ES1269230U - BIDIRECTIONAL FLOATING BALL VALVE (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Bidirectional floating ball valve of the type comprising: - a body (1) with walls that integrate a first port (11) in fluid communication with a second port (12) through a cavity, where the cavity is defined by: - or a central housing (130) interposed between both ports (11, 12), and - a peripheral chamber (131) located on the periphery of the central housing (130), - a ball (2) with a through hole (21), which is attached to a stem (22), the ball (2) being housed in said central housing (130) and the stem (22) being accessible from the outside of the body (1), so that the ball (2) is rotatable by means of the stem (22) and can be adjusted well in an opening position where the through hole (21) allows fluid communication between both ports (11, 12), or in a closed position where the walls of the ball (2) block the passage of fluid between both ports (11, 12), - a first sealing seat (31) located between the ball (2) and the first port (11), and a second sealing seat (32), located between the ball (2) and the second port (12), the ball (2) being arranged between said sealing seats (31, 32), so that, when the ball is in the closed position, only the sealing seat (31, 32) whose port (11, 12) is located the lower the pressure is the one that seals the fluid passage, due to the displacement of the ball (2) against it, characterized in that it comprises a non-return valve (4) arranged in such a way as to allow the passage of fluid from the peripheral chamber (131) towards the first port (11) when the pressure in the peripheral chamber (131) is equal to or greater than the pressure in the first port (11), and prevents the passage of fluid from the first port (11) to the peripheral chamber (131). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

BIDIRECTIONAL FLOATING BALL VALVE

The present invention is framed in the field of valves, and more specifically that of bidirectional floating ball valves comprising depressurization means.

Background of the invention

Bidirectional floating ball valves are known in the state of the art, such as those disclosed in documents US4552335A or US2020355276A1. This type of valve includes a body with inlet and outlet ports, and a ball with a through hole arranged between the ports, which allows the passage between the ports to be opened and closed depending on the rotation applied to it by means of a stem fixed to is. The body also houses sealing seats, arranged on each side of the ball. When the ball is in the closed position, the port where there is less pressure is sealed, due to the displacement of the ball towards its seat.

In cryogenic applications, where the fluid managed by the valve is liquefied gas, there is the problem that when maneuvering the valve (either when opening or closing it) fluid is trapped in the valve cavities, which can cause a Excessive internal overpressure causing extreme damage to the valve, possibly even bursting. To avoid this, the balls of some valves include a perforation that communicates said cavities with one of the ports, with the intention that they can be depressurized. However, there are applications where this type of perforated ball valves are not suitable, such as in the loading of liquefied natural gas (LNG) tanks. In this application, before the tanks are filled, nitrogen is applied to the receiving port to inert it and, in cases where the nitrogen pressure exceeds that of the tank, the ball is pressed against the seat of the tank port, causing the receiver seat does not seal nitrogen passage into cavities. Since the valve cavities are in fluid communication with the tank port through the aforementioned perforation, the nitrogen has a free path to the tank, which can cause the torch used in the safety system to go out and leave the tank. to function.

Therefore, the need to provide a bi-directional valve that is capable of sealing the passage of fluid in both directions while allowing the depressurization of the cavities within it is clear.

Description of the invention

The aim of the present invention is to provide a valve that solves the aforementioned drawbacks and has the advantages that are described below.

The present bi-directional floating ball valve is of the type comprising:

- a body with walls that integrate a first port in fluid communication with a second port through a cavity, where the cavity is defined by:

^or a central housing interposed between both ports, and

^or a peripheral chamber located on the periphery of the central housing,

- a ball with a through hole, which is attached to a stem, the ball being housed in said central housing and the stem being accessible from outside the body, so that the ball is rotatable by means of the stem and orientable well in a open position where the through hole allows fluid communication between both ports, or in a closed position where the walls of the ball block the passage of fluid between both ports,

- a first sealing seat located between the ball and the first port, and a second sealing seat, located between the ball and the second port, the ball being arranged between said sealing seats, so that, when the ball is located in the closed position, only the sealing seat whose port is at a lower pressure is the one that seals the passage of fluid, due to the displacement of the ball against it.

This bidirectional floating ball valve is characterized by the fact that it comprises a depressurization mechanism consisting of a non-return valve, arranged in such a way that it allows the passage of fluid from the peripheral chamber to the first port and prevents it in the opposite direction.

Thanks to this, the present bidirectional floating ball valve is capable of sealing the passage of fluid in both directions while allowing the depressurization of its peripheral cavity in the event that fluid is trapped in it once closed.

Optionally, the ball may comprise a hole that fluidly communicates the internal through hole of the ball with the peripheral chamber, with the intention that the peripheral cavity can be depressurized when the ball is in the open position.

In a first embodiment, the peripheral chamber extends in the longitudinal direction of the first port, and said non-return valve is located in the wall of the body which is between the peripheral chamber and the first port.

In a second embodiment, the bidirectional floating ball valve comprises at least one first metal bush housed in the first port (if necessary, the bidirectional floating ball valve could comprise two metal bushings, each one housed in one of the ports), which holds the first sealing seat. In this case, the non-return valve can be located on the wall of the first metal bushing, while the peripheral chamber comprises a fluidic connection channel that accesses the non-return valve.

In a third embodiment of the bidirectional floating ball valve, where the ball comprises the hole that fluidly communicates the internal through hole of the ball with the peripheral chamber, the non-return valve is located in the wall section of the ball intended to cover the first port (in this way it allows the passage of fluid from the peripheral chamber to the first port through the through hole). In this case, the non-return valve may be defined longitudinally and, preferably in this last embodiment, the non-return valve is positioned perpendicular to the longitudinal axis of the through hole.

In a possible embodiment, the non-return valve is of the spring type, where a shutter supported by a spring closes the flow of fluid in both directions, except when the upstream pressure exceeds the spring force and the downstream pressure, which is when it allows the fluid passage downstream of the non-return valve. Preferably, the spring is calibrated so that the shutter allows the passage of fluid when the upstream pressure is equal to or greater than 1.33 times the pressure downstream of the non-return valve. In relation to the shutter, it can have different geometries, such as spherical or frusto-conical.

Brief description of the figures

For a better understanding of what has been stated, some drawings are attached in which a practical case of embodiment is schematically represented, only as a non-limiting example.

Figure 1.- Is a sectional view of a first embodiment of the present bidirectional floating ball valve.

Figure 2.- Is a sectional view of a second embodiment of the present bidirectional floating ball valve.

Figure 3.- Is a sectional view of a third embodiment of the present bidirectional floating ball valve.

Figure 4.- Is a detailed and sectioned view of a first embodiment of a non-return valve.

Figure 5.- Is a detailed and sectioned view of a second embodiment of a non-return valve.

Description of preferred embodiments

In the following, preferred embodiments of the present bi-directional floating ball valve are described with reference to Figures 1 to 5.

Figures 1 to 3 illustrate sectional views of three different embodiments of the bi-directional floating ball valve. In them a body (1), substantially cylindrical, with walls that integrate a first port (11) in fluid communication with a second port (12) through a cavity can be seen. This cavity is defined by a central housing (130) interposed between both ports (11, 12), and a peripheral chamber (131) located on the periphery of the central housing (130). There is also a ball (2) with a through hole (21), which is attached to a stem (22). The stem (22) is accessible from the outside of the body (1) for its rotation, although only a portion of it is shown in the figures. The ball (2) is housed in said central housing (130), so that it can be rotated by means of the stem (22). Thanks to this, it is adjustable from an opening position where the through hole (21) allows fluid communication between both ports (11, 12) to a closed position where the walls of the ball (2) block the passage of fluid. between both ports (11, 12). A first sealing seat (31) located between the ball (2) and the first port (11), and a second sealing seat (32), located between the ball (2) and the second port (12) are also appreciated. . The ball (2) is arranged between said sealing seats (31, 32), so that only the sealing seat (31, 32) whose port (11, 12) is at a lower pressure is the one that seals the passage of fluid due to the displacement of the ball (2) against it. Likewise, it can be seen that the peripheral chamber (131) extends in the longitudinal direction of the first port (11) and that the ball (2) comprises a hole (23) that fluidly communicates the internal through hole (21) of the ball (2) with the peripheral chamber (131).

In the embodiment of figure 1, the peripheral chamber (131) extends in the longitudinal direction of the first port (11), and the non-return valve (4) is located in the wall of the body (1) which is between the chamber peripheral (131) and the first port (11).

In the embodiment of Figure 2, the bi-directional floating ball valve comprises a metal bushing (311) housed in the first port (11), which holds the first sealing seat (31). In this case, the non-return valve (4) is located on the wall of the metal bushing (311), thus there is a non-return fluid communication between the peripheral chamber (131) and the first port (11) through the metal bushing (311). .

In the embodiment of figure 3, the non-return valve (4) is located in the wall section of the ball (2) destined to cover the first port (11), so that it allows the passage of fluid from the peripheral chamber ( 131) to the first port (11) through the through hole (21). In this preferred case, the longitudinal direction of the non-return valve (4) is positioned perpendicular to the longitudinal axis of the through hole (21).

Figures 4 and 5 show detailed and sectioned views of two different embodiments of the non-return valve (4) used as a depressurization mechanism in the bidirectional floating ball valve. In both cases, the body (40) of the non-return valve (4) is defined by a longitudinal shape and houses a shutter (41) supported by a spring (42), the spring (42) being calibrated so that the shutter ( 41) allows the passage of fluid when the upstream pressure is equal to or greater than 1.33 times the downstream pressure of the non-return valve (4). In the embodiment of Figure 4, the plug (41) has a spherical shape, while in that of Figure 5 the plug (41 ') has a frusto-conical shape.

Despite the fact that reference has been made to specific embodiments of the invention, it is clear to a person skilled in the art that the invention described is susceptible to numerous variations and modifications, and that all the mentioned details can be replaced by other technically equivalent ones, without departing from the scope of protection defined by the appended claims.

Claims (10)

1. Bidirectional floating ball valve of the type comprising: - a body (1) with walls that integrate a first port (11) in fluid communication with a second port (12) through a cavity, where the cavity is defined by: ^or a central housing (130) interposed between both ports (11, 12), and ^or a peripheral chamber (131) located on the periphery of the central housing (130), - a ball (2) with a through hole (21), which is attached to a stem (22), the ball (2) being housed in said central housing (130) and the stem (22) being accessible from the outside of the body (1), so that the ball (2) is rotatable by means of the stem (22) and can be adjusted well in an opening position where the through hole (21) allows fluid communication between both ports (11, 12), or in a closed position where the walls of the ball (2) block the passage of fluid between both ports (11, 12), - a first sealing seat (31) located between the ball (2) and the first port (11), and a second sealing seat (32), located between the ball (2) and the second port (12), the ball (2) being arranged between said sealing seats (31,32), so that, when the ball is in the closed position, only the sealing seat (31,32) whose port (11, 12) is located the lower pressure is the one that seals the fluid passage, due to the displacement of the ball (2) against it, characterized in that it comprises a non-return valve (4) arranged in such a way as to allow the passage of fluid from the peripheral chamber (131) towards the first port (11) when the pressure in the peripheral chamber (131) is equal to or greater than the pressure in the first port (11), and prevents the passage of fluid from the first port (11) to the peripheral chamber (131). Two-way floating ball valve according to claim 1, characterized in that the peripheral chamber (131) extends in the longitudinal direction of the first port (11), and the non-return valve (4) is located on the wall of the body (1 ) located between the peripheral chamber (131) and the first port (11). Bidirectional floating ball valve according to claim 1, characterized in that it comprises at least one first metal bushing (311) housed in the first port (11), which holds the first sealing seat (31), the non-return valve being (4) located at the wall of the first metal sleeve (311) and the peripheral chamber (131) comprise a fluidic connection channel that accesses the non-return valve (4). 4. Bidirectional floating ball valve according to claim 1, characterized in that the non-return valve (4) is located in the wall section of the ball (2) destined to cover the first port (11), in such a way that it allows the passage of fluid from the through hole (21) to the first port (11). 5. Bidirectional floating ball valve according to any of the preceding claims, characterized in that the ball (2) comprises a hole (23) that fluidly communicates the internal through hole (21) of the ball (2) with the peripheral chamber (131 ). Bidirectional floating ball valve according to claim 5, characterized in that the non-return valve (4), which is defined by a longitudinal shape, is positioned perpendicular to the longitudinal axis of the through hole (21). Bidirectional floating ball valve according to any of the preceding claims, characterized in that the non-return valve (4) is of the spring type. Bidirectional floating ball valve according to claim 7, characterized in that the non-return valve (4) comprises a shutter (41) supported by a spring (42), the spring (42) being calibrated so that the shutter (41) allows the passage of fluid when the upstream pressure is equal to or greater than 1.33 times the downstream pressure of the non-return valve (4). Bidirectional floating ball valve according to claim 8, characterized in that the plug (41) has a spherical shape. Bidirectional floating ball valve according to claim 8, characterized in that the plug (41 ') has a frusto-conical shape.