DE4440247A1 - LPG generator - Google Patents

Abstract

A liquid gas generator for inflatable air bags that protect vehicle passengers in the event of a collision has a housing, a closed liquid gas reaction container (7) arranged in the housing, a cavity (9) arranged in the housing next to the reaction container (7), a firing element (4), and a piercing element (16) movable in the cavity that pierces a wall of the reaction container (7) when the firing element (4) is actuated, allowing the liquid gas combustion gases to escape from the reaction container (7) into the cavity (9) and from there out of the housing into the air-bag. In order to make it easier to open and pierce the reaction container (7) and to generate gas in a controlled and reproducible manner during the whole service life of the liquid gas generator, the piercing element (16) pierces with its whole length the wall of the reaction container (7) and penetrates in its entirety into the reaction container (7).

Description

The invention relates to a liquid gas generator according to the preamble of Claim 1.

In passive safety devices for motor vehicles, where drivers or Passenger thanks to inflatable impact protection cushions against injuries from impact be protected on the steering wheel or dashboard (also called air bag), are used to generate gas either gas generators with fixed propellant charge Set or gas generators with compressed gas under pressure (Hybrid generator, compressed air generator) or alternators with liquid gas mixtures, some of which are actively involved in combustion. The advantages of gas mixtures over fixed propellant charge sets at Use in a generator is well known. A problem with gas or liquid gas generators is that the pressurized gases in a container must be enclosed, which in the application, d. H. at Function triggering of the generator must be opened in a defined manner.

DE 42 41 221 A1 describes a liquid gas generator for an inflatable Impact protection cushion to protect a motor vehicle occupant from injuries known. The LPG generator has a housing in which a reaction container with LPG is housed. To trigger combustion of the Liquid gas is a breakdown element with an overflow channel drove. The kinetic energy for the breakdown element becomes pyrotechnic generated by initiating an igniter. The fumes from the Ignition element reach the inside of the overflow channel Reaction vessel, where they initiate the combustion of the liquid gas. The Combustion gases are released through the overflow channel the reaction vessel out into a cavity in which the breakthrough element is arranged. The cavity is opposed by a bursting membrane an outflow chamber (through hole) closed. This bursting membrane breaks up when a minimum pressure of the combustion gases is reached and gives thus the way to discharge the combustion gases via the outflow space (Through hole) out of the housing.  

The disadvantage of this is that the punch element or the striking piece is direct must be on the reaction vessel, otherwise there will be behind the hammer Can build up pressure, which ver penetration of the reaction container prevents. There is also a risk that the striking piece is asymmetrical is stressed, which in turn can lead to uncertainties when penetrating. A major disadvantage is the necessary bursting membrane, through which the Cavity is designed as a pressure chamber. First, these bursting membranes extremely expensive and secondly, when using only one bursting membrane Recoil generated by the escaping gas, which is an undesirable spin moment of the gas generator.

The invention has for its object a liquid gas generator according to the Improve the preamble of claim 1 such that the opening or Strikethrough of the reaction vessel is simplified and that over the Total operating time controlled and reproducible gas generation.

According to the invention, a liquid gas generator is used to achieve this object beaten, the housing of a closed reaction vessel to open Inclusion of liquid gas. A cavity is formed in the housing, which adjoins this when the reaction container is inserted. Is in the cavity slidably arranged a breakdown element, the ignition of a Ignition element with its entire length through the wall of the reaction is driven through and fully immersed in the reaction vessel. After puncturing or punching the wall of the reaction container through the breakdown element and further penetration of the breakdown elements in the previously closed reaction container is therefore a Ver bond with the diameter of the punch element.

A major advantage is the lack of a separate pressure chamber Rupture disc. This gives a decisive price advantage. By the The absence of a rupture disc is simply a symmetrical outflow through a to achieve a larger number of outflow bores across the diameter. A recoil or an undesired torque is avoided. On Another advantage is the simple construction of the gas generator, the quasi only is to be made from rotationally symmetrical components.

The punch element is advantageously a solid body.  

In a preferred embodiment of the invention is for better through punch / punch through the wall of the reaction vessel element as projectile, d. H. Cylinder with attached cone, ball, cylinder, etc. educated.

In an advantageous embodiment, the ignition element contains a squib.

To trigger the LPG generator, the igniter or Detonator ignited. The combustion gases that are generated when the Ignition element arise, drive the breakdown element through the wall of the reaction container. Ignition element and breakdown element are like this connected to each other that in any case a clean punching the Partition is guaranteed. By penetrating the following are called Gases in the reaction container and the outflow of the liquid gas mixture in the cavity ignites and reacts LPG mixture. The resulting combustion gases are removed from the Cavity outgoing overflow channels derived. By shape, location and diameter of the overflow channels can control the gas generation become reproducible. This can make the use more complex Rupture disks in this area are not required. The in the overflow channels Coming combustion gases pass through drain holes in the housing out of the gas generator where they have the folded impact protection cushion inflation.

As already mentioned, the breakdown element is advantageously in Projectile form trained to a safe and defined penetration of the Ensure partition. The breakdown element is advantageously included the ignition element or a sleeve connected via a tear-off edge, so only after a defined pressure has arisen, caused by the ver combustion gases of the igniter, the breakdown element with high Can set energy in motion.

Alternatively, a radial extension and / or in the Guide sleeve arranged a radial constriction.  

To achieve the energy necessary to break through the wall advantageously between the breakdown element and the ignition element a cavity (exploitation of the combustion gases) arranged. The cavity is conveniently filled with a charge. Charging is an advantage a pyrotechnic propellant powder or ignition mixture like e.g. B. nitrocellulose, a boron potassium nitrate mixture or a black powder mixture. According to the invention, the ignition element is advantageously provided with a ver cylindrical guide sleeve for guiding the punch element see.

The breakdown element advantageously consists of a temperature stable combustible molded part, which after penetration into the Reaction vessel due to the high resulting during the conversion of the gas Temperature is burned with. Another advantage is that when it flows back of the breakthrough element through the opening, none when burned Overflow channel can clog more. The punch element is preferred, the tear-off edge and the sleeve are a molded part.

The wall to be penetrated by the penetration element is expedient of the reaction container a rupture disc, which is preferably in the lid of a Cap of the reaction container is integrated.

Further features result from the figures, which are described below are. It shows:

Fig. 1 is a liquefied gas generator according to the invention in section;

Fig. 2 shows a first embodiment of an ignition element in partial section and

Fig. 3 shows a second embodiment of an ignition element in section.

Fig. 1 shows a liquid gas generator 1 according to the invention, which consists in wesent union of a head piece 2 , a bottom piece or adapter 9 and a cylindrical discharge pipe 10 . In the outflow pipe 10 outflow holes 11 are arranged. In addition, a reaction container 7 is arranged in the outflow pipe 10 or in the liquid gas generator 1 as an intrinsically pressure-resistant bottle. In this reaction container 7 there is liquid gas or a liquid gas mixture.

The reaction container 9 serves as a storage container and as a combustion chamber of the liquid gas mixture. The end of the reaction container 9 is closed by a rupture disk 5 . The rupture disc 5 is integrated in the lid of a closure cap 18 . This closure cap 18 is screwed into the head piece 2 via a thread 20 such that a cavity 9 is adjacent to the rupture disk 5 . Overflow channels 6 lead from the cavity 9 into the intermediate space between the reaction container 7 and the discharge pipe 10 . An ignition element holder 3 with an ignition element 4 is also arranged in the head piece 2 . The front tip of the ignition element 4 has a penetration element 16 designed as a projectile and projects with it into the cavity 9 . The ignition element 4 lies on the longitudinal axis 21 of the reaction container 7 .

The reaction container 7 is advantageously made of tempered steel. The housing is also advantageously made of steel or aluminum.

Fig. 3 shows a variant of the ignition element. 4 The ignition element 4 is inserted into the ignition element holder 3 . The ignition element 4 consists of a squib 12 and a cavity between the striking element 16 and squib 12 which is filled with a charge 13 . The punch element 16 is firmly connected to the ignition element 4 by shaping via a sleeve 14 with a tear-off edge 15 . In the event of ignition, the ignition element 4 is ignited, the gases and hot particles that are ignited ignite the charge 13 . Since the penetration element 16 , which is firmly connected to the ignition element holder 3 via the sleeve 14 and tear-off edge 15 , cannot start to move, pressure build-up is determined by the thickness of the tear-off edge 15 . After a certain defined pressure has been reached, the breakdown element 16 and the sleeve 14 tear off very quickly at the tear-off edge 15 . The guide sleeve 17 of the ignition element holder 3 leads to a directional acceleration of the breakdown element 16 . The penetration element is accelerated in the guide sleeve 17 by the combustion gas pressure (principle of a projectile in a short barrel).

After the breakdown element 16 has been separated from the ignition element holder 3 or ignition element 4 , the breakdown element 16 crosses the cavity 7 of the head piece 2 and penetrates the rupture disk 5 , which separates the liquid gas mixture in the combustion chamber 8 from the head piece 2 or cavity 9 (see FIG. 1). . The LPG mixture in the combustion chamber 8 is ignited by the hot gases and hot particles of the ignition element 4 following the breakdown element 16 . A volume expansion into the cavity 9 of the head piece 2 takes place via the opening of the rupture disk 5 and thus the inflation of the gas bag begins via the overflow channels 6 and the outflow bores 11 . The gas flow and pressure increase in the cavity 9 of the head piece 2 can be controlled in a defined manner by position, diameter and by the number of overflow channels 6 . The penetration element 16 can consist of a temperature-stable, combustible molded part (plastic or metal) which is designed as a projectile. Due to the high temperature arising during the conversion of the liquid gas mixture, the penetration element 16 burns after penetrating into the combustion chamber 8 .

Fig. 2 shows a slightly different from FIG. 3 embodiment of the striking element 16 and the charge 13th The punch element 16 is not connected to the sleeve 14 or the ignition element 4 via a tear-off edge 15 . For this purpose, a radial extension 31 is arranged on the penetration element 16 . Alternatively, a radial constriction 30 can also be provided in the guide sleeve. Both measures, like the tear-off edge 15 in FIG. 3, cause a directed acceleration of the penetration element 16 only after a certain pressure has been reached.

Claims (13)

1. LPG generator for an inflatable impact protection cushion to protect a motor vehicle occupant from injury, with

• - a housing,
• - A closed reaction container ( 7 ) arranged in the housing for holding liquid gas,
• - A cavity ( 9 ) in the housing adjoining the reaction container ( 7 ),
• - an ignition element ( 4 ),
• - And in the cavity ( 9 ) movable breakdown element ( 16 ) for breaking through a wall of the reaction container ( 7 ) upon initiation of the ignition element ( 4 ), the combustion gases of the liquid gas from the reaction container ( 7 ) into the cavity ( 9 ) and get there from the housing to the impact protection cushion,

characterized in that the entire length of the penetration element ( 16 ) penetrates one wall of the reaction container ( 7 ) and fully immerses it in the reaction container ( 7 ). 2. LPG generator according to claim 1, characterized in that the breakthrough element ( 16 ) is a solid body. 3. LPG generator according to claim 1 or 2, characterized in that the penetration element ( 16 ) is designed as a projectile. 4. LPG generator according to one of claims 1 to 3, characterized in that the penetration element ( 16 ) via a tear-off edge ( 15 ) with the ignition element ( 4 ) or a sleeve ( 14 ) is connected. 5. LPG generator according to one of claims 1 to 4, characterized in that the breakthrough element ( 16 ) consists of a temperature-stable combustible molding. 6. LPG generator according to claim 4 or 5, characterized in that the penetration element ( 16 ), the tear-off edge ( 15 ) and the sleeve ( 14 ) are a molded part. 7. LPG generator according to one of claims 1 to 6, characterized in that the ignition element ( 4 ) is provided with a cylindrical guide sleeve ( 17 ) for guiding the breakdown element ( 16 ). 8. LPG generator according to one of claims 1 to 7, characterized in that a radial enlargement ( 31 ) and / or in the guide sleeve ( 17 ) has a radial constriction ( 30 ) is arranged on the piercing element ( 16 ). 9. LPG generator according to one of claims 1 to 8, characterized in that the ignition element ( 4 ) contains a squib ( 12 ). 10. LPG generator according to one of claims 1 to 9, characterized in that a cavity is arranged between the igniter ( 4 ) and the breakdown element ( 16 ), which is preferably filled with a charge ( 13 ). 11. LPG generator according to one of claims 1 to 10, characterized in that the one wall of the reaction container ( 7 ) is a rupture disc ( 5 ). 12. LPG generator according to claim 11, characterized in that the rupture disc ( 5 ) is integrated in the lid of a closure cap ( 18 ) of the reaction container ( 7 ).