SU479089A1 - Liquid Flow Regulator - Google Patents

Description

one

The invention relates to liquid flow controllers; namely, to those of them that provide dispensing of liquids in time.

A fluid flow regulator is known, comprising a housing divided by a partition with a hole in the inlet cavity, with a spool regulator located in the drink, and an outlet cavity with a spring-loaded actuating element in it - a piston connected to the slide located in the opening of the partition.

The purpose of the invention is to improve the accuracy, sensitivity and reliability of the controller.

For this purpose, an elastic membrane with an opening is installed in the output cavity of the proposed regulator, which divides the output cavity into two chambers. In one of these chambers, a regulating element is installed, made with a protrusion, the diameter of which is larger than the diameter of the opening in the membrane. In the other chamber there is a spring-loaded ancillary body, connected to the regulating element through a glass installed in the sleeve, made with ribs. The glass is connected through an annular groove and holes in the sleeve and the housing with a chamber in which the regulating element is located.

The drawing shows schematically the proposed regula tor.

The proposed regulator consists of a housing 1, divided by a partition 2 with a hole in the input cavity 3 and an output cavity consisting of two chambers 4 and 5, a regulating element 6, a bellows 7, an elastic membrane 8 with an opening and a tuning throttle 9.

The regulating member is located in the non-bore hole and is a regulating choke. It is made with a working surface 10 and protrusion 11, the diameter of which is larger than the diameter

holes in the membrane.

The bellows, which serves as an executive body, is connected to the clamp 12 for supplying fluid to the regulator and to the regulating element through the one installed in the sleeve

13 a cup 14. The outer surface of the cup is made with ribs (not shown in the drawing) and communicates through the holes 15 in the sleeve, the annular groove 16 and the hole 17 in the key 18 and the hole 19 in the housing with the chamber 4.

On the BELLOW, on the one hand, through the regulating element and the membrane, the spring force 20, the pressure force in the input cavity and the pressure force in chamber 4 act, and on the other hand, the pressure opposite the nerve force at the regulator input.

An elastic membrane with a hole is installed in the output floor and divides the cavity into two chambers 4 and 5. It is made with a rigid center 21 and presses against the protrusion, its element is adjusted with a lever 22, the tension of which is adjusted by rotating the nut 23 placed on the threaded part of the regulating an item. By tensioning the lips 22, the pressure is set to open the membrane aperture.

The target value of the adjustable flow rate is changed by compressing the spring 20 by rotating the nut 24.

Fluid is drained from chambers 4 and 5 through nozzles 25 and 26.

Works regulator as follows.

Liquid node pressure from the fitting 12 enters the bellows 7 and through the tuning throttle 9, the input cavity 3 and the adjustable opening of the partition 2 into the chamber 4, and from it liquid is drained through the nozzle 25 into the object and through the holes 19 and 17 into the annular groove 16, from which the liquid penetrates through the holes 15 on the surface of the glass 14 and lubricates it.

Lubricating the surface of the glass and making it work with ribs made it possible to significantly reduce friction force and increase the sensitivity of the regulator.

When the pressure at the inlet and in the chamber 4 deviates from the preset values, the equilibrium is disturbed and, depending on the sign of the deviation, the regulating element 6 moves to the right or left, thus reducing or increasing the flow area of the septum opening. Due to the change in flow resistance, the flow rate is maintained at a predetermined level.

With a short absence of flow, which takes place in the process of dosing liquids with container switching, the pressure in chamber 4 rises, the force of which, acting on the membrane 8, causes the regulating element to move to the right. Initially, before the opening in the membrane, the regulating element promotes a more rapid increase in pressure in chamber 4. When the pressure in chamber 4 is greater than the predetermined pressure of opening the membrane, spring 22 contracts and the membrane departs from protrusion I. Fluid from chamber 4 is discharged through the open hole to chamber 5, reported with the atmosphere. When the force of counteraction is 22

compared with the force created by the pressure in the chamber 4, the movement of the regulating element with the membrane is stopped when the aperture is open. When the flow is resumed, the pressure in chamber 4 quickly drops to the set point.

The membrane under the force of the spring 22 presses against the protrusion and the discharge of fluid through the opening of the membrane stops. The regulating element returns to its original position by the force of the pressure in the bellows.

The installation of a membrane with a hole in the exit cavity made it possible to increase the accuracy and reliability of the proposed controller.

Subject invention

Claims (2)

1. The fluid flow regulator, comprising a housing divided by a partition with a hole in the inlet cavity, with a regulating throttle located in it, and an output cavity with a spring-loaded actuator installed in it, connected to a regulating element located in the opening of the partition, characterized by that, in order to increase the accuracy and reliability of the controller, an elastic membrane with an a hole dividing the cavity into two chambers, in one of which a regulating element is installed, made with a protrusion, the diameter of which is larger than the diameter of the hole in the membrane, and in the other - spring-loaded executive agency. 2. The regulator according to claim I, characterized in that, in order to increase the sensitivity, the spring-loaded actuator is connected to the regulating element through a cup installed in the sleeve, made with ribs and an annular groove connected through an opening in the sleeve and the housing with the chamber, which is located regulatory element.