RU110809U1 - PRESSURE REGULATOR - Google Patents

Abstract

 1. A pressure regulator containing! A housing made with a through cavity and with an element from the side of the first of the ends for connection to the pipeline,! a plug rigidly connected to the body from the side of its second end, made with a through cavity and with an element for connecting to the pipeline from the side opposite to the location of the body,! a holder located inside the body cavity and rigidly fixed in it, also made with a through cavity,! a valve installed in the plug with the possibility of longitudinal movement and fixing the position with the passage of the transported medium through the through cavity of the plug,! a sleeve made with a through cavity and installed in the through cavity of the holder with the possibility of longitudinal movement and interaction of one end surface with the valve to prevent movement of the transported medium,! a compression spring located in the cage with the possibility of interaction with the sleeve with compression in the direction of movement of the sleeve to the valve,! the sleeve is made in a T-shaped cross section and installed in a cage with the possibility of contacting the inner surface of the expanded section with the compression spring and passing a narrow section through the through cavity of the casing, the narrow and expanded sections of the bushing being sealed relative to adjacent sections of the casing for isolating the compression spring. ! 2. The regulator according to claim 1, characterized in that the cage is made with a U-shaped wall in cross section forming an annular cavity in which the compression spring is located, while the narrow and extended sections of the sleeve are sealed relative to adjacent to them respectively

Description

The utility model relates to construction, and specifically to a pressure regulator (reducer) designed for controlled pressure reduction of the transported medium in cold and hot water supply networks, water heating, compressed air pneumatic drives, as well as in other process pipelines transporting liquids and gases. The pressure regulator maintains the adjustment pressure at the outlet, regardless of pressure surges in the network, as well as in static mode, when the pressure after the pressure regulator does not exceed the adjustment pressure.

A pressure regulator (reducer) is known, comprising a body with a longitudinally extending cavity divided into an inlet and outlet part arranged longitudinally by a partition in which a hole is made transverse to the longitudinal direction of the body with a valve seat and a valve installed transversely to the body located in the valve outlet cavity, which can completely or partially block the hole with the saddle. The valve is made with a rod, at the end of which there is a radially protruding piston located in the cylinder of the body, oriented along the axis of the valve. The output part of the through cavity communicates with the sub-piston cavity, that is, with the cavity located relative to the piston on the valve side, and this cavity is isolated from the input part of the through cavity of the housing. On the other side of the piston there is a compression spring, which compresses the piston relative to the housing, and accordingly the valve in the direction of its opening. The amount of spring compression can be adjusted with a screw to adjust the pressure regulator. The housing on opposite sides with openings in the inlet and outlet of the through cavity has elements for connecting to the pipeline (Vesta Trading Technical Catalog, 2009, p. 292, 293).

The design of this well-known pressure regulator allows the possibility of unauthorized adjustment by the user, a non-specialist, which can cause a malfunction of the network in which it is used.

There is a known pressure regulator that eliminates the possibility of unauthorized adjustment, which is designed for water supply networks and provides an economical flow of water by maintaining a given pressure (flow) of water at the outlet of devices used by the consumer, such as water taps and shower faucets (CN 101398098 A, IPC F16K 17 / 04, 2009).

This known pressure regulator comprises a housing with a through cavity, access to which is accessible from opposite sides of the housing, where it has means for connecting to a pipeline, water tap or mixer. A conical surface is made at the inlet portion of the cavity, in which a valve with a conical seating surface is located, from which a rod extends in the direction of the apex, passing through a central section located inside the through cavity of the housing and connected with it by radial jumpers. The rod on the other side of the central section is fixed with a screw. Between the valve and the central section, there is a compression spring, which can be compressed when the pressure of the transported medium is exerted on the valve moving deep into the conical surface, thereby reducing the flow area of the through cavity of the housing and the pressure at the outlet is reduced.

In this design, the pressure regulator provides adjustment of the pressure of the transported medium at the inlet, that is, “up to you” and does not allow you to adjust the pressure in cases of its change at the outlet, that is, in the “after you” mode, similar to the design of the regulator described above, but which does not prevent unauthorized adjustment. The screw securing the rod in the central section allows the rod length to be adjusted, however, it can only be adjusted if the pipeline is dismantled by a competent person, since access to the screw is possible only through the fluid supply cavity.

The technical result of the utility model consists in expanding the arsenal of means for adjusting the pressure of the transported liquid or gaseous medium, which provides automatic pressure control in the pre-configured range in the “after you” mode, eliminating the possibility of unauthorized access to change the tuning parameters.

This technical result is achieved by a pressure regulator, which contains:

- a housing made with a through cavity and with an element from the side of the first of the ends for connection to the pipeline;

- a plug rigidly connected with the casing from the side of its second end, made with a through cavity and with an element for connecting to the pipeline from the side opposite to the location of the casing;

- a clip located inside the body cavity and rigidly fixed in it, also made with a through cavity;

- a valve installed in the tube with the possibility of longitudinal movement and fixing the position with the passage of the transported medium through the through cavity of the tube;

- a sleeve made with a through cavity and installed in the through cavity of the holder with the possibility of longitudinal movement and interaction of one end surface with the valve to prevent movement of the transported medium;

- a compression spring located in the cage with the possibility of interaction with the sleeve with compression in the direction of movement of the sleeve to the valve.

In this case, the sleeve is made in a T-shaped cross section and installed in a cage with the possibility of contacting the inner surface of the expanded section with the compression spring and passing a narrow section through the through cavity of the casing, the narrow and expanded sections of the bushing being sealed relative to adjacent sections of the casing for isolating the compression spring.

In the best embodiment of the utility model, the cage is made with a U-shaped wall in cross section forming an annular cavity in which the compression spring is located. In this case, the narrow and extended sections of the sleeve are sealed relative to adjacent to them, respectively, narrow and wide sections of the cage.

Also, in the best embodiment of the utility model, the plug is made with a central section located inside its through cavity and connected with it by radial jumpers, the central section is made with a threaded hole, and the valve is made in the form of a screw installed in the threaded hole of the central section of the tube, at the end of which facing the sleeve, a support cup is fixed, inside of which there is an elastic sealing element with the possibility of interaction with the end surface of the sleeve. Preferably, the threads of the central portion of the plug and valve screw are made in small steps.

The body, cork, ferrule and sleeve can be made of brass, and the compression spring made of stainless steel. The screw and valve support cup can also be made of brass. The resilient sealing element may be made of ethylene-propylene-diene rubber, butadiene-nitrile elastomer or fluoroelastomer.

The sleeve in the best embodiment of the utility model is sealed relative to the casing using elastic sealing rings located in the annular grooves made in the sleeve. Elastic o-rings can be made of the same materials as the elastic sealing element of the valve.

In the best embodiment, the design of the pressure regulator satisfies the following condition:

P ₁ S ₁ ± N _Tr + kΔ _s = P ₂ S ₂ ,

Where

P ₁ - pressure of the transported medium to the end surface of the sleeve from the side of the tube;

P ₂ - pressure of the transported medium to the end surface of the sleeve from the side of the first end of the housing;

S ₁ - the projection area on the transverse plane of the end surface of the sleeve from the side of the tube;

S ₂ - the projection area on the transverse plane of the end surface of the sleeve from the side of the first end of the housing;

N _tp is the friction force in the seals between the sleeve and the cage;

k is the coefficient of elasticity of the compression spring;

Δ _s is the distance between the interacting surfaces of the valve and the sleeve.

The possibility of implementing a utility model is confirmed by a specific example of a pressure regulator, which is illustrated by graphic materials, where Fig. 1 shows a longitudinal section of a pressure regulator, and Fig. 2 shows a diagram of the loading forces of its regulating elements.

The pressure regulator includes a housing 1 made with a through cavity 2 and with an element 3 from the side of the first end 4 for connection to the pipeline (not shown in the drawing). A plug 5 is rigidly connected with the housing 1, located on the side of the second end 6 of the housing 1, which is also made with a through cavity 7 and with an element 8 for connecting to the pipeline from the side opposite to the location of the housing 1. A rigid connection of the housing 1 with the plug 5 is provided by their threaded connection.

A valve 9 is installed inside the through cavity 7 of the plug 5 with the possibility of longitudinal movement and ensuring the passage of the transported medium through the through cavity 7 of the plug 5. To install the valve 9, the plug 5 is made with a central section 10 located inside its through cavity 7 and connected with it radial jumpers 11. The Central section 10 is made with a threaded hole 12, and the valve 10 is made in the form of a screw 13 installed in the threaded hole 12 of the Central section 10 of the plug 5, at the end of which is fixed on the support cup 14 inside which a resilient sealing element 15. The thread of the threaded hole 12 and the screw 13 is formed with a fine pitch.

Inside the cavity 2 of the housing 1 is a ferrule 16, rigidly fixed in it due to clamping between the housing 1 and the plug 5, which is also made with a through cavity 17. The ferrule 16 is made with a U-shaped wall 18 in cross section forming an annular cavity 19, in which the compression spring 20 is located.

A sleeve 21 having a through cavity 22 is installed in the through cavity 17 of the sleeve 16. The sleeve 21 is mounted with the possibility of longitudinal movement and is made in the cross section T-shaped with the possibility of contact of the inner surface 23 of the extended section 24 with the compression spring 20.

A narrow section 25 of the sleeve 21 passes through the through cavity 17 of the sleeve 16. In this case, the sleeve 21 is mounted to interact with the end surface 26 of the narrow section 25 with an elastic sealing element 15 located in the support cup 14 at the end of the screw 13 facing toward the sleeve 21, the compression spring 20 interacts with the sleeve 21 with compression in the direction of movement of the sleeve 21 towards the valve 9.

The projection area on the transverse plane of the end surface 26 of the sleeve 21, free to interact with the transported medium from the side of the plug 5, is smaller than the projection area on the transverse plane of the end surface 27 of the sleeve 21, free to interact with the transported medium from the side of the first end 4 of the housing 1. Realization of this The conditions are provided by sealing the narrow 25 and extended 24 sections of the sleeve 21 relative to adjacent to them, respectively, the narrow 28 and wide 29 sections of the sleeve 16. To seal the sleeve 21 relative to both pits 16 used elastic sealing rings 30 and 31 located in the corresponding annular grooves made in the sleeve 21 (30, 31). Thus, the annular cavity 19, in which the compression spring 20 is located, is isolated from the fluid and the effects of its pressure on the inner surface 23 and similar to it extended section 24 of the sleeve 21.

During operation, the excess pressure P2 acting on the end surface 27 of the sleeve 21 leads to the movement of the sleeve 21 in the direction of the valve 9. In this case, the passage section between the valve 9 and the end surface 26 of the sleeve 21 is reduced, and the passage of the transported medium is completely blocked by contact the end surface 26 of the sleeve 21 with an elastic sealing element 15 of the valve 9. This eliminates the increase in pressure from the side of the plug 5 and the excess flow of the transported medium into the pipeline, connecting nny from the first end 4 of the housing 1.

Setting the pressure regulator is carried out from the following ratio, taken into account by the design of the pressure regulator as a whole:

P ₁ S ₁ ± N _Tr + kΔ _s = P ₂ S ₂ ,

Where

p ₁ - pressure of the transported medium to the end surface 26 of the sleeve 21 from the side of the tube 5;

P ₂ - pressure of the transported medium to the end surface 27 of the sleeve 21 from the side of the first end 4 of the housing 1;

S ₁ - the projection area on the transverse plane of the end surface 26 of the sleeve 21 from the side of the tube 5;

S ₂ - the projection area on the transverse plane of the end surface 27 of the sleeve 21 from the side of the first end 4 of the housing 1;

N _Tr - the friction force in the seals between the sleeve and the cage;

k is the coefficient of elasticity of the compression spring 20;

Δ _s is the distance between the interacting surfaces of the valve 9 and the sleeve 21.

The choice in the ratio of the plus or minus sign depends on the direction of movement of the sleeve 21, that is, it depends on the specific design conditions.

The regulatory ability of pressure regulator A is equal to the ratio P ₂ / P ₁ . The regulatory ability A is the higher, the greater the area ratio S ₂ / S ₁ . In this case, the elasticity of the compression spring is directly proportional to the product A × B.

In the above embodiment of the utility model, the housing 1, plug 5, ferrule 16 and sleeve 21 are made of brass, and the compression spring 20 is made of stainless steel. A variant is possible when the body 1 and plug 5 are made of polypropylene by a random copolymer with ethylene (this option is not shown in the drawings), in which brass elements are threaded to connect the body 1 and plug 5. The screw 13 and the support cup 14 of the valve 9 also made of brass. The elastic sealing element 15 and the sealing rings 30 and 31 are made of ethylene-propylene-diene rubber. Butadiene-nitrile elastomer and fluoroelastomer may also be used.

All parts of the pressure regulator, made in accordance with this utility model, are manufactured using well-known technologies for manufacturing parts from the listed materials. The example of the implementation of the utility model is not exhaustive. Other embodiments of the utility model are possible, corresponding to the scope of patent claims.

Claims (9)

1. A pressure regulator containing A housing made with a through cavity and with an element from the side of the first of the ends for connection to the pipeline, a plug rigidly connected to the housing from the side of its second end, made with a through cavity and with an element for connecting to the pipeline from the side opposite to the location of the housing, a clip located inside the cavity of the housing and rigidly fixed in it, also made with a through cavity, a valve installed in the plug with the possibility of longitudinal movement and fixing the position with the passage of the transported medium through the through cavity of the plug, a sleeve made with a through cavity and installed in the through cavity of the holder with the possibility of longitudinal movement and interaction of one end surface with the valve to prevent movement of the transported medium, a compression spring located in the cage with the possibility of interaction with the sleeve with compression in the direction of movement of the sleeve to the valve, the sleeve is made in a T-shaped cross section and installed in a cage with the possibility of contacting the inner surface of the expanded section with the compression spring and passing a narrow section through the through cavity of the casing, the narrow and expanded sections of the bushing being sealed relative to adjacent sections of the casing for isolating the compression spring. 2. The regulator according to claim 1, characterized in that the cage is made with a U-shaped wall in cross section forming an annular cavity in which the compression spring is located, while the narrow and extended sections of the sleeve are sealed relative to adjacent narrow and wide sections of the cage . 3. The regulator according to claim 1, characterized in that the plug is made with a central section located inside its through cavity and connected with it by radial jumpers, the central section is made with a threaded hole, the valve is made in the form of a screw installed in the threaded hole of the central section of the tube , at the end of which, facing the sleeve, a support cup is fixed, inside of which there is an elastic sealing element with the possibility of interaction with the end surface of the sleeve. 4. The regulator according to claim 3, characterized in that the thread of the central portion of the plug and valve screw is made in small increments. 5. The regulator according to any one of claims 1 to 4, characterized in that the housing, cork, clip and sleeve are made of brass, and the compression spring is made of stainless steel. 6. The regulator according to claim 3, characterized in that the screw and the valve support cup are made of brass. 7. The regulator according to claim 3 or 6, characterized in that the elastic sealing element is made of a material selected from the group including: ethylene-propylene-diene-rubber, butadiene-nitrile elastomer, fluoroelastomer. 8. The regulator according to claim 1, characterized in that the sleeve is sealed relative to the holder using elastic sealing rings located in the grooves made in the sleeve and made of a material selected from the group consisting of ethylene-propylene-diene-rubber, butadiene- nitrile elastomer, fluoroelastomer. 9. The controller according to claim 1, characterized in that it satisfies the following condition: P ₁ S ₁ ± N _Tr + kΔ _s = P ₂ S ₂ , where P ₁ - pressure of the transported medium to the end surface of the sleeve from the side of the tube; P ₂ - pressure of the transported medium to the end surface of the sleeve from the side of the first end of the housing; S ₁ - the projection area on the transverse plane of the end surface of the sleeve from the side of the tube; S ₂ - the projection area on the transverse plane of the end surface of the sleeve from the side of the first end of the housing; N _Tr - the friction force in the seals between the sleeve and the cage; k is the coefficient of elasticity of the compression spring; Δ _s is the distance between the interacting surfaces of the valve and the sleeve.