KR100563857B1 - Multi ignition control typed air bag device for using gas influx - Google Patents

Abstract

The present invention relates to a multi-stage ignition control type airbag device using a gas flow, wherein when inflators having the same specification are separated from each other and exploded with a time difference, the airbag deployment is controlled by controlling the mixing characteristics of the gases ejected from them. The purpose of the present invention is to solve the increase in technical difficulties and cost in the multi-stage ignition in the common module by having the multi-stage ignition characteristic.

The present invention for achieving the above object is a cockpit core (1, Cockpit Core) that is equipped with various instrument panels, such as the airbag device forms the driver's seat at the front of the vehicle, and cowl bar provided in the cockpit core (1) First and second inflators (6, 6) which are fixed by using (3, Cowl Bar) and separated from each other at intervals and explode with time difference according to the control signal generated from the controller that detects the signal of the shock sensor. A nozzle formed inside the cockpit core 1 to induce a gas flow according to the time difference of the explosion during the explosion of the air bag 5 and the inflator 6 and 6, 7) and a cushion (8, Cushion) that is torn and developed by tearing the deployment door (2) of the cockpit core (1) while being expanded by the gas ejected through the nozzle (7).

Description

Multi ignition control typed air bag device for using gas influx}

1 is a block diagram of a vehicle equipped with a multi-stage ignition control type airbag device using a gas flow according to the present invention

2 is a block diagram of a multi-stage ignition control type airbag device using a gas flow according to the present invention

    <Description of the symbols for the main parts of the drawings>

1: cockpit core 2: development door

3: cowl bar 4: fixed bracket

5: air bag 6,6 ': first and second inflator

7: nozzle 7a: narrow path portion

7b: bottleneck 7c: extension path

8: cushion

The present invention relates to a multi-stage ignition airbag device, and more particularly, to eliminate the difference in ignition time required in the inflator through a nozzle forming a gas flow to use a single-stage ignition inflator having the same specification. A multistage ignition control type airbag device is provided.

In general, the performance of the car and the improvement of the pavement condition of the road are gradually increased, so that the driving speed of the car is gradually increased, thereby increasing the tendency of the passengers to be very injured in the event of a car crash. In the event of a vehicle crash, an airbag that absorbs and buffers a shock at the movement position of passengers is installed.In particular, a steering wheel or cockpit core (commonly called an instrument panel) due to an impact during a vehicle collision is installed. ) And front windshield glass to prevent the loss of life.

As such, an air bag system that reduces the injuries of drivers or passengers during a vehicle crash, instantly inflates the cushion with gas between the passengers and the steering wheel or cockpit core during frontal charging. It is designed to reduce the secondary injury of the occupants by hopping the kinetic energy, which is installed at the position that detects the collision of the vehicle well. An airbag micom, an inflator that generates gas by igniting a primer according to the control signal of the micom, and a cushion developed by the gas generated in the inflator.

Accordingly, as the airbag micom recognizes the shock signal of the acceleration detection sensor that detects when a shock is applied to the vehicle at a predetermined level or more, it ignites the primer of the inflator to burn the gas generating material. As it flows in, it is inflated toward the driver or the passenger, and it contacts the front upper body to effectively cushion the impact load caused by the collision to reduce secondary injury.

These airbags protect the head and chest of the passengers to prevent secondary collisions with the steering wheel or the windshield glass, which are different depending on the type of collision and the speed of the vehicle. The time until the electric signal is output and the airbag is fully inflated should be 30-40ms in a very short time.

In other words, at such an extremely short moment, the airbag is reduced by absorbing energy by stopping and protecting the passengers and at the same time being discharged to the gas, all of which are completed in a very short time.

In addition, although the airbag system may never operate during the lifetime of the vehicle, it is of course required to operate reliably in the event of an accident and, conversely, when the operation is not necessary, high reliability of the device is required.

Such airbags typically blow gas at a predetermined pressure without distinction between adults and children due to one gas expansion during operation, thereby reducing the effectiveness of the airbag as a result of operating regardless of the rider's body size. Rather, in recent years, the weak and the infants have been injured by airbags, such as the closing.

Therefore, to reduce the damage caused by the rapid temporary deployment, the technology that allows the inflator to operate in multiple stages (typically two stages) while the airbag is deployed (called a smart airbag) is applied to reduce the above-mentioned closures. It is the situation.

However, in the case of igniting the inflator in multiple stages during airbag deployment, there is considerable difficulty in manufacturing the inflator which is ignited at a time interval from each other, that is, exploding with a time difference in one module to expand the cushions from each other. The development of an inflator that does not interfere is very difficult in terms of time, technology, and cost.

Accordingly, the present invention has been invented in view of the above, and in such a manner that the inflators having the same specification are separated from each other and exploded with a time difference to control the mixing characteristics of the gases ejected from them so as to have a multi-stage ignition characteristic when the airbag is deployed. Solution The objective is to solve the technical difficulties and cost increase of multistage ignition in a common module.

The present invention for achieving the above object, the cockpit core is equipped with a variety of instrument panels while forming a driver's seat in the front portion of the vehicle;

A first inflator fixed to the cowl bar by a bracket at a lower side of the cowl bar installed to cross the width direction in the cockpit core, and a cowl bar fixed to the cowl bar at an upper side of the cowl bar by ignition of the first inflator. An airbag composed of a second inflator that is ignited at a time differential relative to the first;

A controller for generating a control signal for igniting the first inflator according to a signal of a sensor detecting a vehicle collision;

A nozzle formed inside the cockpit core to induce a gas flow ejected from the second inflator ignited at a time difference to the first inflator while inducing a gas flow by ignition of the first inflator;

A cushion which expands and expands and expands the deployment door of the cockpit core while being expanded by the gas ejected through the nozzle;

Characterized in that consisting of.

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

1 is a configuration diagram of a vehicle equipped with a multi-stage ignition control type airbag apparatus using a gas flow according to the present invention, and FIG. 2 is a block diagram of a multistage ignition control type airbag apparatus using a gas flow according to the present invention. Inva, the present invention is provided with a cockpit core (1, Cockpit Core) is equipped with a variety of instrument panels, such as the airbag device to form a driver's seat at the front of the vehicle, and the shock-mounted in the cockpit core (1) has a different mounting position According to the control signal generated from the controller that senses the signal of the sensor (Air bag) (5, Air bag) for generating a gas (Gas) by exploding with a time difference, the gas flow generated when the air bag (5) Exploded view of the cockpit core 1 as it is expanded by a nozzle 7 formed inside the cockpit core 1 and a gas ejected through the nozzle 7 to induce multistage ignition characteristics. Comprises a cushion (8, Cushion) that is deployed rip (2).

The airbag 5 has a first inflator 6 fixed to the cowl bar 3 via a bracket at the bottom of the cowl bar 3 installed to cross the width of the cockpit core 1. And a second inflator 6 'fixed to the cowl bar 3 by a bracket on the cowl bar 3, wherein the ignition time of the second inflator 6' is the first inflator ( After 6) is exploded, the flow pressure of the gas exiting the nozzle 7 is determined so that the controller ignites with a time difference for the explosion.

At this time, the explosion time difference of the first and second inflators 6 and 6 'determined by the controller is experimentally determined according to the characteristics of the nozzle 7 through which the gas ejected from the first inflator 6 explodes. This is because the amount of gas to be ejected and the ejection velocity are all different according to the specification of the inflator cannot be determined uniformly.

 In addition, the nozzle 7 includes a narrow path portion 7a positioned at a portion of the first inflator 6 so that the gas ejected from the first inflator 6 of the airbag 5 flows in, and the narrow path portion 7a. The expansion path portion 7c and the path portion 7a positioned at the portion of the second inflator 6 'such that the gas passing through) is introduced into the cushion 8 while being mixed with the gas ejected from the second inflator 6'. 7c) consists of a bottleneck 7b connecting between them.

Here, the narrow path portion 7a has a shape that gradually narrows from the gas inlet to the bottleneck portion 7b, while the expansion path portion 7c has a shape gradually expanding from the bottleneck portion 7b. Is done.

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

According to the present invention, an inflator explosion of an airbag operated in a vehicle crash is performed in multiple stages (two stages with time difference). That is, a controller (not shown) that receives a signal of a sensor detecting a vehicle collision receives an airbag operation signal. When generated, the control signal of the controller is to ignite the first inflator 6 fixed via the bracket under the cowl bar 3 installed to cross the width inside the cockpit core 1 to explode.

Subsequently, the gas generated while the first inflator 6 is ignited and exploded flows into the nozzle 7, where the flow rate of the gas discharged from the first inflator 6 is narrow path portion of the nozzle 7. Passing through the expansion path portion 7c through the portion 7a and the bottleneck portion 7b, the pressure of the expansion path portion 7c, which is the outlet portion through which the gas flows out through the nozzle 7, exits the gas, is increased. It is possible to determine the ignition timing of the second inflator 6 'according to the characteristics of the nozzle 7 determined by.

That is, after the controller ignites the first inflator 6, the gas flow rate according to the pressure of the expansion path portion 7c which is the outlet of the nozzle 7-flows into the nozzle 7 from the first inflator 6. Cushion (8) considering the calculated pressure of the expansion path portion 7c according to the flow of the gas (which is determined experimentally and is not limited to specific values because it depends on the nozzle characteristics and inflator specifications) The second inflator 6 'is ignited so as not to deteriorate the deployment characteristics.

Subsequently, when the second inflator 6 'is ignited with a time difference following the first inflator 6, the second inflator 6' is applied to the nozzle 7 through which the gas generated from the first inflator 6 flows. Gas generated from the mixture is supplied to the cushion 8 to tear and expand the deployment door 2 to protect the passengers.

At this time, the cushion (8) is generated from the second inflator (6 ') that the gas generated in the first inflator 6 is primarily expanded while passing through the nozzle (7), and then ignited with a very short time difference. Gas is expanded together with the gas generated in the first inflator 6 in the nozzle 7 and then expands secondly, and thus different from each other due to the time difference ignition characteristics of the inflator 6 and 6 'of the same specification. It is possible to implement the deployment characteristics of the cushion (8) having two inflators of the specification to prevent the injury of the passengers as much as possible.

As described above, according to the present invention, the airbag according to the multi-stage ignition operation of the inflators having different specifications in one module is used because it uses a nozzle which induces the gas flow generated from the inflator which is made with the same specification and is ignited with time difference. The smart characteristic of the implementation has the effect that can be easily achieved without technical difficulties.

In addition, the present invention is implemented by using the inflators installed in the same specifications and different positions of the smart (Smart) characteristics of the airbag has the effect that can eliminate the cost increase due to the development of the inflator module (Module) having a multi-stage ignition characteristics do.

Claims (3)

Cockpit core (1) which is equipped with various instrument panels while forming a driver's seat in the front portion of the vehicle; The first inflator 6 fixed to the cowl bar 3 via a bracket at the bottom of the cowl bar 3 installed to cross the width direction in the cockpit core 1, and the cowl bar 3. An airbag (5) consisting of a second inflator (6 ') fixed to the cowl bar (3) via a bracket from above and ignited at a time difference with respect to the ignition of the first inflator (6); A controller for generating a control signal for igniting the first and second inflators 6 and 6 'according to a signal of a sensor for detecting a vehicle collision; Inside the cockpit core 1 to induce a gas flow ejected from the second inflator 6 ignited at a time difference to the first inflator 6 while inducing a gas flow by ignition of the first inflator 6. A nozzle 7 formed; A cushion 8 which expands and expands and expands the deployment door 2 of the cockpit core 1 while being expanded by the gas ejected through the nozzle 7; Multi-stage ignition control type airbag device using a gas flow consisting of. 2. The nozzle (7) according to claim 1, wherein the nozzle (7) is provided with a narrow path portion (7a) positioned at a portion of the first inflator (6) so that the gas ejected from the first inflator (6) of the airbag (5) flows in, The expansion path portion 7c positioned at the second inflator 6 'portion and the path so that the gas passing through the passage portion 7a is introduced into the cushion 8 while being mixed with the gas ejected from the second inflator 6'. Multi-stage ignition control type airbag device using a gas flow, characterized in that consisting of a bottleneck (7b) connecting between the portions (7a, 7c). 3. The narrow path portion 7a is formed in a shape that gradually narrows from a gas inlet to a bottleneck portion 7b, and the expansion path portion 7c gradually increases from a bottleneck portion 7b. Multi-stage ignition control type airbag device using a gas flow, characterized in that formed in an expanded shape.

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