RU2073905C1 - Pressure regulator - Google Patents

Abstract

FIELD: automatics. SUBSTANCE: pressure regulator has housing 1, inlet branch pipe 2 and outlet branch pipe 3 with spaces 4 and 5, respectively, flexible clutch 6 secured between housing 1 and flanges of branch pipes 2 and 3, and control space 7 interposed between flexible clutch 6 and housing. The flanges are tightened by means of screw 8 to define inner chamber 13. Pilot 9 is connected with receivers 10 and 11 of static input and output pressure through pulse pipes 17 and 18 and with control space 7 through pulse pipe 12. The flange of branch pipe 2 is provided with receivers of total pressure which are in communication with inner chamber 13. Pressure drop meter 14 is connected with inner chamber 13 and receiver 10 of input static pressure through pulse pipes 15 and 16. EFFECT: enhanced reliability. 1 dwg

Description

 The invention relates to automation, in particular to control equipment for gas supply systems of industrial facilities.

Known pressure regulators used in gas supply systems [1]
The closest in technical essence to the proposed one is a pressure regulator [2] containing a housing located between the inlet and outlet nozzles, the opposing flanges of which are interconnected in the center and form an inner chamber, an elastic coupling, fixed between the housing and the opposite flanges of the inlet and outlet nozzles and forming a control valve with the lateral surface of the flanges, and with the body a control cavity connected to the pilot's output, the input of which is connected to the static input receiver ION.

 The disadvantage of such a regulator is limited functionality, in particular the inability to measure the flow rate of the controlled medium passing through it.

 The aim of the invention is to expand the functionality of the regulator to provide a measurement of the flow rate of gas passing through it.

 The goal is achieved by the fact that the inner chamber is connected to full pressure receivers made in the form of pressure pipes located in the inlet pipe and mounted on its counter flange, and the pressure regulator is equipped with a differential pressure meter connected via pulse tubes to the inner chamber and the static input receiver, respectively pressure.

 The drawing shows the proposed pressure regulator.

 The controller comprises a housing 1, input 2 and output 3 nozzles, input 4 and output 5 cavities, an elastic sleeve 6 fixed between the housing 1 and opposite flanges of the nozzles 2 and 3, a control cavity 7 located between the elastic sleeve 6 and the housing 1. Counter flanges the nozzles 2 and 3 are fastened together by a screw 8, pressing together an elastic sleeve 6 and a housing 1 and forming an internal chamber 13. The pilot 9 is connected to the receivers 10 and 11 of the static input and output pressure through the pulse tubes 17 and 18 and through the pulse tube 12 s I manage cavity 7.

 On the counter flange of the pipe 2, full pressure detectors are fixed, made in the form of pressure pipes 19, connected to the inner chamber 13. The differential meter 14 is connected to the inner chamber 13 and the receiver 10 of the static inlet pressure by pulse tubes 15 and 16.

 The pressure regulator operates as follows.

 In the static non-flow mode, the elastic sleeve 6 is pressed against the side surface of the oncoming flanges of the nozzles 2 and 3 due to the influence of the outlet pressure from the pilot 9 in the control cavity 7.

 The output pressure of the pilot depends on the pressure in the output cavity 5 supplied to the pilot's control cavity (not shown), and the setting value in the pilot 9.

If there is a flow rate, the elastic sleeve 6 adjusts the clearance with respect to the lateral surface of the oncoming flanges of the nozzles 2 and 3, maintaining the outlet pressure in the cavity 5, and therefore, constant in the load. At the same time, pressure is formed in the pressure tubes 19 taking into account the pressure head equal to
ΔP = ρv ² / 2g
where V is the flow rate at the installation site of the total pressure receiver; ρ is the density of the medium; g acceleration of gravity. This total pressure P _article + ΔP enters the inner chamber 13.

 The differential pressure meter 14 receives impulse tubes 15 and 16 with full and static pressure, and the meter determines the flow rate in the cross section of the inlet cavity. The flow rate in the cross section is determined by the product of the average velocity and the cross-sectional area.

 Consequently, meter 14 measures the flow rate through the regulator.

 Thus, due to the introduction of full pressure receivers and a differential pressure meter with pulse tubes into the regulator, the regulator not only stabilizes the pressure in the load, but also measures the flow rate.

Claims (1)

 A pressure regulator comprising a housing located between the inlet and outlet nozzles, the opposing flanges of which are fastened together in the center and form an inner chamber, an elastic coupling fixed between the housing and opposite flanges of the inlet and outlet nozzles and forming a control valve with the side surface of the opposing flanges, and with the body - a control cavity connected to the pilot outlet, the input of which is connected to a static input pressure receiver, characterized in that the inner chamber is connected and a total pressure receiver, made in the form of pressure tubes arranged in the inlet pipe and attached to its counter-flange, wherein the pressure regulator is provided with a differential pressure meter, connected via a pulse tube, respectively, with the internal chamber and the static inlet pressure receiver.