SE531712C2 - Valve - Google Patents

Description

The section may be formed in the valve element and the abutment element is formed on the retaining component or alternatively the locking section may be formed in the retaining component and the abutment element is formed in the valve element.

In a particularly preferred arrangement, the distance of the relative axial movement of the abutment element in the pawl mainly defines the axial movement of the valve element.

The abutment element preferably comprises a bracket arm.

In the assembled condition, the distal end of the bracket arm is forced in a direction toward the locking section.

The bracket arm is preferably formed with a hook-shaped distal end. The means for limiting the axial movement of the valve element preferably comprises two abutment elements.

The retaining component preferably comprises means for anchoring the retaining component in the chamber. The means for anchoring the retaining component in the chamber preferably comprises a push-fit arrangement.

The means for anchoring the retaining component in the chamber preferably comprises a snap-arrangement between a radially inner surface of the chamber and a radially outer surface of the retaining component.

The snap-out arrangement preferably comprises a raised element which is adapted to be snapped into a locking shape, wherein the locking element may be formed in the radially inner surface of the chamber and the abutment element is formed on the radially outer surface of the retaining component or alternatively the locking element may be formed in the radially outer surface of the retaining component and the abutment member are formed in the radially inner surface of the chamber.

The valve element preferably comprises a projection and means for limiting the movement of the valve element is a corresponding ratchet formed on the retaining component, the ratchet being arranged to be toothed in the projection to limit the outward movement of the valve element relative to the chamber. The valve device is preferably a poppet valve, the valve member being formed with a substantially axial hole facing outwardly and communicating with a test device (which is not part of this invention) and the valve member having a channel facing inwards and which in an open relative position for the valve element and the retaining component is in communication with the fl uid to be tested.

Preferably, the valve member has a circumferential seat and the retaining component has a circumferential abutment and a sealing member is disposed between the seat and the circumferential abutment to actuate a seal between the valve member and the retaining component.

The valve device preferably comprises means for forcing the valve element towards the closed position. The means for forcing the valve element towards the closed position preferably comprises a compressible element. The compressible element may comprise any suitable shape or material, but preferably the element is a helical spring element.

Preferably, the valve element and the retaining component can be inserted into the chamber in the same direction along the longitudinal axis of the chamber.

The duct formed in the chamber comprises an end which is open to the atmosphere and preferably the valve element and the retaining component can be inserted into the duct in the chamber through the end open towards the atmosphere.

It is also preferred that the means for forcing the valve element towards the closed position and the sealing element can be inserted into the chamber in the same direction along the longitudinal axis of the chamber.

Preferably, at least one of the valve member or retaining component or means for forcing the valve member toward the closed position or sealing member may be pulled out of the chamber in the same direction along the longitudinal axis of the chamber.

The fluid channel formed in the chamber preferably has a decreasing diameter in the direction of insertion of the valve element. 10 15 20 25 30 35 353% 7%? The valve device is preferably made of a plastic material and the components of the device, such as the chamber, the valve element and the retaining component, are preferably manufactured by an injection molding process. To support the manufacture of the valve device in a composite or plastic material, a cavity or holes must be made in the material. When doing this in composite material, it is advantageous that the diameter of the cavity gradually decreases in the direction of the hole. It is otherwise difficult to extrude the core.

The present invention furthermore offers a valve device, in which all internal parts are mounted from the same direction, i.e. from the front of the valve device.

The distance of the relative axial movement of the abutment element in the pawl mainly defines the axial movement of the valve element and affects the compressive force from the member which forces the valve element towards the closed position.

According to a second aspect of the present invention, there is provided a method of assembling a valve device according to one or more of the features of the first aspect of the invention, the method comprising inserting the valve member into the chamber before inserting the retaining component.

The valve device comprises a chamber formed with a channel for communication, a valve element and a retaining component for retaining the valve element in the chamber, the valve element and the retaining component being accommodated in the chamber, the housing being formed with a channel at one end which is open to the atmosphere, the method preferably comprising inserting the valve element and the retaining component into the channel in the chamber through the end open to the atmosphere.

Brief description of the figures A specific embodiment of the invention will now be described by way of example only with reference to the accompanying drawings, of which: Fig. 1 is a cross-sectional view through AA in Fig. 3 and shows a valve device in a closed condition, Fig. 2 is a cross-sectional view through BB in Fig. 1 and shows the valve device in a closed state, 53% 713 5 Pig. 3 is a view along the axis of the valve and shows the valve device in a closed condition, Pig. 4 is a cross-sectional view through C-C in FIG. 6 and shows the valve device in an open condition, Pig. 5 is a cross-sectional view through D-D in Figs. 4 and shows the valve device in an open condition, Pig. 6 is a view along the axis of the valve and shows the valve device in an open condition, Pig. 7 is a side view of a valve element and a retaining component in a valve according to the invention and shows the element in a disassembled condition, Pig. 8 is an isometric view of Pig. 7 Pig. 9 is an isometric view of a chamber, a part of the sealing element, a valve element and a retaining component in a valve according to the invention and a push-in coupling and showing the elements in a disassembled condition, and Pig. 10 is an isometric view of the elements shown in Figs. 9 showing the elements in an assembled state.

Referring to the figures, a valve device 1 is shown in the form of a poppet valve for testing pressure in a pressurized fluid system. The valve device 1 comprises a chamber 2 provided with a channel 4 which extends along the longitudinal axis 6 of the chamber 2.

The duct 4 forms an external communication between the opposite ends 5, 7 of the chamber 2. The end 5 of the chamber 2 is provided with an axial outer opening 9. also a hole 12 extending from one end of the element 8 along the shaft 6 to an area spaced from the other closed end of the element 8. There are two radial openings 14 extending radially outwards from the hole 12. The valve element 8 and the retaining component 10 can both be inserted into the chamber 2 and can also be taken out of the chamber 2.

The valve device 1 comprises means for forcing the valve element against the closed position in the form of a compressible coil spring 16. The means for forcing the valve element 10 15 20 25 30 35 53? F12 12 against the closed position may alternatively comprise any other suitable compressible shape or material. The spring 16 is arranged inside the channel 4 and extends from the closed end of the valve 8 to the end 5 of the chamber 2. One end of the spring 16 abuts against a lug 18 formed on a radially outer surface of the closed end of the valve element 8.

Inside the channel 4 there is a sealing element in the form of an O-ring 20. The O-ring 20 is arranged between the lug 18 and an annular ledge formed in the inner surface of the karnmar 2.

The valve element 8 is axially movable relative to the chamber 2 from a closed position (as shown in Figs. 1 and 2) to an open position (as shown in Figs. 4 and 5). In the open position, fluid can pass through the valve device and consequently to a test device.

The valve device 1 comprises means for limiting the axial movement of the valve element 8 relative to the chamber 2 in the form of an annular locking section 22 formed in the valve element 8 and two corresponding abutment elements 24 extending from the retaining component 10. In an alternative arrangement the locking section 22 may be formed in the retaining component 10 and the abutment elements 24 may be formed on the valve element 9. In a particularly preferred arrangement, the distance of the relative axial displacement of the abutment element 24 in the blocking section 22 defines substantially the axial movement of the valve element 8.

The abutment elements 24 comprise a bracket arm (cantilever arm) provided with a hook-shaped distal end. In the assembled condition, the distal end of the bracket arm is forced in a direction toward the shaft 6 and into the locking section 22.

The distance of the relative axial movement of the abutment element 24 in the locking section mainly defines the axial displacement of the valve element 8. The distance of the relative axial movement of the abutment element 24 in the locking section 22 can also be used to influence or control the compressive force of the spring 16. The abutment element 24 which comes into contact with the end stop of the locking section 22 can be used to reduce the force from the spring 16 which presses the lug 18 against the O-ring 20.

The retaining component 10 includes means for anchoring the retaining component 10 within the chamber 2. The means for anchoring the 53% TWEÉ retaining component within the chamber 2 preferably comprises a push-arrang arrangement. The retaining component 10 may be anchored within the chamber 2 in the form of an annular raised edge 26 formed in the radially outer surface of the retaining component 10 and adapted to snap into an annular latch 28 formed in a radially inner surface of the chamber 2. The means for anchoring the retaining component 10 within the chamber 2 preferably includes a snap arrangement between a radially inner surface of the chamber 2 and a radially outer surface of the retaining component 10. In an alternative arrangement, the locking member 28 may be formed in the radially outer surface of the retaining component 10 and adjacent. is formed on the radially inner surface of the chamber 2.

The valve device 1 shown is of the poppet valve type, the valve element 8 being designed so that the substantially axial hole 12 facing outwards can communicate with a test device (not shown) and the valve element 8 has an opening 14 facing radially inwards, whereby there is a communication in an open relative position of the valve element 8 with the opening 9 and consequently the fluid to be tested.

Preferably, the valve member 8 has a circumferential seat and the retaining component 10 has a circumferential abutment and a sealing member is disposed between the seat and the circumferential abutment to actuate a seal between the valve member 8 and the retaining component 10.

It will be appreciated that the valve element 8 and the retaining component 10 can be inserted into the chamber 2 in the same direction along the longitudinal axis of the chamber 2. The chamber 2 comprises an end which is provided with an outer helical thread 30 which is used for attaching an instrument such as a pressure gauge. The other end of the chamber 2 is provided with two annular recesses 32. Two O-ring seals 34 are arranged in the recesses 32.

One end of the chamber 2 can be inserted into a pipe coupling 36 (as shown in Fig. 9). The O-rings 34 form a sealing arrangement with the inner surfaces of the pipe coupling 35.

The pipe coupling 36 may form part of a fluid pressure system as described above.

It is also preferred that the means 16 for forcing the valve element 9 towards the closed position and the sealing element in the form of O-ring 20 can be inserted into the chamber 2 in the same direction along the longitudinal axis of the chamber.

The fluid passage 4 formed in the chamber 2 preferably has a decreasing radial diameter in the direction of the insertion of the valve element 8 and the retaining component 10. As shown in Figs. 7, 8 and 9, the valve element 8 and the retaining component 10 are mounted in the chamber through the open end of the chamber 2. which is provided with a thread 30. The valve element 8 enters the chamber before the retaining component 10 is inserted. The O-ring 20 can be placed on the valve element 8 before the element is placed in the chamber 2. The spring 16 can be placed in the chamber before the valve element 8 is inserted in the chamber 2 or alternatively the spring 16 and / or the O-ring 20 can be placed on the element 8 before they are placed in the chamber 2.

The retaining component 10 is preferably placed on the end of the valve element 8 before the two are placed in the chamber 2.

The valve device 1 is preferably made of a plastic material and the components of the device 1, such as the chamber 2, the valve element 8 and the retaining component are preferably manufactured by a mold spraying process.

It will be appreciated that the chamber 8 may form part of another device inside a pressurized system such as a pipe fitting or a branch unit.

The valve element 8 and the retaining component 10 can be received inside a fluid opening formed in such another device in the system.

The valve device 1 can function in a similar way as known pressure test points, i.e. idt expression can be tested by pressing the valve stem into the test point. In the rest position, the valve stem can be pressed outwards by a spring.

Claims (23)

10 15 20 25 30 35 531 'F12 REQUIREMENTS Valve device (1) for testing pressure in a system with pressurized fluid, the valve device comprising a chamber (2) provided with a channel (4) for fluid communication, a valve element (8) and a retaining component (10) for retaining the valve element (8) in the chamber (2), wherein the valve element (8) and the retaining component (10) can be received by the chamber (2), the retaining component (10) can be anchored in the chamber, the valve element (8) can be moved axially relative to the chamber from a closed position to an open position, wherein fluid can pass from the valve device (1) and consequently to a fluid test device, characterized in that the retaining component (10) comprises means for limiting the axial movement of the valve element (8) relative to the chamber (2), the means comprises a locking section (22) and a corresponding abutment element (24), the locking section (22) being formed in the valve element (8) and the abutment element (24) being formed on the retaining component (10) or alternatively the locking section (22) is formed in the retaining component (10) and the abutment element (24) is formed on the valve element (8). Valve device according to claim 1, wherein the distance of the relative axial movement of the abutment element (24) in the ratchet substantially defines the axial movement of the valve element (8). A valve device according to claim 1 or claim 2, wherein the abutment element (24) comprises a bracket arm. Valve device according to claim 3, wherein in the assembled condition the distal end of the bracket arm is forced in a direction towards the locking section. A valve device according to claim 3 or claim 4, wherein the bracket arm is formed with a hook-shaped distal end. A valve device according to any one of the preceding claims, wherein the means for limiting the axial movement of the valve element (8) comprises two abutment elements (24). A valve device according to any one of the preceding claims, wherein the retaining component (10) comprises means for anchoring the retaining component (10) inside the housing. 10 15 20 25 30 35 EEÉ 1912 l0 A valve device according to claim 7, wherein the means for anchoring the retaining component (10) inside the housing comprises a push-arrang arrangement. A valve device according to claim 7 or claim 8, wherein the means for anchoring the retaining component (10) in the chamber (2) comprises a snap-fit arrangement between a radially inner surface of the chamber (2) and a radially outer surface of the retaining grain component (10). ). Valve device according to claim 9, wherein the snap-on arrangement comprises a raised element which is adapted to be slid-fit in a locking shape, wherein the locking element may be formed in the radially inner surface of the chamber (2) and the abutment element (24) is formed on the radially outer surface of the retaining component (10) or alternatively the locking element may be formed in the radially outer surface of the retaining component (10) and the abutment element (24) is formed in the radially inner surface of the chamber (2). 11. ll. A valve device according to any one of the preceding claims, wherein the valve element (8) preferably comprises a projection, and means for limiting the movement of the valve element (8) is a corresponding ratchet formed on the retaining component (10), the ratchet being arranged to be toothed in the projection to restrict the outward movement of the valve element (8) relative to the chamber (2). Valve device according to any one of the preceding claims, wherein the valve device constitutes a poppet valve, wherein the valve element (8) is provided with a substantially axial hole facing outwards and can communicate with a test device (which does not form part of this invention) and the valve element (8) has a through hole facing inwards and in an open relative position for the valve element (8) and the retaining component (10) communicates with the fl uid to be tested. Valve device according to claim 12, wherein the valve element (8) has a circumferential seat and the retaining component (10) has a circumferential abutment and a sealing element is arranged between the seat and the circumferential abutment to actuate a seal between the valve element (8) and the retaining component (10). ). A valve device according to any one of the preceding claims, wherein the valve device comprises means for forcing the valve element (8) towards the closed position. 10 15 20 25 30 35 53? 752 ll A valve device according to claim 14, wherein the means for forcing the valve element (8) towards the closed position comprises a compressible element. A valve device according to claim 15, wherein the compressible element comprises a helical spring element (16). Valve device according to any one of the preceding claims, wherein the valve element (8) and the retaining component (10) can be inserted into the chamber (2) in the same direction along the longitudinal axis (6) of the chamber (2). Valve device according to claim 17, wherein the means for forcing the valve element (8) towards the closed position and the sealing element can be inserted into the chamber (2) in the same direction along the longitudinal axis (6) of the chamber (2). The valve device according to any one of the preceding claims, wherein at least one / one of the valve element (8) or the retaining component (10) or the means for forcing the valve element (8) against the closed bearing or the sealing element can be pulled out of the chamber (2) in the same direction along the longitudinal axis (6) of the chamber (2). Valve device according to one of the preceding claims, wherein the fl outlet channel formed in the chamber (2) has a decreasing diameter in the direction of the insertion of the valve element (8). Valve device according to any one of claims 14-20, wherein the distance of the relative axial movement of the abutment element (24) in the ratchet substantially defines the axial movement of the valve element (8) and influences the compressive force from the means intended to force the valve element (8) towards the closed mode. A method of assembling a valve device according to any one of the preceding claims, wherein the method comprises inserting the valve element (8) into the chamber (2) before inserting the retaining grain component (10). A method according to claim 22, wherein the valve device comprises a chamber (2) provided with a channel (4) for fluid communication, the valve element (8) and the retaining component (10) for retaining the valve element (8) in the chamber (2), the housing is provided with a channel at one end which is open to the atmosphere, the method comprising inserting the valve element (8) and 53? Raw 12 retaining component (10) in the channel in the chamber (2) through the open end to the atmosphere.