RU2599405C2 - Ball valve - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to machine building, in particular, to aerospace engineering, and designed as manual actuated shutoff valve. Ball valve consists of housing with inlet and outlet unions and two seats. Said seats are made in form of sealing elements having through holes with spherical surfaces to interact with ball shutoff element closing flow opening. Ball shutoff element has slot with ledge located in it. Stem includes sealing element held by coupling nut. Rotary mechanism is made in form of damping piston with rod. Coupling nut is made with through holes. In formed between coupling nut and damping piston end cavity is formed. Said cavity is made with possibility of volume changing inversely proportional to working medium volume change, located in closed ball shutoff element closed cavity. In above cavity a spring is installed.

EFFECT: technical result is ball valve reliability improvement, providing housing protection against pressure damage in case of temperature considerable variation, working fluid heating or freezing.

1 cl, 2 dwg

Description

The invention relates to the field of engineering, in particular to space rocket technology, and is intended as a shut-off valve with a manual actuator designed to pass along the valve path of the working fluid flow when the valve is open and to shut off the working fluid flow when the valve is closed, with protection from damage by pressure with a significant change in temperature (heating) or its freezing.

Known ball valve comprising a housing with flanges that form the inlet and outlet of the valve located on the same axis, a rotary actuator that provides overlap of the valve seats in the closed position or the full opening of the valve in the open position. Moreover, each seat consists of a spring-loaded floating piston with limited axial movement (RU No. 2467233 C2, IPC F16K1 / 22, F16K5 / 06, F16K39 / 06).

The disadvantages of this design is the rotary mechanism, made in the form of a fixed piston along the vertical axis, which makes it impossible to protect the housing from pressure damage with a significant change in temperature, heating of the working fluid or its freezing.

This valve is operated at a space station in the COTP system in outer space. Because the station constantly revolves around the Earth, it either falls on the sunny side, then goes into the shade. The problem is that the case could not withstand constant temperature changes, cracks formed, which led to a violation of the sealing system. Subsequently, this affected the temperature inside the station, a sharp increase in temperature, very different from room temperature. The valve is not in the piece quantity in the system and it is possible to install a damper in the system, but it is very unprofitable from the point of view of manufacturing.

Close in technical essence to the proposed technical solution is a ball valve (RU No. 2517467 C2, IPC F16K 5/20, F16K 43/00), consisting of a housing with inlet and outlet fittings and two seats in the form of ring sealing elements having passage openings with spherical surfaces for interacting with a spherical locking element connected to the rod, overlapping the passage opening. A movable sealing element is installed in the valve body on the inlet choke side, made in the form of a sleeve with a seat on the side of the ball locking element and spring-loaded with a disk washer on the inlet choke side. The saddle is installed in the outlet fitting on the side of the ball locking element. The junction of the outlet fitting and the movable sealing element with the housing are sealed with sealing rings. The rod is installed in the housing and fixed with a sleeve and a retaining ring with the possibility of rotation around its axis. In this case, the protrusion of the rod enters the groove of the ball locking element. The upper part of the hexagonal rod for opening and closing the ball valve with a standard wrench.

A significant drawback of valves without a damper is that cosmonauts have to go into open space to replace it, and this in turn leads to a halt in the main activities of the crew. In addition, when the station is deployed, i.e. goes from the sunny side to the shadow, the liquid freezes, which leads to the destruction of the body. Thus, freezing of the working fluid in pressure steel pipelines leads to rupture of the pipes. This is one of the main reasons that a temporary interruption in the supply of working fluid leads to dire consequences. At the same time, in specialized publications it was reported: ball valves do not collapse when the working fluid freezes in them; deformed, they, however, can be exploited in the future. In this regard, our corporation conducted tests consisting in modeling the processes occurring in filled ball valves when exposed to negative temperatures. The purpose of the research was to assess the resistance of ball valves to failure during a one-time exposure to cold in emergency situations, as well as the possibility of normal functioning when alternating negative and positive temperatures. In addition, the task of the tests included determining the effect on the stability of ball valves of the quality of the working fluid taken from various pipelines (cold, hot water, heating, etc.), and the magnitude of the overpressure. The tests were carried out before the destruction of the walls of the valve with the determination of the number of seasoned cycles. The necessary studies were carried out. The studies used 2-way control valves with a correcting disk DN 10 ... 80 for smooth adjustment of the working fluid. The tests were carried out as follows. The collected samples were filled with a working fluid, ensuring complete removal of air from them, and blocked the water with a ball valve, blocking the fittings of inlet 2 and outlet 3 with plugs. Next, the samples were placed in a chamber with a temperature of -100 ° C, where they were kept until the entire volume of the working fluid was frozen with its passage to ice. Then the samples were removed and placed in a chamber with a temperature of + 100 ° C. After that, liquid was removed from them, the condition of the valves was evaluated, and the cycle was repeated from the beginning. (Thus, the cycle means: filling the sample with liquid; cutting off the working volume by closing the ball valve; cooling the sample in the freezer and holding it until the liquid is completely freezing; taking the sample out of the chamber; completely thawing the ice; examining the sample for destruction of the casing or cracks). Then they carried out the same test, but with a damping piston.

Preliminary swelling and subsequent rupture of the body wall occurs exclusively along the generatrix. The destruction in shape resembles a “boat” with pointed ends, the edges of the hole are even. The length of the hole is 12-30 mm, the width of 4-10 mm. The gap is accompanied by a relatively soft sharp sound reminiscent of cotton. Initial experiments on negative temperature loading of ball-sealed ball valves with liquid showed that samples that had not previously been exposed to this can withstand at least one freezing of the liquid in them without breaking. And valves with a damping piston were subjected to repeated loading in the amount of 50 times. All valves have been successfully tested. Until the moment of destruction, the outer diameter of the body increases from cycle to cycle, respectively, the thickness of the wall of the sample decreases, at the point of rupture it is equal to half the original.

The objective of the invention is the creation of such a ball valve, the design of which would protect the body from damage by pressure with a significant change in temperature, heating of the working fluid or its freezing.

The essence of the invention lies in the fact that in a ball valve, consisting of a housing with inlet and outlet fittings and two seats, made in the form of sealing elements having passage openings with spherical surfaces for interacting with a spherical shut-off element having a groove overlapping through passage with in it with a protrusion, as well as a rod with a sealing element held by a union nut, the rotary mechanism is made in the form of a damping piston with a rod, while the union nut is made with a squaw holes, and in the cavity formed between the union nut and the end face of the damping piston, made with the possibility of changing the volume in inverse proportion to the volume change of the working fluid in the closed cavity of the ball locking element in the closed position, a spring is installed, the force of which is calculated by the formula

F _CR = P _slave × S _piston ,

where P _slave is the working pressure, S of the _piston is the cross-sectional area of the piston, while the stroke of the damping piston is less than the height of the protrusion of the damping piston.

The technical result of the invention is to increase the reliability of the design of the ball valve, which protects the housing from pressure damage with a significant change in temperature, heating of the working fluid or its freezing.

The invention is illustrated in FIG. 1 and 2.

In FIG. 1 shows a general view of a ball valve in a closed state.

In FIG. 2 shows a general view of a ball valve in a closed state with a damping piston in its extreme position.

The design of the ball valve consists of a housing 1 with an inlet fitting 2 and an outlet fitting 3 and two saddles 4 and 5 in the form of sealing elements, for example, annular ones, having passage openings with spherical surfaces for interacting with a ball-locking element 6 that overlaps the passage opening, in which a groove 7 for the protrusion 8 of the damping piston 9. In the valve body, from the side of the inlet fitting 2, a movable sealing element 10, made in the form of a sleeve, is installed on the side of the ball locking element 6 spring-loaded disc washer 11 from the inlet fitting 2. The junction of the inlet fitting 2 and the movable sealing element 10 with the housing 1 are sealed by the sealing rings 12. The rod 13 of the damping piston 9 in the housing 1 is spring-loaded by a spring 14 held by the union nut 15. In this case, the protrusion 8 of the damping the piston 9 enters the groove 7 of the ball locking element 6, and the rod 13 can rotate around its axis. Thanks to the spring 14, the rod 13 can move along the vertical axis without leaving the groove 7 of the ball locking element 6, since L1 <L2, the stroke of the damping piston is less than the depth of the groove 7 of the ball locking element 6 (Fig. 1). A cavity 16 with a volume V2 is formed between the end face of the damping piston and the union nut 15. The upper part of the stem 13 is hexagonal so that the ball valve can be opened and closed with a standard wrench. The junction of the rod 13 with the housing 1 is sealed with o-rings 17. The output fitting 3 is attached to the housing 1 with pins 18 and nuts 19.

The ball valve operates as follows.

The principle of operation of the ball valve is based on blocking the flow by rotating the ball locking element 6 around an axis perpendicular to the direction of flow. In the ball locking element 6, a through hole is made equal to the inner diameter of the pipeline. In the open position, the axis of the hole in the valve coincides with the axis of the pipeline, and in the closed axis it is perpendicular. To fully open or close the valve, just turn the ball 90 °.

Hermetic shutoff of the flow is ensured by the tight fit of the surface of the ball locking element 6 of the sealing elements 4 and 5. During operation, the ball valve shutter must be in one of the extreme positions - fully open or completely closed. It is not allowed to operate the ball valve when the shutter is partially opened, since the abrasive wear of the rotary mechanism will lead to a violation of the tightness of the flow shutoff.

On the product, the ball valve is fixed by the fittings of the inlet 2 and outlet 3 to the pipeline. Stem 13 in the "Open" position. A working fluid passes through the ball valve path. With significant changes in temperature, the damping piston 9 rises, reducing the volume of the cavity formed between the union nut and the end face of the damping piston, allowing the volume of the working fluid located in the closed cavity of the ball locking element with the volume V1 to be closed, while V1 <V2. Due to the fact that the damper piston 9 is spring-loaded by the spring 14 from the side of the union nut 15, it returns to its original position. The magnitude of the spring force is calculated by the formula

F _CR = P _slave × S _piston ,

where P _slave is the working pressure, S of the _piston is the cross-sectional area of the piston. The flare nut 15 has through channels connecting the cavity between the flare nut and the end face of the damping piston 16 with the surrounding environment to allow air to escape. The protrusion of the damping piston is always in the groove of the ball locking element, since the stroke of the damping piston L1 is less than the height of its protrusion L2.

Thus, the proposed design protects the housing from pressure damage during a significant change in t, heating of the working fluid or its freezing due to the damping piston.

Claims (1)

Ball valve, consisting of a housing with inlet and outlet fittings and two seats, made in the form of sealing elements having passage openings with spherical surfaces for interacting with a ball locking element having a groove overlapping the passage opening, with a protrusion placed in it, and also a rod with a sealing element held by a union nut, characterized in that the rotary mechanism is made in the form of a damping piston with a rod, while the union nut is made with through holes, and in the formed cavity between the union nut and the end face of the damping piston, configured to change the volume inversely proportional to the change in the volume of the working fluid located in the closed cavity of the ball locking element in the closed position, a spring is installed, the force of which is calculated by the formula:
F _CR = P _slave × S _piston ,
where P _slave - working pressure;
S _piston - cross-sectional area of the piston,
wherein the stroke of the damping piston is less than the height of the protrusion of the damping piston.

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