SU1444722A1 - Pressure controller - Google Patents

Abstract

The invention relates to automation, in particular to pressure regulators, it is designed to maintain a predetermined pressure and establish a uniform flow in the pressure pipe. The aim of the invention is to improve the accuracy, reliability and range expansion is regulated1. Regulator pressure, 1eni contains body 1, input 2 and output 3 cavities, cover 4, stem 5, locking member 6, sensitive element - working diaphragm 7, mounting discs 8 and 9, spring 10, through holes 11 and 12, axial channel 13, the outlet 14, the overmembrane cavity 15, the regulator - iiopuiCHi 16 with a tapered end 17, the pusher 18, the membrane 19, the spring 20, the adjusting screw 21, the lock nut 22, the overmembrane cavity 23, the tube 24, the throttle 25, the hole 26, sent a young 27. 2 Il.

Description

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The invention relates to automation, in particular to fluid pressure regulators, and is intended to maintain pressure and establish a uniform flow in the discharge pipe.

The purpose of the invention is to improve the accuracy, reliability and expansion of the range of adjustment.

Pa figs. 1 shows the pressure regulator of the abundance view; in fig. 2 - stem design with a locking organ.

The pressure regulator comprises a housing 1 with a B.CODI 2 YU 2 and an outlet 3 cavities. The housing 1 pe1 and 1 ora is equipped with a crank 4, and inside the housing there is a locking and regulating device, consisting of a stem 5, a locking member 6, a sensing element — a working diaphragm 7, mounting discs 8 and 9, and a spring 10.

The floor part of the rod 5 is equipped with through holes 11 and 12 located one against the other and made in the form of a tray | Solo form, the vertices of which are directed towards the working membrane. Their cross-sectional area is not less than that of the axial channel 13 with the outlet 4 in the wall of the cavity and in the subfloor. The design of the through holes allows an increase in the ability to operate at low pressure changes, i.e. increase the sensitivity of the proposed regulator design, and the range of adjustment. Through the axial channel 13 with the outlet orifice. M. 14, the hydraulic connection of the supermembrane cavity 15 with the outlet nozzle is established. The throttling of the through holes I and 12 is regulated by means of an opio-MioM by means of an open 16, and the axial channel by a 13 with a coic end 17. Such a design of drop-ups allows to increase the accuracy of maintaining a given pressure. The piston 16 is provided with a pusher 18, which is rigidly connected to a controllable sensitive element — a membrane 19 of the pressure setting device. The membrane 19 is spring-loaded by a spring 20, the rigidity of which is set by an adjusting screw 21 with a lock nut 22. The over-membrane cavity 23 of the pressure setting device is hydraulically connected by a tube 24 to the output cavity 3. The input cavity 2 is connected via a throttle 25 to an over-membrane cavity 15. The upper part of the cover 4 of the regulator has a drainage hole 26 for free movement of the stem 5 in the direction of junction 27 of the cover 4.

The pressure torus operates as follows.

Water is supplied to the regulator housing 1 through the inlet cavity 2, lifts the stop valve 6 and enters the output bore 3, and then into the sprinkler or other irrigation pipeline.

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Before starting the operation of the pressure regulator, it is necessary to unscrew the adjusting screw 21 so that the spring 20 takes up its normal position, in which the through holes 11 and 12 and, therefore, the axial channel 13 will not be blocked by a throttle connected to the pusher 18, which in turn rigidly fixed on the membrane 19. When the adjusting screw 21 is turned out, the spring 20 is restored to its original position, lifts the membrane 19, and consequently, the entire throttle mechanism is up and the through holes 11, 12 and the axial channel 13 will be t open. Adjust the throttling needle 25 to the desired constant flow rate in the working chamber and in the inlet cavity 2 into the cavity 15. Water is supplied to the controller body 1 through the inlet cavity 2, lifts the valve 6 and enters the output cavity 3, and then into the sprinkler machine or other irrigation pipeline. At the same time, water through the choke 25 enters the above-membrane one. the regulator cavity 15, from where through the through holes II and 12, the axial channel 13 with the outlet hole 14 to the output cavity 3. With the aid of the pressure setting device, the required pressure is applied to the sprinkler or to another consumer, i.e. ., turning the adjusting screw 21, move the membrane 19 downwards and, consequently, the entire throttle mechanism. The through passage section of the through holes 11 and 12 is covered and the required annular area of the axial passage through which discharge of fluid from the supramembrane cavity 15 into the outlet cavity 3 occurs. By setting the adjusting pressure of the fluid at the outlet screw 21, it stops the lock nut 22.

When the pressure rises before the regulator, the locking member 6 rises, the cross section of the through holes II and 12 decreases, as they are slightly covered by the piston 16, the annular section of the axial channel 13 decreases, through which the fluid flows from the cavity 15 into the cavity 3. Simultaneously through the tube 24, the increased pressure acts on the membrane 19 and moves it downward, compressing the spring 20. The force from the membrane is transmitted through the pusher 18 to the piston 16, which further covers or completely covers the transverse area echeni through holes 11 and 12. Tapered end also shifted downward further reduces or completely overlaps the annular cross section of the axial passage 13. The fluid discharge 15 from the cavity to the outlet cavity 3 is reduced to .minimuma or completely stopped. This leads to an increase in pressure in the working chamber of the regulator, which causes movement: the membrane 7 down, and together with it closes the flow area of the regulator and the flow, and consequently, the pressure downstream of the regulator decreases to a predetermined value.

When the pressure in front of the regulator decreases, the locking member 6 lowers somewhat, which is facilitated by the spring 10. The cross section of the through holes 11, 12 and the annular area of the axial channel 13 increase, i.e. the flow of fluid from the cavity 15 into the outlet cavity 3 increases. The pressure in cavity 15 drops slightly. At the same time, when the pressure in front of the regulator decreases, it decreases in the supermembrane cavity 23 of the pressure setting device. Consequently, the spring 20 restores the normal position and the force from it is transferred to the membrane 19. The membrane 19 is slightly shifted upwards, and therefore, the entire throttle mechanism is slightly shifted upwards. This further increases the area of the through holes 11 and 12 and the annular area of the axial channel 13. The flow of fluid from the working cavity 15 into the output cavity 3 increases even more, the pressure in the working chamber decreases even more or is completely absent, which leads to even more pressure shutoff valve 6, as a result of which the flow through the regulator and the pressure behind it increase to a predetermined value.

The design of the pressure regulator can perform the functions of a valve, rotating the adjusting screw 21 clockwise up to the stop to close the flow area of the through holes 11, 12 and the annular area of the axial channel. The discharge from the cavity 15 is stopped, therefore, the locking member 6 tightly closes the flow area of the pressure regulator.

The pressure regulator is simple in design, reliable in operation, has a large adjustment range, increased sensitivity, and can perform the function of a retract.

Claims (1)

Invention Formula A pressure regulator, comprising a housing, between the inlet and outlet cavities of which a locking member is mounted, fixed at one end of the stem, connected by a sensitive element in the form of a spring-loaded working membrane, the supramembrane cavity of which is connected through a choke to 5 through the regulator and with the output cavity, the regulating body is connected via a pusher with a spring-loaded control sensing element, the control cavity of which is connected to the output cavity, characterized in that, in order to improve accuracy, reliability and range expansion adjustment, the locking member is made with a spherical surface, the second end of the rod is installed in the supermembrane cavity, is hollow and has a regulating member, made in the form of a piston with a conical shaft With the axial channel in the rod connected to the output cavity and through symmetrical holes in the wall of the hollow brush, there are two successively installed throttle elements, the holes in the wall of the hollow rod are triangular in shape, the tops of which are directed towards the working membrane, and area of their transverse 5 is not smaller than the cross-sectional area of the axial channel of the rod, and the control sensing element is associated with an adjusting screw. 0 five R .77, fZ