Classifications

• • G—PHYSICS
  • G05—CONTROLLING; REGULATING
  • G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
  • G05D16/00—Control of fluid pressure
  • G05D16/04—Control of fluid pressure without auxiliary power
  • G05D16/10—Control of fluid pressure without auxiliary power the sensing element being a piston or plunger
  • G05D16/107—Control of fluid pressure without auxiliary power the sensing element being a piston or plunger with a spring-loaded piston in combination with a spring-loaded slideable obturator that move together over range of motion during normal operation
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
  • F16K—VALVES; TAPS; COCKS; ACTUATING-FLOATS; DEVICES FOR VENTING OR AERATING
  • F16K17/00—Safety valves; Equalising valves, e.g. pressure relief valves
  • F16K17/02—Safety valves; Equalising valves, e.g. pressure relief valves opening on surplus pressure on one side; closing on insufficient pressure on one side
  • F16K17/04—Safety valves; Equalising valves, e.g. pressure relief valves opening on surplus pressure on one side; closing on insufficient pressure on one side spring-loaded
  • F16K17/048—Safety valves; Equalising valves, e.g. pressure relief valves opening on surplus pressure on one side; closing on insufficient pressure on one side spring-loaded combined with other safety valves, or with pressure control devices

Definitions

• the invention is directed to a regulator for compressed gas with a pressure relief valve.
• Prior art patent document published US 2014/0238508 A1 discloses a pressure reducing device for compressed gas.
• the device comprises a regulating valve with a movable closure member located upstream of the seat, i.e. on the high pressure side.
• the position of the movable closure member is controlled by a piston that delimits with the body of the device a regulating chamber downstream of the regulating valve.
• a main spring urges the piston towards the regulating valve and tends therefore to open said valve.
• the movable closure element is only in thrust abutment with the piston, meaning that said closure element is not attached to said piston.
• Prior art patent document published EP 2 765 471 A1 discloses a pressure regulating device for compressed gas and comprising a regulating valve with a seat and a movable closure member located downstream of the seat, i.e. on the low pressure side.
• the closure member is carried by a shaft of a piston of the regulator. The gas whose pressure is reduced through the regulating valve flows through the shaft towards a regulating chamber delimited by the piston and located on a side of the piston that is opposed to the regulating valve.
• a spring urges the piston away from the regulating valve and the pressure in the regulating chamber compensates said urging force.
• a pressure relief valve is provided on the piston. It consists essentially in a sleeve slip on the shaft of the piston and urged in a gas tight manner on the disk-shaped portion of the piston by the spring. The sleeve forms with the piston a cavity that is in fluid connection with the regulating chamber via a leak passage. When the pressure in the regulating chamber increases beyond a predetermined level, the sleeve moves away from the piston against the biasing force of the spring and opens a discharge passage.
• This construction is interesting but has for disadvantage that the closure element of the regulator is on the downstream side of the seat, contrary to the preceding mentioned teaching. Such a regulator shows a higher variability of the outlet pressure along the discharge of a gas container to which it is connected.
• the invention has for technical problem to provide a regulator for compressed gas that overcomes at least one of the drawbacks of the above cited prior art. More particularly, the invention has for technical problem to provide a regulator with a pressure relief valve that is secure and reliable.
• the invention is directed to a regulator for compressed gas, comprising: a body with an inlet, an outlet and a channel for guiding a flow of gas from said inlet to said outlet; a regulating valve with a seat in the channel and a movable closure member upstream of said seat; a piston housed in the body and mechanically linked with the closure member, said piston delimiting with said body a regulating chamber downstream of the regulating valve and controlling said valve; a resilient member able to exert a biasing force on the piston towards the regulating valve in order to open the regulating valve; a pressure relief valve for the channel downstream of the regulating valve; wherein the pressure relief valve comprises a movable element interposed between the resilient member and the piston, said element forming a gas tight closure of the channel and being able to move by virtue of the pressure of the gas in said channel and against the biasing force of the resilient member so as to allow said gas to leak.
• the regulator can be a pressure reducer, e.g. from an inlet pressure of up to 300 bar to an outlet pressure comprised between 1 and 20 bar.
• the regulator can be integrated in a device to be screwed to a gas cylinder.
• the device can for example comprise a flow selector downstream of the regulator.
• the regulator can comprise an additional resilient member located in the regulating chamber, said additional resilient member only partially compensating the biasing force of the resilient member on the opposite side of the piston.
• the regulating chamber is advantageously delimited by a face of the piston in vis-a-vis of the regulating valve.
• the pressure relief valve is in fluid connection with the regulating chamber.
• the piston comprises at least one passage interconnecting the regulating chamber with the movable closure element.
• the movable closure element is disk-shaped.
• the movable closure element comprises at least one lateral guiding surface, said surface preferably being a cylindrical surface formed by a wall extending longitudinally.
• the movable closure element is urged against the piston by the biasing force of the resilient member.
• the pressure relief valve forms a chamber with a height of at least 0.5mm, preferably at least 1 mm.
• the chamber is delimited by the movable closure element and the piston.
• At least one of the movable closure element and the piston is recessed for forming the chamber.
• At least one of the piston and the movable closure element comprises a circular groove housing a seal for a gas tight mutual contact of said piston and element.
• the seal shows an outer diameter that is larger than 80%, preferably 90%, of a diameter of the piston.
• said regulator further comprises a thrust bearing interposed between the resilient member and the movable closure element.
• the thrust bearing comprises a pressure plate resting on the resilient member and a ball resting in a recess on said pressure plate and an opposed recess on the movable closure element.
• said regulator comprises a screw for adjusting a compression of the resilient member.
• the piston comprises a first face oriented in front of the regulating valve and delimiting the regulating chamber, and a second face opposed to the first one, said second face being in contact with the movable closure element.
• said regulator comprises a residual pressure valve with a first annular contact surface on the piston and a second annular contact surface on the body, both first and second surfaces being in the regulating chamber and configured to be brought in mutual contact by the resilient member for closing said valve; wherein the first and second annular contact surfaces are located at the periphery of the piston and the chamber, respectively.
• the periphery of the piston or the chamber means an outer annular portion that comprises the periphery of said piston or chamber. By outer annular portion it is meant that this portion is distant from a central portion that can correspond to 50% of the diameter of the piston or chamber.
• the body comprises in the regulating chamber a central portion that protrudes towards the piston and houses the seat of the regulating valve, the second annular contact surface of the residual pressure valve surrounding said central portion.
• the second annular contact surface of the residual pressure valve is set back relative to a distal end of the central protruding portion of the body, preferably at a distance of more than 3mm, more preferably at a distance of more than 6mm.
• the second annular contact surface of the residual pressure valve is formed on a ring that is slip on the central protruding portion of the body.
• the ring can be attached to the body by various fastening means.
• said regulator comprises a seal between the ring and the central protruding portion of the body, said seal being housed in a groove on an inner surface of said ring or on an outer surface of said portion.
• the inner surface of the ring and the outer surface of the central protruding portion of the body are cylindrical and contact each other.
• the regulating chamber forms an annular cavity around the central protruding portion of the body, the ring being located in said cavity and providing a passage for the gas between an external surface of said ring and an internal surface of said cavity.
• a bottom surface of the ring and/or a bottom surface of the cavity of the regulating chamber comprises at least one passage for the gas towards the central protruding portion of the body.
• the second annular contact surface of the residual pressure valve is on a portion of the body that is integral and forms the regulating chamber.
• the first annular contact surface of the residual pressure valve is on an annular shoulder portion of the piston, said portion being toward a bottom of the regulating chamber.
• the piston comprises a central disk- shaped portion, the annular shoulder portion extending from the central disk-shaped portion and forming a groove that opens radially outwardly, said groove housing a seal that is configured for sliding along an inner cylindrical surface of the body and delimit the regulating chamber.
• the annular shoulder portion of the piston extends along the central protruding portion of the body.
• the second annular contact surface of the residual pressure valve is formed by a seal, preferably of the O-ring type, housed in a groove.
• the residual pressure valve is configured to close when the pressure at the inlet is below a threshold that is comprised between 1 and 10 bar, preferably between 2 and 5 bar.
• the closure member of the regulating valve comprises a rod that extends through the seat and rigidly attached to the piston.
• the invention is particularly interesting in that it provides a regulator with a regulating valve where the closure member is upstream of the seat, i.e. in the high pressure of the inlet, and with an integrated pressure relief valve.
• the latter can present a larger active surface and thereby be more sensitive by opening at a lower pressure.
• the compression of the resilient member can be adjusted for adjusting the outlet pressure.
• the adjustment of the outlet pressure via the compression of the resilient member automatically adjusts the threshold of the pressure relief valve. Indeed, upon increase of the compression of the resilient member, the outlet pressure and automatically also the relief pressure are increased.
• the presence of a chamber in the pressure relief valve guarantees that the gas pressure is applied to the whole active surface of the valve.
• the invention is further particularly interesting with regard to the residual pressure valve in that providing the first and second annular contact surfaces at the periphery of the piston and of the chamber results in a larger active surface on which the pressure of the gas results in an opening force of the valve.
• the residual pressure can therefore be lower.
• the fact of providing these first and second annular contact surfaces at the periphery of the piston and of the chamber avoids the conical engagement of the prior art (WO 2014/009279 A1 ) which is bulky (longitudinally) and which can remain stuck under certain circumstances.
• the invention provides the advantage that the central protruding portion can be designed with more freedom, e.g. the seat of the regulating valve can be mounted from the top of said portion.
• the invention makes profit of free space at the periphery of the piston and chamber that is anyway available, resulting in a more compact design.
• the use of a ring attached to the body for forming the second annular surface is interesting in that it provides more freedom for the passage of gas downstream of the residual pressure valve.
• Figure 1 is a sectional view of a regulator according the invention in an open state and where the pressure relief valve is closed.
• Figure 2 corresponds to figure 1 where the opposed other half of the regulator is represented and the pressure relief valve is opened.
• Figures 1 and 2 are sectional view of a regulator with a residual pressure valve in accordance with the invention.
• the residual pressure valve is in an open state and the pressure relief valve is closed whereas in figure 2 the pressure relief valve is opened.
• the regulator 2 is a pressure reducer for compressed gas. It comprises a body 4 with an inlet 6 and an outlet 8 which are only schematically represented.
• the regulator can indeed by integrated into a device with additional functions like a shut-off valve, a flow selector, an anti-refill device, a pressure indicator and/or a remaining usage time indicator.
• the inlet and outlet of such an integrated device can therefore be distant from but anyway in connection with the schematic inlet and outlet represented in figure 1.
• the body 4 comprises a channel 10 interconnecting the inlet 6 with the outlet 8. The normal gas flow is from the inlet 6 to the outlet 8.
• the regulator 2 comprises also a regulating valve 12 arranged in the channel 10.
• the regulating valve 12 comprises a seat 12 1 located in the channel 10 and a closure member 12 2 designed for cooperating with said seat 12 1 . More particularly, the closure member 12 2 is located on the upstream side of the seat, i.e. is located in the high pressure of the inlet 6.
• the seat 12 1 is attached to the body 4 by means of a blocking screw 12 3 and preferably by means of one or several centring washers.
• the regulating valve 12 is housed in a central portion 4 1 of the body 4 that protrudes in a regulating chamber 14 towards a piston 16.
• the regulating chamber 14 is directly downstream of the regulating valve 12 and is delimited by the body 4 and the body 4.
• the piston comprises a central disk-shaped portion 16 1 . It can also comprise on the face delimiting the regulating chamber 14 an annular shoulder portion 16 2 extending axially away from the disk-shaped portion 16 1 . That annular shoulder portion 16 2 forms a groove on the external peripheral surface of the piston 16, said groove housing a seal 16 3 that is configured for sliding along a cylindrical surface of the body 4.
• the closure member 12 2 of the regulating valve 12 is advantageously rigidly attached to the piston.
• the piston 12 is urged towards the valve 12 by means of the spring 18.
• This spring 18 located on the side of the piston 12 that is opposite to the regulating valve 12.
• the spring 18 is held by an adjusting screw 20 engaged in a cap 22 that is attached to the body 4.
• the adjusting screw 20 is held in position by means of a counter-nut 24.
• the spring 18 contacts the piston 12 via a pressure plate 26, a ball 28 and a closure element 30 that contacts the piston in a gas tight manner.
• the ball 28 rests in opposite recesses formed in the pressure plate 26 and the closure element 30.
• the closure element 30 and the piston 16 form a pressure relief valve.
• the piston 16 comprises in its central portion 16 1 at least one communication hole 16 4 for communication the pressure in the regulating chamber 14 and the outlet 8 to the opposite side of the piston and therefore to the closure element 30.
• the closure element 30 can move slightly away from the piston 16 and allows gas to escape and limit the outlet pressure. This situation is illustrated in figure 2 where the flow of gas escaping radially and outwardly between the piston 16 and the closure element 30 is illustrated by two arrows.
• the pressure relief valve can form a chamber 31 between the closure element 30 and the piston 16. To that end, at least one of the faces of the element 30 and of the piston 16 that are in vis-a-vis is recessed.
• the height of the chamber can be of at least 0.5mm or 1 mm.
• the movable closure element 30 can comprise a disk-shaped central portion 30 1 . That central portion can be generally flat.
• the movable closure element 30 can also comprise a cylindrical wall 30 2 extending axially from the central portion 30 1 towards the spring 18.
• the external surface of that wall 30 2 forms a guiding surface along a fixed cylindrical surface of the body 4. For instance that surface is the inner surface of the screw 20.
• the central portion 30 1 of the movable closure element 30 can also comprise a groove housing a seal 30 3 for contacting the piston 16 and delimiting in a gas tight manner the chamber 31.
• the regulator 2 can comprise also a residual pressure device 32 comprising a first annular contact surface 32 1 on the piston 12 and a second annular contact surface 32 2 on the body 4. More particularly, the second annular contact surface 32 2 can be a seal that is housed in a groove formed in the body or on a separate ring 34 attached to the body 4. The ring 34 is slip on the central protruding portion 4 1 of the body 4 in a gas tight manner. To that end, the outer surface of the central protruding portion 4 1 and the inner surface of the ring contact each other and at least one of them can comprise a groove housing a seal 34 1 .
• the second annular contact surface 32 2 of the residual pressure valve 32 can be at another level than the distal end of the central protruding portion 4 1 of the body 4, for instance deeper in the annular cavity between the central protruding portion 4 1 and the chamber 14. Also the annular shoulder portion extends axially into that annular cavity. This provides a clear advantage of compactness.
• the spring 18 tends to close the residual pressure valve by moving the piston 12 towards the regulating valve 12 so that the first annular contact surface 32 1 on the piston 12 contacts in a gas tight manner the second annular contact surface 32 2 on the body 4 (for instance the ring 34).
• This situation does not occur as long as the pressure in the regulating chamber is above a predetermined threshold that corresponds to the closing pressure of the residual pressure valve 32.
• This threshold is determined by the geometry of the residual pressure device and also by the characteristics and pre-constraint of the spring 18. This situation is illustrated in figure 1 where the regulating valve 12 is partially opened.
• the gas under pressure at the inlet can flow through the regulating valve 12 to the chamber 14 and then flows from said chamber 14 radially outwardly between the first and second annular contact surfaces 32 1 and 32 2 of the residual pressure valve 32.
• the gas flows then along the channel section 10 1 , between the outer surface of the ring 34 and the cavity housing the ring and forming the chamber.
• the bottom of the cavity housing the ring 34 is raised and comprises passages (not visible) that allow the gas to flow along the channel section 10 2 radially inwardly towards the central protruding portion 4 1 of the body 4.
• a drilled hole can extend from there towards the outlet or a further function that might be integrated in the regulator. For instance, this could be a flow selector (not represented).
• the gas passage does not necessarily need to circumvent the outer surface of the ring 34 as illustrated in figure 1. Indeed, one or several drilled holes can be made in the wall of the body 4 delimiting the cavity in order to guide the gas towards the next downstream function (if any) or the physical outlet.
• the first annular contact surface 32 1 on the piston 12 contacts in a gas tight manner the second annular contact surface 32 2 on the body 4 when the regulator supplies gas to a consumer and, further to said supply, the pressure in the container, e.g. a gas cylinder, drops down below a predetermined threshold that corresponds to the closing pressure of the residual pressure valve 32.
• This pressure can be comprised between 1 and 10 bar, preferably between 2 and 5 bar.

Landscapes

• Physics & Mathematics (AREA)
• Engineering & Computer Science (AREA)
• Fluid Mechanics (AREA)
• General Physics & Mathematics (AREA)
• Automation & Control Theory (AREA)
• General Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Control Of Fluid Pressure (AREA)
• Safety Valves (AREA)

Applications Claiming Priority (2)

Publications (1)

Family

ID=56008838

Family Applications (1)

Country Status (3)

Families Citing this family (2)

Family Cites Families (7)

• 2016
  • 2016-05-09 LU LU93061A patent/LU93061B1/en active IP Right Grant
• 2017
  • 2017-05-05 EP EP17721177.8A patent/EP3455692A1/de not_active Withdrawn
  • 2017-05-05 WO PCT/EP2017/060836 patent/WO2017194429A1/en unknown

Also Published As

Similar Documents

Legal Events