DE2313710A1 - GAS RELEASE REGULATOR - Google Patents

Description

Throttle control

The invention relates to gas delivery regulators, and more particularly to a device for controlling variables of the gas delivery from such regulators.

It is known to those skilled in the art that, in the case of gas delivery regulators that respond to ambient pressure, this is desirable with increasing altitude is that a slight positive pressure, often referred to as a "security pressure", should be generated first, and that this pressure should be maintained in the pilot's mask so that it can penetrate inwards around the edges around is prevented. Furthermore, it is often necessary that, at lower altitudes, release oxygen by adding is diluted by ambient air, but this must be reduced or completely prevented with increasing altitude. at

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Heights above, for example, 11,500 m, it is necessary that Another positive pressure is maintained in the mask and sometimes in pressure suits, a condition that is common referred to as "pressure breathing".

In the case of pressurized gas delivery regulators which are based on ambient pressure conditions address and the a "safety pressure", air dilution and "pressure breathing", it is common nowadays for each of these three functions to be controlled by independently operating ones Control aneroids. In order to prevent working with a phase deviation of the three separate aneroids, which is due to The applicant suggests that various causes can occur, for example through vibration, wear and tear or soiling a dispensing regulator operated by a single aneroid without limiting other requirements. This also results in cost savings, a reduction in size and weight, and simple maintenance and longer intermediate periods between two consecutive overhauls.

According to the invention, in a pressurized gas delivery regulator, in which a single aneroid acts on a pressure control valve that regulates the gas pressure in several chambers, proposed that a device in a first chamber operates a flow control valve to allow gas to be delivered to a consumer component is carried out that a second chamber that opens into the environment is a device for further actuation of the flow control valve and that a third chamber is provided with an actuating device for controlling an air inlet is to mix the air with for consumer parts to allow flowing gas.

The invention is described below in conjunction with the drawing explained using two exemplary embodiments. The figures show:

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Pig. 1 is a partial view of a gas delivery regulator according to one embodiment of the invention, and

FIG. 2 schematically shows a partial view of a gas delivery regulator according to FIG another embodiment of the invention.

The regulated, tapped gas provides pneumatic energy to achieve the variable.

In Fig. 1, an aneroid can 10 is within an outflow chamber 11 of an oxygen delivery regulator 12 for use in a Pilot provided when connecting through 'an outlet 42 is made with a mask or a corresponding device. The free end of the can 10 receives a valve plate 13 which cooperates with a valve seat 14; an outflow valve 15 is thereby formed. From the valve plate 13 extends through the mouth of the valve seat 14- and in a valve chamber 16, an arrangement which receives a flange 17 which is provided with the arm of a sealing valve 18 (pad valve) comes into engagement. Furthermore, a compression spring rests against a solenoid valve plate 20. Connect four lines the valve chamber 16 with the interior of the regulator 12. The first line runs between a valve seat 22, with which the Sealing valve 18 cooperates and the oxygen inlet 23 of the regulator 12. The line 21 receives an orifice plate 24 in the vicinity of the connection with the inlet 23. The second and third lines 25, 26 are connected to each other and are in connection with the arrangement of the controller in a manner known per se, in particular they are in connection with a first or intermediate chamber 27 between a sensing membrane 28 and a follower membrane 29 · The second conduit 25 has a Safety pressure relief valve 30, which allows an outflow to the valve chamber 16, while the third line 26 ends in a valve seat 31 with which the solenoid valve plate 20 cooperates ;. The fourth conduit is a simple open channel that has a closed, second chamber 33 on the outer

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Side of the follower membrane 29 connects to the valve chamber 16. A third or control chamber of a simple pneumatic actuator worker 34- is connected to the first line 21, the actuator being adapted to have an air inlet check valve 35 controls. The construction of a flow control valve is 4-0 which is a demand valve and an injector 4-1 and the corresponding operation are known.

In the operation of the first embodiment of the invention, the aneroid can 10 expands with increasing height (it can have internal stops due to which an expansion only begins when a height of e.g. 3000 m is reached); for example at 4.5ΟΟ m the aneroid can has shifted so far, that the leather 19 is compressed to an amount at which the magnetic influence of the valve plate 20 is overcome; the valve plate 20 then closes on the valve seat 3I · dies causes a previously unrestricted outflow from the first or intermediate chamber 27 in the open air must build up a sufficiently high pressure so that the pressure relief valve 30 is opened, before the air gets outside, causing the sensing membrane is deflected so that the flow control valve 4-0 is opened sufficiently wide to achieve the desired low pressure (or Safety pressure) in the mask. A further increase in height causes a continued displacement of the aneroid can 10, so that then e.g. at 6,000 m the flange of the collar 17 comes into contact with the arm of the sealing valve 18 and after being overcome a (not shown) spring gradually lifts the sealing valve from the seat 22, so that the oxygen in the first Line 21 and included in the third or control chamber of the pneumatic actuator 34- and previously as an inlet oxygen pressure consisted, is gradually reduced in the pressure head. This reduction in pressure enables the operating rod of the actuator 34- slowly moves under the influence of a spring shifts so that, for example, at 9,000 m, the air inlet check valve 35 is held firmly on its seat. One

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such an effect ensures that between these heights the introduction of ambient air to dilute the oxygen to be released is gradually reduced until no more air is supplied. A further increase in height extends the aneroid can 10 even further until, for example, at 11,500 m, the drain valve 15 begins to regulate the flow of oxygen from the valve chamber 16; the valve plate 13 is increasingly pressed in the closed position against the valve seat 14- by the can 10, which causes the pressure in the valve chamber 16 is kept increasing and thus the valve plate 13 is held in suspension, whereby a drain is passed which has a predetermined Pressure generated in the valve chamber 16 at a value that is compatible with the ambient or absolute pressure at the respective altitude. The predetermined pressure is transmitted to the closed or second chamber 33 via the fourth line or channel 32 and causes a displacement of the follower membrane 29 and thus a further displacement of the sensing membrane 28 beyond the safety pressure displacement, with another positive pressure or "pressure breathing." ^{11 is present} in the mask and, if necessary, is available to inflate the pressure suit.

In the second embodiment according to Pig. 2 is an aneroid can 16 is provided, which is connected to a chamber 61 of an oxygen delivery regulator 62 for use by a pilot is attached when a connection to a mask or a corresponding device is produced. The free end of the can 10 takes an extension in In the form of an open tube 63 which cooperates with a first annular seat 64 which has a mouth over a regulating membrane 65 defines. A second annular seat 66 forms the mouth on the opposite side of the Control diaphragm 65 and interacts with a pressure control valve 67. This valve 67 has a plunger which at one end has a has conical valve head 68 which is in engagement with the

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second annular seat 66, and which at the other end has an annular valve head 69 which is in contact with a valve seat 70 via a spring 71 and by gas pressure via a main line 72 which is in communication with the oxygen inlet 73 of the regulator 62 , is printed. On the downstream side of the valve seat 70, a regulating pressure chamber 74 is provided, which is delimited on one of its sides by the control membrane 65. A line 75 connects the regulating pressure chamber 74 with a first or control chamber 76 which is delimited on one side by a membrane 77 which receives a valve plate 78 on its outside. The opposite side of the chamber 7 & is delimited by a membrane arrangement 79 which contains a spring-loaded valve plate 80. The valve plate 80 has a centrally arranged mouth which is defined by a valve seat 81, and a valve head 82 cooperates therewith within the chamber 76 and has a plunger through the mouth. The opposite end of the plunger is formed into a contact disc 83 which can contact the sensing diaphragm 84. A spring above the plunger pushes the valve head 82 into the closed position on the seat 81. The space in which the contact disc 83 lies, namely between the membrane arrangement 79 and the sensing membrane 84, forms an intermediate chamber 85 which is connected to a second or drainage chamber 86 over a line 8? in connection. The line 87 leads into the drainage chamber 86 via a valve seat 88 which, together with the aforementioned valve plate 78 ©, forms the drainage valve 89, which via an opening 90 enables drainage into the open. Another line 91 connects the control chamber 74- to a larger or third chamber of a stepped cylinder of a pneumatic actuator 92, and the smaller chamber is connected to the main line 72. The actuator 92 extends with the rod towards the air inlet check valve 93. A lever 94- is assigned to a hand-operated cam selector (not shown) and can be moved towards the regulating diaphragm so that it is 100%

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Oxygen release and also a floor test option is given. The arrangement of the demand valve flow control valve 100 and the injection nozzle 101 and the mode of operation are known per se.

The following is the operation of the second embodiment described to a "safety pressure", a termination of the air dilution of the released oxygen and a "pressure breathing" to achieve.

As the height increases, the aneroid can 60 expands and compresses the open tube 63 towards the regulating diaphragm 65. First, the tube 63 comes into contact with the seat 64 on the diaphragm 65 and then moves it into a position in which the annular valve seat 66 engages comes and is closed by the conical valve head 68 of the pressure control valve 67. A further movement causes the ring-shaped valve head 69 to be raised against the pressure of the oxygen fed in in the line 72 and in the inlet 73, whereby a regulating pressure can be built up in the pressure regulating chamber 74-. The regulating pressure balances the pressure which is constantly exerted by the aneroid can, with an increasing can pressure opening the valve further and a decreasing can pressure causing the valve to reduce its opening. The control pressure is therefore proportional to the ambient pressure or the absolute pressure. The control pressure in the chamber 74 · is also in the first or control chamber 76 via the line 7 ¹ ? present, and .in an increase with increasing altitude, a pressure is exerted on the membrane of the assembly 79, which gradually overcomes the spring force supporting the valve plate 80 so that the plate moves towards stops, for example at 4-500 m ; in this position the contact disc 83 has moved onto the sensing diaphragm 84- and shifted the latter so that the flow control valve is opened sufficiently to generate the desired "safety pressure". The regular pressure

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is also available in the larger or third chamber of the pneumatic Actuator 92 available via line 91, and the inlet pressure 73 is present in the smaller chamber and is from the Line 72 removed. The relative diameters of the smaller ones and larger chambers together with a compression spring in the latter are designed so that the regulating pressure that comes from the inlet feed pressure is reduced, the feed pressure overcomes with increasing altitude. At 6,000 m, for example, the actuator rod has moved in the range of motion of the valve plate of the air inlet check valve 93 moves, and for example at 9,000 m the valve plate closes on its seat and becomes there at all higher altitudes held vigorously, so that a dilution of the released oxygen. is terminated. In context with the diaphragm arrangement 79, when the contact disk 83 is displaced onto the sensing diaphragm 84 and when there is a displacement of the sensing diaphragm 84- wiBä the spring holding the valve head holds in engagement with the valve seat 81, is overcome and thus oxygen flows from the first or control chamber 76 through the Line 87, drain valve 89 and port 90. A further increase in height increases the control pressure, and if this takes effect in the first or control chamber 76 he that the valve plate 78 attached to the membrane 77 is moves against the valve seat 88 until, for example, 11.500 m the pressure of the outflowing oxygen at the seat in of the second or drainage chamber 86 balances the pressure on the valve plate 78, which, as it were, is floating. Takes over the height II.5OO m to, a further increase in the control pressure is generated, a continuous valve balancing and a limitation of the outflow into the open air from the third or drain chamber 85

causes an increasing pressure to be applied to the sensing diaphragm 84 so that its further deflection is achieved and thus a greater discharge pressure is provided by the regulator. This creates the conditions for "pressure breathing ^11. With decreasing altitude, the sequence of processes and work steps is reversed, the control pressure in the control chamber 74 via the opening in the control diaphragm 65 and the can chamber

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is propagated when the can 60 contracts into position has, in which the membrane regulator 65 is withdrawn and the annular seat 66 iron the conical valve head 68 of the BruckregpLventiles 67 has released, which then closes and prevents that oxygen can enter the control device from inlet 73. The lever 94- is operated by hand with the aid of the Squat Select Devices (not shown) that are remotely operated can, pressed down at two levels so that the regulating membrane is deflected, whereby the first level results in a control pressure, to get the conditions for the "security printing", and the second altitude provides a control pressure sufficient to operate the pneumatic actuator 92, so that the air inlet check valve is kept closed. This latter condition enables a 100% release of oxygen at low heights where the lift inlet would normally be open and dilution occurs.

In both embodiments, the following applies that - since the pneumatic actuators 34? 92 against the closed position of the air inlet valves 35j 93 are spring-loaded - for the pail that the fed Oxygen does not reach the regulator, this can be seen immediately by a user when putting on the mask, since it receives neither oxygen nor air.

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Claims (6)

231371Q 3/16/1973 W / He - 10 - Ν / ρ 7612 Patent claims: f 1 J Pressurized gas delivery regulator, "in which a single oieroid can acted upon a pressure control valve which regulates the gas pressure in a plurality of chambers, characterized by a device (28; 84) in a first chamber (27; 76) for actuating a flow control valve (40; 100), · allows the gas to reach a consumer stile, a second chamber (33; 86) which is open to the outside and which has a device for further actuation of the flow control valve (40; 100), and a third chamber (85) with an actuating device (34; 92) for controlling an air inlet which enables the air to be mixed with the gas flowing to the consumer point. 2. Sailor according to claim 1, characterized in that the Device C28; 84) in the first chamber (27; 76), which is the Flow control valve (40; 100) actuated, a deflectable Has wall that works as a sensing diaphragm of the flow control valve. 3. Regulator according to claim 1 or 2, characterized in that that the pressure control valve (15; 67) has an outlet valve to the outside has, which can be actuated by the aneroid can (10; SO) and in communication with the chambers (27, 33; 76, 86, 85). 4. Regulator according to claim 1, 2 or 3, characterized in that that the device (29) in, the second chamber (33 »8ζ) the the flow control valve (40; 100) is further actuated, one has deflectable wall which also forms a wall of the first chamber. . · 5. Regulator according to one of claims 1 to 4, characterized in that that the actuator (34; 92) has an extendable rod which is adapted to is extended under the action of a control pressure and a 309840/0383 March 16, 1973 W / He ~ d 1 - N / p 7612 Keeps the valve plate of the air inlet closed. 6. Regulator according to claim 1, characterized in that part of the pressure control valve (15; 67) has a magnetically "applied" Has valve plate (20) which is displaced by the aneroid can (10; 60) so that an outlet of a line is closed which releases a gas pressure into the open air from the first chamber, the line having another outlet via a check valve owns. 309840/0383