DE20300500U1 - Gas generator and gas bag module - Google Patents

Description

PRINZ &PARTNERobR" ^: " ^: " ^: '"'

PATENT ATTORNEYS Manzingerweg 7

EUROPEAN PATENT ATTORNEYS D-81241 Munich

EUROPEANTRADEMARKATTORNEYS ^{Tel +49} 89 89 69

TRW Occupant Restraint Systems GmbH & Co KG
Industriestrasse 20
D-73553 Alfdorf

Our reference: T10317 DE
KI/da/mr

Gas generator and gas bag module

The invention relates to a gas generator with an elongated housing and a gas outlet nozzle, wherein the gas outlet nozzle has a diffuser section with a plurality of outflow openings and the axial length of the gas outlet nozzle is less than the axial length of the gas generator. The invention also relates to a gas bag module with such a gas generator.

Gas generators with gas outlet nozzles, through which the gas generated in the generator leaves the gas generator centrally, have the problem that an impulse is generated when the gas generator is ignited, meaning that the gas generator does not behave in a thrust-neutral manner. If the gas bag is installed in the module or in the vehicle, this behavior is not critical, but special transport locks that make the gas generator at least approximately thrust-neutral must be used to transport the gas generator. However, it is an additional work effort to install such transport locks and then remove them again before installing the gas generator in a module or vehicle.

The invention provides a simplification here. In the case of a gas generator mentioned above, radially directed outflow openings (i.e. outflow openings whose cross-sectional area is essentially perpendicular to the radial direction of the gas outlet nozzle) and axially directed outflow openings (i.e. outflow openings whose cross-sectional area is essentially perpendicular to a longitudinal axis of the gas outlet nozzle) are provided on the diffuser section with respect to the gas outlet nozzle.

zens), and/or outlet openings directed at an angle to the longitudinal axis of the gas outlet nozzle. By simultaneously providing radial and axial outlet openings or outlet openings directed at an angle, the impulse component of the gas in the longitudinal direction of the gas outlet nozzle can be reduced to such an extent that the gas generator no longer poses a hazard during transport. The diffuser section serves as a transport safety device, but does not have to be removed before the gas generator is installed in a module or in a vehicle.

Of course, obliquely directed outlet openings can also be combined with radially or axially directed outlet openings.

A further advantage of the gas generator according to the invention is that a targeted gas distribution can be carried out through the diffuser section, which is particularly advantageous in the case in which a gas bag is directly connected to the gas outlet nozzle of the gas generator.

Preferably, the total radially directed surface area of the outflow openings is larger than the total axially directed surface area of the outflow openings in order to ensure that the gas generator is approximately thrust neutral. If a gas line pipe is connected to the gas outlet nozzle, the axial surface area of the outflow openings must, however, be large enough to ensure sufficient gas flow through the gas line pipe. The respective surface area is understood here to mean the proportion of the cross-sectional area of the outflow opening in a projection in the axial or radial direction.

The total area of the outlet openings is preferably larger than the cross-sectional area of the gas outlet nozzle in order to ensure a sufficiently high gas flow.

At least some of the outlet openings can be designed like gills, which allows the outlet behavior of the gas to be influenced via another parameter.

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The diffuser section can either be formed integrally with the gas outlet nozzle or as a separate component which is connected to the base of the gas outlet nozzle, for example by caulking.

In the case that the diffuser section is a separate component, it is advantageous if it is cap-shaped, since the outflow openings with the desired orientations can easily be formed in a cap.

In a first embodiment of the gas generator, the diffuser section has a hemispherical or conical shape at its free end. It does not matter whether the diffuser section is formed in one piece with the gas outlet nozzle or is a separate component. Thanks to their cross-section tapering in the axial direction, a hemispherical shape, a conical shape or any shape in between allows for sufficiently obliquely directed outflow openings to be provided in order to have a sufficiently large axially directed surface area to ensure the necessary gas flow from the diffuser section despite a large radially directed surface area of the total area. Other shapes with a section tapering in the axial direction of the gas outlet nozzle can of course also be used.

In a second embodiment, the gas generator is designed with a diffuser section, at the free end of which one or more gap-shaped outflow openings are provided. The width of the gap or gaps is preferably less than 2 mm. The gaps can be formed, for example, by a narrowing of the free end of the diffuser section, which can be brought about, for example, by caulking the free end.

The first embodiment of the gas generator can preferably be used in a gas bag module in which a gas line pipe is attached to the gas outlet nozzle, with the diffuser section located inside the gas line pipe. The wall of the gas line pipe then closes at least some of the radially directed outflow openings, since the diameters of the diffuser section and the gas line pipe in the area of the attachment of the gas line pipe to the gas outlet

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It is possible that the gas pipe closes all radially directed outlet openings. The diffuser section is designed in such a way that, despite the partial or complete closure of radially or obliquely directed outlet openings, a sufficiently large total outlet area is maintained so as not to impair the outlet characteristics of the gas generator.

Both described embodiments of the gas generator, but particularly the second embodiment, can be used in a gas bag module in which a gas bag is provided which is attached to the gas outlet nozzle with an inflow section. The number and position of the radially directed outflow openings and the width of the gap can be used to easily influence the direction and distribution of the gas flowing into the gas bag and thus the inflation behavior of the gas bag.

To attach the gas bag to the gas generator, a sleeve is preferably provided which surrounds the inflation mouth and the gas outlet nozzle, whereby the sleeve and the gas outlet nozzle are caulked together in such a way that the inflation mouth of the gas bag is clamped between the sleeve and the wall of the gas outlet nozzle. A hose clamp can of course also be used.

Further features and advantages of the invention will become apparent from the following description of several embodiments in conjunction with the accompanying drawings, in which:

- Figure 1 is a schematic sectional view of an airbag module according to the invention with an inventive gas generator according to a first embodiment and a gas line pipe attached to the gas generator;

- Figure 2 shows a gas generator according to the invention according to a variant of the first embodiment;

- Figure 3 shows a gas bag module according to the invention with a gas generator according to the invention according to a second embodiment and a gas bag attached to the gas generator;

- Figure 4 shows a gas bag module according to the invention with a gas generator according to the invention according to a variant of the second embodiment:

- Figure 5 is another view of the gas generator from Figure 4; and

- Figure 6 shows the gas generator from Figure 4 in a plan view.

Figure 1 shows a gas bag module 10 with a gas generator 12 according to a first embodiment. The gas generator has an elongated, cylindrical housing 14, on the peripheral surface of which a radially protruding gas outlet nozzle 16 is arranged. The axial length of the gas outlet nozzle 16 is less than the axial length of the gas generator 12.

A cap-shaped diffuser section 18 is attached to the free end of the tubular extension of the gas outlet nozzle 16 in the direction of the longitudinal axis A of the gas outlet nozzle. The attachment is made here by caulking, but other types of attachment are also conceivable. In the examples shown here, the diffuser section 18 and the gas outlet nozzle 16 are each separate components, but it is also possible to form the diffuser section 18 in one piece with the gas outlet nozzle 16.

In the embodiment shown in Figure 1, the cap-shaped free end of the diffuser section 18 has a hemispherical shape. In the variant shown in Figure 2, the diffuser section 18 is conical.

A large number of outflow openings 20 are provided on the diffuser section 18. A portion of the outflow openings 20a, namely those arranged near the gas outlet nozzle 16, have a cross-sectional area in the radial direction (radially directed), while the remaining outflow openings 20b are directed obliquely to the longitudinal axis A of the gas outlet nozzle. A portion of the total area of the

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Outflow openings 20 are therefore directed radially, while another part of the total surface area of the outflow openings 20 is directed axially.

The diffuser section 18 serves in a first function as a transport lock for the gas generator 12. Due to the radially directed surface portion of the outflow openings 20, a part of the outflowing gas is deflected from the axial direction A in the radial direction (arrows), so that the total impulse of the gas generator 12 is significantly reduced compared to a radially closed and axially open gas outlet nozzle.

The diffuser section 18 is not removed prior to mounting the gas generator 12 in a module or on a vehicle.

If, as in the example shown in Figure 1, the gas generator is connected to a gas line pipe 22 (e.g. by caulking), through which the gas is guided to a more distant gas bag (not shown), the radially directed outflow openings 20a are preferably completely (see upper half of Figure 1) or partially (see lower half of Figure 1) closed by the wall of the gas line pipe 22. The diffuser section 18 is, however, designed in such a way that a sufficiently large total outflow area remains open to allow the gas to flow out of the gas generator 12 unhindered.

The gas generator shown in Figure 2 corresponds to the one described above, only the diffuser section 18 is in the shape of a cone and not in the shape of a hemisphere. Hemisphere and cone shapes are mentioned here as examples. Other shapes that have a section tapering in the axial direction A can also be used.

A further function of the diffuser section is explained below in connection with the description of a second embodiment of the gas generator. The reference numerals already assigned will continue to be used for components already described.

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The gas bag module 100 shown in Figures 3 and 4 has a gas generator 112 which, analogously to the first embodiment, is provided with a diffuser section 118 attached to the base of the gas outlet nozzle 16. The wall of the diffuser section 118 is provided with radially directed outflow openings 120, while the free end 130 of the diffuser section 118 is narrowed to a gap 132 by caulking (or another suitable technique). In the embodiment shown in Figures 4 to 6, the outer surface of the diffuser section 118 forms two oblique guide surfaces 134 at the transition from the cylindrical geometry to the gap 132. The gap 132 represents an axially directed outflow opening. The narrowing can also be designed so that several gaps result. The width of the gap or gaps 132 is preferably less than 2 mm.

A gas bag 140 is connected directly to the gas outlet nozzle 16 of the gas generator 112. For this purpose, a sleeve 150 is pushed over the gas outlet nozzle 16 and the diffuser section 118 in such a way that it encompasses an injection mouth 160 of the gas bag 140 on the circumference. The sleeve 150 is caulked to the gas outlet nozzle 16 or the diffuser section 118 in such a way that the injection mouth 160 of the gas bag 140 is gas-tight and firmly clamped.

The diffuser section 118 is used in the gas bag module 100 specifically to distribute the gas flowing out in the gas bag 140. The precise design of the radially directed outflow openings 120 and the gap 132 allows the filling behavior of the gas bag 140 to be adjusted very precisely.

However, even in this case, the total impulse of the gas generator 12 during ignition is significantly reduced compared to a gas generator with an axially open and radially closed gas outlet nozzle.

Figure 4 shows a variant of the gas bag module from Figure 3. Here, too, radially directed outflow openings 120 and an axially directed gap-shaped outflow opening 132 are provided (see also Figures 5 and 6).

The gas generators shown in Figures 3 to 6 can also be used together with a gas distributor such as the gas line pipe 22 shown in Figure 1.

The diffuser sections 18 presented in Figures 1 and 2 can also be used like the diffuser section 118 just described for the targeted distribution of the gas in a gas bag.

All of the outflow openings 20, 120 can also be designed in the form of gills designed in a known manner in order to additionally influence the gas outflow. Of course, only some of the outflow openings can also be designed as gills.

Overall, the total area of the outlet openings 20 is larger than the cross-section of the gas outlet nozzle 16.

In the examples shown here, the gas outlet nozzle protrudes radially from a peripheral surface of the housing. However, the invention can easily be transferred to gas generators with gas outlet nozzles arranged axially on the gas generator.

Claims (16)

1. Gas generator with an elongated housing ( 14 ) and a gas outlet nozzle ( 16 ),
wherein the gas outlet nozzle ( 16 ) has a diffuser section ( 18 ; 118 ) with a plurality of outflow openings ( 20 ; 120 , 132 )
and the axial length of the gas outlet nozzle ( 16 ) is less than the axial length of the gas generator ( 12 ),
characterized in that on the diffuser section ( 18 ; 118 ) a) with respect to the gas outlet nozzle ( 16 ) radially directed outflow openings ( 120 ) and axially directed outflow openings ( 132 ) and/or b) outflow openings ( 20 ) are formed which are directed obliquely to a longitudinal axis (A) of the gas outlet nozzle ( 12 ). 2. Gas generator according to claim 1, characterized in that the total radially directed surface area of the outflow openings ( 20 ; 120 , 132 ) is larger than the total axially directed surface area of the outflow openings ( 20 ; 120 , 132 ). 3. Gas generator according to one of the preceding claims, characterized in that at least some of the outflow openings are gill-shaped. 4. Gas generator according to one of the preceding claims, characterized in that the gas outlet nozzle ( 16 ) projects radially from a peripheral surface of the housing ( 14 ). 5. Gas generator according to one of the preceding claims, characterized in that the diffuser section ( 18 ; 118 ) is a separate component. 6. Gas generator according to claim 5, characterized in that the diffuser section ( 18 ; 118 ) is caulked to a projection of the gas outlet nozzle ( 16 ). 7. Gas generator according to one of claims 5 and 6, characterized in that the diffuser section ( 18 ; 118 ) is cap-shaped. 8. Gas generator according to one of the preceding claims, characterized in that the diffuser section ( 18 ) has a hemispherical or conical shape at its free end ( 130 ). 9. Gas generator according to one of the preceding claims, characterized in that one or more gap-shaped outflow openings ( 132 ) are provided at the free end ( 130 ) of the diffuser section ( 118 ). 10. Gas generator according to claim 9, characterized in that the width of the gap ( 132 ) or the gaps is less than 2 mm. 11. Gas generator according to one of claims 9 and 10, characterized in that the gap or gaps ( 132 ) are formed by a narrowing of the free end ( 130 ) of the diffuser section ( 118 ). 12. Gas bag module according to one of the preceding claims, characterized in that a gas line pipe ( 22 ) is attached to the gas outlet nozzle ( 16 ), the diffuser section ( 18 ) being located inside the gas line pipe ( 22 ). 13. Gas bag module according to claim 12, characterized in that the gas line pipe ( 22 ) closes radially directed outflow openings ( 20 ) on the gas outlet nozzle ( 16 ). 14. Gas bag module according to claim 13, characterized in that the gas line pipe ( 22 ) closes all radially directed outflow openings ( 20 ). 15. Gas bag module with a gas generator ( 12 ; 112 ) according to one of claims 1 to 11 and a gas bag ( 140 ), characterized in that the gas bag ( 140 ) is fastened with its inflation mouth ( 160 ) to the gas outlet nozzle ( 16 ). 16. Gas bag module according to claim 15, characterized in that a sleeve ( 150 ) is provided which encompasses the inflow section ( 160 ) and the gas outlet nozzle ( 16 ), and that the sleeve ( 150 ) and the gas outlet nozzle ( 16 ) are caulked together such that the inflation mouth ( 160 ) of the gas bag ( 140 ) is clamped between the sleeve ( 150 ) and the wall of the gas outlet nozzle ( 16 ).