JP2002166818A - Gas generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas generator in which an air bag for passenger seat can be gradually expanded and developed, the gas generator being for the air bag reduced in size and weight, in particular, for the air bag for passenger seat. SOLUTION: This gas generator comprises a housing 1 of lengthy cylindrical shape whose both ends are closed, an ignition means 13 mounted to at least one shaft end of the housing, and an inflammation means 30 connected to the ignition means 13, charged with an inflammation agent 15, and having a plurality of inflammation holes 18. In this gas generator, an inside of the housing 1 is divided into a gas generating chamber 3 in which a gas generating agent 12 is housed and a filter chamber 4 in which filter member 7 is mounted. In the gas generating chamber 3, a hollow space 6 is formed by an internal cylindrical member 5 having a plurality of gas passing holes 21 in which a generated gas of the gas generating agent 12 flows, and after the generated gas is made to be retained in the hollow space 6, the gas is discharged to the filter chamber 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a gas generator for an airbag, and more particularly, to a gas generator suitable for inflating and deploying an airbag for a passenger seat.

[0002]

2. Description of the Related Art A gas generator for instantly deploying an airbag in order to protect an occupant from an impact generated at the time of an automobile collision is incorporated in an airbag module mounted in an instrument panel or the like. This gas generator instantaneously generates a large amount of high-temperature gas based on a collision detection signal from a collision sensor in the event of a collision.

A gas generator for inflating a passenger airbag is required to generate a larger amount of gas than a gas generator for inflating a driver airbag. Further, the shape of the airbag device including the gas generator is limited by the accommodation space of the airbag device.

In recent years, in particular, in order to improve safety and to increase the degree of freedom of design of an instrument panel for accommodating an airbag device, in addition to improving the performance of a gas generator, the size and weight of the gas generator have been reduced. Is becoming more desirable.

A gas generator which has been used for a side collision airbag device has been used as a gas generator which can be reduced in size and weight. As this type of gas generator, a gas generation chamber and a filter chamber are partitioned, and those in which these are formed coaxially in series are often used.

[0006] As the airbag on the passenger side, it is preferable that the airbag be inflated gradually for safety of the occupant. However, when these gas generators that have been used in the conventional side-impact airbag device are used as a gas generator for the passenger seat, the gas generating agent in the gas generating chamber burns at a stretch, and the airbag is damaged. It expands and expands at a stretch. Therefore, gradual inflation of the airbag as required for a passenger airbag cannot be expected.

Therefore, the composition of the gas generating agent is adjusted so as to gradually inflate the airbag to adjust the amount of generated gas, or the shape of the orifice at the connection between the gas generating chamber and the filter chamber. Various methods have been proposed, such as providing a plurality of igniters for igniting a gas generating agent and igniting the gas generating agent with a time difference.

[0008]

However, these conventional methods are not sufficient for adjusting the amount of gas released into the airbag, especially the passenger airbag, and gradually inflating and deploying the airbag.

SUMMARY OF THE INVENTION The present invention provides a gas generator for an airbag which is capable of progressively inflating and deploying a passenger airbag and which is reduced in size and weight, especially for a passenger airbag. The purpose is to:

[0010]

According to a first aspect of the present invention, there is provided a gas generator comprising a long cylindrical housing having both ends closed, and at least one shaft of the housing. An ignition means attached to an end, and a transmission means connected to the ignition means and loaded with a transfer agent, and having a plurality of transfer holes, wherein the inside of the housing contains a gas generating agent. A gas generator partitioned into a gas generating chamber and a filter chamber in which a filter material is mounted, wherein the gas generating chamber has a plurality of gas passage holes through which generated gas of the gas generating agent flows. A hollow space is defined by the inner cylinder material, and the generated gas is retained in the hollow space and then discharged to the filter chamber. A hollow space having a plurality of gas passage holes is defined in the gas generating chamber, and a gas generating agent is loaded around the hollow space. Then, the combustion is sequentially started by the flame from the ignition means having a plurality of ignition holes. For this reason, since the gas generating agent does not burn at once, the airbag can be gradually inflated and deployed as required for the passenger airbag. Further, the gas generated in the gas generation chamber spreads throughout the gas generation chamber, passes through a plurality of gas passage holes, flows into the hollow space, and stays in the hollow space. Flow into filter chamber. In addition, the generated gas flows throughout the filter chamber, where it is collected and cooled, and is discharged as a clean gas into the gas passage chamber. Thus, slag collection and cooling of generated gas can be sufficiently performed by effectively using the entire filter chamber.

[0011] The gas generator according to the second aspect is the first aspect.
In the above, the hollow space is formed on the same axis as the long cylindrical housing, and has a length of 50% or more of an axial length of the gas generating chamber. According to this configuration, since the hollow space is formed by the inner cylinder having the same axis as the housing, the gas generating agent is uniformly loaded on the outer peripheral portion of the hollow space. In addition, since the hollow space has a plurality of gas passage holes and has a length of 50% or more, preferably 60% or more of the axial length of the gas generating chamber, the gas generating agent loaded in the gas generating chamber is used. The gas generated from the gas flows into the hollow space easily and reliably without staying in the gas generating chamber.

According to a third aspect of the present invention, there is provided a gas generator.
Or In 2, the hollow space communicates with the filter chamber via an orifice for controlling combustion of the gas generating agent. According to this configuration, the amount of generated gas released from the hollow space to the filter chamber can be controlled by the orifice.

[0013] The gas generator according to the fourth aspect is the first aspect.
In the above, the transmission means extends into the hollow space,
It is provided with a nozzle having a plurality of heat transfer holes that open in the radial direction. According to this configuration, the entire gas generating agent loaded around the hollow space can be efficiently burned. Further, by adjusting the length of the nozzle portion, the combustion order of the gas generating agent can be controlled. This makes it possible to release the generated gas as needed.

According to a fifth aspect of the present invention, there is provided a gas generator.
In the above, the transmission means has a cylindrical shape having the same diameter as the hollow space, and has a plurality of transmission holes which are opened in a radial direction. According to this configuration, the inside of the inner cylinder that defines a hollow space in the housing can be partitioned, and a sintering agent can be loaded on the side of the igniting unit to form a squib. Therefore, the structure inside the housing is simplified. Further, by adjusting the length of the partition portion, the amount of the transfer agent to be charged can be adjusted, and the combustion of the gas generating agent can be controlled.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A gas generator according to an embodiment of the present invention will be described with reference to FIGS. The gas generator according to the embodiment of the present invention mainly inflates and deploys an airbag for a passenger seat.
At 3, the gas generating agent 12 is burned.

A gas generator P1 shown in FIG. 1 includes a housing 1, an ignition means 13 mounted on one shaft end of the housing 1, and a transmission means 30 connected to the ignition means 13.
A partition plate 19 for partitioning the housing 1 into the gas generation chamber 3 and the filter chamber 4; and a hollow space 6 in the gas generation chamber 3.
And a gas generating agent 12 loaded on the outer periphery of the hollow space 6.

The housing 1 includes an outer cylindrical member 2 having both ends opened.
A cover plate 10 for closing one end of the outer tubular member 2, and a cover member 1
4. The housing 1 includes a cover plate 10
And the lid member 14 is inserted into each opening side in the outer cylindrical member 2,
This is a structure that forms a sealed space inside. The housing 1 has the cover plate 10 and the cover member 14 as respective shaft ends.
It has a long cylindrical shape with both ends closed. The sealed space inside the housing 1 is divided by a partition plate 19 into two chambers, a gas generating chamber 3 and a filter chamber 4.

The partition plate 19 has a stepped portion, and an orifice 20 is formed on the axis of the housing 1. The orifice 20 allows the gas generating chamber 3 and the filter chamber 4 to communicate with each other. The partition plate 19 is welded after the outer cylinder 2 is fixed to a predetermined position of the outer cylinder 2 by caulking the outer cylinder 2 from the outer peripheral side. The orifice 20 is closed by a burst plate 20a attached to the partition plate 19. The burst plate 20a is formed of a metal foil such as aluminum, and plays a role in preventing moisture in the gas generating chamber 3 and adjusting the internal pressure.

On the filter chamber 4 side of the outer cylindrical member 2, a plurality of gas discharge holes 11 for communicating the inside of the filter chamber 4 and the airbag are formed. Each gas release hole 11 is
Are formed at predetermined intervals in the axial direction and the circumferential direction.

The lid member 14 has a stepped space S1. The stepped space S <b> 1 has a screw formed in the inner diameter portion, and is screwed with a screw formed in the large diameter portion 25 of the ignition means 30.

The filter material 7 is formed into a hollow cylindrical shape by, for example, an assembly of a knitted wire mesh or a crimp-woven metal wire. The filter member 7 is inserted into the filter chamber 4 defined by the partition plate 19 in the housing 1 and is located between the cover plate 10 and the partition plate 19. The filter member 7 forms an annular gas passage space 8 with the outer cylinder member 2.

The gas generating chamber 3 includes a hollow space 6 defined by an inner cylindrical member 5 made of metal such as aluminum, and an annular space S2 in which a gas generating agent 12 is loaded.
In the hollow space 6, one end of the inner cylindrical member 5 is fitted to a stepped portion provided on the partition plate 19, and the other end is fitted to the large-diameter portion 25 of the fire transmitting means 30 provided on the lid member 14. It is formed. The inner cylinder 5 has a plurality of gas passage holes 21 communicating the hollow space 6 inside the inner cylinder 5 and the space between the outer cylinder 2.
Are formed. Each gas passage hole 21 is formed at predetermined intervals in the axial direction and the circumferential direction of the inner cylindrical member 5. The hollow space 6 is formed on the same axis as the gas generating chamber 3 and has a length of 50% or more of the axial length of the gas generating chamber 3 and about 90% in this embodiment. Have been. Therefore, the gas generated in the annular space S2 efficiently flows into the hollow space 6.

The ignition means 30 extending into the hollow space 6 includes:
As shown in FIG. 1, it is constituted by a pressure combustion chamber 26 and a nozzle 17 extending in the axial direction in the hollow space 6 so as to be concentric with the axis of the housing 1.

As shown in FIG. 1, the nozzle 17 extends axially in the hollow space 6 so as to be concentric with the axis of the housing 1. The pressure combustion chamber 26 side of the nozzle 17 is in contact with the rupture plate 27, and the rupture of the plate 27 enables communication with the pressure combustion chamber 26. Also,
The inner diameter of the nozzle 17 is smaller than the inner diameter of the pressure combustion chamber 26, and the extension length L of the ignition nozzle 4 is
Within any length dimension. Preferably, the length is set to 1/3 or more in the hollow space 6.
Thereby, the gas generating agent 12 can be gradually burned. Further, a plurality of fire holes 18 are formed in the nozzle 17. Each of the heat transfer holes 18 is arranged in the axial direction and the circumferential direction of the nozzle 17, and communicates with the inside of the nozzle 17 into the hollow space 6. In addition, each of the heat transfer holes 18
Is formed such that the pitch between holes is reduced in the vicinity of the pressure combustion chamber 26, and the pitch between holes increases as the distance from the pressure combustion chamber 26 increases. Each of the heat transfer holes 18 is closed by a rupture plate 28 attached to the outer periphery of the nozzle 17. The rupture plate 28 is formed of a metal foil such as aluminum, and seals the inside of the nozzle 17 from the hollow space 6.

As shown in FIG. 1, the gas generating agent 12 loaded in the annular space S2 of the gas generating chamber 3 generates a high-temperature gas by combustion.
Is loaded axially inside.

The ignition means 13 connected to the transmission means 30
As shown in FIG. 1, for example, is constituted only by an igniter that ignites when energized (hereinafter referred to as “igniter 13”).
It is attached to the lid member 14 from inside the pressure combustion chamber 26. The igniter 13 protrudes into the pressure combustion chamber 26, is energized and ignited based on a collision detection signal from a collision sensor, and ejects a flame into the pressure combustion chamber 26.

In the pressure combustion chamber 26, the first transfer agent 15
Is loaded into the pressure combustion chamber 26 so as to cover the tip side of the igniter 13. This first transfer agent 15 is used for the igniter 13.
The composition contains a composition that is ignited and burned by the flame generated by the ignition, generates heat by the ignited combustion, and generates a high-temperature gas.
As the first transfer agent 15, the calorific value due to combustion is 350
0 J / g or more, and the number of moles of gas generated by combustion is 0.1 M / g.
It is preferable to use a mixture of 5-aminotetrazole, boron fine powder, molybdenum trioxide, and potassium nitrate in predetermined amounts so as to be 5 mol / 100 g or more.

As shown in FIG. 1, the second transfer agent 16
Are loaded in the nozzle 17 in the axial direction.
The second transfer agent 16 has a composition that is ignited and burned by the heat of combustion of the first transfer agent 15 and generates heat by the ignited combustion. As the second transfer agent 16, the first transfer agent 15
Similarly to the above, 5-aminotetrazole, boron fine powder, molybdenum trioxide and potassium nitrate are added in predetermined amounts so that the calorific value becomes 3500 J / g or more and the number of moles of gas generated by combustion becomes 0.5 mol / 100 g or more. It is preferable to use the compounded one.

The first transfer agent 15 and the second transfer agent 1
6 may be of the same composition. Further, the composition can be appropriately adjusted. For example, the first transfer agent 15 may include a composition that generates heat by ignition combustion, and the second transfer agent 16 may have a composition that generates heat by ignition combustion and generate high-temperature gas. In addition, the first and second transfer agents 15 and 16 may have a composition that generates heat by ignition combustion and generates a high-temperature gas.

Next, the operation of the gas generator P1 will be described with reference to FIG.

When the collision sensor detects a vehicle collision,
As shown in FIG. 1, the igniter 13 of the gas generator P1 is energized and fired. The flame resulting from the ignition of the igniter 13 is jetted into the pressure combustion chamber 26 to ignite and burn the first transfer agent 15. The combustion of the first transfer agent 15 causes the pressure combustion chamber 2
Heat and a high-temperature gas such as a flame are generated in 6, and the first transfer agent 15 is instantaneously burned toward the nozzle 17 by the heat energy. When the combustion of the first transfer agent 15 proceeds and the pressure inside the pressure combustion chamber 26 reaches a predetermined pressure, the rupture plate 27 ruptures, and the inside of the pressure combustion chamber 26 communicates with the inside of the nozzle 17.

The heat and the high-temperature gas generated in the pressure combustion chamber 26 propagate and flow into the nozzle 17 to ignite and burn the second transfer agent 16 on the opening side of the nozzle 17. At this time, since the inner diameter of the nozzle 17 is smaller than the pressure combustion chamber 26, the heat and the high-temperature gas generated in the pressure combustion chamber 26 are concentrated in a state of being constricted to the opening side of the nozzle 17, and instantly 2 The ignition agent 16 is ignited and burned.

By the ignition and combustion of the second transfer agent 16,
Heat such as a flame is generated in the nozzle 17, and this heat causes the second transfer agent 16 to burn instantaneously in the axial direction of the nozzle 17. The combustion of the second transfer agent 16 causes the rupture plate 2
8 is ruptured, and each fire hole 18 of the nozzle 17 is opened in the hollow space 6. Each of these heat transfer holes 18 is provided with the second transfer agent 16.
Are sequentially opened by the combustion in the axial direction, and heat such as a flame generated in the nozzle 17 is sequentially jetted into the intermediate space 6. Further, as shown in FIG. 1, the heat such as the flame is jetted into the intermediate space 6 over the circumferential direction of the nozzle 17. Then, the heat such as the flame injected into the intermediate space 6 is injected into the annular space S2 from the gas passage holes 21 formed in the inner cylinder 5. The gas generating agent 12 loaded in the annular space S2 is sequentially ignited and burned by heat of a flame or the like sequentially ejected from the gas passage holes 21 of the inner cylinder member 5. Here, the hollow space 6
Is formed over substantially the entire length of the gas generating chamber 3 (90% or more of the axial length of the gas generating chamber 3), so that the gas generating agent 12 loaded in the annular space S2 burns efficiently. . Then, a large amount of the high-temperature gas generated by the ignition and combustion of the gas generating agent 12 passes through the gas passage holes 21 formed in the inner cylinder 5 again and is discharged into the hollow space 6. Here, since the hollow space 6 is formed over substantially the entire length of the gas generating chamber 3, the high-temperature gas generated in the annular space S2 flows into the hollow space 6 efficiently. Hollow space 6
When the pressure in the gas generating chamber 3 reaches a predetermined pressure due to the gas flowing into the inside, the burst plate 20a provided on the partition plate 19 bursts. Then, the gas flows into the filter chamber 4 through the orifice 20.

The high-temperature gas flowing into the nozzle 17 from the pressure combustion chamber 26 is supplied to each of the heat transfer holes 1 near the pressure combustion chamber 26.
8 escapes into the intermediate space 6. This is the fire hole 18
This is because, by forming a large number of holes near the pressure combustion chamber 26 with a small inter-hole pitch, the high-temperature gas can be quickly discharged into the intermediate space 6 without being confined in the nozzle 17. This can prevent the nozzle 17 from being damaged or the like due to the pressure of the high-temperature gas generated in the pressure combustion chamber 26 or the like.

The high temperature gas flowing into the filter chamber 4 is
After passing through the hollow portion of the filter material 7 in the filter chamber 4, the gas flows into the filter material 7 from the entire axial direction, where it is collected and cooled, and then flows out into the gas passage space 8. Then, the purified gas is discharged into the airbag through each gas discharge hole 11. The airbag is rapidly inflated and deployed by the clean gas discharged from each gas discharge hole 11.

As described above, according to the gas generator P 1, the flame caused by the ignition of the igniter 13 is transmitted to the first and second transfer agents 1.
The heat is propagated in the axial direction inside the housing 1 by the heat generating holes 5 and 16, and the heat such as a flame is ejected from each of the heat transfer holes 18 of the nozzle 17 into the intermediate space 6. Are sequentially burned. Since the gas generated by the combustion of the gas generating agent 12 passes through the orifice 20 and is discharged to the filter chamber 4, the pressure of the gas discharged by the orifice 20 can be controlled. Further, since the hollow space 6 is formed and the gas generating agent 12 is loaded in the annular space S2 formed on the outer periphery thereof, even when a predetermined amount of the gas generating agent 12 is loaded, the diameter of the housing 1 can be reduced. Can be reduced,
The size and weight of the gas generator can be reduced. Furthermore, since the gas generating agent 12 burns sequentially, the amount of generated gas gradually increases, and the airbag can be gradually expanded and deployed. In addition, since the filter member 7 has a hollow portion along the axial center, the gas generating chamber 3
Can be introduced over the entire area of the filter member 7 in the axial direction.

Next, the gas generator P2 shown in FIG. 2 will be described. 2, the same reference numerals as those in FIG. 1 denote the same members.

The gas generator P2 shown in FIG.
Has a cylindrical shape having the same diameter as the inner cylindrical member 5 forming the hollow space 6. As shown in FIG. 2, in the gas generator according to the present embodiment, the inside of the inner cylindrical member 5 is defined by the partition portion 22 into the hollow space 6 and the transfer agent chamber 6a. The transfer medium 15 is loaded in the transfer medium chamber 6a. A plurality of heat transfer holes 18 are formed on the outer periphery of the inner cylindrical member 5 constituting the transfer agent chamber 6a. Each of the heat transfer holes 18 is arranged in the axial direction and the circumferential direction of the inner cylindrical member 5 and communicates with the annular space S2. Each of the heat transfer holes 18 is closed by a rupture plate 28 attached to the outer periphery of the inner cylindrical member 5. The rupture plate 28 is formed of a metal foil such as aluminum, and seals the inside of the transfer agent chamber 6 a from the gas generation chamber 3. Therefore, when the igniter 13 is ignited and the igniting agent 15 is ignited, the gas generating agent 12 near each igniter hole 18 is sequentially burned to the gas generating agent 12 on the filter chamber 4 side. For this reason, the amount of gas generated from the gas generating agent 12 gradually increases. Here, the partition part 22
The length L ₁ of the partitioned hollow space 6 is preferably 50% or more, and more preferably 60% or more, of the axial length L ₂ of the gas generating chamber 3. As a result, a flame or the like generated by the transfer agent 15 loaded in the transfer means 30 causes
The gas generating agent 12 reliably burns. In addition, the annular space S
The high temperature gas generated in 2 flows into the hollow space 6 efficiently. The holder 29 is fitted to one end of the inner cylinder 5 on the side of the lid member 14, and the holder 29 is screwed and fixed to a stepped space S1 formed in the lid member 14.

As described above, the gas generator P2 is configured such that the inside cylindrical member 5 defining the hollow space 6 is partitioned by the partition portion 22 so that the hollow tube 6 and the transfer agent are formed of the same inner cylindrical member 5. 15 can be formed. Therefore, the size of the gas generator can be reduced without lowering the combustion characteristics. In addition, the length L ₁ of the hollow space 6
It is possible to gradually increase the amount of gas generated by adjusting.

Further, the gas generator according to the present invention may have, for example, the structure shown in FIG. 3, the same members as those in FIGS. 1 and 2 are denoted by the same reference numerals. The gas generator P3 of FIG. 3 differs from the gas generator P2 shown in FIG. 2 in that the inner cylinder member 5 and the ignition means 30 are formed as separate members. The gas generating chamber 3 of the gas generator P3 includes a hollow space 6 defined by a bottomed inner cylindrical member 5, an annular space S2 formed on the outer periphery of the inner cylindrical member 5, A space S3 between the bottom 5a and the transmission means 30 is provided. The open end of the inner cylindrical member 5 is fitted to a stepped portion provided on the partition plate 19. The gas generating agent 12 is loaded in the annular space S2 and the space S3. The length L ₁ of the hollow space 6 defined by the inner tubular member 5 is 50% or more, preferably 60%, of the axial length L ₂ of the gas generating chamber 3.
It is preferable that it is above. As a result, similarly to the gas generators P1 and P2, the high-temperature gas resulting from the combustion of the gas generating agent 12 flows into the hollow space 6 efficiently.

In the gas generator P3, the flame of the ignition means 30 propagates to the gas generating agent 12 located near the ignition means 30, and the gas generating agent 12 located on the filter chamber 4 side burns sequentially. Go. The generated gas sequentially flows into the hollow space 6, passes through the filter chamber 4, and is discharged.

In the gas generators P1 to P3, a gas generating agent containing a nitrogen-containing organic compound can be employed in addition to the gas generating agent containing a metal azide compound. As described above, in each of the gas generators P1 to P3, even if a nitrogen-containing organic compound-based gas generating agent having a lower ignition performance than that of the metal azide compound-based gas generating agent is employed, the ignition and burning are performed stably. In addition, as a gas generating agent containing a nitrogen-containing organic compound,
Compounds containing nitrogen-containing organic compounds such as tetrazole compounds, triazole compounds, amide compounds, and guanidine compounds as combustion components can be used. Further, the gas generating agent is not limited to a pellet, but may be a disk, a granule, or a hollow column.

The gas generators P1 to P3 according to the embodiment of the present invention are not limited to those shown in FIGS. 1 to 3, and may take the following forms, for example. (1) A configuration in which the gas generation chambers 3 are formed on both left and right sides of the filter chamber 4 and a plurality of ignition means 13 are provided can also be adopted. In this case, the configuration of the gas generation chamber 3 is the same as that of the gas generator P1 described above.
Any of the gas generating chambers 3 of the gas generators P to P3 may be used. In this case, the filter chamber 4 may be a single chamber, and the filter material 7 may be shared by the gas generation chambers 3 on the left and right sides. Further, the filter chamber 4 may be partitioned by a partition plate or the like and may be dedicated to each gas generating chamber 3. (2) The combustion of the gas generating agent 12 may be adjusted by the gas discharge holes 11. In addition, a seal tape or plate made of metal, resin, or the like may be provided in the gas discharge hole 11 for adjusting the internal pressure of the gas generator and / or preventing moisture.

[0044]

According to the gas generator of the present invention, the housing is divided into a gas generation chamber and a filter chamber, and a hollow space having the same axis as the housing is formed in the gas generation chamber. In addition, since the gas from the gas generating agent flows in and out as needed, the size of the gas generator can be reduced, and the airbag can be gradually expanded and deployed.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a gas generator according to an embodiment of the present invention.

FIG. 2 is a sectional view showing a modification of the gas generator in the embodiment of the present invention.

FIG. 3 is a sectional view showing a modified example of the gas generator in the embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Housing 2 Outer cylinder material 3 Gas generation chamber 4 Filter chamber 5 Inner cylinder material 6 Hollow space 7 Filter material 13 Ignition means 20 Orifice 21 Gas passage hole 30 Fire transmission means

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Yoshiyuki Kishino 3903-39, Tomimachi, Himeji-shi, Hyogo F-term (reference) in Nippon Kayaku Co., Ltd. Himeji Plant 3D054 AA03 AA14 BB08 DD15 DD21 DD28 DD40 FF13 FF14 4G068 DA08 DB15 DB20 DD12

Claims (5)

[Claims] 1. An elongated cylindrical housing having both ends closed, ignition means attached to at least one shaft end of the housing, and a plurality of transfer agents connected to the ignition means and loaded with a transfer agent. A transmission means having a transmission hole, wherein the interior of the housing, a gas generation chamber containing a gas generating agent, and a filter chamber in which a filter material is mounted,
Wherein the gas generating chamber has a hollow space defined by an inner cylindrical member having a plurality of gas passage holes into which the generated gas of the gas generating agent flows, and the generated gas is A gas generator, wherein the gas is discharged into the filter chamber after being retained in a hollow space. 2. The gas generating chamber according to claim 1, wherein the hollow space is formed on the same axis as the elongated cylindrical housing, and has a length of 50% or more of an axial length of the gas generating chamber. Gas generator. 3. The gas generator according to claim 1, wherein the hollow space communicates with the filter chamber via an orifice controlling combustion of a gas generating agent. 4. The gas generator according to claim 1, wherein the ignition means comprises a nozzle extending in the hollow space and having a plurality of ignition holes that open in a radial direction. 5. The gas generator according to claim 1, wherein the transmission means has a cylindrical shape having the same diameter as the hollow space and has a plurality of transmission holes which are opened in a radial direction.