 |
Claims  |
|
|
What is claimed is:
1. A combination low pressure switch/initiator/gas generator device for a
compressed gas air bag inflator comprising,
first and second diaphragms each of which are electrically conducting,
electrically non-conductive spacer means having a first side and a second
side,
attaching means attaching said first diaphragm and said second diaphragm in
opposed and sealing relation to said first and second sides, respectively,
of said spacer means thereby forming a hermetically sealed chamber, with
said first diaphragm and said second diaphragm being movable toward and
away from each other from a predetermined spaced relationship as the
pressure of the environment externally of said hermetically sealed chamber
increases and decreases relatively to the pressure in said hermetically
sealed chamber,
pyrotechnic means contained in said hermetically sealed chamber, said
pyrotechnic means igniting when heated to a predetermined level,
a bridgewire resistor having a first end and a second end, said bridgewire
resistor being located in said hermetically sealed chamber and having said
first end electrically connected to said first diaphragm and said second
end electrically connected to said second diaphragm,
a pressure monitoring resistor having first and second ends positioned so
as to make and break electrical contact with said first and second
diaphragms as said first and second diaphragms are moved toward and away
from each other from a predetermined spaced relation,
electrical circuit means in which said bridgewire resistor and said
pressure monitoring resistor are connected in parallel relation when both
said first and second ends of said pressure monitoring resistor are in
electrical contact with said diaphragms, said electrical circuit means
normally having a flow of electrical monitoring current therein which is
too low to cause sufficient heating of said bridgewire resistor to ignite
said pyrotechnic means in said hermetically sealed chamber, but having a
capability of having produced therein a flow of electrical current at a
level high enough to cause such heating of said bridgewire resistor,
whereby, with said hermetically sealed chamber pressurized to a
predetermined reference level, in atmospheric environment conditions the
pressure in said chamber is higher than atmospheric pressure and said
first and second diaphragms are caused to move away from each other and
thereby break the electrical contact of said pressure monitoring resistor
with said second diaphragm and cause a change of resistance in said
electrical circuit means,
whereby with the pressure of the environment external to said hermetically
sealed chamber higher by a predetermined amount than said predetermined
reference level in said chamber, said first and second diaphragms are
caused to move toward each other and cause the ends of said pressure
monitoring resistor to make electrical contact with said diaphragms and
cause a change in the resistance of said electrical circuit means,
whereby, if the seal of said hermetically sealed chamber fails, the
resulting equalization of the chamber pressure and the pressure of the
environment external to said chamber causes said first diaphragm and said
second diaphragm to move away from each other and break the electrical
contact between one end of said pressure monitoring resistor and said
respective diaphragm and cause a change in the resistance of said circuit
means, and
whereby with a flow of a large electrical current through said bridgewire
resistor, that is, an electrical current at a level high enough to cause
heating thereof, said bridgewire resistor heats up to a point that causes
ignition of said pyrotechnic means in said hermetically sealed chamber.
2. A device as defined by claim 1 wherein said first and said second
diaphragms are mirror symmetrical.
3. A device as defined by claim 1
wherein said pyrotechnic means in said hermetically sealed chamber
comprises an oxidizer selected from the group consisting of solid, liquid
and gas and a fuel selected from the group consisting of solid, liquid and
gas.
4. A device as defined by claim 1
wherein said pyrotechnic means in said hermetically sealed chamber
comprises a gaseous oxidizer and a combustible gas.
5. A device as defined by claim 4
wherein said combustible gas in said hermetically sealed chamber is
methane.
6. A device as defined by claim 1
wherein said pyrotechnic means in said hermetically sealed chamber
comprises a gaseous oxidizer and a solid fuel disc.
7. A device as defined by claim 1
wherein said pyrotechnic means in said hermetically sealed chamber
comprises a solid oxidizer and a combustible gas.
8. A device as defined by claim 7
wherein said combustible gas in said hermetically sealed chamber is
methane.
9. A device as defined by claim 1
wherein said spacer means comprises a spacer ring, and
wherein said attaching means includes first and second protective rings
each of which has an aperture therein in a central portion thereof and has
a first side and a second side, said first diaphragm being attached in
sealing relationship to said first side of said first protective ring
symmetrically with respect to the aperture therein, said second diaphragm
being attached in sealing relationship to said second side of said second
protective ring symmetrically with respect to the aperture therein, with
the first side of said first protective ring being disposed in sealing
relationship with the first side of said spacer ring and the second side
of said second protective ring being disposed in sealing relationship with
the second side of said spacer ring.
10. A device as defined by claim 9,
wherein said first and said second diaphragms are attached to said first
and second protective rings by mechanical bonding.
11. A device as defined by claim 9,
wherein said first and said second protective rings are each electrically
conductive.
12. A device as defined by claim 11 further including a separate electrical
lead attached to each of said first and second protective rings.
13. A device as defined by claim 9 further including a housing therefore,
said housing including a base and parallel walls between which said device
over a portion, at least, thereof is positioned in a snug fit, with each
of said walls having a circular cutout therein to expose a substantial
portion of the adjacent protective ring including the aperture therein.
14. A device as defined by claim 9,
further including a pressure disc provided in at least one of said
protective rings to rupture and allow the heated gases to flow out of said
hermetically sealed chamber upon ignition of said pyrotechnic means
therein.
15. A device as defined by claim 1,
wherein said pyrotechnic means in said hermetically sealed chamber
comprises a combination of combustible gases whose pressure/temperature
curve substantially matches that of the environment external to said
hermetically sealed chamber to provide temperature compensation in
pressure sensing of the external environment.
16. A device as defined by claim 1,
further including a fuse connected in series with said pressure monitoring
resistor to break the continuity thereof immediately upon the application
of a large electrical current by said circuit means so as to avoid
interference thereof with the operation of said bridgewire resistor in
causing ignition of said pyrotechnic means in said hermetically sealed
chamber.
17. A combination low pressure switch/initiator/gas generator device for an
inflator of a hybrid inflatable air bag safety restraint system that
includes a storage chamber containing stored inflation gas under high
pressure, comprising,
an ignition train and pressure differential switch positioned in said
storage chamber,
said ignition train and differential switch comprising first and second
diaphragms each of which is electrically conducting,
electrically non-conductive spacer means having a first side and a second
side, attaching means attaching said first diaphragm and said second
diaphragm in opposed and sealing relation to said first and second sides,
respectively, of said spacer means thereby forming a hermetically sealed
chamber with said first diaphragm and said second diaphragm being movable
toward and away from each other from a spaced relationship as the pressure
in said inflator storage chamber increases and decreases relatively to the
pressure in said hermetically sealed chamber,
pyrotechnic means contained in said hermetically sealed chamber, said
pyrotechnic means combusting when heated,
a bridgewire resistor having a first end and a second end, said bridgewire
resistor being located in said hermetically sealed chamber and having said
first end electrically connected to said first diaphragm and said second
end electrically connected to said second diaphragm,
a pressure monitoring resistor having first and second ends with said ends
positioned so as to make and break electrical contact with said first and
second diaphragms as said first and second diaphragms are moved toward and
away from each other from a predetermined spaced relationship, and
electrical circuit means in which said bridgewire resistor and said
pressure monitoring resistor are connected in parallel relation when said
second end of said pressure monitoring resistor is in electrical contact
with said second diaphragm, said electrical circuit means normally having
a flow of electrical monitor current therein which is too low to cause
sufficient heating of said bridgewire resistor to cause said pyrotechnic
means in said chamber to combust, but having a capability of having
produced therein a flow of electrical current at a level high enough to
cause such heating of said bridgewire resistor. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to combining the functions of an initiator, gas
generator/heater and a "low pressure switch" (LPS) into a single device
for convenience, termed herein an "initiator/monitor" device and having
especial utility in the inflator of a vehicular stored gas inflatable air
bag safety restraint system. A stored gas system includes a gas generator
for the generation of gas and a vessel in which compressed or pressurized
gas is stored to supply additional gas under pressure to inflate an
inflatable air bag to protect the occupants of a vehicle upon the impact
thereof with a harm producing object.
2. Description of the Prior Art
An inflatable air bag has a folded condition for storage in a steering
wheel, dashboard or other appropriate location within a vehicle in close
proximity to normal occupant position. Upon the occurrence of a collision
of the vehicle, expansion of the inflatable bag may be effected or
augmented by an inflator comprising a fluid supply in the form of a
pressure vessel defining a chamber which contains a stored compressed or
pressurized supply of gas.
In U.S. application for patent bearing Ser. No. 989,854 filed on Dec. 14,
1992 by Bradley W. Smith entitled "HYBRID GAS GENERATOR FOR AIR BAG
INFLATABLE RESTRAINT SYSTEMS" now U.S. Pat. No. 5,290,060 and assigned to
the assignee of the present invention, a pressurized stored gas supply in
a pressure vessel is released upon the actuation of a gas generator, more
particularly, a pyrotechnic heater, which heats and increases the pressure
of the stored gas. This causes the rupture of a portion of the pressure
vessel which communicates with suitable gas flow directing means leading
to and allowing the gas to escape into the interior of an inflatable bag.
The bag inflates in front of the occupant and acts as a protective
cushion.
The compressed or pressurized supply of gas is a very important part of a
hybrid safety restraint system. If the gas pressure falls below a
predetermined level, the system will not operate properly.
The pressurized vessel typically is compressed or pressurized with an inert
gas such as argon, or a mixture of argon and another inert gas, to
approximately 3000 psi at room temperature. Such vessels must be adapted
to maintain the stored gas pressure so that the pressure does not drop by
more than about 200 psi when at room temperature during the life of the
vehicle which may be fifteen (15) years or more. These limits are
illustrative only and are not intended in any manner to place restrictions
on the scope of the claimed invention.
In a compressed or pressurized gas air bag inflation system, a means of
predictably and substantially instantaneously releasing the pressurized
gas from the inflator to fill the air bag is required. In addition, it may
be desirable to heat the gas at the time of release to increase the
pressure and/or improve the air bag inflation characteristics. Most
domestic car manufacturers currently also require a temperature
compensated means of detecting if a substantial amount of the compressed
or pressurized gas has leaked from the inflator during the lifetime of the
inflator.
Current hybrid air bag inflators use a "low pressure switch" to indicate
the adequacy of the volume of gas stored in the inflator, an initiator
(squib), a gas generator, and additional pyrotechnic material to heat the
"cold" gas stored in the pressure vessel. There is a need and a demand for
the replacement of the above components with one, cost effective, small
device to reduce the complexity and cost of the inflator assembly. The
present invention was devised to fill the gap that has existed in the art
in this respect.
SUMMARY OF THE INVENTION
An object of the invention is to combine the functions of an initiator, gas
generator/heater, and a low pressure switch into a single device.
Another object of the invention is to provide in a single device a
combination LPS/initiator/gas generator for a compressed gas air bag
inflator.
Still another object of the invention is to provide in a single device the
initiation train and pressure differential switch of the inflator of a
hybrid inflatable air bag safety restraint system to reduce, for example,
the cost, size and weight, with the pressure monitoring function being
added to the initiating train at little cost.
A further object of the invention is to provide such a device that is
characterized by the incorporation therein of a temperature compensating
means for detecting whether any compressed or pressurized gas has leaked
from the inflator during the lifetime of the inflator.
In accomplishing these and other objectives of the invention the device
utilizes the basic structure of the "DIFFERENTIAL PRESSURE SWITCH FOR
STORED GAS PRESSURE VESSEL" disclosed in U.S. Pat. No. 5,225,643 granted
on Jul. 6, 1993 to Brent R. Marchant and assigned to the assignee of the
present invention. The device detects the adequacy of pressure in the
pressure vessel and acts as an ignition train initiator by the
incorporation of an oxidizer (solid or gas) and a fuel (solid or gas)
within the device. For example, the device may have a combustible gas in
an inner chamber, the pressure temperature curve of which combustible gas
matches that of the compressed gas in an outer chamber. The outer chamber,
for example the chamber of a pressure vessel of a hybrid air bag inflator
in which the device is positioned, may contain a combustible or inert gas,
depending upon the energy release needed. Monitor electric current for the
air bag restraint system flows through a pressure monitoring resistor and
a bridgewire ignition initiating resistor within the device, monitoring
continuity. When and if the pressure in the outer chamber decreases below
a preset threshold value, the pressure monitoring circuit breaks
continuity. Thus, a resistance change occurs in a circuit in which the
pressure monitoring and bridgewire resistors are connected, which circuit
is connected to a diagnostic unit. The switch acts as a low pressure
switch when the pressure inside the switch is set such that it forces two
diaphragms together, completing an electrical circuit including the
pressure monitoring resistor when there is sufficient pressure in the
hybrid inflator for proper air bag inflation. A pressure drop in the
inflator causes the diaphragms to be forced apart opening the electrical
circuit through the pressure monitoring resistor.
The bridgewire resistor inside the LPS body preferably has a resistance
value higher than or comparable to that of the pressure monitoring
resistor and never loses continuity until it has performed as expected or
operated properly, that is, functioned. The two circuits connecting the
bridgewire resistor and the pressure monitoring resistor are connected in
parallel and the continuity of both of the resistor circuits is
continuously measured externally by a suitable diagnostic unit by running
a small or low current through the two LPS pins and measuring the overall
resistance. For example, if the pressure monitoring resistor is 100 ohms
and the bridgewire resistor is 50 ohms, the external diagnostic circuitry
would measure 1/(1/100+1/50)=33 ohms. If the pressure monitoring resistor
lost continuity due to pressure loss in the inflator, the resistance
measured by the diagnostic unit would change to 50 ohms (the resistance of
the bridgewire circuit alone) and the diagnostic unit would detect that
the low pressure switch had lost continuity. If the bridgewire resistor
somehow became disconnected, the resistance would change to 100 ohms (the
resistance of the pressure monitoring resistor alone) and the diagnostic
unit would detect this also. Under normal operating conditions, both
circuits would be closed and 33 ohms would be measured at all times. In
the event of a vehicular collision, the diagnostic unit would apply a
large current through the LPS pins, causing the bridgewire resistor to
heat to a predetermined level to ignite the solid material or explosive
gas(ses) in the initiator/monitoring device. If needed, the pressure
monitoring resistor could have a fuse incorporated therewith to break
continuity immediately upon application of the large current so as not to
interfere with the operation of the bridgewire resistor ignition. When
ignited, the gas inside the LPS body expands and ruptures at least one
pressure disc in the wall of the LPS body, allowing the hot gas to mix
with the stored gas(ses) in the inflator and to ignite or expand it/them.
This, in turn, builds up enough pressure to cause a diaphragm restraining
the stored inflator gas to rupture, allowing that gas to escape into the
air bag and to inflate it.
The various features of novelty which characterize the invention are
pointed out with particularity in the claims annexed to and forming a part
of this specification. For a better understanding of the invention, its
operating advantages, and specific objects attained by its use, reference
is made to the accompanying drawings and descriptive matter in which a
preferred embodiment of the invention is illustrated.
BRIEF DESCRIPTION OF THE DRAWINGS
With this description of the invention, a detailed description follows with
reference being made to the accompanying figures of drawings which form
part of the specification, in which like parts are designated by the same
reference numbers, and of which:
FIGS. 1, 2 and 3 are front, side and end views, respectively, illustrating
a hybrid inflator;
FIG. 4 is a cross-sectional view of the hybrid inflator taken along the
lines 4--4 of FIG. 1;
FIG. 5 is a cross-sectional view taken along the lines 5--5 of FIG. 2;
FIG. 6 is a front view of the initiator/monitor device of FIG. 4;
FIG. 7 is a cross-sectional view of the initiator/monitor device taken
along the lines 7--7 of FIG. 6;
FIG. 8 is a circuit diagram illustrating the connection to a diagnostic
unit of a bridgewire resistor and an LPS resistor provided in the
initiator/monitor device; and
FIGS. 9 and 10 are fragmented disclosures of modified initiator/monitor
devices according to the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to the drawings, there is shown a hybrid inflator assembly 10 for
inflating a vehicle occupant restraint such as an air bag (not shown). The
inflator assembly 10 comprises a pressure vessel 12 including a storage
chamber 14 that is filled and pressurized with an inert gas such as argon
or nitrogen to a pressure typically in the range of 2000-4000 psi.
The chamber 14 is defined by an elongated cylindrical sleeve 16. A fill
plug 18 is attached by a circumferential weld 20 in sealing relation to a
first end 22 of sleeve 16. An initiator/monitor device 24 according to the
invention is recessed in sealing relation into chamber 14 from a second
end 26 of sleeve 16. A diffuser 28 extends at substantially a 90.degree.
angle from the exterior surface 30 of sleeve 16 at a location intermediate
the ends 22 and 26 thereof. Diffuser 28 is arranged in sealing relation
with sleeve 16 and provides a passage for the flow of gas from pressure
chamber 14 through one or more normally closed constricting orifices 32
that are provided in the wall of sleeve 16.
The initiator/monitor device 24 includes a chamber 34 which is pressurized
to a predetermined reference or control level. The chamber 34, which is
hermetically sealed, is defined by two mirror symmetrical electrically
conductive flexible diaphragms 36 and 38. Each of the diaphragms 36 and 38
may have a raised surface 40 and 42, respectively, as shown, in the
central region thereof. Adapted for electrical connection between the
raised surfaces 40 and 42 is a resistor 44 which may have a value of 100
ohms and serves an LPS monitoring function. Resistor 44 is adapted to make
and break contact with the diaphragm raised surfaces 40 and/or 42 as the
diaphragms 36 and 38 move toward and away from each other from a
predetermined spaced relation.
When the pressure inside the chamber 34 defined by the diaphragms 36 and 38
as illustrated in FIG. 7 is set such that it forces the diaphragms 36 and
38 toward each other completing a circuit through the resistor 44, there
is sufficient pressure of stored gas in the vessel 12 for proper
inflatable bag inflation. A pressure drop of the stored gas in the vessel
12 forces the diaphragms 36 and 38 apart, opening the circuit through the
resistor 44.
The diaphragms 36 and 38 which, typically, may be made out of stainless
steel or other suitable material including inconel and carbon steel, are
physically positioned in parallel relation to each other. Each of the
diaphragms 36 and 38, termed first and second diaphragms, respectively
hereinafter, is attached in a symmetrical manner, as by brazing, in
sealing relation to a respectively associated electrically conductive
protective ring or washer 46 and 48. The protective rings 46 and 48, in
turn, are mounted in spaced relation to each other on the opposite sides
of an electrically non-conductive spacer ring or washer 50, being
hermetically sealed thereto by suitable sealing means indicated at 52 and
54, respectively. Alternatively, the diaphragms 36 and 38 may be attached
directly to the electrically non-conductive spacer ring 50 and backed up
with the protective rings 46 and 48 or another suitable backing method.
More specifically, each of the protective rings 46 and 48 has a first side
56 and 58, respectively, and a second side 60 and 62, respectively. The
first diaphragm 36 is attached in sealing relationship to the first side
56 of the first protective ring 46, symmetrically with respect to an
aperture 64 in the ring 46. The second diaphragm 38 is attached in sealing
relationship to the second side 62 of the second protective ring 48,
symmetrically with respect to an aperture 66 in the ring 48. The first
side 56 of the first protective ring 46 is disposed in sealing
relationship with a first side 68 of the spacer ring 50. The second side
62 of the second protective ring 48 is disposed in sealing relationship
with the second side 70 of the spacer ring 50.
The arrangement is such that the diaphragms 36 and 38 are positioned so
that the surfaces 40 and 42, which may or may not be raised, are directly
opposed. Apertures or openings 64 and 66 in the protective rings 46 and
48, respectively, allow external pressure, that is, the pressure outside
of the chamber 34, specifically the pressure of the pressurized or
compressed gas that is stored in the pressure vessel 12, to act on the
diaphragms 36 and 38.
Electrical leads from the protective rings 46 and 48 are attached to pins
or lead wires 72 and 73, respectively, through a header 76. To that end,
each of the pins 72 and 73 may be welded to a respectively associated one
of the protective rings 46 and 48.
Positioned in the chamber 34 adjacent the connection of the pins 72 and 73
to the protective rings 46 and 48, respectively, and extending between the
protective rings 46 and 48, to each of which is permanently connected, is
a bridgewire initiator resistor 74. The value of resistor 74 may be 50
ohms.
A suitable housing 78 may be provided to protect the initiator/monitor
device 24. The housing 78 includes a base 80 and parallel vertical walls
82 and 84 that are spaced to receive the assembled diaphragms 36 and 38,
the protective rings 46 and 48 and the spacing ring 50 in a snug fit.
Cutouts 86 and 88 in the housing 78 expose a substantial portion of each
of the protective rings 46 and 48 including the apertures 64 and 66
therein, respectively.
The header 76, as best seen in FIG. 4, mates with the second end 26 of the
cylindrical sleeve 16 of the pressure vessel 12. The sleeve 16 and the
adjacent outer region of the header 76 are joined in sealing relation by a
circumferential weld 92.
Pressurization of the chamber 34 of the initiator/monitor 24 may be
effected in a pressurized atmosphere of a combination of combustible gases
whose pressure/temperature curve substantially matches that of the
compressed gas in the storage chamber 14 during assembly of the diaphragms
36 and 38 to protective rings 46 and 48, respectively associated
therewith, and to the spacer ring 50. No fill ports are required when the
chamber 34 is pressurized during the assembly process. Optionally,
pressurization may be effected through a fill port 90 provided in
protective ring 48. Upon charging or pressurizing the chamber 34 to the
desired pressure level through the fill port 90, the latter may be closed
off in any suitable manner. Pressurizing the chamber 34 does not involve
penetration of the wall of the diaphragms 36 and 38. This is for the
reason that the diameter of the protective rings 46 and 48, as shown, is
sufficiently greater than that of the diaphragms 36 and 38 to allow access
to the chamber 34 from the outside through the protective rings 46 and 48
alone. Alternatively, the chamber could be pressurized through a hole in
the diaphragm and closed off using any suitable method.
When the diaphragms 36 and 38 are pressurized internally, as herein
disclosed, with low pressure on the outside, that is, externally of the
chamber 34, the diaphragms 36 and 38 are forced apart by the internal
pressure in chamber 34. When the diaphragms 36 and 38 are pressurized
externally, the diaphragms are caused to move closer together.
In accordance with the invention, the reference or control pressure level
to which the chamber 34 is selected to be pressurized typically is lower
by about 200-300 psi than that of the stored gas in the pressure vessel 12
which is to be monitored by the initiator/monitor device 24.
Diffuser 28 comprises a generally cylindrical sleeve 94 that is joined at
one end to the sleeve 16, at a depressed portion 96 of the surface 30
thereof in which the orifice 32 is provided, by a circumferential weld 98.
The other end of sleeve 94 is joined to and sealed by a gas impervious
closure plate 100. A thin metal diaphragm 102, referred to hereinafter as
a third diaphragm, provides a seal for orifice 32 in the wall of sleeve 16
which defines storage chamber 14. Provided in sleeve 94 of diffuser 28 are
a plurality of orifices 104 for dispensing inflating gas uniformly from
chamber 14 into an air bag assembly (not shown).
A course screen or perforated metal sheet indicated at 106 is provided in
the diffuser 28 to cover the diffuser orifices 104 to prevent fragments of
the diaphragms from entering the air bag assembly. If filtering is
desired, the coarse screen 106 could be replaced with a filter assembly of
wraps of metal and/or ceramic fiber materials which are common in the art.
Further filtering may be achieved by placing impingement filter material
indicated at 108 on the inside surface of the fill port and plug 18
opposite the initiator/monitor 24. Filter 108 would be made with woven or
matted metal and/or ceramic fibers which functions by providing a large
surface area upon which liquid phased particulates entrained in the
impinging gases may condense.
In the operation of the hybrid gas generator, upon the receipt of an
electric signal indicative of the onset of a crash and a need for
inflation of an air bag (not shown) a diagnostic unit (not shown) supplies
a large current through the pins 72 and 73, causing the bridgewire
resistor 74 to ignite the gas in the chamber 34 of the initiator/monitor
device 24. When ignited the gas in chamber 34 explodes and ruptures
pressure discs 110 in the wall members 46 and 48 of the initiator/monitor
device 24, allowing the hot gas to mix with the stored gas in chamber 14
of the pressure vessel 12. This heats the stored gas in vessel 12 causing
a rapid pressure rise in the chamber 14.
When the pressure of the stored gas exceeds the structural capability of
the thin metal diaphragm 102 in the diffuser 28, the diaphragm 102
ruptures allowing the heated stored gas to vent through the orifice 32 and
the diffuser orifices 104 into the inflatable bag assembly. Between the
diffuser diaphragm 102 and the storage chamber 14 are one or more
constricting orifices 32 which throttle the flow of gas from the storage
chamber 14, providing the proper fill rate to the air bag. The coarse
screen or perforated metal sheet 106 prevents fragments of the
initiator/monitor 24 and diaphragm 102 from entering the air bag assembly.
Impingement filter 108 on the fill port and plug 18 provides further
filtering by condensing thereon liquid phase particles entrained in the
impinging gases.
In a first embodiment of the invention, the initiator/monitor device 24
acts as an ignition train monitor by the incorporation of an oxidizer gas
and a fuel gas, for example, methane, within the internal chamber 34 and
with an inert stored gas such as argon or nitrogen contained in the outer
chamber 14 within the pressure vessel 12.
In a second embodiment of the invention, it is contemplated that the outer
chamber 14 may contain a combustible gas depending upon the energy release
needed.
In a third embodiment of the invention, as illustrated in FIG. 9, the
oxidizer in the internal chamber 34 of the device 24 is in the form of a
solid disc.
In a fourth embodiment of the invention, as illustrated in FIG. 10, the
pyrotechnic fuel in the internal chamber 34 of the device 24 is in the
form of a solid disc.
As shown in FIG. 9, the initiator/monitor device 24' differs from the
device 24 shown in FIGS. 6 and 7 by the inclusion of a perforated oxidizer
disc 112 that is supported between the diaphragms 36 and 38 internally of
a non-conductive spacer ring 50' in the inner chamber 34 with the LPS
resistor 44 extending through an aperture 114 in the disc 112. The
oxidizer disc 112 provides an oxidizer selected from the group consisting
of solid, liquid and gas. The device 24' has combustible gas in the inner
chamber 34. The outer chamber 14 has a gas which may or may not be
combustible. The monitor current flows through the pressure monitoring
resistor 44 and the bridgewire resistor 74, monitoring continuity. When
and if the pressure in the outer chamber 14 decreases below a threshold
value, the resistor 44 breaks continuity and there is a resistance change.
If the air bag is to deploy, the bridgewire resistor 74 heats up to a
point that the combustible gas and the oxidizer disc 112 combust. This
ruptures the pressure discs 110 and heats the gas in the outer chamber 14.
The outer chamber ruptures and gas flows through diffuser 28 into the air
bag (not shown).
The initiator/monitor device 24" shown in FIG. 10 differs from the device
24 shown in FIG. 6 by the inclusion in the inner chamber 34 of a
perforated fuel disc 116. The fuel disc 116 provides a fuel selected from
the group consisting of solid, liquid and gas. The disc 116 is supported
between the diaphragms 36 and 38 internally of the non-conductive spacer
ring 50' with the LPS resistor 44 extending through an aperture 118 in the
disc 116. Thus, the switch/initiator or igniter/generator 24" need not use
a combustible gas. For the function of the switch, it is preferred to use
the same gas in the inner chamber 34, that is, internally of the device
24", as is used in the external chamber 14 in order that the detection of
whether any of the pressurized gas in the inflator has leaked therefrom
may be temperature compensated.
Thus, in accordance with the invention, there has been provided in a single
size, weight and cost effective device a combination LPS/initiator/gas
generator for a compressed gas air bag inflator, with the pressure
monitoring function being added to the initiation train at little cost.
Incorporating the initiator and gas generator functions into the
differential pressure low pressure switch reduces the cost and complexity
of the inflator assembly.
With this description of the invention in detail, those skilled in the art
will appreciate that modifications may be made to the invention without
departing from the spirit thereof. Therefore, it is not intended that the
scope of the invention be limited to the specific embodiments that have
been illustrated and described. Rather, it is intended that the scope of
the invention be determined by the scope of the appended claims.
* * * * *
|
|
|
|
|
|
|
Description |
|
