JP2009082788A - Gas generator - Google Patents

Abstract

A gas generator for ejecting low-temperature high-pressure gas is provided.
A gas generator (10) has a casing (20) loaded with a gas generating agent, and jets high-pressure gas by the reaction of the gas generating agent. A heat absorbing member (40) that absorbs heat from the high pressure gas is provided at the gas outlet (21) of the casing (20) from which the high pressure gas is ejected from the casing (20).
[Selection] Figure 1

Description

    The present invention relates to a gas generator, and particularly relates to measures for reducing the temperature of high-pressure gas.

Conventionally, as disclosed in Patent Document 1, some gas generators are provided in explosive actuators. As shown in FIG. 8, this explosive actuator is applied to various vehicles and includes a cylinder (a), a piston (b), and a gas generator (c). For example, when the collision detection sensor detects a collision, the explosive charged in the gas generator (c) is burned, and the gas generator ejects the high-pressure gas (d) into the cylinder (a) and piston ( Move b). By this movement, the engine hood is lifted to ensure a large amount of deformation of the hood at the time of a pedestrian collision.
JP 2004-330912 A

    However, the gas generator (c) in the conventional explosive actuator injects the high-pressure gas (d) at a high temperature after combustion, as shown in FIG. Then, this high-temperature high-pressure gas (d) is supplied to the cylinder (a). Therefore, after the high-temperature high-pressure gas (d) once operates the piston (b), the temperature rapidly decreases. Due to this temperature drop, the volume of the high-pressure gas (d) in the cylinder (a) is reduced, and there is a problem that the piston (b) cannot be maintained in the operating state.

    Therefore, the advent of a new gas generator that generates low-temperature, high-pressure gas was screamed.

    This invention is made | formed in view of such a point, and it aims at providing the gas generator which ejects low temperature high pressure gas.

    The first invention is directed to a gas generator in which a gas generating agent is loaded in a casing (20) and high-pressure gas is ejected by a reaction of the gas generating agent. The gas outlet (21) of the casing (20) from which the high pressure gas is ejected from the casing (20) is provided with a heat absorbing means (40) for absorbing heat from the high pressure gas.

    In a second aspect based on the first aspect, the casing (20) has the gas outlet portion (21) opposed to the fuse (51) so that the high pressure gas is ejected to the blocking portion of the fuse (51). Are arranged as follows.

    In a third aspect based on the first aspect, the casing (20) is provided in an actuator body (65) that moves a piston (62) housed in the cylinder (61) by high-pressure gas.

    In a fourth aspect based on the first aspect, the heat absorption means (40) is configured to absorb the heat of the high pressure gas when the high pressure gas passes through the ceramic particles.

    In a fifth aspect based on the first aspect, the heat absorption means (40) includes a metal mesh and is configured to absorb heat of the high pressure gas when the high pressure gas passes through.

    Therefore, in the first invention, a high-temperature high-pressure gas is generated by the reaction of the gas generating agent. Then, the endothermic means (40) absorbs heat from the high pressure gas. Specifically, in the fourth invention, the ceramic particles of the heat absorbing means (40) absorb heat, and in the fifth invention, the metal mesh of the heat absorbing means (40) absorbs heat. As a result, the high-pressure gas having a low temperature is ejected.

    In particular, in the second aspect of the invention, high pressure gas is ejected to the interrupting part of the fuse (51) to blow off the arc discharge at the interrupting part of the fuse (51). At this time, since the high-pressure gas is cooled and not ionized, the discharge is suppressed.

    In the third invention, the high pressure gas is supplied to the cylinder (61), and the piston (62) moves. At this time, since the high-pressure gas is at a low temperature, the decrease in volume is suppressed, and the piston (62) maintains the moving position.

    According to the present invention, since the high-pressure gas endothermic means (40) is provided, low-temperature high-pressure gas can be ejected. As a result, the influence by the temperature change of the said high pressure gas can be suppressed reliably.

    In particular, according to the second invention, when the arc discharge at the interrupting portion of the fuse (51) is blown off with the high pressure gas, the high pressure gas is cooled and not ionized, so that the discharge can be reliably suppressed. .

    According to the third aspect of the invention, since the high pressure gas that has moved the piston (62) is cooled, the volume does not decrease, so that the piston (62) is reliably maintained at the moved position. Can do.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Embodiment 1>
As shown in FIGS. 1 and 2, the gas generator (10) of the present embodiment is used for a safety device of an automobile, etc., and generates a high-pressure gas (11) to drive an airbag or the like.

    The gas generator includes a casing (20), a gas generating agent sealed container (30), and a heat absorbing member (40).

    The casing (20) is formed, for example, in a bottomed cylindrical body with one end opened, and the open end is configured as a gas outlet (21).

    The closed container (30) is filled with a gas generating agent (for example, explosive) and is formed so as to be ruptured. Although not shown, the casing (20) includes an ignition device for igniting and burning the gas generating agent, and the ignition device is connected to a controller (not shown). And the said gas generator (10) is comprised so that a gunpowder will start combustion by the action | operation of an ignition device, ie, a gas generating agent will start reaction, and generate | occur | produce a high pressure gas (11).

    The said heat absorption member (40) is provided in the gas outlet part (21) in a casing (20). The heat absorbing member (40) constitutes heat absorbing means for absorbing heat from the high pressure gas (11) generated by the operation of the ignition device. The heat absorbing member (40) is filled with ceramic particles and configured to absorb heat of the high pressure gas (11) when the high pressure gas (11) passes through. That is, the high pressure gas (11) generated by the operation of the ignition device passes through the heat absorbing member (40) before being ejected from the gas outlet (21) to the outside of the casing (20). Absorbs heat and lowers the temperature of the high-pressure gas (11).

    The heat absorbing member (40) may be configured to include a metal mesh instead of ceramic particles and absorb the heat of the high pressure gas (11) when the high pressure gas (11) passes through.

-Action-
Next, the operation of the gas generator (10) will be described.

    First, for example, when the collision detection sensor detects a collision of a pedestrian or the like, an operation signal is input to the gas generator. The ignition device is actuated by this activation signal, and the explosive starts to burn, that is, the gas generating agent starts to react. When the gas generating agent reacts, the sealed container (30) is filled with the high-pressure gas (11), the pressure in the sealed container (30) rises, the sealed container (30) bursts, and the high-pressure gas (11 ) Jets out of the casing (20) from the gas outlet (21). During the ejection, the high pressure gas (11) passes through the heat absorbing member (40), so that the heat of the high pressure gas (11) is absorbed and the high pressure gas (11) is ejected at a low temperature (see FIG. 2).

-Effect of Embodiment 1-
According to the embodiment, since the heat absorbing member (40) of the high pressure gas (11) is provided, the low temperature high pressure gas (11) can be ejected. As a result, the influence of the temperature change of the high pressure gas (11) can be reliably suppressed. For example, the driven airbag can be maintained in the driven state.

<Embodiment 2>
Next, a second embodiment of the present invention will be described in detail based on the drawings.

    In the present embodiment, as shown in FIGS. 3 and 4, a gas generator (10) is applied to a power breaker (50).

    Specifically, the power breaker (50) includes a fuse (51), and is configured so that the fuse (51) is cut off when an overcurrent exceeding a predetermined value flows. And the said gas generator (10) is arrange | positioned so that a high voltage | pressure gas (11) may be injected toward a interruption | blocking part at a fuse (51).

    That is, the casing (20) of the gas generator (10) is arranged such that the gas outlet (21) faces the fuse (51) so that the high-pressure gas (11) is ejected to the blocking portion of the fuse (51). Is arranged. The configuration of the gas generator (10) is the same as that of the first embodiment.

    Therefore, when an overcurrent flows through the fuse (51), the fuse (51) is cut off. By this interruption, the ignition device is activated and the gas generating agent starts to react. The closed vessel (30) is ruptured by the reaction of the gas generating agent, and the high-pressure gas (11) is ejected to the outside of the casing (20). During the ejection, the high pressure gas (11) passes through the heat absorbing member (40), so that the heat of the high pressure gas (11) is absorbed and the high pressure gas (11) is ejected at a low temperature.

    This low-temperature high-pressure gas (11) flows through the interrupting part of the fuse (51) and blows off the arc discharge generated at the interrupting part of the fuse (51) (see FIG. 4). At that time, the high-pressure gas (11) is cooled to a low temperature and is not ionized, so that the discharge can be reliably suppressed.

<Embodiment 3>
Next, Embodiment 3 of the present invention will be described in detail based on the drawings.

    In this embodiment, as shown in FIGS. 5 and 6, a gas generator (10) is applied to an explosive actuator (60) which is a gas pressure actuator.

    The explosive actuator (60) is for reducing the impact of a secondary collision of a pedestrian that has collided with the front end of the automobile, and is provided below the engine hood of the automobile. When a collision signal is input, The engine hood is forcibly lifted.

    The explosive actuator (60) includes a cylinder (61) and a piston (62) provided in the cylinder (61).

    The cylinder (61) is formed in a cylindrical shape. On the other hand, the piston (62) includes a disk-shaped piston part (63) and a rod part (64). The piston part (63) is slidably provided in the cylinder (61). One end (lower end) of the rod portion (64) is connected to the piston portion (63). The rod portion (64) penetrates the cylinder (61), and the upper end that is the other end is exposed to the outside of the cylinder (61). The cylinder (61) and the piston (62) constitute an actuator body (65).

    The upper end of the rod portion (64) is configured to contact the engine hood and lift the engine hood when the explosive actuator (60) is operated.

    The gas generator (10) is attached to the closed end of the cylinder (61). The configuration of the gas generator (10) is the same as that of the first embodiment, and is configured to eject the high-pressure gas (11) to the cylinder (61).

-Action and effect-
Next, the operation of the explosive actuator (60) will be described.

    For example, when the collision detection sensor detects a pedestrian collision, a collision signal is input to the explosive actuator (60). When the collision signal is input, the ignition device is activated and the explosive starts to burn, that is, the gas generating agent starts to react. When the gas generating agent reacts, the sealed container (30) is ruptured, and the high-pressure gas (11) is ejected to the cylinder (61) (see FIG. 6).

    At that time, since the high-pressure gas (11) passes through the heat absorbing member (40), the heat of the high-pressure gas (11) is absorbed, and the high-pressure gas (11) becomes low temperature and is ejected to the cylinder (61). The piston (62) protrudes from the cylinder (61) by the jet output of the high-pressure gas (11). The engine hood of the automobile is lifted by the protrusion of the piston (62). Since the high pressure gas (11) is cooled when the piston (62) lifts the engine hood, the volume does not decrease, so that the piston (62) can be reliably maintained at the moved position. .

<Other embodiments>
The present invention may be configured as follows with respect to the above embodiment.

    Although the said Embodiment 1 demonstrated the gas generator (10) used for the safety device of a motor vehicle, etc., this invention is not restricted to these, The gas generator (1) which ejects high pressure gas (11) with a gas generating agent ( Of course, it can be applied to 10).

    In addition, the gas generator (10) of Embodiment 3 is not necessarily limited to the one provided at the end of the cylinder (61), and may be provided to the piston (62).

    In each of the above embodiments, explosives are used as the gas generating agent of the gas generator (10). However, the present invention is not limited to this, and the gas generator (10) of the present invention generates gas by reaction. I just need it.

    In addition, each above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a gas generator that generates high-pressure gas by reaction of a gas generating agent.

1 is a schematic cross-sectional side view of a gas generator according to Embodiment 1. FIG. FIG. 2 is a schematic cross-sectional side view of the gas generator according to the first embodiment showing when high-pressure gas is ejected. FIG. 3 is a schematic cross-sectional side view of the gas generator of the power breaker according to the second embodiment. FIG. 4 is a schematic cross-sectional side view of the gas generator according to the second embodiment, showing when high-pressure gas is ejected. FIG. 5 is a schematic cross-sectional side view of the explosive actuator of the third embodiment. FIG. 6 is a schematic cross-sectional side view of the explosive actuator of Embodiment 3 showing when high-pressure gas is ejected. FIG. 7 is a schematic cross-sectional side view of a conventional gas generator. FIG. 8 is a schematic cross-sectional side view of an explosive actuator using a conventional gas generator.

Explanation of symbols

10 Gas generator
11 High pressure gas
20 casing
21 Gas outlet
30 Airtight container
40 Endothermic member (endothermic means)
50 Power circuit breaker
51 fuse
60 Gunpowder actuator
61 cylinders
62 Piston
65 Actuator body

Claims (5)

A gas generator in which a gas generating agent is loaded in a casing (20), and a high pressure gas is ejected by a reaction of the gas generating agent,
A gas generator characterized in that a heat absorbing means (40) for absorbing heat from the high pressure gas is provided at a gas outlet (21) of the casing (20) from which the high pressure gas is ejected from the casing (20). In claim 1,
The casing (20) is characterized in that the gas outlet (21) is arranged so as to face the fuse (51) so as to inject high-pressure gas into the interrupting portion of the fuse (51). vessel. In claim 1,
The gas generator according to claim 1, wherein the casing (20) is provided in an actuator body (65) that moves the piston (62) accommodated in the cylinder (61) by high-pressure gas. In claim 1,
The heat-absorbing means (40) is filled with ceramic particles and configured to absorb heat of the high-pressure gas when the high-pressure gas passes through the gas generator. In claim 1,
The heat-absorbing means (40) includes a metal mesh, and is configured to absorb heat of the high-pressure gas when the high-pressure gas passes through the gas generator.

Images