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Claims  |
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What we claim is:
1. A gas generator for inflating an inflatable article, comprising a
housing, a reaction chamber in said housing for generating gas, a filter
chamber arranged for receiving gas from said reaction chamber, first gas
exit opening means (10 to 15) in said reaction chamber for a gas flow from
said reaction chamber into said filter chamber, second gas exit opening
means (22) in said filter chamber for a gas flow from said filter chamber
into said inflatable article, temperature responsive flow control means
arranged in said gas generator for influencing a gas flow from said
reaction chamber into said inflatable article in such a way that an
inflation duration and an inflation pressure are substantially independent
of a gas generator temperature, and wherein said reaction chamber (4) has
a circular cross-section, wherein said filter chamber has a ring
configuration surrounding said reaction chamber, said temperature
responsive flow control means comprising a baffle ring (16) extending
around said reaction chamber with a radial spacing for guiding a flow of
generated gas, a ring slide (28) rotatably surrounding said reaction
chamber in said radial spacing, said a temperature responsive drive member
(40) connected to said ring slide for driving said ring slide (28) between
closing and opening positions in response to temperature changes, said
baffle ring (28) having flow ports (24, 25, 26) therein, said ring slide
(28) having flow port closing wall sections (32 to 34) for cooperation
with said flow ports (24, 25, 26) of said baffle ring (16), said
temperature responsive drive member (40) driving said ring slide (28) to
close said flow ports (24, 25, 26) in said baffle ring in response to a
higher gas generator temperature and to open said flow ports (24, 25, 26)
in said baffle ring in response to a lower gas generator temperature.
2. The gas generator of claim 1, wherein said temperature responsive flow
control means are arranged to cooperate with said first gas exit opening
means (10 to 15) in said reaction chamber for increasing their
cross-sectional flow area in response to a rising of said gas generator
temperature and for decreasing said cross-sectional flow area in response
to a dropping of said gas generator temperature.
3. The gas generator of claim 1, wherein said temperature responsive flow
control means are arranged to cooperate with said filter chamber for
increasing a flow path length through said filter chamber in response to a
rising of said gas generator temperature and for decreasing said flow path
length in response to a dropping of said gas generator temperature.
4. The gas generator of claim 1, wherein said ring slide (28) comprises, in
addition to said flow port closing sections (32 to 34), further closing
sections (29 to 31) for reducing the total flow cross-sectional area of
said first gas exit openings (10 to 15) of said reaction chamber, wherein
said temperature responsive drive member (40) drives said ring slide (28)
with its closing sections (29 to 34) in such a way, that said first gas
exit openings (10 to 15) are all opened while said flow ports (24 to 26)
in said baffle ring (16) are all closed in response to a rising
temperature, thereby increasing the cross-sectional flow area through said
first gas exit openings (10 to 15) and also increasing the average flow
path length through said filter chamber (2) at a given high temperature,
said temperature responsive drive member (40) further driving said ring
slide (28) with its closing sections (29 to 34) so, that at least certain
of said first gas exit openings (10 to 15) are closed while said flow
ports (24 to 26) in said baffle ring are opened in response to a dropping
temperature, thereby decreasing the cross-sectional flow area through said
first gas exit openings (10 to 15) and also decreasing the average flow
path length through said filter chamber (2) at a given low temperature.
5. The gas generator of claim 4, wherein said ring slide (28) comprises a
cylinder structure having said flow port closing sections (32 to 34) in
the form of cylinder wall sections contacting said baffle ring (16) in a
slideable manner, said flow port closing sections having holes (35 to 37)
therein for cooperation with said flow ports (24, 25, 26) in said baffle
ring (16), said further closing sections (29 to 31) forming radially
inwardly projecting ridges of said cylinder structure for cooperating with
said first gas exit openings (10 to 15).
6. The gas generator of claim 5, wherein said flow port closing sections
(32 to 34) of said cylinder structure and said further closing sections
(29 to 31) of said cylinder structure alternate with each other in a
circumferential direction of said cylinder structure, thereby forming a
corrugated-type cross-sectional configuration of said cylinder structure.
7. The gas generator of claim 1, wherein said temperature responsive means
comprise a slide valve member (28) and a temperature responsive drive
member (40) having one end connected to said slide valve member and
another end connected to a fixed point in said gas generator, said drive
member having a high temperature expansion coefficient for changing its
length in response to temperature changes for driving said slide valve
member.
8. The gas generator of claim 7, wherein said reaction chamber has a
cylindrical wall (4), said temperature responsive drive member comprising
a rod wound into a coil surrounding said cylindrical wall of said reaction
chamber.
9. The gas generator of claim 8, further comprising a baffle (16)
surrounding said cylindrical wall with a spacing to form a ring space (39)
between said baffle and said cylindrical wall, said coil (40) of said
drive member being located in said ring space (39).
10. The gas generator of claim 9, wherein said slide valve member (28)
comprises a ring having a ring shoulder (38) facing and closing said ring
space (39) at one end thereof, said baffle (16) having a radially inwardly
directed flange (18) closing said ring space at the other end thereof.
11. A gas generator for inflating an inflatable article, comprising a
housing, a reaction chamber in said housing for generating gas, a filter
chamber arranged for receiving gas from said reaction chamber, first gas
exit opening means (10 to 15) in said reaction chamber for a gas flow from
said reaction chamber into said filter chamber, second gas exit opening
means (22) in said filter chamber for a gas flow from said filter chamber
into said inflatable article, temperature responsive flow control means
arranged in said gas generator for influencing a gas flow from said
reaction chamber into said inflatable article in such a way that an
inflation duration and an inflation pressure are substantially independent
of a gas generator temperature, and wherein said temperature responsive
flow control means are arranged to cooperate with said filter chamber for
increasing a flow path length through said filter chamber in response to a
rising of said gas generator temperature and for decreasing said flow path
length in response to a dropping of said gas generator temperature.
12. The gas generator of claim 11, wherein said reaction chamber has a
circular cross-section, wherein said filter chamber has a ring
configuration surrounding said reaction chamber, wherein said temperature
responsive flow control means comprise a ring slide (28) rotatably
surrounding said reaction chamber and a temperature responsive drive
member (40) connected to said ring slide for driving said ring slide
between closing and opening positions in response to temperature changes,
said ring slide having gas exit opening closing sections (29 to 31) for
cooperation with said first gas exit opening means (10 to 15) of said
reaction chamber to close said first gas exit opening means at least
partially when said ring slide (28) is in said closing position in
response to a lower gas generator temperature, and to open said first gas
exit opening means when ring slide is in said opening position in response
to a higher gas generator temperature. |
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Claims |
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Description |
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FIELD OF THE INVENTION
The invention relates to a gas generator for inflating an inflatable
article such as a safety bag forming part of an impact protection system
for persons in a vehicle or for inflating any other inflatable device such
as a rubber raft.
BACKGROUND INFORMATION
Such gas generators conventionally comprise a reaction or combustion
chamber in which the gas is generated and which is surrounded by a
ring-shaped filter chamber. Flow openings are provided in the wall which
separates the reaction or combustion chamber from the filter chamber.
Further flow openings are provided in the filter chamber wall for
permitting the generated and filtered gas to enter into the article or
device, such as a so-called "air bag" in an impact protection system.
German Patent Publication (DE-AS) 2,915,202 discloses a gas generator of
the above described type. It is desirable for such inflating devices,
especially when an air bag for a safety system is to be inflated, that the
inflating satisfies a certain efficiency. Stated differently, a safety air
bag must be inflated to a certain degree or rather to a certain internal
pressure within a defined inflating time. Additionally, the inflating time
and the inflating pressure shall be as much as possible independent of the
gas generator temperature at the time of ignition of the gas generating
fuel. The gas generator temperature may be within the range of about
-40.degree. C. to about +85.degree. C. However, conventional gas
generators are noticeably dependent in their efficiency from the
temperature to which they are exposed at the time of the ignition. As a
result, the air safety bag is inflated, for example at a temperature of
-40.degree. C., much slower and to a lesser inflation pressure than when
the same generator is exposed to a higher temperature at the time of
ignition.
On the other hand, the inflating characteristic or efficiency of the gas
generator must also be satisfactory when the generator is exposed to a
high temperature, for example, of +85.degree. C. In conventional gas
generators the inflating time at high temperatures is respectively shorter
and the inflating pressure of the safety bag is very high. As a result,
the safety bag must be constructed to withstand the higher pressures when
the inflating takes place with high gas generator temperatures. This makes
the air bags relatively more expensive and such air bags become heavier.
Still another undesirable characteristic of such air bags with a high
inflated pressure resides in the fact that the intended cushioning effect
may be substantially reduced.
Further, when the gas generating fuel is combusted, hot particles travel
from the combustion chamber into the filter chamber where these particles
are supposed to be filtered out of the inflating gas. The discharge of the
hot particles from the reaction or combustion chamber into the filter
chamber also depends on the temperature of the gas generator. In other
words, at a high temperature of about +85.degree. C. a relatively large
proportion of hot particles exits from the reaction chamber. As a result,
the filter and the filter chamber must be constructed to meet the
operating conditions at such high temperature. Such construction again
makes the filter chamber and the filter itself more expensive.
OBJECTS OF THE INVENTION
In view of the above it is the aim of the invention to achieve the
following objects singly or in combination:
to construct a gas generator of the type described above in which the
inflating time and the inflating pressure of an inflatable device such as
an air safety bag are substantially independent of the gas generator
temperature or the temperature to which the gas generator is exposed at
the time of ignition;
to make sure that also the discharge of hot particles from the combustion
chamber into the filter chamber is substantially independent of the gas
generator temperature; and
to vary the cross-sectional flow areas for the inflating gas and/or the
length of the path through which the inflating gas must travel, in
response to the gas generator temperature.
SUMMARY OF THE INVENTION
The above objects have been achieved according to the invention in a gas
generator of the type described above, wherein the total cross-sectional
flow area of the gas flow openings permitting a gas flow from the reaction
chamber into the filter chamber and/or the average gas flow path length
through which the generated gas must travel from the exit openings of the
reaction chamber to the exit openings of the filter chamber are varied in
response to the gas generator temperature. The control is such that with
an increasing temperature the total cross-sectional flow area of the gas
exit openings of the combustion chamber and/or the average flow path
lengths are increased while the cross-sectional flow area and/or the path
lengths are decreased in response to a dropping temperature.
According to the invention, preferably both controls are performed
simultaneously, namely the cross-sectional flow area may be increased
while the path length is increased or the flow cross-sectional area may be
decreased while the path length is decreased. However, performing both
controls simultaneously is not critical for achieving the objects of the
invention. It is quite possible to perform but one of the two controls,
namely the cross sectional flow area control, or the path lengths control.
In both instances it is quite possible to make the time required for the
inflating and the final inflated pressure substantially independent of the
gas generator temperature and to also reduce the difference between the
quantities of hot particles that are being ejected from the combustion
chamber at high temperatures and at low temperatures.
BRIEF DESCRIPTION OF THE DRAWINGS
In order that the invention may be clearly understood, it will now be
described, by way of example, with reference to the accompanying drawings,
wherein:
FIG. 1 is a cross-sectional view through a broken-away portion of a gas
generator according to the invention;
FIG. 2 shows a sectional view along section line A--A in FIG. 1,
illustrating the gas generator and its flow control at a relatively hot
temperature; and
FIG. 3 is a sectional view similar to that of FIG. 2, but showing the flow
control at a relatively cold temperature.
DETAILED DESCRIPTION OF PREFERRED EXAMPLE EMBODIMENTS AND OF THE BEST MODE
OF THE INVENTION
The gas generator comprises a reaction chamber 1 having, for example, a
cylindrical or toroidal configuration. The reaction chamber 1 is filled
with a gas generating fuel not shown. The fuel is ignited by an ignition
device also not shown, but of conventional construction. The ignition
device is located for example coaxially with the central axis of the
reaction chamber. The ignition signal is generated by an impact sensor not
part of the invention. The reaction or combustion chamber 1 is
concentrically surrounded by a filter chamber 2 also having a toroidal or
ring-shaped configuration.
The housing of the reaction chamber 1 and the housing for the filter
chamber 2 comprise a common housing shell 3 having a radially inner wall 4
which forms a dividing wall between the combustion chamber 1 and the
filter chamber 2. Additionally, the housing shell 3 has a bottom 4' which
closes the combustion chamber 1, and a radially outer rim wall 4" which
faces an inflatable article such as a safety air bag 9 shown by a dashed
line. The filter chamber 2 is formed between the radially inner wall 4 and
the outer rim wall 4". The top of the combustion chamber 1 is closed by a
cover 5. The top of the filter chamber 2 is closed by a shell section 6
interconnecting the inner wall 4 with the outer rim wall 4". Such a
housing construction corresponds to that disclosed in the above mentioned
German Patent Publication (DE-AS) 2,915202. The bottom 4', the wall 4, and
the shell section 6 form an approximate S-configuration in the
cross-sectional view. The wall 4, the shell section 6, and the rim wall 4"
form substantially an inverted U-configuration in the sectional view. The
downwardly facing end of the filter chamber 2 is closed by a sheet metal
ring element 7 having a radially outwardly extending ring flange 8 which
is used for mounting the gas generator.
As shown in FIG. 1, the article to be inflated such as an air safety bag 9
is arranged in a bellows type folding that surrounds one side of the gas
generator. The safety bag 9 covers the upwardly facing surfaces of the gas
generator including the radial flange 8. This arrangement is suitable for
installation in the steering wheel of a motor vehicle, especially a
passenger car. However, the invention is not limited to this particular
type of use. Rather, the present gas generator is generally suitable for
generating pressurized inflating gas, for example, for inflating life
rafts or the like.
First, gas exit openings 10, 11, 12, 13, 14, and 15 are provided in the
housing wall 4 to permit generated gas to flow from the combustion chamber
1 into the filter chamber 2. Second gas exit openings 22 are provided in
the housing rim wall 4" to permit filtered gas to exit from the filter
chamber 2 into the air bag 9.
A deflection baffle or flow guide 16 is arranged in the filter chamber 2 to
concentrically surround the combustion chamber 1. The baffle 16 has an
upper radially inwardly extending flange 18 dimensioned to provide an
upper ring space 39 between the wall 4 and the upper portion of the wall
17 of the baffle 16. The wall 17 of the baffle 16 is substantially
cylindrical and may have an upper section with a smaller diameter and a
lower section with a somewhat larger diameter. The two sections are
interconnected by a slanted step. The lower section of the cylindrical
wall 17 of the baffle 16 encloses a lower ring space 27 between the wall 4
and the wall 17. The baffle 16 further has a lower radially outwardly
directed flange 19 connected to the downwardly facing edge of the rim wall
4".
The cover sheet metal member 7 and the flange 19 form a lower portion of
the filter chamber 2. The lower filter chamber portion communicates with
the lower ring space 27 through a ring gap RG. Additionally, the lower
filter chamber portion communicates with the upper portion of the filter
chamber 2 through holes 23 in the flange 19. A first ring shaped filter
body 20 is located in the lower filter chamber portion. A section filter
21 is located in the upper portion of the filter chamber between the main
section 17 of the baffle 16 and the outer rim wall 4" of the housing. The
baffle 16 is provided with flow ports 24, 25, and 26 in its main section
17. Thus, the generated gas can follow a shorter flow path through the
first exit openings 10 to 15, through the flow ports 24, 25, 26, and out
through the second exit openings 22. Alternatively, the generated gas can
take a longer path through the exit openings 10 to 15, the ring gap RG,
the first filter 20, the holes 23, the second filter 21, and out through
the second flow openings 22. The conditions under which the generated gas
will take one or the other path depend on the temperature responsive
control according to the invention to be described below.
The temperature responsive flow control means according to the invention,
comprise a ring slide 28 located in the ring space 27 between the wall 4
and the main section 17 of the baffle 16 where the gas exit openings 10 to
15 and the flow ports 24 to 26 are located. The ring slide 28 functions as
a valve. For this purpose, the ring slide 28 is rotatably supported for
movement back and forth around the housing wall 4. The slide 28 is
constructed as a cylinder of a corrugated type sheet metal. The
corrugations comprise radially inwardly directed ridges 29, 30, 31 which
form closing sections cooperating with at least certain first gas exit
openings 10 to 15 in the housing wall 4. The slide 28 has further
circumferentially wider corrugations which form radially outwardly facing
wall sections 32, 33, and 34 provided with holes 35, 36, and 37 for
cooperation with the flow ports 24, 25, and 26 in the baffle 16. The slide
28 is so constructed that the radially inwardly directed ridges 29, 30,
and 31 slide along the radially outwardly directed surface of the housing
wall 4 while the radially outwardly directed sections 32, 33, and 34 slide
along the radially inwardly facing cylindrical surface of the main section
17 of the baffle 16. Thus, the ridges 29, 30, and 31 cooperate with at
least some of the gas exit openings 10 to 15 while the flow port closing
wall sections 32, 33, and 34 cooperate with the flow ports 24, 25, and 26
in the main section 17 of the baffle 16. In FIG. 2, the wall sections 32,
33, and 34 close the flow ports 24, 25, and 26 while in FIG. 3 the holes
35, 36, and 37 are aligned with the flow ports 24, 25 and 26 respectively,
to permit a direct flow from the combustion chamber 1 into the upper
portion of the filter chamber 2. The holes 35, 36, and 37 in the wall
sections 32, 33, and 34 of the slide 28 may be stamped into the sheet
metal of which the slide 28 is made. Further, the upward edge of the slide
28 is formed as a shoulder 38 best seen in FIG. 1. The shoulder 38 closes
the ring space 39 formed, as mentioned above, between the flange 1 and the
shoulder 38 on the one hand and between the wall 4 and the cylindrical
section 17 of the baffle 16.
According to the invention the temperature responsive control means further
comprise a drive member 40 which is changing its physical characteristic,
for example, its length, in response to temperature changes. The member 40
comprises, for example, a rod of a material having a high heat expansion
coefficient. The rod 40 is, for example, wound into a coil having three
windings located in the upper ring space 39. One end of the coil of the
drive member 40 is connected to the upper shoulder 38 of the slide 28
while the other end of the coil is secured either to the inner wall 4 of
the housing or to the baffle 16, in any event to a fixed point.
The temperature responsive drive member 40, due to its high heat expansion
coefficient, shortens its length in response to a temperature drop while
it lengthens in response to a temperature rise. Thus, the slide 28 is
driven to slide around the housing wall 4 in one or the other direction
for moving the closing sections 29, 30, and 31 relative to the gas exit
openings 11, 13, and 15 while moving the flow port closing wall sections
32, 33, and 34 relative to the flow ports 24, 25, and 26 in accordance
with or in response to the respective temperature conditions which are
present in the generator at the time the gas generating fuel is ignited in
the reaction chamber 1.
The slide 28 is properly guided in the ring space 27 by the wall 4 and the
baffle 16. Additionally, the wall 4 protects the temperature responsive
drive member 40 against the influence of the hot inflating gas and against
the hot particles carried by this gas. The temperature responsive drive
member 40 is, for example, made of a polyethylene rod wound into the above
mentioned coil. In the downward direction the slide 28 is supported by a
shoulder of the baffle 16. The slide 28 cooperates with the first gas exit
openings 10 to 15 in response to temperature in such a way that at a given
maximum temperature of, for example +85.degree. C., all first gas exit
openings 10 to 15 will be unobstructed, thereby providing the largest
cross-sectional flow area at this maximum temperature. At this time, the
closure sections 29, 30, and 31 are located outside the respective
openings 11, 13, and 15 as shown in FIG. 2, representing the high
temperature operational state of the slide 28. On the other hand, FIG. 3
shows the low temperature operational state of the slide 28 in which the
closing ridges or sections 29, 30, and 31 close off the exit openings 11,
13, and 15 so that the cross-sectional flow area is reduced by 50%.
As a result of the just described operation of the slide 28 in response to
temperature, more specifically, when ignition begins in a gas generator
chamber at a low temperature, the closing of half of the exit openings 10
to 15 results in the build-up of a higher pressure in the chamber 1 as
compared to the situation when all the openings 10 to 15 would be open and
the temperature would be equally low at the beginning of the ignition. Due
to this pressure increase, the combustion in the reaction chamber 1 is
accelerated so that the inflating time of the safety air bag 9 is reduced
and hotter inflating gas, in other words, a larger inflating gas volume,
is supplied into the bag 9 as compared to the gas generator in which the
gas exit openings have a constant total cross-sectional flow area
independently of the temperature.
Simultaneously with the decrease in the cross-sectional flow area by the
closing of the gas exit openings 11, 13, and 15 as shown in FIG. 3 at the
cold state of the combustion chamber 1, the average gas flow path length
is also reduced or shortened in the cold state of the generator. As shown
in FIG. 3, gases passing through the openings 10, 12, and 14 can flow
through the gas flow ports 24, 25, and 26 so that they do not have to pass
through the ring gap RG and through the first filter 20. For this purpose
the slide 28 as shown in FIG. 3 is so positioned that the holes 35, 36,
and 37 are located to register with the gas flow ports 24, 25, and 26
respectively to open up the above mentioned shorter flow path length.
Thus, the gas flow is directly into the second filter 21 and out through
the section gas exit openings 22, thereby bypassing the first filter 20.
On the other hand, when the generator is at a higher temperature, at the
beginning of the fuel ignition, the slide 28 is in the position shown in
FIG. 2 in which the flow ports 24, 25, and 26 are closed, thereby
increasing the average gas flow path length since now the gas must travel
through the ring gap RG, the filter 20, the holes 23, the filter 21, and
out through the second gas exit openings 22.
In view of the above, the invention achieves a filling efficiency for the
safety bag 9 which is substantially independent of the temperature of the
generator at the time the gas generating fuel is ignited. This is so
because when the gas generator is cold, the generated gas flows relatively
uncooled, that is, with a higher temperature and hence with a
correspondingly higher volume into the bag 9 along the shorter flow path
as illustrated in FIG. 3, thereby increasing the filling efficiency.
On the other hand, when the fuel ignition takes place at a given maximum
temperature of, for example +85.degree. C., the operational state of the
slide 28 as shown in FIG. 2 makes sure that the gas must follow the longer
path as described above, whereby the gas is relatively cooled down. By
keeping all first gas exit openings 10 to 15 open as shown in FIG. 2, the
pressure in the reaction chamber 1 is respectively reduced. As a result,
the temperature of the inflating gas is also reduced along with the
pressure in the bag 9 so that the inflating time is also reduced along
with the quantity of hot particles travelling out of the reaction or
combustion chamber 1 with the generated gas. The result is a normally
inflated bag that does not become too hard.
Although it is preferred to make the slide 28 of sheet steel, other
materials may be used for making the slide 28, for example,
polytetrafluoroethylene, or cast aluminum may be used.
It is advantageous that the closure sections 29, 30, and 31 as well as the
openings or holes 35, 36, and 37 have rectangular configurations with
straight edges. This feature assures that a relatively linear control of
the entire cross-sectional flow area through the openings 10 to 15 and/or
of the average length of the flow path is achieved as a function of
temperature changes. For the same reason, the cross-sectional flow areas
of the first gas exit openings 10 to 15 and/or the respective
cross-sectional flow areas of the flow ports 24 to 26 in the baffle 16
could also have a rectangular configuration.
Although the invention has been described with reference to specific
example embodiments it will be appreciated that it is intended to cover
all modifications and equivalents within the scope of the appended claims.
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