SU742886A1 - Flowrate regulator - Google Patents

Description

This invention relates to automatic regulation and can be used in pneumatic and hydraulic systems in various fields of technology.

A known flow regulator comprising a housing with an outlet channel, a rotary cylindrical regulating member with an S-shaped passage channel and an axial inlet channel 1.

The disadvantage of this regulator is a large hydraulic resistance.

Closest to the invention, the technical solution is a flow regulator comprising a cylindrical body with inlet tangential output channels and a spring-loaded cylindrical rotary regulating member G2 located therein.

The disadvantage of this regulator is its low accuracy, due to the fact that it does not use the dynamic pressure head at the entrance to the rotary regulator.

The purpose of the invention is to improve the accuracy of the controller.

This is achieved by the fact that the inlet channel is located tangentially to the cylindrical body of the regulator, and in the regulating body there is an S-shaped passageway, and also that the regulator is installed in a swivel glass having tangential openings.

Fig. 1 shows the flow control in section; in fig. 2 is a section A-A in FIG. 1; Fig, 3 - section bb in Fig, 2.

The flow regulator contains a cylindrical housing 1 with an inlet 2 and an outlet 3 channels. In case 1, there is a cylindrical rotary regulator 4 with a spring 5, Inlet 2 and outlet 3 channels are located tangentially to the cylindrical housing 1 of the regulator, In the regulator 4, 5-shaped flow channel 6, additionally to ensure full closure

25 of the regulator regulator 4 is installed in a swivel glass 7, having tangential bore holes 8 and 9, Regulator 4 is installed in glass 7 with a gap.

thirty

The cavity of body 1 is closed by a lid 10, and the shank 11 of the glass 7 is led out of the body 1 to the outside through the gland 12 in the lid 10. The rotation of the regulator 4 is limited by the stop 13, which is integral with the body 1 and is included in the recess 14 at the end of the regulator 4. Spring 5 One end attached to the regulator body 4, and the other interacts with the adjusting screw 15 installed in the hole of the stop 13 and brought out through the gland 16 to the outside, the screw 15 is pivotally fixed forks | and 17, the end sections 18 and 19 of the proCode channel 6 form a reactive surface.

The flow regulator operates as follows.

With the open position of the glass 7, the liquid will flow from the inlet nozzle 2 through the channel 6 to the nozzle 3; In this case, due to the uniform distribution of static pressure on the surface of the regulator 4, its resultant force is directed towards the center and the regulator 4 does not react to the changes of static dissolution in the liquid.

Regions of the reactive surface; 18 and 19 of the channel 6, located on the flow path, perceive the dynamic pressure of the liquid, and in section 19 there is also the effect of repulsing the outgoing jet from the regulating body 4. The resulting pair of forces at the ends of the flow channel tries to turn the regulating body 4 counterclockwise, and the spring 9 holds it in the middle position.

If the flow rate, and hence the flow rate, increases in the line, then the increasing dynamic pressure on sections 18 and 19 rotates the regulator 4, overcoming the force of the spring 5. The 5-shaped passage channel 6 shifts relative to nozzles 2 and 3 and partially overlaps. The flow rate of fluid through the device is thus equalized.

npii decrease in flow in the line dynamic pressure in the liquid also decreases.

The spring 5, overcoming a couple of forces in sections 18 and 19 from the dynamic head, turns the regulator 4 towards the open position, thereby increasing the flow area, and the flow rate through the device is also equalized.

When the flow of fluid through the device completely stops, the stop 13 prevents the regulator from turning under the action of the spring 5 for the open position,

In the case of the necessity of complete overlap of the regulator, the cup 7 is turned over the shank 11, the holes 8 and 9 in the cup are displaced relative to the pipes 2 and 3, and the channels of the pipes overlap.

Similarly, a pre-adjustment of the regulator is made, as well as manual control of the flow rate.

To adjust the installation force, the spring 5 rotates the adjusting screw 15,

Due to the implementation of the regulator housing with tangential inlet and outlet channels, and the regulator with a shaped flow channel, the hydraulic resistance of the device is reduced.

This increases the sensitivity of the regulator, which is caused by the complete use of the losses of dynamic pressure in the S-shaped channel to turn the regulator,

In addition, the installation of a regulator in a glass ensures the adjustability of the device and allows it to be used (if necessary, to completely shut off the pipeline) as a shut-off valve.

Claims (1)

Invention Formula 1, a flow regulator comprising a cylindrical body with inlet and tangential outlet nozzles 0 and a spring-loaded cylindrical rotary regulating member located therein, characterized in that, in order to increase the accuracy of the regulator, the inlet pipe is tangentially rimmed to the cylindrical body of the regulator, and the regulating body has a $ -shaped channel, 2, the flow regulator according to claim 1, characterized in that the regulator is installed in a pivoting cup having tangential bore holes. Sources of information taken into account in the examination 51, USSR Author's Certificate  590702, CLT G 05 D 7/01, 1975, 2, Authors | USSR certificate №576568, class, G 05 D 7/01, 1975 (prototype), 0 Output ft ten / Ft.2 Lzl. 13