SU957025A1 - Pneumatic switching device - Google Patents

Description

(54) PNEUMATIC SWITCHING DEVICE

one

The invention relates to instrumentation, in particular, to pneumatic switching devices.

Known pneumatic switches for sequential pressure measurement, containing a stator with openings, connected by drainage tubes with pressure selection points and a rotor with a interrogating solenoid valve, driven by a periodic action mechanism 1.

These devices do not provide high measurement accuracy in multipoint measurements.

Closest to the invention in technical essence and the achieved effect is a pneumatic switching device comprising a stator with openings connected to drainage tubes arranged in several rows, ground rotor, rotor drive and pneumatic converter 2.

The known device also does not provide high accuracy of pressure measurement.

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

The goal is achieved by the fact that in a pneumatic switching device containing a stator with openings connected to drainage tubes arranged in several rows, a ground rotor is driven

 the rotor and pneumatic converter, the stator and the rotor are made flat, and the interrogating holes in the rotor are connected by deaf radial channels in the fluoride sleeve of the rotor with a central hole

10 in it, connected to a pneumatic converter.

The drawing shows a pneumatic switching device, a general view and its functional connections with an automated measurement, recording and control system.

 The pneumatic switching device consists of a housing 1, inside which there is a fixed disk 2 with a differential type pressure sensor 3. In the fixed disk 2, two or more concentric circles are arranged with openings 4 interrogations, which are connected with pressure selection points by means of pipelines 5. Fixed disk 2 is coupled with a fluoroplastic liner 6 rolling

a disk 7 in which deaf, radially directed channels 8 are made, which are out of phase relative to each other and numerically equal to the number of concentric circles of the fixed disk 2, in which 4 polling holes are located. At the diverging ends, the channels 8 have holes 9, mated with the corresponding holes 4 of the survey of the fixed disk 2, and the other ends of the channels 8 are connected by one common hole 10, which is connected with the central hole 11 connected to the measuring cavity of the sensor 3. The opposite cavity of the sensor 3 via conduit 12 is connected to a source 13 of a reference pressure, the value of which is minimized depending on the measured pressure. In one of the positions of the movable disk 7, for example at the beginning, the reference cavity of the sensor 3 through the pipeline 12, the interrogation opening 4 through the opening 9, the channel 8, the opening 10 of the insert 6 and the opening 11 of the fixed disk 2 is connected to the measuring cavity of the sensor 3, providing calibration zero level sensor 3 when polling measured pressure.

A movable disk 7 designed to interrogate measured pressures supplied to openings 4 is installed in housing 1 and, with its shaft 14, is connected to a drive 15 intended to turn disc 7 during interrogation of measured pressures. A gauge, 17 point numbers, is mounted on the shaft 14 and the cap 16, which serves to decipher the measured pressures and is connected to the automated system 18 for measuring, recording and controlling.

In order to balance the forces acting on the movable disk 7 from the side of the polled pressures and to improve the accuracy, the chamber 19 of the supercharging is measured by means of a pipe 20 connected to an external pressure source 21, which specifies a positive pressure drop depending on the polled pressures and the accuracy.

The pressure sensor 3, the reference pressure source 13, the point number marker 17, the actuator 15 and the external pressure source 21 are electrically connected to the automated measurement, control and recording system 18, which provides the entire measurement process during the experiment.

The proposed pneumogaping device operates as follows.

The drive 15, through the shaft 14, transmits rotation to the disk 7, providing alternate connection of the corresponding channel 8 with openings 4 located along concentric circles of the fixed disk 2.

The measured medium flows through the pipelines 5 through the openings 4 when interrogated through the opening 9 into the deaf channel 7, and from the opening 10 and into the measured cavity of the sensor 3.

On the other hand, the air from the source 13 of the reference pressure through the pipeline 12 enters the reference cavity of the sensor 3. At the same time, during the polling cycle, this air through one of the holes 4 and through the channel 8 of the moving disk 7 enters in one of its positions into the measuring cavity of the sensor 3, providing a zero calibration level during measurements.

When the disk 7 rotates, the marker 17, the point number in the position when the hole 4 with the measured pressure coincides with one of the holes 9, gives a pulse to the recorder of the automated measurement system 18. The same system 18 receives electrical signals of the position of the shaft 14 from the actuator 15, controlled pressure from source 13, measured pressure and a zero level calibration signal from sensor 3.

At the same time, air from the source 21 of the external pressure enters through the pipe 20 into the chamber 19 of the pressurization, thereby providing the necessary preload of the movable disk 7 with the fluoroplastic liner b at the time of the survey of the measured pressure.

The presence of a movable disk in the PTFE liner of radially directed deaf channels displaced in phase relative to each other by an angle proportional to the number of concentric circles along which the interrogation holes are located in the fixed disc allowed the manufacture of a compact pneumatic switching device with the number of interrogation holes up to 50 measurement points increase its effectiveness.

The use of a pressurization chamber to press a rotating disk with a software setting of pressure and a fluoroplastic liner allows, by 20-25%, to increase the accuracy of the device and the impermeability of the lapped surfaces, with less cost to manufacture the device.

The use of a zero-level calibration of a pressure sensor and a point number gauge simplifies the drive device and the automated measurement system, which also has an effect on reducing the laboriousness of manufacturing the device and deciphering the measurement results.

Claims (2)

Invention Formula A pneumatic switching device comprising a stator with openings connected to drainage tubes arranged in several rows, a ground rotor, a rotor drive and a pneumatic converter, characterized in that, in order to improve accuracy, the stator and the rotor are flat and the polling openings in the rotor are connected deaf radial channels in the fluoroplastic liner of the rotor with a central hole in it connected to a pneumopus converter. 2 7 20 Sources of information taken into account in the examination I. USSR author's certificate 290188, cl. G 01 L 19/00, 1969. 2..Avtorskoe certificate of the USSR 540178, cl. G 01 L 19/00, 1975 (prototype). 2f / 7 $