Breathing protection systems for the crew of aircraft likely to fly at high altitude include a regulator for feeding a breathing mask from a source of pressurized breathing gas (generally oxygen). The regulator can be carried by the mask or it can be mounted on the seat of the crew member.
Usually, such regulators include two selector members made available to the user:
The user thus has four possible operating states available:
The inventors have found that it suffices, in fact, to have only states 1 and 4 available, state 4 being able to replace state 2 without drawback, particularly since state 2 is little used.
It is an object of the invention to provide type of demand regulator that nevertheless satisfies all requirements.
To this end, the invention provides in particular a demand regulator comprising:
The last disposition is to prevent the mask being stored while operating at high pressure. Under such circumstances, the mask would be fed continuously from the source, and the source would rapidly be depleted.
The means enabling the last function to be performed are advantageously designed so that the mask can be stored (or must necessarily be stored) with the manual control member in the emergency position. This improves safety, since the crew member is supplied with pure breathing gas at high pressure as soon as the mask is put on the face. The same result can be obtained, when the demand regulator is mounted on the mask, by providing its storage box with means that bring the manual control member into the normal position when the mask is stored and that bring it into the emergency position when the mask is extracted.
Other dispositions enable a comparable result to be obtained, e.g. by detecting: that the mask has been taken from its storage box; that the mask has been applied to the face; the mask is forcibly applied to the face; or a harness holding the mask on the face is tensioned, etc. The means used can be mechanical, electrical, or electronic.
The above characteristics and others will appear more clearly on reading the following description of particular embodiments, given as non-limiting examples. The description refers to the accompanying drawings.
The demand regulator whose general structure is shown in
The housing 10 contains a main valve 16 constituted by a diaphragm co-operating with a fixed seat. A control chamber 18 defined by the rear surface of the main diaphragm and the housing is connected via a constriction 20 to the admission. When it is subjected to admission pressure, the diaphragm 16 is pressed against the seat, closing the passage in said seat, and separating the admission 12 from the tube 14.
The pressure that exists in the chamber 18 is controlled by a pilot valve 22. The pilot valve comprises a diaphragm 24 that is sensitive to pressure. The diaphragm carries a shutter or closure member 26 which co-operates with a fixed seat to put the control chamber 18 into communication with a chamber 28 defined by the diaphragm 24, or to separate the chambers.
The chamber 28 also communicates with the admission via a constriction 29.
The pressure that exists inside the chamber 28 is limited by a valve 30 discharging to atmosphere and which prevents the high pressure in the chamber 28 exceeding a predetermined value.
To enable operation with dilution, an ejector 32 is interposed between the main valve 16 and the tube 14. When open, a passage 34 allows dilution air to arrive downstream from the ejector.
The pilot valve 22 is made in such a manner as to serve also as an exhaust valve. For this purpose, the diaphragm 24 has an annular rim 36 which bears against a seat for exhausting to the atmosphere.
The disposition described above is known and it is used by numerous demand regulators, so its operation need not be described in detail.
To enable the invention to be implemented, the
The selector member 38 controls a dilution valve 40 which closes the passage 34 when the member 38 is in its “emergency” position and opens it when the member is in its “normal” position.
The selector member 38 also controls a valve 42 which opens a passage for putting the chamber 28 into communication with the atmosphere when in the “normal” position, and for closing this passage when in the “emergency” position.
It is explained below that the elimination of any communication between the chamber 28 and the atmosphere causes the mask to be fed at a high pressure which is set by the rating of the valve 30. Consequently, except when the supply of pressurized breathing gas to the regulator is prevented by other means, the chamber 28 must remain connected to the atmosphere so long as the mask is not in use.
For this purpose, the regulator shown in
When the regulator is in its “normal” state it operates in conventional manner and that is why there is no need to describe such operation herein.
However, when the selection member 38 is in its “emergency” position, and the valve 44 is closed, then the regulator operates as follows.
Because the chamber 28 is separated from the atmosphere, the admission pressure tends to become established therein via the constriction 29. However, the pressure in the chamber 28 is limited by the atmospheric bleed valve 30 opening when the pressure reached in the chamber 28 is sufficient to open the pilot valve 22. The pressure in the control chamber 18 drops to a value fixed by the rating of the valve 30. The main valve 16 subjected to the difference in pressure between the admission and the pressure in the chamber 18 opens and feeds the tube 14 with pure breathing gas. The main valve 16 opens only when the pilot valve 22 closes under the effect of the increasing pressure inside the mask.
When the user breathes out, the annular rim 36 lifts off its seat and exhausts to the atmosphere.
The regulator does not discharge to atmosphere even when the selector member 30 is in its “emergency” position so long as the valve 44 remains open, and thus so long as the mask is not in place.
In the modified embodiment shown in
For this purpose, the box has a resilient catch 54 and the selector member 38 has a stud 56. When the mask fitted with the regulator is pushed into the box in the direction of arrow f, the catch begins by pushing the member 38 to the left until it has been brought into its “normal” position, after which it snaps into position beyond the stud. When the mask is pulled out, the resilient catch 54 returns the member 38 to the “emergency” position before retracting.
The
The embodiment shown in
When the admission 12 is fed and the selection member 38 is in the “emergency” position, while ambient pressure is too low to open the valve 30, the main valve 16 remains closed. The chamber 28 is separated from the admission by the pilot valve 26 which is held closed by the spring 50. Admission pressure then exists in the chamber 18.
On first breathing in by the wearer of the mask, an under pressure is established in the tube 14. The admission pressure then tends to become established in the chamber 28 and holds the pilot valve continuously open. Nevertheless, the pressure is limited by the continuously open pilot valve. Nevertheless, the pressure is limited by the atmospheric bleed valve 30 to a value that is low enough for the main valve to remain open and high enough for the main valve to remain likewise open.
When the regulator is in the “emergency” position, surrounding depressurization causes the valve 30 to open and decreases the pressure in the chamber 18 to a level such that the main valve delivers gas continuously. To avoid this situation when the mask is not being worn, the mask is generally stored in a box:
The embodiment of
The regulator proper has the same structure as that of
The admission 12 of pressurized breathing gas is connected to the annular chamber situated beneath the diaphragm of the main valve only in response to a valve 62 opening under the control of a differential piston 64. A spring 66 urges the piston 64 towards a position in which the valve 62 is pressed against its seat. Under such circumstances, the inability of the regulator to operate is due to its supply being cut off.
The larger surface of the piston 64 is subjected to atmospheric pressure and tends to close the valve 62. The smaller surface of the piston is subject to the pressure which exists downstream from the valve 62. The annular surface 68 constituted by the staged configuration of the piston is subjected to a pressure that is controlled by a cock for inflating and deflating the harness 60.
The cock can be of various structures. In
A constricted passage 76 enables the pressure which exists inside the harness to be established also against the annular surface 68.
When not in use, a mask fitted with the regulator shown in
Even if the member ˜38 is in its “emergency” position, the regulator does not deliver oxygen. The main valve is not fed because the valve 62 is closed by the spring 66.
When the user of the mask pushes down the plunger 70 in order to inflate the harness, admission pressure becomes established progressively against the annular surface 68. The piston 64 rises and opens the valve 62. From this point on, operation is the same as that of the
When the user releases the plunger 70 in order to deflate the harness, the valve 62 does not close. The admission pressure then acting on the bottom face of the piston 64 holds it in the high position.
Even if the valve 62 is open, the regulator no longer delivers when the mask is not pressed against the face and the member 38 is in the “normal” position.
The embodiment shown in
The regulator has underpressure controlled means which isolate the regulator proper from the admission, as in
This first intake of breath causes the pressure in the tube to decrease and opens the pilot valve 22. Admission pressure then tends to become established inside the chamber 28 and to hold the pilot valve 22 open. This pressure becomes established from the admission 12 via a constriction 84 and the connections via the command chamber 18.
Additional means are provided in the
So long as the breathing gas pressure does not exist in the admission 12, the plunger 88 remains in the position shown in
Once the plunger is in the position communicating the admission with the main valve, the plunger remains in that position. A push rod 96 can be provided to return to its rest position by action in the direction of arrow fl.
All of the embodiments described above operate in purely pneumatic manner. The invention can also be used in a regulator making use of sensors, solenoid valves, and/or piezoelectric actuators, e.g. of the kind described in document U.S. Pat. No. 4,336,590 (French patent No. 79/11072) to which reference can be made.
More generally, the means for preventing operation with the mask being fed with pressurized gas so long as the mask is in a storage position can have a very wide variety of structures. If the regulator is carried by a mask, the means can be controlled by inflating the harness, by deflating the harness after inflation, by measuring forces on the harness, by measuring the force with which the mask is pressed against the face, by detecting the presence of the face. The means can be responsive to a first intake of breath giving rise to a vacuum in the mask after it has been put on the face. The means can prevent a mask fitted with a regulator from being stored in a box while it is in the “emergency” position. When the regulator is separate from the mask, a communication can be provided between the mask and the regulator to transmit reliable information to the regulator. A disposition of the kind shown in
In any event, operation can be prevented by cutting off the feed upstream from the regulator, by cutting off the flow passing through the regulator, or by cutting off the high pressure, and the various solutions can be used in combination.
Number | Date | Country | Kind |
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98 09493 | Jul 1998 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR99/01803 | 7/22/1999 | WO | 00 | 1/23/2001 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO00/04956 | 2/3/2000 | WO | A |
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