KR19990004439U - Tether sewing structure of airbag cushion - Google Patents

Abstract

The present invention is to space the inner sewing line and outer sewing line of the tether attached to the cushion front portion and the cushion rear portion of the airbag cushion to the maximum distance to overcome the vulnerability of the sewing portion due to the sewing needle hole when the airbag cushion deployment The tether sewing structure of the airbag cushion, wherein the sewing portion outer seam of the tether connecting the cushion front portion and the cushion rear portion of the airbag cushion is made in a long shape, and the inner seam line located inside the outer seam is two inequalities. Provides a tether sewing structure of the airbag cushion, characterized in that the shape is made to cross opposite to each other.

Description

Tether sewing structure of airbag cushion

The present invention relates to a tether of an airbag cushion of an automobile airbag system, and more particularly, from a cushion front part and an inflator which are in contact with the body of an occupant so as to prevent damage to the airbag cushion and injury of the occupant due to rapid expansion during deployment. It relates to a tether sewing structure of the airbag cushion having a tether (tether) for connecting between the cushion rear portion in which nitrogen gas is injected.

In particular, the present invention by making the outer sewing line of the sewing section of the tether attached to the cushion front portion and the cushion rear portion of the airbag cushion in the shape of a long, and the inner sewing line to the shape that the two inequality crosses opposite to each other, It is improved to overcome the fragility of the sewing portion due to the density of the sewing needle hole by spaced apart the outer sewing line to the maximum.

In general, a vehicle is equipped with a seat belt that fixes a driver or other crew to the seat to reduce the deceleration acting on each part of the crew body, and the seat belt prevents secondary collision or alleviates the shock. Try to prevent the crew from popping out of the car.

Apart from the above seat belts, in recent years, inflating the airbag (air bag) between the driver and the steering wheel or between the passenger seat and the instrument panel in the event of a collision, it is possible to reduce injuries due to impact. The mounting of air bag systems is becoming increasingly common.

Here, a typical example of the airbag system is shown in FIGS. 1 and 2, which will be briefly described. Nitrogen gas is exploded by an explosion of a plastic cover 125 and a primer 122 in which a deployment part is formed toward the occupant side of the passenger seat. An airbag module (120) installed in the instrument panel consisting of an inflator (121) for generating an airbag, an airbag cushion (124) that is expanded and deployed to the deployment unit by the generated nitrogen gas, and the traveling speed is increased. When the rapid acceleration and gravity acceleration reaches the set value, the shock sensor 130 for generating a shock signal and the electronic control module (Electronic Control module 110) to explode the primer 122 of the inflator 121 in accordance with the shock signal Consists of. The inflator 121 of the airbag module 120 has a gas generator 123 that generates nitrogen gas as the primer 122 is ignited.

The airbag system configured as described above generates a shock signal while contacting the shock sensor 130 when the traveling speed is sharply lowered by, for example, a frontal collision. At this time, the electronic control module 110 recognizes the shock signal to ignite the primer 122, to burn the gas generating agent 121. The burning gas generator 123 expands the airbag cushion 124 while generating nitrogen gas that is rapidly generated, and expands the airbag cushion 124 toward the occupant side through the deployment portion of the pad cover 125. The airbag cushion 124 thus developed partially absorbs the impact load caused by the collision while in contact with the occupant, and when the head and chest of the occupant collide with the inflated airbag cushion 124 by the inertia, the airbag cushion 124 Nitrogen gas is rapidly discharged into the discharge hole formed in the airbag cushion 124 is to buffer the front part of the driver. Accordingly, by effectively buffering the impact force transmitted to the crew during the frontal collision, secondary injuries could be reduced.

On the other hand, the inside of the airbag cushion 124, as shown in Figure 2, the cushion front portion in contact with the body of the occupant so as to prevent damage to the airbag cushion 124 and the injury of the occupant due to rapid expansion during deployment ( A plurality of tethers 126 are provided which connect between 124a and the cushion rear portion 124b into which nitrogen gas is injected from the inflator.

That is, the tether 126 supports the cushion prot portion and the cushion rear portion 124b in a predetermined shape and a predetermined width when the airbag cushion 124 is deployed, whereby the airbag cushion 124 is suddenly expanded by nitrogen gas. Tearing damage can be prevented, and strong inflation forces can prevent injuries from hitting the crew's body.

However, the conventional airbag cushion 124 with the tether 126 has some problems in the sewing portion of the tether despite its usefulness as described above. That is, as shown in Figure 3, the outer sewing line 128 of the sewing section 127 of the tether 126 is made of a square, the inner sewing line 129 is the two triangles are in contact with the edge against each other The upper and lower sides of the mold are adjacent to the right angle side of the inner sewing line 129. At this time, the sewing needle holes 128a and 129a of each of the sewing lines 128 and 129 are also close to each other, thereby becoming a weak spot.

Accordingly, the tension force acting on the tether 126 between the cushion front portion 124a and the cushion rear portion 124b due to the rapid expansion of the high temperature nitrogen gas during the deployment of the airbag cushion 124 is a rectangular edge of the outer seam 128. At the same time, the durability is reduced, and at the same time, it is transmitted to the sewing needle holes 128a and 129a in a vulnerable state so that the sewing section 127, that is, the tether 126 is broken, eventually loses the function of the tether 126. There is a problem.

Accordingly, the present invention is conceived in view of the above-described conventional problems, the airbag cushion by maximally spaced apart the gap between the sewing portion inner seam and outer seam of the tether attached to the cushion front portion and the cushion rear portion of the airbag cushion It is an object of the present invention to provide a tether sewing structure of the airbag cushion to overcome the vulnerability of the sewing portion due to the dense sewing needle hole during deployment.

1 is a block diagram showing the configuration of an airbag system of a typical vehicle

Figure 2 is a side view showing an airbag cushion with a conventional tether

Figure 3 is an excerpt top view showing the tether sewing structure of the conventional airbag cushion

Figure 4 is a side view showing an airbag cushion applied to an embodiment of the present invention

Figure 5 is an excerpt top view showing the tether sewing structure of the airbag cushion according to an embodiment of the present invention

Explanation of symbols on the main parts of the drawings

24: Airbag Cushion 26: Tether

27: sewing part 28: outer sewing line

28a, 29a: sewing needle hole 29: inner sewing line

The present invention for achieving the above object, the sewing section outer seam of the tether connecting the cushion front portion and the cushion rear portion of the airbag cushion is made of a rectangular shape, the inner seam is located inside the outer seam of the two seams It provides a tether sewing structure of the airbag cushion, characterized in that the inequality sign is formed to cross each other.

Hereinafter, an embodiment of the present invention will be described in more detail based on the accompanying drawings.

Figure 4 is a side view showing an airbag cushion 24 applied to an embodiment of the present invention, inside the airbag cushion 24 to prevent damage to the airbag cushion 24 due to rapid expansion during deployment and injury to the occupants A plurality of tethers 26 are provided to connect the sewing machine 127 between the cushion front portion 24a in contact with the body of the occupant and the cushion rear portion 24b into which nitrogen gas is injected from the inflator.

5 is an enlarged plan view of the main portion extracting the tether sewing structure of the airbag cushion according to an embodiment of the present invention, a tether 26 connecting the cushion front portion 24a and the cushion rear portion 24b of the airbag cushion 24. The outer sewing line 28 of the sewing unit 27 is made of a rectangular shape. At this time, the outer seam 28 of the outer seam shape is formed to have a round at both ends in the direction perpendicular to the length of the tether 26. In addition, the inner sewing line 29 positioned inside the outer sewing line 28 has a shape in which two inequalities (<) cross each other. That is, the sewing lines 128 and 129 may be prevented from approaching side by side to maximize the distance between the sewing needle holes 28a and 29a.

According to the present invention configured as described above, first, the tether 26 supports the cushion front portion 24a and the cushion rear portion 24b in a predetermined shape and a predetermined width when the airbag cushion 24 is deployed. At this time, the tensile force acting on the tether 26 between the cushion front portion 24a and the cushion rear portion 24b by the expansion force of the nitrogen gas is more uniformly distributed along the arc of the sewing line 28 outside the sewing portion 27. It acts, and the durability fall of the sewing part 27 can be suppressed. In particular, the inner sewing line 29 and the outer sewing line 28 is spaced apart to the maximum to remove the adjacent portion, so that the sewing needle holes (28a, 29a) of each sewing line 128, 129 at the time of deployment of the airbag cushion 124 It is possible to improve the vulnerability due to compaction.

As described above, the present invention is to make the outer sewing line of the sewing portion of the tether attached to the cushion front portion and the cushion rear portion of the airbag cushion, and the inner sewing line to the shape where the two inequalities cross each other. The gap between the inner sewing line and the outer sewing line is maximized to overcome the fragility of the sewing unit due to the dense sewing needle holes.

Therefore, the present invention prevents damage to the airbag cushion due to rapid inflation force and high heat during deployment by suppressing the tether from being broken at the cushion front part and the cushion rear part when the airbag cushion is deployed. Of course, the safety of the crew can be increased.

Although the present invention has been shown and described in connection with specific embodiments, it is common knowledge in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the appended utility model registration claims. Anyone who has a can easily know.

Claims (1)

The outer sewing line of the sewing portion of the tether connecting the cushion front portion and the cushion rear portion of the airbag cushion is formed in a long shape, and the inner sewing line positioned inside the outer sewing line has a shape in which two inequalities cross each other. Tether sewing structure of airbag cushion.