)

1. USSR author's certificate 256854, cl. (01 8 17/00, 1967. 2. USSR author's certificate No. 168501, cl. 01 W 1/11, 1963.