SU966492A1 - Position pickup - Google Patents

Description

(54) POSITION SENSOR

The invention relates to a measurement technique and can be used to monitor the position of a moving object, as well as detect holes in it.

Position sensors are known that contain a vortex annular nozzle and a pneumoelectric transducer with a sensing element in the form of a membrane, which is placed in a chamber connected by a channel with an end face.

However, the accuracy of these sensors is low due to the influence on the response pressure of the deviations of the supply pressure, as well as the inertia of signal transmission to the chamber where the pneumo-electric transducer is located.

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

This goal is achieved by the fact that in a position sensor containing a vortex annular nozzle and a pneumoelectric transducer with a sensitive element in the form of a membrane, the membrane is placed inside the nozzle flush with its end face, and the pneumoelectric transducer e-membrane cavity communicates with a nozzle by a spiral channel. -,

FIG. i shows the sensor, general view; in fig. 2 shows section A-A in FIG. one.

The position sensor contains a housing

1 with the tangential channel 2 and the central insert 3. The housing 1 and the insert 3 form a converging vortex annular nozzle 4. In the central insert 3 there is a spiral

10 channel 5 and cavity b. A pneumatic-electric converter is placed in the cavity. It consists of a conductive membrane 7 and contacts 8. The membrane 7 is placed inside the nozzle 4 for 15 facing the end of the housing 1 and insert 3. The direction of rotation of the spiral channel 5 coincides with the direction of gas flow (arrow 9) at . annular convergent channel. Output

20 channel 5 tangentially matching

with the surface of the central insert 3.

The sensor works as follows. Compressed air under constant pressure through the tangential channel.

2 enters the annular nozzle 4 and

in the form of a swirling jet expires in the atmosphere. the direction of the surface of the test piece 10, the 3d torus moves in the normal axis

sensor. At a constant distance between the end of the sensor and the part being monitored, the stretch under the membrane 7 decreases when there is an opening 11 in the part 10. At the same time, the discharge on the other side of the membrane 7 arises due to the gas being sucked into the nozzle 4 along the spiral channel 5. Spiral shape Channel 5 allows to obtain a minimally perturbed jet, which does not affect the power jet and does not squeeze it from the surface of the central insertion 3 in a transient mode, which prevents the ripple of the differential pressure on the conductor conductive membrane 7, and false positives.

When the pressure of the power supplied to the sensor changes, the pressure differential acting on the membrane 7 remains almost unchanged, which is achieved by matching the characteristics of the nozzle 4 and channel 5, which creates discharge on both sides of the membrane 7. In order to reduce the dynamic error of the membrane of the pneumoelectric transducer, at the end of the central insert 3.

Thus, the presence of the spiral channel in the central insert and the placement of the conductive membrane at its end substantially eliminates the measurement error when the supply pressure changes and increases the sensor’s dynamic accuracy due to a decrease in the channels and cavities determining its dynamics.

Claims (1)

1. USSR author's certificate No. 808725, cl. G 01 B 13/00, 1979.