JP4970671B2 - Gas generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a gas generator for a situation-adaptive air bag in which a gas generating agent in a housing is combusted by a plurality of igniters to control the inflation and deployment of the air bag. Regarding the generator.
[0002]
[Prior art]
In order to protect an occupant from an impact caused by an automobile collision, a gas generator that rapidly inflates and deploys an air bag is incorporated in an air bag module mounted in a steering wheel or an instrument panel. And a gas generator ignites an igniter (squib) by electricity supply from a control unit (actuator), burns a gas generating agent by this flame, and generates a lot of gas abruptly.
[0003]
Conventional gas generators always have a configuration in which the airbag is rapidly inflated and deployed regardless of the occupant's sitting posture (regular seating, non-regular seating such as forward bending) and the vehicle speed (acceleration) at the time of collision. ing. Therefore, it is difficult to deploy the airbag according to the sitting posture of the vehicle occupant and the vehicle speed (acceleration) at the time of the collision, and there is a possibility that the original function of the airbag protecting the occupant cannot be exhibited.
[0004]
Therefore, in recent years, in gas generators, the gas for an adaptive airbag that deploys the airbag according to the seating posture of the occupant and the vehicle speed (acceleration) at the time of a collision, such as slowing the initial inflation of the airbag, etc. Generators are being proposed and developed.
[0005]
A gas generator (soft inflator) that inflates and deploys a passenger-side airbag is known as a technique for reducing the initial inflation of the airbag.
[0006]
In this gas generator, a long cylindrical housing is defined in two combustion chambers, and a gas generating agent is loaded in each combustion chamber, and the gas generating agents in each combustion chamber are independently provided by two ignition means. And burn. Then, each ignition means is operated (energized ignition) with a time difference to sequentially burn the gas generating agent in each combustion chamber. As a result, at the initial stage of inflation of the airbag, the airbag is gently inflated and deployed by a small amount of gas generated in one combustion chamber, and then the airbag is rapidly inflated and deployed by a large amount of gas generated in each combustion chamber.
[0007]
In this manner, by appropriately selecting the operation (energization ignition) of each igniter, it is possible to control the inflation and deployment of the airbag according to the seating posture of the occupant and the vehicle speed (acceleration) at the time of the collision.
[0008]
[Problems to be solved by the invention]
However, in the gas generator having such a long cylindrical housing, it is necessary to divide the housing into a plurality of sections in order to form a combustion chamber for each igniter. For this reason, each partition member which divides the inside of a housing into plurality is sealed and fixed by welding each. For this reason, it became one of the causes of a manufacturing cost rise by having several welding locations and increasing the number of processes.
[0009]
In addition, depending on the welding location, there is a risk that the flame during welding may ignite the gas generating agent loaded in the combustion chamber, and a gas generator with fewer welding locations is desired in order to increase work safety. Yes.
[0010]
The present invention provides a gas generator having two or more situation-adaptive ignition means that can divide the inside of a housing into a plurality of combustion chambers with less welding and adjust the deployment of the airbag according to the situation. The purpose is to do.
[0011]
[Means for Solving the Problems]
  A gas generator according to claim 1 of the present invention for solving the above-mentioned problems is a cylindrical shape comprising an initiator shell (1) and a closure shell (2) each having two ignition means (10, 11). A housing (3), a combustion chamber (4) in the circumferential direction in the housing (3), andFilter material (8) was placedA cylindrical partition member (6) partitioned into a filter chamber (5), a partition member (7) partitioning the combustion chamber (4) vertically, and upper and lower combustion chambers (4a, 4b) formed by the partition ), And a gas generator (9) that generates gas by combustion, the cylindrical partition member (6) facing the closure shell (2) A stepped portion (22) having a reduced diameter is provided.And an orifice (35) through which gas passes is formed in a portion between the step (22) and the closure shell (2),The cylindrical partition member (6) and the partition member (7) are not welded to each other in the housing (3) by welding and fixing the initiator shell (1) and the closure shell (2). The step (22) and the end (31) of the partition member (7) are fixed by fixing means (13) engaged with each other in a state of being abutted against each other.The cylindrical partition member (6) and the partition member (7) are not welded to other members, and the step (22) is provided on the cylindrical partition member (6). Gas discharged from the orifice (35) is between the portion between the step (22) of the partition member (6) and the closure shell (2) and the filter material (8). A staying space (S2) is formedIt is characterized by being.
  According to such a configuration, it is possible to fix the initiator shell and the closure shell by welding at only one place.Can reduce manufacturing costs and increase safety in the manufacturing processIt becomes. Further, the inside of the housing can be divided into a plurality of combustion chambers.
  In addition, since the cylindrical partition member is reduced in diameter, it is easy to form a space between the inner periphery of the filter material in the filter chamber and the cylindrical partition member, and the gas generated in the combustion chamber once stays in this space. It flows into the filter material from the entire circumferential direction, so that the gas cooling effect and the gas cleaning effect of the filter material can sufficiently function.
  The gas generator according to claim 2 of the present invention defines a combustion chamber (4) between a bottom plate (18) provided with two ignition means (10, 11) and the bottom plate (18). Between the cup-shaped container (53) and the side tube portion of the container (53) disposed outside the container (53)Filter material (8) was placedA housing (3) composed of an outer cylinder member (51) defining a filter chamber (5), a partition member (7) for vertically dividing the inside of the combustion chamber (4), and upper and lower portions formed by the partitions A gas generator (9) that is loaded into the combustion chamber (4a, 4b) and generates gas by combustion, wherein the side cylinder of the container (53)Located on the side opposite to the side on which the bottom plate (18) is fixedA stepped portion (22) having a reduced diameter toward the bottom of the container (53) is provided.And an orifice (35) through which gas passes is formed in a portion between the bottom portion and the step portion (22) of the container (53),By welding and fixing the bottom plate part (18), the container (53), and the outer cylinder member (51), the side cylinder part of the container (53) and the partition member (7) are not welded. In the housing (3), the stepped portion (22) and the end portion (31) of the partition member (7) are fixed by fixing means (13) engaged with each other,The step portion (22) is provided on a side tube portion of the container (53), so that the portion between the bottom portion of the container (53) and the step portion (22), and the filter A space is formed between the material (8) and the gas discharged from the orifice (35).It is characterized by being.
[0012]
  The gas generator according to claim 3 is a claim.1The cylindrical member that guides the flame of one of the ignition means (11) to the combustion chamber (4a) above the upper and lower combustion chambers (4a, 4b) formed by the compartment and supports the partition member (7) (29, 55) is provided. According to such a configuration, the partition member is supported by the cylindrical member, and the displacement of the partition member that partitions the interior of the housing up and down by the generation of gas can be eliminated more reliably, resulting in the generation of gas as designed and adaptable to the situation. Gas generator. In addition, since the gas generator can be configured with a small number of parts, the manufacturing cost can be reduced.
[0013]
  Claim4The gas generator according to claim3In the cylindrical material(29)Is the partition member(7)It is characterized in that it is integrally formed. According to such a configuration, since the number of members can be reduced, it is possible to reduce welding locations.
[0014]
  Claim5The gas generator according to claim3In the cylindrical material(55)Is the initiator shell(1)It is characterized in that it is integrally formed. According to such a configuration, since the number of members can be reduced, it is possible to reduce welding locations.
[0015]
  The gas generator according to claim 6 comprises a cylindrical housing (3) comprising an initiator shell (1) and a closure shell (2) provided with two ignition means (10, 11), and the housing (3 ) A partition member (7) that divides the interior vertically, and a housing (3) that is partitioned vertically by the partition member (7) into a combustion chamber (4) and a filter chamber (5) in the circumferential direction, respectively. A first cylindrical partition member (44) and a second cylindrical partition member (45) that partition, and a gas generating agent that is loaded into the upper and lower combustion chambers (4a, 4b) formed by the partition and generates gas by combustion. (9) and a cylindrical member (29) for guiding one of the ignition means (11) to the upper combustion chamber (4a) of the upper and lower combustion chambers (4a, 4b) formed by the compartment. A gas generator comprising: The initiator shell (1) includes a bottom plate portion (18) having the cylindrical material (29), the first cylindrical partition member (44), the partition member (7), and a side tube portion (15) of the housing. And the plate member (46) formed integrally with each other by welding, and the initiator shell (1) and the closure shell (2) are abutted and fixed by welding. One cylindrical partition member (44) and the second cylindrical partition member (45) are fixed by fixing means (13) in the housing (3) without being welded. According to such a configuration, the initiator shell and the closure shell constituting the housing can be reliably fixed with a small amount of welding. Further, by welding the initiator shell and the closure shell, the partition member in the housing and the cylindrical partition member can be fixed by welding.
  The gas generator according to claim 7 is the combustion chamber (4a) above the upper and lower combustion chambers (4a, 4b) in which the flame of one of the ignition means (11) is formed by the compartment in claim 2. And a cylindrical member (29) for supporting the partition member (7).
  The gas generator according to an eighth aspect is characterized in that, in the seventh aspect, the cylindrical member (29) is integrally formed with the bottom plate (18).
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of a gas generator according to the present invention will be described with reference to the drawings.
[0017]
FIG. 1 shows a sectional view of a gas generator according to a first embodiment of the present invention. In FIG. 1, a gas generator P1 inflates and deploys an air bag for a driver's seat, and includes a short cylindrical housing 3 composed of an initiator shell 1 and a closure shell 2, and a combustion chamber 4 in the housing 3 in the circumferential direction. A cylindrical partition member 6 that divides the filter chamber 5, a partition member 7 that defines the combustion chamber 4 into two upper and lower combustion chambers 4 a and 4 b, a filter material 8 that is attached to the filter chamber 5, and each combustion The ignition means 11 and 10 for independently burning the gas generating agent 9 loaded in the chambers 4a and 4b, respectively, and the cylindrical material 29 for guiding the flame of the ignition means 11 to the upper combustion chamber 4a, The initiator shell 1 and the closure shell 2 are abutted and welded at the weld 50. In the housing 3, the cylindrical partition member 6 and the partition member 7 are fixed by the fixing means 13 without being welded.
[0018]
The closure shell 2 constituting the short cylindrical housing 3 includes a top part 14, a side cylinder part 15 extending from the top part 14 toward the initiator shell 1, and a flange extending from the side cylinder part 15 along the radially outer side. Part 17. The side tube portion 15 is formed with a plurality of gas discharge ports 16 through which gas generated by the combustion of the gas generating agent 9 is released.
[0019]
The initiator shell 1 that is abutted against and welded to the closure shell 2 includes a bottom plate portion 18 and a side tube portion 19 that extends from the bottom plate portion 18 toward the closure shell 2. Cylindrical ignition means holding portions 20 and 21 for holding the ignition means 10 and 11 are integrally formed on the bottom plate portion 18.
[0020]
A cylindrical partition member 6 that divides the inside of the housing 3 constituted by the closure shell 2 and the initiator shell 1 into a combustion chamber 4 and a filter chamber 5 in the circumferential direction is formed in a cylindrical shape, and is a cylindrical partition member 7. Is provided with a stepped portion 22 having a diameter reduced toward the closure shell 2. The cylindrical partition member 6 is disposed and fixed in the housing 3 from the top panel 14 to the bottom panel 18. Further, orifices 35 and 36 through which a plurality of gases pass are formed on the outer periphery, and the combustion chamber 4 and the filter chamber 5 are communicated with each other. These orifices 35 and 36 are sealed with a sheet of aluminum or the like not shown.
[0021]
A filter material 8 is provided in the filter chamber 5 defined by the cylindrical partition member 6. The filter material 8 is manufactured at low cost by, for example, forming an aggregate of knitted wire mesh, plain woven wire mesh, or crimp woven metal wire into a cylindrical shape. The filter material 8 is provided along the inner peripheral wall surfaces of the side cylinder portions 19 and 15 of the initiator shell 1 and the closure shell 2. Even if the filter member 8 is formed from the top 14 to the bottom 18 of the housing 3, for example, as shown in FIG. 1, a space S1 is formed between the filter member 8 and the orifice 36 below the filter chamber 5. It may be. In this case, as shown in FIG. 1, the filter member 8 is supported by a plate member 23 having an L-shaped cross section disposed so as to be in contact with the inner peripheral wall surface of the side cylinder portion 19 of the initiator shell 1, and a space S1 is formed. The filter material 8 is attached so that Thus, by forming the space S1, the gas generated in the combustion chamber 4b once stays in the space S1, and therefore flows into the filter material 8 from the entire circumferential direction, and the filter material 8 This is preferable because the gas cooling and gas cleaning effects can be sufficiently functioned.
[0022]
On the other hand, on the top 14 side of the closure shell 2 of the filter chamber 5, since the cylindrical partition member 6 is reduced in diameter, a space S <b> 2 is formed between the inner periphery of the filter material 8 and the orifice 35. By forming the space S2 in this way, the gas generated in the combustion chamber 4a once stays in the space S2, and therefore flows into the filter material 8 from the entire circumferential direction. This is preferable because the gas cooling and gas cleaning effects can be sufficiently functioned. And the inner cylinder material 24 is arrange | positioned by the inner periphery of the filter material 8 in space S2, and the filter material 8 is supported from the inner peripheral side by this. In addition, a plurality of gas passage holes 25 are formed in the inner cylinder member 24, and the space S2 and the filter member 8 are communicated with each other. The inner cylinder member 24 is manufactured, for example, by forming a porous metal plate (punching metal), expanded metal, or the like into a cylindrical shape.
[0023]
A space S3 is formed between the outer peripheral surface of the filter material 8 and the gas discharge port 16 (between the filter material 8 and the side tube portion 15 of the closure shell 2). For this reason, the gas generated in the combustion chamber 4 and having passed through the filter material 8 once stays in the space S3, and the gas is uniformly discharged from each gas discharge port 16, and in the vicinity of the gas discharge port 16. The passage of gas does not concentrate on the filter material 18. In addition, a cylindrical material 26 produced by forming a porous metal plate (punched metal), expanded metal, or the like into a cylindrical shape is disposed on the outer periphery of the filter material 8 in the space S3. 8 is supported from the outer peripheral side. The cylindrical material 26 is also formed with a plurality of gas passage holes 27 and communicates with the space S3.
[0024]
The combustion chamber 4 defined inside the cylindrical partition member 6 is partitioned into upper and lower combustion chambers 4a and 4b by a partition member 7, and a gas generating agent 9 is loaded in each of them. Cushion members 33 and 32 made of ceramics or the like are provided at the bottom of each combustion chamber 4a and 4b to prevent breakage such as cracking of the gas generating agent 9 due to vibration or the like.
[0025]
The partition member 7 is formed integrally with a disk portion 28 that divides the combustion chamber 4 into upper and lower combustion chambers 4a and 4b and a cylindrical member 29 that guides the flame of the ignition means 21 to the upper combustion chamber 4a. The disk portion 28 is formed with a flame passage hole 30 communicating with the upper combustion chamber 4 a and the inside of the cylindrical material 29. The end portion 31 of the disk portion 28 is bent toward the initiator shell 1 and has a stepped shape along the step portion 22 formed in the cylindrical partition member 6. The end portion 31 and the stepped portion 22 of the cylindrical partition member 6 are engaged with each other in a state where the initiator shell 1 and the closure shell 2 are abutted with each other to become the fixing means 13 of the partition member 7, and the partition member 7 is the cylindrical partition. The member 6 is held against the initiator shell 1. Thereby, even if the pressure in the lower combustion chamber 4b is increased by the generation of gas, the end portion 31 is pressed by the step portion 22, and the movement of the partition member 7 can be suppressed. For this reason, it is not necessary to weld the partition member 7 and the cylindrical partition member 6.
[0026]
In the lower combustion chamber 4 b defined by the partition member 7, the ignition means 10 and 11 are caulked and fixed to ignition means holding parts 20 and 21 formed on the bottom plate part 18, respectively. A pin type squib, a pigtail squib, or the like can be used for the ignition means 10 and 11. In the present embodiment, the ignition means 10 burns the gas generating agent 9 loaded in the lower combustion chamber 4b, and the ignition means 11 is located in the cylindrical material 29 and is placed in the upper combustion chamber 4a. The loaded gas generating agent 9 is combusted.
[0027]
The gas generator P1 configured as above fixes the ignition means 10 and 11 to the ignition means holding portions 20 and 21 of the initiator shell 1 respectively. On the other hand, the cylindrical partition member 6 is disposed on the closure shell 2 with the top portion 14 facing down, the gas generating agent 9 is loaded into the cylindrical partition member 6, and the cushion material 33 is disposed. At this time, the filter material 8 is installed in the space on the outer periphery of the cylindrical partition member 6. Then, the partition member 7 is arranged so that the end portion 31 and the step portion 22 of the cylindrical partition member 6 are engaged, and the gas generating agent 9 is loaded into the space serving as the lower combustion chamber 4b. Then, it is abutted against the closure shell 2 so as to cover the initiator shell 1 and is welded at the welded portion 50 where the initiator shell 1 and the closure shell 2 are abutted. Thus, since the welding part 50 is not directly in contact with the combustion chamber 4 in which the gas generating agent 9 is loaded, heat during welding is not transmitted to the gas generating agent 9. For this reason, the safety | security at the time of welding is improved. Moreover, since there is only one welding location, the manufacturing cost can be reduced.
[0028]
The gas generator P1 configured in this way is incorporated in an airbag module to be mounted in the steering wheel. And each ignition means 10 and 11 of gas generator P1 is connected to the vehicle side connector which illustration is omitted, respectively, and is connected to a control part.
[0029]
The control unit includes, for example, a collision sensor (acceleration sensor) that detects a collision of an automobile, a booster circuit that energizes each ignition means 10, 11, a backup capacitor, and a squib (igniter) drive circuit. Controlled by computer.
[0030]
Then, the gas generator P1 connected to the control unit detects the ignition means 10 by an ignition means that ignites first, for example, a squib drive circuit connected to the ignition means 10 when the collision sensor detects an automobile collision. Only operates (energization ignition), and the gas generating agent 9 in the combustion chamber 4b is burned to generate a high-temperature gas. At this time, the pressure in the combustion chamber 4 b increases, but the partition member 7 is not displaced because it is biased toward the initiator shell 1 by the fixing means 13 by the step portion 22 of the cylindrical partition member 6. The high temperature gas generated in the combustion chamber 4b passes through the orifice 36 and stays in the space S1. Then, it flows into the filter material 8 and is discharged from the gas discharge port 16 through slag collection and cooling. At this stage, since only the gas generating agent 9 in the combustion chamber 4b is combusted, the airbag gradually starts to inflate and deploy.
[0031]
Subsequently, after the combustion in the combustion chamber 4b is started, the ignition means 11 is activated (energized and ignited) with a slight time difference by the squib drive circuit controlled by the microcomputer of the control unit. The flame is ejected into the cylindrical material 29, passes through the flame passage hole 30, and is ejected into the combustion chamber 4a. And the high temperature gas is generated by burning the gas generating agent 9.
[0032]
The high-temperature gas generated in the combustion chamber 4a passes through the orifice 35, flows into the space S2, flows into the filter material 8, and flows out into the space S3 through slag collection and cooling. Then, the gas flowing out into the space S3 merges with the gas from the lower combustion chamber 4b and is discharged from the gas discharge port 16. As a result, the airbag is shifted to rapid expansion and deployment by a large amount of clean gas discharged from the combustion chambers 4a and 4b.
[0033]
In addition, although the operation of each ignition means 10 and 11 has been described in a mode in which the ignition means 10 is operated first, the ignition means 11 may be operated first, and further, it is necessary to perform it with a slight time difference. It is appropriately selected depending on the collision type of the automobile.
Even when the ignition means 11 is operated first, the partition member 7 is displaced even if the pressure in the combustion chamber 4a rises because the cylindrical member 29 is in contact with the initiator shell 1. It is prevented.
[0034]
For example, in a high-risk collision such as a frontal collision or a frontal collision at a high speed, the ignition means 10 and 11 are simultaneously activated (energized and ignited), and a large amount of air bags generated in the combustion chambers 4a and 4b are generated. Rapid expansion and expansion with gas.
Further, in a moderate collision, the ignition means 10 and 11 are operated (energized and ignited) with a minute time difference, and the airbag is gently inflated and deployed with a small amount of gas at the initial stage of deployment. Rapid expansion and expansion with gas.
Further, in the case of a light collision, for example, only the ignition means 10 is operated (energized ignition), and the airbag is gradually inflated and deployed with a small amount of gas over a relatively long time.
[0035]
In this way, according to the gas generator, by selecting the operation (energization ignition) of each ignition means 10, 11, the amount of gas generated can be adjusted, and the airbag inflation and deployment can be controlled. At this time, since the partition member 7 that divides the combustion chamber 4 in the vertical direction does not shift at the time of gas generation, the airbag can be inflated and deployed as designed.
[0036]
Next, a second embodiment of the gas generator of the present invention will be described with reference to FIG. In addition, the same member as FIG. 1 attaches | subjects the same code | symbol, and omits detailed description.
[0037]
FIG. 2 shows a cross-sectional view of the gas generator P2 according to the second embodiment. The gas generator P2 according to the present embodiment is a cylinder integrated with a partition member 7 that guides the flame of the ignition means 11 to the upper combustion chamber 4a in the gas generator P1 according to the first embodiment. The material 29 is replaced with a cylindrical portion 55 formed separately from the partition member 7 and extending upward from the ignition means holding portion 21 formed integrally with the initiator shell 1. The cylindrical portion 55 is in contact with the disk portion 28 of the partition member 7 at its end face.
[0038]
  Thus, cylindrical material55Is integrally formed with the initiator shell 1, so that the flame of the ignition means 11 can be reliably guided to the upper combustion chamber 4a. Further, the number of members can be reduced similarly to the gas generator P1 according to the first embodiment described above, and the inside of the housing 3 can be partitioned vertically by welding at only one place of the welded portion 50. Accordingly, the gas generator P2 can inflate and deploy the airbag. Even if the ignition means 11 is operated first, the disk portion 28 and the cylindrical material55Are in contact with each other, so that the partition member 7 is not displaced.
[0039]
  Next, referring to FIG. 3, the gas generator of the present inventionReference exampleWill be described. In addition, the same member as FIG. 1 attaches | subjects the same code | symbol, and omits detailed description.
[0040]
  First reference exampleA sectional view of the gas generator P3 according to FIG. 3 is shown in FIG.Reference exampleIn the gas generator P3, the cylindrical partition member 6 is cylindrical without being reduced in diameter, and the partition member 7 that divides the combustion chamber 4 in the vertical direction is also a single disk in which the end 31 is not bent. It is formed with a plate.
[0041]
Further, in the combustion chamber 4a, a first tube member 40 extending from the top 14 to the partition member 7 so as to distribute the flame passage hole 30 formed in the partition member 7 to the inner periphery thereof, A second cylinder member 41 extending from the top 14 to the partition member 7 is disposed on the outer periphery of the combustion chamber 4a. The first cylinder member 40 and the second cylinder member 41 penetrate through the inside and outside of the first cylinder member 40 and lead the flame 42 from the ignition means 11 to the combustion chamber 4a, the combustion chamber 4a and the filter chamber 5 (cylindrical). Holes 43 communicating with the orifices 35) of the partition member 6 are provided. The partition member 7 is fixed in the housing 3 without being welded by a fixing means that is sandwiched between the first cylindrical member 40 and the second cylindrical member 41 and the cylindrical portion 55.
[0042]
  Next, referring to FIG. 4, the gas generator of the present invention is3The embodiment example will be described. In addition, the same member as FIG. 1 attaches | subjects the same code | symbol, and omits detailed description.
[0043]
  First3FIG. 4 shows a cross-sectional view of the gas generator P4 according to the embodiment. The gas generator P4 according to the present embodiment includes a cylindrical housing 3 composed of an initiator shell 1 and a closure shell 2 provided with two ignition means 10 and 11, and a partition member 7 that partitions the inside of the housing 3 up and down. A first cylindrical partition member 44 and a second cylindrical partition member 45 that divide the inside of the housing 3 partitioned vertically by the partition member 7 into a combustion chamber 4 and a filter chamber 5 in the circumferential direction, respectively, and a plurality of combustion chambers 4a, 4b, and a gas generating agent 9 that generates gas by combustion, and a cylindrical member 29 that guides the flame of the ignition means 11 to the combustion chamber 4a on the upper side of the combustion chamber 4, and includes an initiator shell 1 and a closure The first cylindrical partition member 44 and the second cylindrical partition member 45 are not welded to each other by the fixing means 13 in the housing 3 by welding and fixing the shell 2 together. It has been fixed Te.
[0044]
In the gas generator P4 according to the present embodiment, the initiator shell 1 includes a side cylinder part 15 having a flange formed at one end, and a ring board part 56 extending radially inward from the other end of the side cylinder part 15. The plate member in which the first cylindrical partition member 44 extending toward the one end side from the inner periphery of the ring disk portion 56 and the partition member 7 that closes the end surface of the first cylindrical partition member 44 are integrally formed. 46 and the bottom plate portion 18 in which the ignition means holding portions 20 and 21 and the cylindrical material 29 are integrally formed, and the bottom plate portion 18 is connected to the inner periphery of the first cylindrical partition member 44 of the plate member 46 on the cylindrical material 29 side. And is integrally formed by welding at the welding portion 47.
[0045]
In the plate member 46, a step portion 48 is formed at a corner portion from the partition member 7 to the first cylindrical partition member 44. The second cylindrical partition member 45 has a cup shape whose bottom is in contact with the top portion 14 of the closure shell 2, and is formed so that the end portion 49 is enlarged in diameter. It is designed to engage. The second cylindrical partition member 45 is fixed by a fixing means that is sandwiched between the step portion 48 of the first cylindrical partition member 44 and the top plate portion 14 of the closure shell 2, and the initiator shell 1 and the closure shell 2 are brought into contact with each other and welded. By welding at the portion 50, the inside of the housing 3 can be reliably partitioned. As a result, the partition member 7 and the first and second cylindrical partition members 44 and 45 are not displaced even if gas is generated in any of the combustion chambers 4a and 4b.
[0046]
  Next, referring to FIG. 5, the gas generator of the present invention4The embodiment example will be described. In addition, the same member as FIG. 1 attaches | subjects the same code | symbol, and omits detailed description.
[0047]
  First4A cross-sectional view of the gas generator P5 according to the embodiment is shown in FIG. In the gas generator P5 according to the present embodiment, the two ignition means 10 and 11 are molded by the bottom plate portion 18 and a single plate member is molded by press molding or the like, and the container 53 constituting the combustion chamber 4, and the container 53 And the outer cylindrical member 51 constituting the filter chamber 5 which is welded and fixed to the welded portions 52 and 50.
[0048]
The container 53 is formed in a substantially cup shape by pressing a single plate member or the like. A plurality of orifices 35 and 36 are formed in the cylinder portion. The inside of the container 53 forms combustion chambers 4 a and 4 b that are partitioned vertically by the partition member 7. The container 53 is formed with a step portion 22 in the side tube portion. The step portion 22 and the bent end portion 31 of the partition member 7 are engaged with each other, and are formed integrally with the bottom plate portion 18. The partition member 7 is fixed by being supported by the cylindrical material 29. As described above, the gas generator P5 according to the present embodiment is welded and fixed at three locations 47, 50, and 52 on the outer peripheral portion of the housing 3, but inside the housing 3, the partition member is provided by the fixing means 13. Since 7 is fixed, welding inside the housing 3 is not performed, so that the safety during the process is enhanced.
[0049]
【The invention's effect】
The gas generator of the present invention is configured as described above, and by performing the minimum welding, it is possible to reliably fix the partition member partitioning the inside of the housing into a plurality of combustion chambers without welding. For this reason, of course, the manufacturing cost can be reduced, but the safety in the manufacturing process can be improved.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing an embodiment of a gas generator according to the present invention.
FIG. 2 is a sectional view showing another embodiment of the gas generator according to the present invention.
FIG. 3 shows a gas generator according to the present invention.Reference exampleFIG.
FIG. 4 is a cross-sectional view showing another embodiment of the gas generator according to the present invention.
FIG. 5 is a cross-sectional view showing another embodiment of the gas generator according to the present invention.
[Explanation of symbols]
  1 Initiator shell
  2 Closure shell
  3 Housing
  4 Combustion chamber
  5 Filter room
  6 Cylindrical partition member
  7 Partition members
  9 Gas generating agent
  10, 11 Ignition means
  13 Fixing means
  40 First cylinder member
  41 Second cylinder member
  44 First cylindrical partition member
  45 Second cylindrical partition member
  46 Plate member

Claims (8)

A cylindrical housing (3) comprising an initiator shell (1) and a closure shell (2) provided with two ignition means (10, 11);
A cylindrical partition member (6) that divides the inside of the housing (3) in a circumferential direction into a combustion chamber (4) and a filter chamber (5) in which a filter material (8) is disposed ;
A partition member (7) for vertically dividing the inside of the combustion chamber (4);
A gas generator comprising a gas generating agent (9) that is loaded into upper and lower combustion chambers (4a, 4b) formed by the compartments and generates gas by combustion,
The cylindrical partition member (6) is provided with a step portion (22) having a diameter reduced toward the closure shell (2), and the step portion (22) and the closure shell (2) An orifice (35) through which gas passes is formed in the part in between,
The cylindrical partition member (6) and the partition member (7) are not welded to each other in the housing (3) by welding and fixing the initiator shell (1) and the closure shell (2). The cylindrical partition member (6) and the step (22) are fixed by fixing means (13) engaged with the end portion (31) of the partition member (7) in contact with each other . The partition member (7) is not welded to other members,
The said step part (22) is provided in the said cylindrical partition member (6), The said part which exists between the said step part (22) and the said closure shell (2) of the said cylindrical partition member (6) And a space (S2) in which the gas discharged from the orifice (35) stays is formed between the filter material (8) and the gas generator. A bottom plate (18) having two ignition means (10, 11), a cup-shaped container (53) defining a combustion chamber (4) between the bottom plate (18), and the container (53 ) And an outer cylinder material (51) that defines a filter chamber (5) in which a filter material (8) is arranged between the side cylinder portion of the container (53) and the housing (3) When,
A partition member (7) for vertically dividing the inside of the combustion chamber (4);
A gas generator comprising a gas generating agent (9) that is loaded into upper and lower combustion chambers (4a, 4b) formed by the compartments and generates gas by combustion,
A step portion (22) having a reduced diameter toward the bottom of the container (53) located on the side opposite to the side on which the bottom plate portion (18) is fixed is provided on the side tube portion of the container (53). And an orifice (35) through which gas passes is formed in a portion between the bottom portion and the step portion (22) of the container (53),
By welding and fixing the bottom plate part (18), the container (53), and the outer cylinder member (51), the side cylinder part of the container (53) and the partition member (7) are not welded. In the housing (3), the stepped portion (22) and the end portion (31) of the partition member (7) are fixed by fixing means (13) engaged with each other,
The step portion (22) is provided on a side tube portion of the container (53), so that the portion between the bottom portion of the container (53) and the step portion (22), and the filter A gas generator in which a space in which the gas discharged from the orifice (35) stays is formed between the material (8) . Cylindrical material (29) for guiding one of the ignition means (11) to the upper combustion chamber (4a) of the upper and lower combustion chambers (4a, 4b) formed by the compartment and supporting the partition member (7) 55). The gas generator according to claim 1 , wherein the gas generator is provided.   The gas generator according to claim 3, wherein the cylindrical member (29) is formed integrally with the partition member (7).   The gas generator according to claim 3, wherein the cylindrical member (55) is formed integrally with the initiator shell (1). A cylindrical housing (3) comprising an initiator shell (1) and a closure shell (2) provided with two ignition means (10, 11);
A partition member (7) for vertically dividing the inside of the housing (3);
A first cylindrical partition member (44) and a second cylinder that divide the inside of the housing (3) vertically divided by the partition member (7) into a combustion chamber (4) and a filter chamber (5) in the circumferential direction, respectively. A partition member (45);
A gas generating agent (9) that is loaded into the upper and lower combustion chambers (4a, 4b) formed by the compartment and generates gas by combustion;
A gas generator comprising: a cylindrical member (29) for guiding one of the ignition means (11) to the upper combustion chamber (4a) of the upper and lower combustion chambers (4a, 4b) formed by the section; Because
The initiator shell (1) includes a bottom plate portion (18) having the cylindrical member (29), the first cylindrical partition member (44), the partition member (7), and a side tube portion (15) of the housing. And the plate member (46) formed integrally with each other by welding, and the initiator shell (1) and the closure shell (2) are abutted and fixed by welding. A gas generator characterized in that one cylindrical partition member (44) and the second cylindrical partition member (45) are fixed by fixing means (13) in the housing (3) without being welded. Cylindrical material (29 ) for guiding one of the ignition means (11) to the upper combustion chamber (4a) of the upper and lower combustion chambers (4a, 4b) formed by the compartment and supporting the partition member (7) ) gas generator according to claim 2, characterized in that is provided. The gas generator according to claim 7, wherein the cylindrical member (29) is formed integrally with the bottom plate (18).