SU478538A1 - Pressure ratio sensor - Google Patents

Abstract

A PRESSURE RELATION SENSOR, containing an inlet nozzle with a critical expiration mode, which is connected to a source of greater of reduced pressure, and a receiving nozzle,! coaxially mounted in a housing connected to a smaller source of comparable pressure, which differs from and to _. so that, in order to expand the range of the sensor, it is equipped with a ring coaxially mounted between the inlet and receiving nozzles, and the inner diameter is larger than the diameter of the input edge of the receiving nozzle.

Description

The invention relates to instrumentation, in particular, to devices for measuring pressure. A pressure ratio sensor is known which contains an inlet nozzle with a critical outflow mode, which is associated with a source of a larger of the compared pressures, and a receiving nozzle coaxially mounted in a housing associated with a source of a lower of the compared pressures. The known pressure ratio sensor is not characterized by a wide range of pressure ratio. . The purpose of the invention is to expand the range of the sensor. The goal is achieved by the fact that the sensor is equipped with a ring coaxially mounted between the entrance and receiver i, the inner diameter of the ring being larger than the diameter of the entrance edge of the receiving nozzle. The drawing shows the proposed pressure ratio sensor. The inlet 1 and the coaxial receiving 2 nozzles are installed in the housing 3 at a certain distance from one another, with a cylindrical ring between the nozzles. 4. The sensor works as follows. Gas at a higher pressure enters nozzle 1 and flows into the inter-nozzle chamber, where ha is supplied at a lower pressure P ,. The gas jet created by the nozzle 1 enters the nozzle 2, creating a pressure Rsch, which is used to control the actuator. When the pressure ratio - / P-j reaches 1.89, the gas jet at the exit of the nozzle 1 reaches sonic velocity. In this case, expansion and contraction waves intersecting in the center of the jet are formed, which are reflected from the outer boundary of the jet. With an increase in the pressure ratio Pj / P -, - above the value of 1.8.9, the steady-state jet structure is disturbed and a sharp drop in pressure is observed at the exit of the nozzle 2. by displacing the front of the intersection of the expansion (contraction) waves with the outer boundary of the jet towards the entrance edge of the nozzle 2. Ring 4 increases the pressure ratio P2 / P, at which a sharp stepwise decrease in pressure FBJ occurs, due to the additional constraint of the supersonic jet, which does not allow The front of the intersection of the expansion waves (compression) with the outer boundary of the jet is displaced towards the entrance edge of the nozzle 2, before a higher pressure ratio P- / P is reached. . Thus, mounting the ring 4 allows the range of the pressure ratio sensor to be expanded.

Claims (1)

PRESSURE RELATIONS SENSOR containing an input nozzle with a critical expiration mode, which is connected to the source of the larger of the compared pressures, and a receiving nozzle, coaxially mounted in the housing connected to the source of the smaller of the compared pressures, which is connected to the receiver. the fact that, in order to expand the range of operation of the sensor, it is equipped with a ring coaxially mounted between the inlet and receiving nozzles, and the inner diameter is larger than the diameter of the input edge of the receiving nozzle ·. ss ω (Ζ h 00 ‘sl: Q0 V