FR3133320A1 - Improved Integrated Regulator Gas Container Faucet - Google Patents

Abstract

Title of the invention Valve for gas container with improved integrated regulator The invention relates to a valve with integrated regulator (1) or RDI for a pressurized gas container comprising a valve body (2) comprising: a gas circuit (15) , gas expansion means (100) comprising an expansion valve (101) movable axially (XX) within a first chamber (107) and cooperating with a valve seat (102). A second chamber (109) is located downstream of the first chamber (107) and connected to the first chamber (107) via a connecting channel (110). The seat element (104) includes a gas passage (103) coaxial with the connecting channel (110). The valve seat (102) is arranged around the periphery (103a) of the inlet port of the gas passage (103). Pressurized gas container (50) comprising such an integrated regulator valve (1), in particular a gas cylinder, and its use for storing a gas or a gas mixture, typically oxygen. Abstract figure: Fig. 4

Description

Improved Integrated Regulator Gas Container Faucet

The invention relates to an integrated regulator valve (RDI) for a pressurized gas container, as well as a pressurized gas container, such as a medical oxygen cylinder equipped with such an RDI and its use for storing a gas or gas mixture under pressure, in particular oxygen.

An integrated regulator valve (RDI) fitted to a pressurized gas container, such as a gas cylinder, makes it possible to control not only the expansion of the pressurized gas but also the subsequent distribution of the gas at reduced pressure, i.e. tell its flow.

To control the gas expansion, expansion means are integrated into the body of the valve. They are arranged on the internal gas circuit of the RDI which conveys the gas from an inlet in fluid communication with the pressurized gas container and a gas outlet carried by an outlet connector, that is to say a nozzle, or the like. In this respect, we can cite EP-A-1512895, EP-A-3851733, EP-A-3382259, EP-A-3643958 and EP-A-3191764 which describe RDIs fitted to gas cylinders.

The expansion means usually include a movable expansion valve cooperating with a valve seat to operate the expansion of the gas, that is to say to reduce its pressure level from a so-called “high” pressure or high pressure (HP) corresponding to the pressure of the gas when it is compressed in the container, up to a so-called “low” pressure or low pressure (LP) corresponding to the operating pressure, that is to say a BP pressure less than high pressure HP, for example a HP between 100 and 300 bar abs (for a full container) and a BP obtained after expansion, less than 10 bar abs.

However, it has been observed in practice that conventional RDIs can pose problems of sealing and/or incorrect expansion, particularly between the valve and the seat, particularly over time and wear of these elements causing irreversible damage. leading to reliability problems which can be aggravated by the temperature and/or pressures used.

In this context, a problem is therefore to propose a valve with an integrated regulator or improved RDI, i.e. making it possible to avoid the aforementioned disadvantages affecting the expansion valve and the valve seat.

A solution according to the invention relates to a valve with an integrated regulator (RDI), in particular for a pressurized gas container, such as a pressurized gas cylinder, comprising a valve body comprising:

• a gas circuit for conveying a gas under pressure between a gas inlet and a gas outlet,
• gas expansion means arranged on the gas circuit comprising an axially movable expansion valve (XX) within a first chamber and cooperating with a valve seat, and
• a second chamber located downstream of the first chamber and in fluid communication with said first chamber via a connecting channel comprising an inlet orifice arranged in a bottom of the first chamber,

characterized in that:

• a seat element comprising a gas passage is arranged in the bottom of the first chamber so that the gas passage of the seat element and the connecting channel connecting the first chamber to the second chamber are coaxial (XX), And
• the valve seat is arranged around the gas passage inlet port of the seat member.

Depending on the embodiment considered, the RDI according to the invention may comprise one or more of the following characteristics:

• the expansion valve is arranged on an axially movable valve stem (XX).
• said valve stem comprises a front part extending through the gas passage of the seat element and the connecting channel connecting the first chamber to the second second, and further comprising a free end projecting into the second second .
• the valve stem carrying the seat valve is normally pushed towards the seat member by a valve spring.
• the seat valve and the valve seat are configured to cooperate with each other to provide gas expansion, that is, a reduction in gas pressure.
• the seat valve and the valve seat are shaped to be complementary to each other so as to be able to ensure gas expansion or, conversely, fluid sealing between them.
• the gas expansion means are configured to reduce the pressure of the pressurized gas circulating in the gas circuit, that is to say high pressure gas (HP), and obtain a gas at reduced pressure, that is to say a low pressure gas (LP), where the reduced pressure obtained (i.e. pressure of the expanded gas or LP gas) is lower than the starting pressure, i.e. the pressure of the gas HP.
• the high pressure (HP) gas has a starting pressure or high pressure (HP) of at least 20 bar abs, preferably at least 100 bar abs, more preferably at least 150 bar abs, more preferably at least 200 bar abs, more preferably at least 250 bar abs, for example of the order of 300 bar abs.
• the expanded gas or LP gas has an expansion pressure of less than 10 bar abs, typically less than 6 bar abs.
• it comprises a guide part arranged within the first chamber, the valve rod carrying the seat valve being movable axially (XX) within said guide part.
• the seat element is sandwiched and held between the guide piece and the bottom of the first chamber.
• a sealing element is arranged between the seat element and the bottom or an internal wall of the first chamber.
• the guide part includes a valve chamber open and facing the seat element.
• the expansion valve carried by the valve rod is movable in axial translation in the valve chamber of the guide part.
• the guide part is pushed back towards the seat element by a housing part comprising a front bore through which the rear part of the valve stem 111 passes.
• the housing part is itself held in position by a cover part which is attached to the housing part, for example in the manner of a sleeve.
• the living room is located in the first bedroom of the RDI.
• the cover piece is arranged in the first chamber of the RDI.
• the first chamber of the RDI is open outwards at an end opposite its bottom carrying the inlet orifice of the connecting channel between the first and the second chamber.
• the cover piece is arranged and fixed in the first chamber via the opening towards the outside of the first chamber.
• the cover part forms a bottom wall allowing the internal compartment of the housing part to be closed.
• the valve stem is normally pushed towards the valve seat by the valve spring, via an actuating part arranged between the valve spring and the rear part of the valve stem.
• the housing part comprises an internal housing in which the actuating part and the valve spring are arranged.
• the internal housing of the housing part is open on the side of the cover part, said cover part compressing the valve spring in said internal housing of the housing part, that is to say pushing it in the direction of the seat element carrying the valve seat.
• the seat element is made of polymer material, preferably a polymer of the polyamide, polyimide or other type.
• the seat element is made of polymer material whose polymer fibers are oriented axially.
• the seat element has the general shape of a disc pierced in its center by the gas passage.
• the seat element has a general disc shape comprising a groove or a peripheral shoulder for housing the sealing element.
• the seat member has an external diameter of 4 to 20 mm, a thickness of 1 to 6 mm, and an internal diameter of the gas passage of 0.5 to 5 mm.
• the sealing element is an O-ring or the like.
• it further comprises a trigger adjustment system comprising a trigger piston cooperating with a piston spring, arranged in the second chamber.
• the piston spring normally pushes the expansion piston towards the outlet of the connecting channel located in the second chamber
• the expansion piston is configured to interact with the free end of the front part of the valve stem, in particular via a front shield associated with said expansion piston.
• the gas inlet of the gas circuit is located on a threaded end of the valve body, which end is intended to be fixed by screwing to the gas container.
• the gas outlet of the gas circuit is located on a gas outlet fitting.
• the piston spring and the valve spring are made of steel.
• the piston spring and the valve spring are helical.
• the front shield has a disc shape and includes a central part that cooperates with the free end of the valve stem.
• the movable expansion piston has a tubular shape with axis AA and comprises a peripheral annular shoulder forming a piston head.
• the trigger spring presses on the peripheral annular shoulder of the trigger piston.
• the detent spring normally pushes the detent piston toward the valve stem.
• the trigger spring, the trigger piston, the valve spring and the valve rod are arranged coaxially.
• a rear cover closes the second chamber where the trigger spring and the trigger piston are arranged
• the rear cover has the shape of a bell, cup or the like.
• the rear cover cooperates with the trigger spring to set or adjust the level of trigger pressure.
• the rear cover is screwed to the RDI body.
• The trigger pressure level is adjusted by screwing or unscrewing the rear cover on the RDI body.
• the rear cover is tapped.
• the rear cover has a bell, cup or similar sleeve shape around at least part of the trigger spring.
• the bottom of the rear cover includes one or more gas evacuation ports communicating with the outside atmosphere.
• the gas circuit includes one or more internal gas passages passing through the valve body.
• the expanded gas outlet orifice is carried by a connector or end piece configured to allow the fluid connection, direct or indirect, of an appliance or device using the gas, typically via a flexible conduit carrying the gas from the RDI to the appliance or device, preferably a medical apparatus or device.
• the gas expanded by the gas expansion means has a pressure lower than the pressure of the gas under pressure before expansion, i.e. not expanded.
• the faucet body is made of brass.
• a spacing or clearance is provided between the external peripheral surface (i.e. the perimeter) of the seat element and the internal wall of the guide part so as to ensure good self-centering between the valve and the valve seat.

The invention further relates to a pressurized gas container comprising an integrated regulator valve (RDI) according to the invention, in particular a gas cylinder.

Preferably, the gas container comprises a protective covering arranged around the RDI so as to protect it against shocks or the like.

The invention further relates to a use of a pressurized gas container, in particular a gas cylinder, equipped with an RDI according to the invention for storing a gas or a gas mixture chosen from oxygen, air, N ₂ O /O ₂ , He/O ₂ , NO/nitrogen, typically oxygen.

The invention will now be better understood thanks to the following detailed description, given by way of illustration but not limitation, with reference to the appended figures among which:

represents a 3/4 view of an embodiment of an integrated regulator valve (RDI) according to the invention,

is a side view of the RDI of ,

is a sectional view of the RDI of And showing the means of gas expansion,

is a magnified view of ,

is an analogous view of ,

illustrates the installation of an integrated regulator valve (RDI) on a gas cylinder,

represents an embodiment of a seat element of the gas expansion means of a valve with an integrated regulator according to the invention, and

schematizes (sectional view) the cooperation between the valve stem and the seat element.

And represent an embodiment of a valve with integrated regulator 1 or RDI according to the invention used for the distribution of gas, which comprises a valve body 2 formed of metal, for example brass, namely a CuZn40Pb2 alloy or other.

The RDI 1 comprises, as detailed below, gas expansion means 100, that is to say pressure reduction means, making it possible to carry out expansion of the gas under pressure, that is to say say a reduction in the gas pressure from a high pressure value of several tens, or even hundreds of bar abs, to a low pressure value, that is to say a relaxation pressure level. The relaxation pressure level, that is to say after pressure reduction, can be fixed or adjusted by means of the pressure reduction means 100, as explained below with reference to the has , for example of the order of a few bars (ie < 10 bar abs), for example of the order of 4.5 bar abs.

The valve body 2 is crossed by an internal gas circuit, that is to say one or more passages or conduits, making it possible to convey the gas, namely a high pressure gas and the expanded gas, between a fluid inlet 10 carried by an expansion or threaded end piece 3, of cylindrical or frustoconical shape, used to fix the RDI 1 on a gas bottle 50 as illustrated in , and a fluid outlet 40, namely a flow outlet 11, carried by a first outlet connection 12 supplying low pressure gas (LP).

The threaded end 3 allows the valve body 2 to be screwed to a gas container 50, such as a gas bottle, as illustrated in , containing the gas under pressure, ie at high pressure, in its pointed body 51 (partially visible) comprising an internal volume supplying the RDI 1.

Optionally, the body 2 of the RDI 1 can also include another fluid outlet 13, typically a so-called pressure outlet, carried by another outlet connection 14, which supplies the non-expanded gas, that is to say at high pressure.

The gas expansion means 100, also called pressure reduction means, are arranged on the internal gas circuit 15 of the body 2, between the gas inlet 10 of the RDI 1 and the gas outlet 11 at low pressure (LP ), also called flow outlet, carried by the outlet connection 12, that is to say the flow outlet connection.

The outlet connectors 12, 14 are made of a metal, such as a copper alloy, in particular brass, for example an alloy of the CuZn39Pb3 type. They have general tubular shapes, i.e. elongated with axial passage for the gas communicating fluidly with the internal fluid circuit of the body 2 and opening out at the outlet orifices 11, 13.

Furthermore, the body 2 of the RDI 1 is also equipped with a pressure gauge 4 making it possible to visualize the gas pressure in the internal gas circuit 15 of the body 2, upstream of the expansion means 100 so as to reflect the residual pressure at its internal volume of the container 50 of pressurized gas.

On the And , the pressure gauge 4 is of the needle type, while on the , the pressure gauge 4 is digital, that is to say it is an electronic device with a digital display, implementing one (or more) microprocessor associated with one or more temperature and/or pressure sensors. pressure and making it possible to determine the gas pressure, or even other quantities, such as gas autonomy or a volume of residual gas in the container 50, then to display them on the digital display.

The body 2 of RDI 1 also carries a flow adjustment member 5, such as a rotary wheel, cooperating with flow control means so as to allow a user to adjust the flow rate of fluid delivered by the connection 12 for distributing the fluid. fluid, typically flow rates of between 0 and 30 L/min, preferably between 0 and 15 L/min, or even 20 L/min. The flow control means may include, for example, a disk with calibrated orifices of different dimensions, i.e. diameters, which correspond to the different selectable gas flow rates.

In the embodiments of And , the flow adjustment member 5 is a rotating handwheel that can be manipulated by the user, which is arranged around and coaxially with the fluid distribution connector 41. The rotary wheel 5 has the general shape of a graduated crown marked by flow rate indications. It comprises housings offset angularly from each other and dimensioned to allow a user to insert fingers therein in order to exert a movement aimed at turning the rotary wheel 5 clockwise or counterclockwise to set the desired gas flow. As can be seen, the outlet connector 12 carrying the gas outlet 11 at low pressure is arranged in the center of the rotating flywheel 5; however, the outlet connection 12 could be arranged elsewhere.

The faucet body 2 also includes other components, such as a filling connection 6, that is to say an additional connection, configured to receive a filling socket which is connected to it mechanically and fluidically in order to allow introduce fresh fluid into the internal volume of the fluid container 50 when it is empty for example. This filling connection includes a filling valve preventing, under normal circumstances, the escape of fluid through this connection. The filling connection is in fluid communication with the internal volume of the container 50 via the internal gas circuit 15 of the body 2 of the RDI 1 and the inlet orifice 10 carried by the threaded end piece 3.

The valve body 2 may also include a residual pressure mechanism (not shown) making it possible to guarantee or maintain a minimum positive pressure in the container 50 by preventing total emptying thereof, that is to say total withdrawal of the fluid, as well as a safety valve 7 including the expansion piston 122, as explained below, making it possible to evacuate any excessive pressure in the gas circuit 15 of the valve body 2, that is to say to evacuate to the atmosphere any pressure greater than a safety threshold value, for example in the event of an internal leak from the valve body 2.

schematizes an RDI 1 according to the invention mounted on a fluid container 50 of the gas bottle type in the shape of an ogive, that is to say with a container body 51 of cylindrical shape (of axis AA) comprising an end narrowed forming a neck carrying a threaded opening communicating fluidly with the internal volume of the gas bottle. The RDI 1 is fixed by screwing, via its threaded end 3, into the tapped opening in the neck of the fluid container 50.

The hollow cylindrical body of the container 60 comprises an internal volume used to contain the gas under pressure, that is to say at high pressure, typically a compressed medical gas, such as oxygen, at a pressure which can reach 180 to 300 bar abs, or even more (when the bottle is full). The internal volume can have a capacity of 0.5 to 10 L (water equiv.), for example 2 L, 5 L or 7 L. Its diameter is of the order of 10 to 20 cm, typically of the order from 12 to 16 cm, for example approximately 14 cm.

Furthermore, we see that the body 2 of the RDI 1 is protected here by a protective covering 55 comprising a rigid body, made of polymer or metal, defining a protective enclosure in which the valve body 2 of the RDI 1 is positioned (not visible) and fixed to it or to the neck of the bottle 50 by its base 56.

The cover 55 also comprises a carrying handle 58 surmounting the body and connected to it by support posts 59 in order to allow a user to manually lift and transport the cover/RDI/bottle assembly 55, 1, 50 The carrying handle 58 is located opposite the base 56 relative to the cowling body.

Preferably, a pivoting attachment device 57 is also provided (partially visible) located here opposite the RDI 1 outlet connection 11. This pivoting attachment device 57 is used to attach the cowling/cover assembly. RDI/bottle on a hospital bed or stretcher bar or any other similar support, for example rod or other. The hooking device 57 can pivot, when it is unfolded by the user, between a folded position or rest position, in which it is positioned along the cowling body, as illustrated in , and an unfolded position or hooking position, in which the hooking device 57 is pivoted and angularly spaced from the covering body so as to allow it to be secured or hooked to a bed bar or the like. Such a pivoting hooking device 57 is described by EP-A-2918893

More generally, the gas under pressure is introduced into the internal volume, when filling the container 50, via the filling connection 7 and the upstream portion of the internal circuit 15 of the RDI 1 and through the neck of the container 50. Extraction gas under pressure, when drawn off, is done in the opposite direction.

When in use, flexible pipes, metal or plastic, or other interfaces or devices can be connected and disconnected to the fitting(s) 12, 14 of the RDI 1, which can be nickel plated, i.e. covered a nickel-based coating deposited on the brass forming these connections 12, 14.

has are sectional diagrams of the pressure reduction means 100 of the RDI 1 according to the invention.

As mentioned above, these gas expansion means 100 are arranged on the internal gas circuit 15 passing through the body 2 of the RDI 1 and serve to reduce the pressure of the gas under pressure, that is to say a relaxation of the gas. gas, circulating in the gas circuit 15 and obtaining an expanded gas, that is to say at reduced pressure. During this expansion, the pressurized gas passes from the high pressure (i.e. which is equivalent to the pressure in the bottle) to a preset low pressure, typically less than 10 bars abs.

As illustrated in , the gas expansion means 100 arranged in the body 2 of the RDI 1 comprise a movable expansion valve 101 cooperating with a valve seat 102 to operate a gas expansion.

The expansion valve 101 is carried by a valve stem 111 which is normally pushed towards the valve seat 102 by a valve spring 106, via an actuating part 112 arranged between the valve spring 106 and the valve stem 111 carrying the expansion valve 101. The valve spring 106 therefore presses on the actuating part 112 and the latter itself presses on the rear part 111b of the valve rod 111.

As visible on And , the trigger spring 106 has a spring body formed by turns and of generally cylindrical shape, while the actuating part 112 comprises a tubular body which is housed in the center of the cylinder forming the body of the spring 106 and a radial shoulder at the the free end of the tubular body on which the terminal end of the body of the cylindrical spring 106 rests. The terminal end of the rear part 111b of the valve stem 111 is housed in the front face of the actuating part 112.

Furthermore, we see that the actuating part 112 and the trigger spring 106 are arranged in the internal compartment 113b of a hollow housing part 113 comprising a front bore 113a crossed by the rear part 111b of the valve stem 111 The housing part 113 is itself held in position by a cover part 114 which is fixed to the housing part 113 like a sleeve. The cover part 114 also forms a bottom wall making it possible to close the internal compartment 113b of the housing part 113 which houses

The valve stem 111 and the expansion valve 101 therefore form a set of movable valve 101, 111 axially (axis XX) within a first chamber 107 or high pressure chamber of the body 2 of the RDI 1 which is supplied with gas at high pressure (HP). More precisely, the valve assembly 101, 111 is movable while being guided by a guide part 108 arranged within the first chamber 107. The rear part 111b of the valve rod 111 and the expansion valve 101 are arranged in a valve chamber 118 of the guide part 108, which valve chamber 118 is open facing a seat element 104 with which the expansion valve 101 cooperates, as explained below.

The first chamber 107 or high pressure chamber of the body 2 of the RDI 1 is supplied by high pressure gas (HP) which enters it through an HP gas supply port 119. It communicates fluidly with a second chamber 109 or low pressure chamber (LP) of the body 2 of the RDI 1, via a connection channel 110 for the expanded gas connecting these two chambers 107, 109 comprising an inlet orifice 110a communicating fluidly with the first chamber 107 and an outlet 110b communicating fluidly with the second chamber 109.

The first chamber 107 comprises a seat element 104, arranged in the bottom 117 of the first chamber 10 into which the inlet orifice 100a of the connecting channel 110 opens.

As illustrated in And , the seat element 104 is pierced with a gas passage 103 passing right through the seat element 104 which is arranged coaxially with the connecting channel 110 connecting the two chambers 107, 109. The valve seat 102 is formed on the periphery 103a of the inlet port of the gas passage 103, that is to say, the valve seat 102 is circular/annular.

Preferably, the seat element 104 is a part made of polymer material, for example a polyamide or polyimide type polymer, the polymer fibers of which are oriented axially along the axis XX. Indeed, such an orientation of the polymer fibers makes it possible to minimize the mechanical compressive stresses applying to the valve seat 102 while ensuring a maximum compression rate.

To do this, the polymer part forming the seat element 104 is obtained for example by extrusion of the raw material and machining to obtain the shape.

In addition, good retention of the seat element 104 is guaranteed by simple mechanical contact due to the sandwiching of said seat element 104 between the guide part 108 and the blind bottom 117 of the first chamber 10.

The seat element 104 is a piece of revolution having here the general shape of a disc pierced in its center by the gas passage 103, ie substantially in the shape of a washer, and comprising a groove or a peripheral shoulder or the like 104c on its perimeter exterior serving to accommodate a sealing element 105, as visible on And .

The seat element 104 has for example an external diameter of between 4 and 20 mm, a thickness of between 1 and 6 mm, and an internal diameter of the gas passage 103 of between 0.5 and 5 mm.

The guide part 108 presses axially, via its front face 108a, on the rear face 104a of the seat element 104 to push it back into the blind bottom 117 and therefore hold it in place. The front face 104b of the seat element 104 therefore rests on the blind bottom 117 and the sealing element 105, like an O-ring, is then positioned and itself held between the seat element 104 and the side wall and/or the blind bottom 117 of the first chamber 107, within the peripheral groove or the shoulder 104c or the like.

The rear face 108b of the guide part 108 is itself in contact with the housing part 113. The housing part 113 holds the guide part 108 by pushing it axially (axis XX) towards the element of seat 104.

Note that sealing means 130, such as O-rings, are provided to ensure a gas seal between the housing part 113 and the guide part 108, and between the housing part 113 and the cover part 114.

We see on And that a front part 111a of the valve stem 111 is movable within the gas passage 103 and the connecting channel 110 so that the expansion valve 101, which is carried by the valve stem 111, can cooperate with the valve seat 102 formed on the periphery 103a of the inlet orifice of the gas passage 103 (cf. ) in order to adjust the expansion, that is to say the level of expansion pressure, when the expansion valve 101 is slightly detached from the valve seat 102 or, conversely, to ensure a gas seal between valve 101 and seat 102 when they are in contact with each other.

The cooperation between the valve stem 111 and the seat element 104 is illustrated in . To ensure good self-centering between valve 101 and valve seat 102, it is preferable to provide a small spacing 141, that is to say a clearance, between the external peripheral surface (ie the perimeter) of the element of seat 104 and the cylindrical internal wall of the guide part 108. This spacing 141 will allow the seat element 104 to position itself well in relation to the valve 101 by offering it lateral movement when it is subjected to the force elastic of the trigger spring 106, ie the axial action (XX) of the trigger spring 106 which is directed towards the seat element 104. For example, a spacing of the order of approximately 1 mm but of course, depending of the dimensioning of the other elements, it can be chosen greater or less than approximately 1 mm.

This self-centering ensures that an optimal contact zone 140 is obtained between the valve seat 102 of here frustoconical shape and the valve seat 102 of complementary shape, as shown schematically in , so as to either ensure sealing when no expansion is required or, conversely, to guarantee effective expansion of the gas.

As shown on , And , the inlet of the gas passage 103 is shaped to be flared, that is to say frustoconical. However, the expansion valve 101 must have a complementary shape to the valve seat 102 in order to ensure effective expansion or, conversely, a gas seal, when no expansion is desired. Therefore, the valve seat 102 which is formed on the periphery 103a of the inlet orifice of the gas passage 103 also has a circular shape, or even slightly frustoconical. Furthermore, the expansion valve 101 must also have a complementary frustoconical shape in order to be able to penetrate (partially) into the gas passage 103 of the seat element 104, through the inlet of said gas passage 103, and that its external peripheral surface can cooperate with the circular, or even frustoconical, shape of the valve seat 102.

The trigger pressure is adjusted by a trigger adjustment system 120 comprising a trigger piston 121 comprising an active part or front shield 122 and a piston spring 123 associated with said trigger piston 121, which are arranged in the second chamber 109 arranged in the body of the RDI 1, which is open to the outside so as to be able to insert the various elements of the trigger adjustment system 120.

The expansion piston 121 comprises a piston body 121a of generally cylindrical shape carrying a peripheral annular shoulder 121b extending radially on which rests the proximal end 123a of the piston spring 123 which is arranged like a sleeve around the body of cylindrical piston 121a. The piston spring 123 then normally pushes the expansion piston 121 towards the connecting channel 110 opening into the second chamber 109 through which the low pressure gas (LP) passes.

A rear cover 124 in the shape of a bell, cup or the like makes it possible to house and maintain the various elements 121-123 of the relaxation adjustment system 120 within the second chamber 109 arranged in the body 2 of the RDI 1, as visible on . The distal end 123b of the piston spring 123 presses against the bottom 124a of the rear cover 124. The rear cover 124 further comprises a tapping 125 on its internal wall which is fixed by screwing to a complementary thread 2a provided on the body 2 of RDI 1, as shown in .

The rear cover 124, the expansion piston 121, the piston spring 123 and the front shield 122 are arranged coaxially within the second chamber 109 and also coaxial to the expansion valve 101, to the valve rod 111, to the spring of trigger 106 and seat element 104, as shown in And .

By adjusting the screwing of the rear cover 124, the expansion piston 121 can be moved more or less within the second chamber 109 along the axis XX, that is to say towards or away from the channel. connection 110 opening into the second chamber 109, which makes it possible to adjust the desired pressure level.

Indeed, the front part 111a of the valve stem 111 which is movable within the gas passage 103 and the connecting channel 110, projects axially (axis XX) into the second chamber 109 and is in contact with the front shield 122 of the expansion piston 121. The front shield 122 of the expansion piston 121 then cooperates with the free end 111c of the front part 111a of the valve rod 111 which projects into the second chamber 109, to push it back more or less in the direction of the connecting channel 110, depending on the more or less significant screwing (i.e. clockwise or counterclockwise) applied to the rear cover 124, which makes it possible to adjust the level of relaxation. Thus, any axial movement of the valve stem 111 generates an equal axial movement of the expansion valve 101 which is carried by the valve stem 111, therefore a separation or proportional distance of the expansion valve 101 from its valve seat 102, this which then allows a more or less significant passage of gas, therefore an adjustable relaxation of the pressure level.

The high pressure (HP) gas, for example at approximately 180 to 200 bar abs, enters the first chamber 107 via the HP gas supply port 119, as illustrated in , then into the valve chamber 118 via one (or more) inlet channel 118a which puts the first chamber 107 in fluid communication with the valve chamber 118, according to the gas path shown schematically by arrows F on .

The HP gas then undergoes expansion while passing between expansion valve 101 and valve seat 102, and the lower pressure gas (LP) obtained, for example at approximately 4 or 5 bar abs, then travels successively through the passage of gas 103 from the seat element 104 and the connecting channel 110 to then reach the second chamber 109, before exiting via a LP gas evacuation channel 126 which routes it to the low-pressure gas circuit pressure 127 of body 2 of RDI, as illustrated in .

The low pressure gas circuit 127 then makes it possible to convey the LP gas to the low pressure (LP) gas outlet 11, also called flow outlet, carried by the outlet connection 12, i.e. say the flow outlet connection, visible on And .

The rear cover 124 therefore makes it possible to adjust the preload of the piston spring 123, therefore to adjust the trigger pressure. The constraint adjustment, and therefore the relaxation pressure, is carried out by adjusting the screwing stroke of the rear cover 124.

Preferably, the bottom 124a of the rear cover 124 in the shape of a bell, cup or the like, is pierced with one or more vent orifices 129 communicating with the ambient atmosphere making it possible to evacuate gaseous excess pressures towards the exterior and therefore acts as a safety valve 7.

In other words, the expansion piston 122 and the expansion spring 121 serve not only to adjust the gas expansion pressure level but also as a safety valve 7 making it possible to evacuate any possible or accidental overpressure, after expansion, it is that is to say any BP greater than a desired threshold value or safety pressure.

Indeed, in the event of gas overpressure greater than the thrust force of the piston spring 123, the expansion piston 121 which is movable, will be pushed back towards the rear cover 124 and the front shield 122 will then be detached from the seal. seal 128, such as an O-ring, which normally ensures a gas seal between the periphery of the front shield 122 and the peripheral internal wall of the second chamber 109. This rupture of seal will allow the gas under excess pressure to pass through the system of relaxation adjustment 120 until reaching the venting orifices 129 passing through the bottom wall 124a of the rear cover 124, and thus being evacuated to the outside, that is to say the ambient atmosphere.

A pressurized fluid container 50 equipped with an RDI 1 according to the invention is well suited to use for storing a medical grade gas or gas mixture of the oxygen, air, N ₂ O/O ₂ , He/O type. ₂ , NO/nitrogen, typically oxygen.

Claims (11)

Valve with integrated regulator (1) for pressurized gas container (50) comprising a valve body (2) comprising:

• a gas circuit (15) for conveying a gas under pressure between a gas inlet (10) and a gas outlet (11),
• gas expansion means (100) arranged on the gas circuit (15) comprising an expansion valve (101) movable axially (XX) within a first chamber (107) and cooperating with a valve seat (102 ), And
• a second chamber (109) located downstream of the first chamber (107) and in fluid communication with said first chamber (107) via a connecting channel (110) comprising an inlet orifice (110a) arranged in a bottom (117) ) of the first chamber (10),

characterized in that:

• a seat element (104) comprising a gas passage (103) is arranged in the bottom (117) of the first chamber (10) so that the gas passage (103) of the seat element (104) and the connecting channel (110) connecting the first chamber (107) to the second chamber (109) are coaxial (XX), and
• the valve seat (102) is arranged on the periphery (103a) of the gas passage inlet port (103) of the seat element (104).

Valve according to claim 1, characterized in that the expansion valve (101) is arranged on an axially movable valve stem (111) (XX), said valve stem (111) comprising a front part (111a) extending through the gas passage (103) of the seat element (104) and the connecting channel (110) connecting the first chamber (107) to the second second (109), and further comprising a free end (111c ) projecting into the second second (109). Valve according to one of claims 1 or 2, characterized in that the valve stem (111) carrying the seat valve (101) is normally pushed towards the seat element (104) by a valve spring ( 106). Faucet according to claim 1, characterized in that it comprises a guide part (108) arranged within the first chamber (107), the valve rod (111) carrying the seat valve (101) being movable axially ( XX) within said guide piece (108), the seat element (104) being sandwiched and held between the guide piece (108) and the bottom (117) of the first chamber (10). Tap according to one of the preceding claims, characterized in that a sealing element (105) is arranged between the seat element (104) and the base (117) or an internal wall of the first chamber (10). . Faucet according to one of the preceding claims, characterized in that the seat element (104) is made of polymer material, preferably a polymer whose polymer fibers are oriented axially. Faucet according to one of the preceding claims, characterized in that the seat element (104) has the general shape of a disc pierced in its center by the gas passage (103). Faucet according to claim 7, characterized in that the seat element (104) has a general disc shape comprising a groove or a peripheral shoulder (104c) for housing the sealing element (105). Valve according to claim 1, characterized in that it further comprises a relaxation adjustment system (120) comprising a relaxation piston (121) cooperating with a piston spring (123), arranged in the second chamber (109) , said piston spring (123) normally pushing the expansion piston (121) towards the outlet orifice (110b) of the connecting channel (110) located in the second chamber (109) said expansion piston (121) being configured to interact with the free end (111c) of the front part (111a) of the valve stem (111). Pressurized gas container (50) comprising an integrated regulator valve (1) according to one of the preceding claims, in particular a gas cylinder. Use of a pressurized gas container (50) equipped with an RDI (1) according to claim 10 for storing a gas or a gas mixture chosen from oxygen, air, N ₂ O/O ₂ , He/O ₂ , NO/nitrogen, typically oxygen.