SU1462258A1 - Flow rate control apparatus - Google Patents

Abstract

The invention relates to an automatic control technique and can be used in heat engineering devices and systems. The purpose of the invention is to improve the accuracy, reliability and expansion of the field of application of the device for flow control. The device contains a housing with inlet 1 and outlet 2 nozzles and a toroidal chamber 5 located between them, with the outlet nozzle on the chamber 5 side forming a control valve seat, the shutter of which is formed by a disk 7 located in chamber 5, and in the closed position of the disk there is a gap the disk 7 and the end of the inlet nozzle 1 from the side of the chamber 5, and the outlet nozzle 2 is made with a local narrowing, the flow section, which is communicated with the supra-disk cavity of the chamber 5 through the bypass channel 10, in which En spring-loaded control valve 11. 2C. p. f-ly, 1 ill. i cl c

Description

The invention relates to automatic control and can be used in heat engineering devices and systems.

The purpose of the invention is improving accuracy, reliability and expanding the scope of the device,

The drawing shows a device.

The device comprises a housing with inlet 1 and outlet 2 nozzles separated by a partition 3, a cover 4 in which a toroidal chamber 5 is made, and the end face of the outlet nozzle 2 on the side of the toroidal chamber forms a valve seat 6, the shutter of which is formed by a disk 7. In the cover 4 is made profiled groove 8 with a cross-sectional area increasing in height, and in the above-disk cavity of the chamber | 5 there is a limit stop 9 of the disk 7, equipped with measuring slots.

The outlet pipe is made with local restriction with an area F _{c of the} bore, which is communicated with the above-disk cavity of the chamber 5 through the bypass channel 10. The latter is equipped with a spring-loaded control valve 11. The disk 7 is installed with the gap C in the closed position between the disk and the end of the inlet pipe from the side of the toroidal chamber, for example, due to the location of this end below the end of the outlet pipe from the side of the toroidal chamber.

The device operates as follows.

With the control valve 11 closed, the disk 7 is pressed against the saddle by the inlet pressure entering the over-disk cavity through the gaps between the end of the inlet pipe 1 from the side of the chamber 5 and the disk 7, as well as between the disk 7 and the walls of the toroidal chamber. When the valve 11 is opened, the pressure in the over-disk cavity decreases and the disk 7 floats up, communicating the inlet and outlet nozzles, and the working fluid enters the over-disk cavity also through the profiled groove 8. in the cover 4.

A certain opening to the height h of the control valve 11 corresponds to a certain opening of the disk by an angle. If, for any given reason, for a given h, the disk in the chamber pops up by a large value of this value with ( _} then the passage area of the groove 8 increases, determined by the position of the disk 7 In this case, the total hydraulic resistance of the gap c and the groove decreases.The leakage of the working fluid into the nadisci cavity exceeds its discharge into the outlet pipe 2 through the control valve 11 and the bypass channel 10.

The pressure above the disk 7 rises, which leads to its cover. If under the influence of any reasons, the disk pops up by an amount less than o /, then the discharge from the over-disk cavity exceeds the leakage. The pressure above the disk in this case decreases, which leads to the additional opening of the disk 7, i.e. the disc always monitors the position of the control valve.

The narrowing of the flow in the outlet pipe 2 allows to reduce the pressure in the cross section F _c , i.e. increase the pressure drop across the device and, accordingly, at the control valve 11 and, due to the ejection effect, strengthen the discharge of the working fluid from the over-disk cavity, which increases the efficiency of the control action of the valve 11. The opening of the disk 7 is limited by an adjustable stop 9.

Claims (3)

Claim 1. Device for regulating flow, comprising a housing with inlet and outlet nozzles and is located. between them a toroidal chamber, as well as a control valve and a control body, and the end face of the outlet pipe on the side of the toroidal chamber forms a saddle of the control valve, the shutter of which is formed by a disk placed in a toroidal chamber, in the disc space of which there is a restrictive stop of the disk, characterized in that that, in order to improve accuracy, reliability and expand the scope of the device, the disk is installed with a gap in the closed position between the disk and the end of the inlet pipe with orons of the toroidal chamber, the outlet pipe is made with local narrowing, the passage section of which is connected to the supra-disk cavity of the toroidal chamber through the bypass channel made in the housing, and the control organ is made in the form of a spring-loaded valve installed in the bypass channel. 2. The device according to claim 1, characterized in that the end of the inlet pipe from the side of the torus of the distant chamber is located below the end of the outlet pipe from the side of the toroidal chamber. 3. The device according to claim 1, wherein the restrictive stop of the disk is removable and provided with measuring slots.