SU1097974A1 - Flow governor - Google Patents

Abstract

A FLOW CONTROLLER, comprising a housing, in the control chamber of which a tuning spring is installed, and in the operating chamber - a normally open pneumatic contact, made in the form of a first nozzle and a first damper, mounted on a rod connected to the sensing organ of the first membrane by a regulator; through the first nozzle with the working chamber, the throttle, the outlet nozzle, which is distinguished by the fact that, in order to control the dynamic accuracy of the regulator, it is equipped with a second diaphragm with an effective area equal to The area of the first membrane, a rotameter whose output is connected to an outlet fitting installed in the working chamber, is normally closed by a pneumatic contact, made in the form of a second nozzle and a second damper mounted on the rod, the working chamber U through the second nozzle and choke (L dinen with the entrance of the rotameter and the chamber formed by the housing and connected by the stem of the first and second membranes. | with CH1 1

Description

The invention relates to automatic flow control and can be used in water supply systems for automatically supplying chlorine to drinking water. A known flow regulator, comprising a housing divided by a membrane into a control and working chamber, communicating with each other via a flow cell. A working spring and a valve connected to the rigid center of the diaphragm and the regulator outlet are installed in the working chamber, and another valve in communication with the pusher mounted on the control chamber lid G13 is installed in the control chamber. A disadvantage of the known regulator is the low accuracy due to the large number of springs that change their force when the membrane moves under the action of the force developed by the pressure differential across the working medium. Closest to the present invention is the flow regulator, which encloses the case, in the control chamber of which a tuning spring is installed, and in the working chamber - normally open pneumatic contact, made in the form of a nozzle and damper mounted on a rod connected to the sensitive organ of the regulator - a membrane . The working chamber of the regulator is connected through a nozzle to the inlet nozzle, and the control chamber with the output nozzle and through the throttle to the working chamber C 2. A disadvantage of the known regulator is the low dynamic accuracy. The regulator fails to provide the necessary degree of attenuation of oscillations arising due to frequent pulsations of the gas pressure at the inlet, which pass the pneumatic contact to the sensing organ, the membrane, almost unhindered, and the core is a passive element that damps them ineffectively. The purpose of the invention is to increase the dynamic accuracy of the controller. The goal is achieved by the fact that the flow regulator, containing a housing, in the control chamber of which the spring is set, and in the working chamber - normally open pneumatic contact, made in the form of the first nozzle and the first valve installed on the rod connected to the sensing organ the regulator, the first diaphragm, the inlet nozzle connected through the first nozzle to the working chamber, the choke, the outlet choke, is equipped with a second diaphragm with an effective area equal to the effective plate of the first membrane and a rotameter. the output of which is connected to an output fitting installed in a working chamber, normally closed by a pneumatic contact, made in the form of a second nozzle and a second damper mounted on the rod, the working chamber through the second nozzle and the throttle connected to the rotameter inlet and the chamber formed by the housing and connected the stem of the first and second membranes. The drawing shows the proposed controller. The regulator contains a housing 1, in the control chamber 2 of which the adjusting spring 3 is installed, and in the working KeiMepe 4 there are pneumatic contacts: normally open, made in the form of the first nozzle 5 and first valve 6, and normally closed, made in the form of the second nozzle 7 and the second flap 8. The flaps 6 and 8 are mounted on the rod 9, which is connected to the sensing element of the regulator — the first membrane 10. The working chamber 4 is connected through the nozzle 5 to the inlet fitting 11 and through the nozzle 7 to the throttle 12. The regulator is equipped with a second membrane 13 with effective an area equal to the effective area of the membrane 10, the rotameter 14, the inlet of which is connected to the throttle 12 and the chamber 15 formed by the housing 1 and the membranes 10 and 13, and the output to the outlet fitting 16. The materials 10 and 13 are connected by a rod 9, which is preloaded by the tuning spring 3 The adjustment of the spring 3 is made by the adjusting screw 17. The regulator operates as follows. When gas is supplied with pressure Pgj, at the inlet fitting 11 it passes through the nozzle 5 into the working chamber 4, in which the pressure acting on the membrane Y rises. Pressure build up in chamber 4 leads to partial closure of the nozzle 5 and partial opening of the nozzle 7. Thus the gas passes through the nozzle 7, the throttle 12 and the rotameter 14 to the outlet fitting 16. Due to the fact that the stroke of the rod is low, the force of the spring 3 at a given setting is almost constant. Therefore, the pressure in chamber 4 will also be constant. In addition, the gas exiting the outlet nipple 16 enters the mixer (not shown), in which its complete withdrawal and subsequent displacement of the residual chlorine gas is ensured in the mixer, i.e. At the outlet nozzle 16 and the chamber 15, the pressure is kept constant. Therefore, the differential at throttle 12 will be so; xe constant, which ensures that the gas flow is maintained by the regulator

31097974

at a predetermined level, which is installed by a hull and two equipments with an adjusting spring 3 and great diaphragms make it

by the throttling cross section 1 2. dynamic accuracy and coKpatnneT

T1implication in the regulator of the two pneumocarbability of the chlorination process

matic contacts and containers, drinking water.

Claims (1)

FLOW REGULATOR comprising a housing. in the control chamber of which a tuning spring is installed, and in the working chamber, a normally open pneumatic contact, made in the form of a first nozzle and a first damper mounted on a rod connected to the sensing organ of the regulator by a first membrane, an inlet fitting connected through a first nozzle to the working chamber, a throttle , an outlet fitting, characterized in that, in order to increase the dynamic accuracy of the regulator, it is equipped with a second membrane with an effective area equal to the effective area of the first membrane, a rotameter, outlet One of which is connected to the outlet fitting installed in the working chamber, normally closed by a pneumatic contact, made in the form of a second nozzle and a second damper mounted on the rod, and the working chamber <q through the second nozzle and throttle is connected to the input of the rotameter and to the chamber formed by the housing and connected by a rod of the first and second membranes. SU, "1097974