Abstract:
The invention relates to a gas generator comprising at least two combustion chambers filled with propellant charges and delimited by combustion chamber walls. The combustion chamber walls have outflow openings which in a non-activated state are closed by at least one applied membrane having an edge. One of an additional fastening device and a protective device is provided at least sections of the edge of the membrane. The device prevents a coming-off of the membrane from the combustion chamber wall.

Description:
TECHNICAL FIELD  
         [0001]    The invention relates to a gas generator comprising at least two combustion chambers.  
         BACKGROUND OF THE INVENTION  
         [0002]    In such gas generators, which may be designed as multiple-stage gas generators, one or more propellant charges are ignited, in order to be able to generate different quantities of gas. If not all of the propellant charges are to be ignited, a so-called ignition transfer must be prevented. The igniting of a propellant charge must not in fact lead to an auto-ignition of the other propellant charge, for example by generated hot gas flowing into the combustion chamber of the propellant charge which is not to be activated. So that this is ruled out, the outflow openings in the combustion chambers are usually closed by membranes, preferably metal foils. The metal foils are constructed such that they are only destroyed by the associated propellant charge, but withstand a destruction owing to the flow of gas and particles on igniting of another propellant charge. At the same time, the membrane can also serve for the hermetic sealing of the combustion chamber, so that no humidity can penetrate into the combustion chamber. So that the generator remains capable of functioning over a period of years, it must be ensured that the membrane remains fastened to the combustion chamber wall. Also on igniting of a propellant charge, the membrane of a propellant charge which is not to be ignited must in no way detach itself from the combustion chamber in the region of its edge, otherwise a stream of gas would arrive into the combustion chamber and ignite the propellant charge.  
         BRIEF SUMMARY OF THE INVENTION  
         [0003]    The invention provides a gas generator in which an ignition transfer can be avoided even more reliably. This is achieved in a gas generator which comprises at least two combustion chambers filled with propellant charges and delimited by combustion chamber walls. The combustion chamber walls have outflow openings which in a non-activated state are closed by at least one applied membrane having an edge. One of an additional fastening device and a protective device is provided at least sections of the edge of the membrane. The device prevents a coming-off of the edge of the membrane from the combustion chamber wall. The additional fastening device or the protective device prevents the edge from coming off owing to the stresses which are produced by the gas stream of an ignited propellant charge.  
           [0004]    Preferably the membrane is fastened on the side of the combustion chamber wall facing away from the propellant charge. In this embodiment the membrane is not provided in the combustion chamber but outside it, so that the edge of the foil is pressed against the wall by the pressure stress and flow stress on igniting a propellant charge which is not associated with the membrane, and is not peeled off from it.  
           [0005]    The fastening- or protective device is arranged on the outer side of the membrane, in order to protect the edge of the membrane from the gas stream.  
           [0006]    According to one embodiment, the fastening device is an adhesive applied from outside to the edge of the membrane, for example a metal adhesive.  
           [0007]    According to another development, a protective foil is fastened externally on the edge of the membrane, the fastening devices always having to extend beyond the edge of the membrane so that it is also actually protected.  
           [0008]    The protective foil can be a ductile metal foil which can be easily adapted to the geometric characteristics.  
           [0009]    If the membrane is likewise of metal, the protective foil can be fastened to the membrane by welding.  
           [0010]    Another embodiment makes provision for constructing the protective device as a depression in the combustion chamber wall, into which depression the edge of the foil is pressed and which thereby can not be caught directly by the gas stream, because it lies in the depression which is protected from flow.  
           [0011]    The protective device can, furthermore, also be a projection of the combustion chamber wall, which runs along the edge so as to adjoin the edge. Also in this development, the projection serves to not expose the edge directly to the gas stream. The projection serves as a flow deflector.  
           [0012]    According to a further embodiment, the membrane is open in peripheral direction and has peripheral ends. The protective device consists in that the end wall is chamfered or rounded. This design, which is favorable to flow, protects the end wall of the membrane from the gas stream.  
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0013]    [0013]FIG. 1 shows a longitudinal sectional view through a two-stage gas generator according to the invention,  
         [0014]    [0014]FIG. 2 shows a cross-sectional view through the combustion chamber insert of the gas generator according to FIG. 1 in accordance with a first embodiment,  
         [0015]    [0015]FIG. 3 shows a side view of the combustion chamber insert of the gas generator according to FIG. 2, as viewed in the direction of the arrow A,  
         [0016]    [0016]FIG. 4 shows a side view of the combustion chamber insert of the gas generator according to a second embodiment,  
         [0017]    [0017]FIG. 5 shows a side view of the combustion chamber insert of the gas generator according to a third embodiment,  
         [0018]    [0018]FIG. 6 shows a side view of the combustion chamber insert of the gas generator according to a fourth embodiment,  
         [0019]    [0019]FIG. 7 shows a cross-sectional view through a combustion chamber insert of the gas generator, the upper half showing a fifth embodiment and the lower half showing a sixth embodiment of the invention, and  
         [0020]    [0020]FIG. 8 shows a side view of the combustion chamber insert of the gas generator according to a seventh and an eighth embodiment.  
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0021]    In FIG. 1 a two-stage gas generator is illustrated, which has a first and a second combustion chamber  3  and  5 , respectively, with a corresponding first and a corresponding second propellant charge  7  and  9 , respectively. The propellant charges  7 ,  9  have associated igniters  11  and  13 , respectively, so that the propellant charges  7 ,  9  can be ignited individually and independently of each other. Each combustion chamber  3 ,  5  is delimited externally by an associated combustion chamber wall  15  and  17 , respectively.  
         [0022]    As can be seen from FIG. 2, the two combustion chamber walls  15 ,  17  continue into each other and complement each other to form a circular cylinder. A common inner combustion chamber wall  18  forms a connecting cross-piece between substantially opposite sections of the circular cylinder and separates the two combustion chambers  3 ,  5 . The combustion chamber walls  15 ,  17 ,  18 , which are connected with each other in one piece, form a combustion chamber insert which is illustrated in FIGS.  2  to  7  in various embodiments. In the outer combustion chamber walls  15 ,  17  numerous outflow openings  19  and  21 , respectively, are provided. On the inner side of each combustion chamber wall  15 ,  17 , associated with the propellant charge, in each case there lies a sealing foil  23  and  25 , respectively, which closes the outflow openings  19  and  21 , respectively, and provides for a sealing of the corresponding combustion chamber  3 ,  5 .  
         [0023]    On the outer side of each combustion chamber  15 ,  17  facing away from the propellant charge in addition in each case a membrane  27  and  29 , respectively, is fastened to the combustion chamber wall  15 ,  17 , which in addition closes the outflow openings  19  and  21 , respectively. The two membranes  27 ,  29  likewise serve for sealing the combustion chambers  3 ,  5  and in addition serve to prevent a so-called ignition transfer, which is explained in further detail hereinbelow.  
         [0024]    Radially externally a common filter chamber  31 , in the form of a circular ring and closed peripherally, adjoins the combustion chamber walls  15 ,  17 , in which filter chamber a filter  33  in the form of a circular ring is arranged. An outer housing  35  with outflow openings  37  closes off the gas generator externally.  
         [0025]    When only one propellant charge  7  or  9  is to be ignited, this destroys the associated insulation foil  23 ,  25  and the associated membrane  27  or  29 , so that the gas arrives via the outflow openings  19  or  21  into the filter chamber  31 . As the generated gas and the generated hot particles are then distributed uniformly in the filter chamber  31 , which is closed peripherally, the gas stream or the hot particles could lead to the destruction of the membrane, which is associated with that propellant charge which is not to be activated. Each membrane  27 ,  29  therefore has to be constructed so as to be so stable that it is not destroyed on igniting of the propellant charge which is not associated with it. The membranes  27 ,  29  are therefore usually of a metal foil, for example a steel foil which is bonded across a large area to the associated combustion chamber wall, the adhesive being provided between the membrane and the combustion chamber wall.  
         [0026]    Through the gas stream, the edges of the membrane  27 ,  29  are exposed to high stresses which could lead to the membranes coming off from the associated combustion chamber wall in peripheral direction, i.e. in particular at their axially running edges  41  and  43 , respectively.  
         [0027]    In order to prevent a coming-off of the membranes  27 ,  29  in the region of their axial edges  41 ,  43 , additional fastening- or protective devices are provided, which are explained in further detail hereinbelow. In FIG. 3 it is shown that in the region of the edges  41 ,  43  externally an adhesive in the form of a metal adhesive is applied to the membrane  27 ,  29 . Thereby, two strip-shaped adhesive sections  45 ,  47  are produced, which completely cover the transition of the axial edges  41 ,  43  to the combustion chamber walls  15 ,  17 . Thus, the adhesive protects here the axial edges  41 ,  43  from hot gas flowing directly against them. A metal adhesive which is known under the commercial name Loctite® 3450 is used as the preferred adhesive for this.  
         [0028]    Instead of the adhesive, as FIG. 4 shows, also protective foils  49 ,  51  preferably of easily deformable metal can be provided, which cover the axial edges  41 ,  43 . The protective foils  49 ,  51 , which are preferably of ductile metal foil which can be readily adapted to the contour of the bonded membrane ends, are either self-adhesive or can be fastened for example by means of an adhesive to the membranes  27 ,  29  and to the combustion chamber walls  15 ,  17 .  
         [0029]    A common protective foil  53  can also be provided (FIG. 5), which covers the adjacent axial edges  41 ,  43 . The protective foil  53  is fastened by welding to the combustion chamber wall, the weld seams  55  running across the membranes  27 ,  29  and being welded therewith. The weld seams extend in axial direction but also beyond the membrane  27 ,  29 , so that the protective foil  53  is connected directly with the combustion chamber wall.  
         [0030]    Instead of a common protective foil  53 , two protective foils  57 ,  59 , as is illustrated in FIG. 6, of metal, for example copper, can also be fastened by welding to the combustion chamber wall and/or the membrane  27  or  29 . The protective foils  57 ,  59  are so thin and ductile that they can easily be adapted to the shape of the combustion chamber wall and to the membrane  27 ,  29  lying therebeneath by pressing thereagainst.  
         [0031]    According to the cross-sectional view of the combustion chamber insert illustrated in FIG. 7, no additional fastening device such as an adhesive or a protective foil is applied from outside to the membrane  27 ,  29 , but rather so-called protective devices are provided, which are intended to prevent the axially running edges  41 ,  43  from being directly impinged by the gas flow.  
         [0032]    In the upper half of the section shown in FIG. 7, at the transition of the combustion chamber walls  15 ,  17  a projection  61  is provided, protruding radially outwards and extending across the entire axial width of the membrane  27 ,  29 , which projection  61  is formed on the combustion chamber wall. The projection  61  serves for gas deflection so that, as the edges  41 ,  43  lie directly against the projection  61 , these are not directly impinged by the gas flow in peripheral direction, if only one propellant charge is ignited. The edges  41 ,  43  lie as it were in lee regions of the projection  61 .  
         [0033]    The same purpose of protection from being directly impinged by the gas flow is also fulfilled by a protective device in the form of a depression  63 , which runs axially and into which the edges  41 ,  43  are pressed, as is illustrated in the lower half in FIG. 7.  
         [0034]    In the embodiments shown in FIG. 8 the membrane is open in the peripheral direction. The protective device is realized in that the shown peripheral ends of the membrane, i.e. the edges  41 ,  43  of the membrane  27 ,  29  are designed so as to be favorable with respect to flow.  
         [0035]    In the left half of FIG. 8, the end wall  41  has two chamfered portions  65  running towards each other, which end in a blunt point. In the right half of FIG. 8, the end wall  43  shows a rounding  67  approximately in the form of a circular arc. In both cases, the chamfered portion  65  or rounding  67  extends across the entire axial length of the end wall  41 ,  43 .  
         [0036]    This chamfered portion  65  and rounding  67 , respectively, serves to protect the end wall  41 ,  43  of the membrane  27 ,  29  from coming off through a reduction of the resistance offered to the gas stream.