RU2690307C1 - Safety valve of indirect action - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to machine building hydraulics, in particular to safety devices of hydraulic systems of vehicles and mechanisms, and serves to protect systems in place of their installation from high pressures. Safety valve of indirect action contains hydraulic distributing housing (1), made with through channel, radial holes (4) and saddle (3) of the first stage. In the hydraulic distribution housing (1) the first stage gate (7), the second stage seat (8) and spring (9) located between them are located. Housing (20) has a through channel, one end of which is detachably connected to hydraulic distributing housing (1), and the other end is closed by adjusting screw (22). Housing (20) accommodates spring (23) of adjusting screw (22), ball (24) and gate (25) of second stage. Gate (7) of the first stage is made with seat (11), with ball (12) placed in it, displacement of which is restricted with perforated disk (13). Gate (7) of the first stage is made with radial hole (14), in which there is additional seat (15) with ball (16). Between housing (20) and hydraulic distribution housing (1) channel (28) is made, and between housing (20) and gate (25) of second stage there is cylinder (26) with radial holes (27). At that diameter of ball (12) is less than diameter of axial cavity (10) of gate (7) of the first stage.EFFECT: technical result consists in improvement of performance of an indirect safety valve.1 cl, 2 dwg

Description

The invention relates to the field of engineering hydraulics, in particular to the safety devices of the hydraulic systems of vehicles and mechanisms, and serves to protect systems at the place of their installation from elevated pressures.

Known pressure regulator, comprising a housing with a flow channel with a calibrated socket and installed in it by means of a clamping ring seat, a locking member with a spring and a ball that is interoperable with the saddle, an adjusting screw with a spring of conical shape and a flywheel with a lock, ring seals. In the middle part of the adjusting screw one above the other is made a supporting step and an annular groove, and the threaded section is made in its lower part, and the length of the threaded section of the adjusting screw does not exceed the amount of compression of the conical spring, half of the upper and lower turns of which are made respectively over the larger and smaller radii and the rest is a spiral of Archimedes. The lower turn is mounted on the support step, and the upper turn is in the annular groove on the inner surface of the housing. The locking organ is made in the form of a cylinder consisting of three sections of different diameters (patent No. RU42615, IPC F16K 17/04, publ. 10.12.2004).

The closest set of essential features to the claimed technical solution is a safety valve for a hydraulic device containing a through valve (shutter), which is paired with the possibility of disconnecting with the auxiliary valve (second stage seat), the through valve moves relative to the auxiliary valve, the through valve spool located in the valve through passage and having at least one internal channel, auxiliary valve spool located during the auxiliary a separate valve and having at least one internal channel, and connected to the spool of a through valve, to provide the working fluid from the first cavity to the second cavity and to measure the flow of the working fluid from the first region to the second region, a bias spring interacting with the auxiliary a valve and auxiliary valve spool to displace the auxiliary spool from the auxiliary valve, the valve body with a central cavity in which the bushing valve is located, partially auxiliary A valve is installed, the valve body has an inlet and an outlet that are hydraulically connected to the reservoir, the inlet of the housing is located next to the first cavity, the second cavity is inside the housing located between the inlet and auxiliary valves, the inlet valve is movably in contact with the valve seat of the inlet valve moves inside the inlet valve, preventing fluid from flowing between the first and second cavities, the inlet valve moves axially inside the valve body and opens yuchaet saddle body, providing fluid communication from the inlet to the outlet. The auxiliary valve spool is detachably in contact with the auxiliary ball, which turns off the auxiliary valve seat to direct the pressure in the second region to the reservoir. The safety valve contains a hexagonal cap with a cavity that receives the valve body and contains a control ball, a third cavity is provided between the control ball and the auxiliary valve, a bias spring is placed in the cavity of the hex cap, which actuates the auxiliary ball holder that displaces the auxiliary ball relative to the auxiliary seat valve (patent number US8360096, IPC F16K 31/122, publ. 01/29/2013).

The designs of the known technical solutions do not provide sufficient tightness of the indirect-action safety valve due to the displacement of the first-stage shutter from the first-stage seat, since in the presence of pressure of the working fluid in the radial cavity of the valve is greater than the pressure in the axial cavity, due to the presence of a pressure difference on the surface of the valve, the valve is exerted by a force displacing it from the saddle and communicating the radial cavity with the axial one. Thus, the tightness of the valve in this case is not ensured.

The task is to improve the performance of the safety valve of indirect action.

The technical result coincides with the task and is achieved due to the fact that in an indirect pressure relief valve containing a hydrodistributing body, made with a flow channel, radial holes and a first-stage seat, a first-stage valve located in the hydrodistribution body, and located between them a spring housing with a flow channel, one end of which is detachably connected to the hydraulic distribution housing, and the other end is closed by an adjusting screw, is placed The spring of the adjusting screw in the housing, the ball and the bolt of the second stage, the bolt of the first step are made with a seat, with a ball placed in it, the movement of which is limited by a perforated disk, and a radial hole in which an additional seat with a ball is placed, between the body and the hydraulic distribution body a channel, and a cylinder with radial holes is installed between the body and the gate of the second stage.

The ball diameter is smaller than the diameter of the axial cavity of the first-stage shutter.

Performing the first-stage shutter with a saddle, with a ball placed in it, the movement of which is limited by a perforated disk, and a radial hole in which an additional saddle with a ball is placed, made it possible to create a check valve system that ensures the compression of the first-stage shutter to the first-stage saddle, thereby provide increased tightness when exposed to fluid pressure, both in the forward (at pressures below the tuning) and in the opposite direction. The implementation of the channel between the housing and the hydraulic distribution housing, and the installation of a cylinder with radial openings between the housing and the second-stage gate allowed supplying fluid from the housing cavity to the radial cavity of the valve.

All of the above symptoms together have improved the performance of an indirectly operated safety valve, thus the technical result has been achieved.

Analysis of the known technical solutions in this field of technology has shown that the claimed technical solution has features that are absent in the analogues, and their use in the inventive set of essential features makes it possible to obtain a new technical result. Therefore, the claimed technical solution meets the conditions of patentability of the invention of "novelty" and "inventive step".

The claimed technical solution is illustrated by the drawings:

FIG. 1 - safety valve of indirect action in the section;

FIG. 2 is a view A of FIG. one.

The indirect-action safety valve contains a hydrodistribution body 1, which is cylindrical with a central through-hole, forming a passageway and an axial cavity 2 of the valve. The through hole is made stepwise with the formation of a saddle 3 of the first stage. The hydrodistributive body 1 is made with radial holes 4, forming a radial cavity 5 of the valve. A thread and an annular groove 6 are made under the seals on the outer surface of the hydraulic distribution housing 1. In the hydraulic distribution housing 1 is placed the shutter 7 of the first stage, the saddle 8 of the second stage and the spring 9 located between them. The shutter 7 of the first stage is cylindrical with a central through stepped hole, forming an axial cavity 10 of the shutter 7 of the first stage. The axial cavity 10 of the shutter 7 is made with a saddle 11, with a ball 12 placed therein. The movement of the ball 12 in the axial cavity 10 is limited to a perforated disk 13 mounted in the axial cavity 10. The diameter of the ball 12 is smaller than the diameter of the axial cavity 10 of the bolt 7 of the first stage. The shutter 7 of the first stage is made with a radial hole 14 in which is placed an additional seat 15 with a ball 16. The saddle 15 is installed in the hole 14 along the thread with a sealant. Hole 14 is made deaf, the bottom of which is perforated with at least two holes "a". The communication of the axial cavity 10 with the cavity of the hole 14 is carried out through the holes "a". On the outer surface of the shutter 7 there is an annular groove 17 for the sealing ring.

The saddle 8 of the second step is made with a central through step hole with the formation of an axial cavity 18. A spring 9 is installed between the shutter 7 and the saddle 8, which is partially located in the opening of the shutter 7 and presses the perforated disk 13. The outer surface of the saddle 8 is made with an annular groove 19 under sealing ring.

The hydrodistributive body 1 is threadedly connected to the body 20. The body 20 is cylindrical with a passageway forming the cavity 21. The other end of the body 20 is closed by an adjusting screw 22. The spring 23 of the adjusting screw 22, the ball 24 and the second stage bolt 25 are placed in the body 20. The ball 24 is located between the saddle 8 and the bolt 25 of the second stage and is placed on the fit with tightness in the recess of the bolt 25 of the second stage. The inner surface of the housing 20 is made stepped with the formation of a support surface. Between the housing 20 and the gate 25 of the second stage is mounted a cylinder 26 with radial holes 27. The cylinder 26 limits the seat 8 from moving in the axial direction. Between the housing 20 and the hydraulic distribution housing 1 there is a channel 28 for communicating the cavity 21 with the radial cavity 5 of the valve. Regulation preloaded spring 23 is carried out by tightening the adjusting screw 22, the position of the screw 22 is fixed by the lock nut 29.

The indirect safety valve operates as follows.

In the normal position of the safety valve (in the presence of pressure in the axial cavity 2 exceeding the pressure in the radial cavity 5), cavity 2 communicates with the axial cavity 10 of the bolt 7 and the cavity 18 of the saddle 8. The bolt 7 of the first stage is pressed against the saddle 3 of the first stage by spring force 9, as well as the difference in axial forces of pressure of the fluid in the cavities 2 and 5 on the surface of the shutter 7. When a fluid pressure forms in the cavity 2 of the force on the ball 24 of the shutter of the second stage 25, exceeding the elastic force of the spring 23 of the second stage, the spring 23 is compressed the second stage and the displacement of the ball 24 together with the gate 25 of the second stage, the fluid flows from the cavity 2 into the cavity 21 and then through the holes 27 in the cylinder 26 and the channel 28 into the radial cavity 5 of the valve. The movement of fluid through the inlet in the gate 7 of the first stage causes a pressure drop on it and as a consequence the formation of an axial force on the gate 7, squeezing it from the saddle 3 of the first stage. As a result of the displacement of the shutter 7 of the first stage from the saddle 3 of the first stage, the cavities 2 and 5 are communicated by means of an annular gap formed. The subsequent decrease in pressure in the cavities 2, 10 and 18 leads to the preload of the ball 24 to the saddle 8 of the second stage. As a result, the flow of fluid through the axial hole in the shutter 7 stops, the pressure drop across this hole becomes zero and the shutter 7 under the force of the spring 9 is pressed against the saddle 3 of the first stage, the valve closes. When this pressure in the cavity 2 above the pressure in the cavity 5 leads to the preload of the ball 16 to the seat 15, installed in the gate 7 on the thread with a sealant.

When the fluid pressure in the cavity 5 exceeds the pressure in the cavity 2, the ball 16 is pressed from the seat 15, the liquid enters the cavity 10 through the holes “a” at the bottom of the hole 14, and the ball 12 is pressed to the saddle

11 of the shutter 7 of the first stage, sealing the cavity 5 from the cavity 2. In this case, the movement of the ball 16 is limited to the perforated bottom of the hole 14. The pressure difference in the cavity 2 and the cavity 5 forms a force pressing the first stage shutter 7 to the saddle 3 of the first stage. Thereby sealing the safety valve.

External tightness and additionally internal tightness of the safety valve is provided by a system of rubber seals.

The safety valve is designed in screw design, which allows it to be installed in a housing with the appropriate channels.

The claimed technical solution allows to improve the performance of a safety valve of indirect action.

The inventive indirect pressure relief valve can be made on standard equipment from modern materials using modern technologies.

Claims (2)

1. Indirect-acting safety valve containing a hydraulic distribution body, made with a flow channel, radial holes and a first-stage seat, a first-degree valve, a second-stage seat and a spring located between them, a housing with a through-passage, one end of which is detachably connected with the hydrodistributive case, and the other end is closed with an adjusting screw placed in the case a spring of the adjusting screw, a ball and a second-stage valve, distinguishing I by the fact that the shutter of the first stage is made with a saddle, with a ball placed in it, the movement of which is limited by a perforated disk, and a radial hole in which an additional saddle with a ball is placed, a channel is made between the case and the hydraulic distribution case, and between the case and the shutter of the second stage mounted cylinder with radial holes. 2. Safety valve according to Claim. 1, characterized in that the ball diameter is smaller than the diameter of the axial cavity of the first-stage gate.

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