Patent Description:
A safety airbag device is commonly used in a vehicle to protect an occupant in the vehicle from injury in an emergency situation. The safety airbag device includes a safety airbag and a gas generator. The safety airbag is generally in a stowed state, and is inflated only when the vehicle encounters a collision or impact. When the vehicle encounters a collision or impact, gas generated by means of blasting performed by the gas generator rapidly inflates the safety airbag in the stowed state, and the inflated safety airbag expands to provide protection for the occupant of the vehicle. However, since the gas generator needs to generate a large amount of gas in a very short time, an airbag of the safety airbag device is subjected to a large impact, and this may cause the airbag to be torn. In addition, when blasting occurs, some metal material components (for example, an aluminum foil or a copper foil located at a gas outlet of the gas generator) in the gas generator are melted due to high temperature. Therefore, the gas generated by the gas generator carries high-temperature metal particles, and collision of the high-temperature metal particles with the airbag results in formation of melt holes on the airbag. <CIT> and <CIT> propose a safety airbag device corresponding to the preamble of claim <NUM>.

Therefore, a highly reliable safety airbag device is desired.

The objective of the present invention is to provide a highly reliable safety airbag device. In order to achieve the above objective, the present invention provides a safety airbag device, comprising:.

According to an embodiment of the present invention, the first gas inlet, the first gas outlet, the second gas inlet, and the second gas outlet are configured so that the gas generated by the gas generator enters the first cavity by means of the first gas inlet in a first direction, exits the first cavity by means of the first gas outlet, enters the second cavity by means of the second gas inlet in a second direction, exits the second cavity by means of the second gas outlet in a third direction, and then enters the safety airbag, wherein the first direction is different from the second direction, and the second direction is different from the third direction.

According to an embodiment of the present invention, the first cavity and the second cavity are configured to be an upper and lower two-piece structure.

According to an embodiment of the present invention, the first gas inlet is arranged at a joint between a first upper member and a first lower member of the first cavity, the first gas outlet is arranged on the first lower member, the second gas inlet is arranged on a second upper member of the second cavity, and the second gas outlet is arranged at a joint between the second upper member and the second lower member of the second cavity.

According to an embodiment of the present invention, the first lower member of the first cavity and the second upper member of the second cavity are configured to have a common portion, and the first gas outlet and the second gas inlet are configured to be located on the common portion to serve as a common opening.

According to an embodiment of the present invention, the first upper member, the first lower member, the second upper member, and the second lower member are configured to be from different sections of the same piece of material.

According to an embodiment of the present invention, a size of the second gas outlet is configured to be greater than a size of the second gas inlet.

According to the present invention, a volume of the first cavity in the inflated state is designed to be greater than a volume of the second cavity in the inflated state.

Specific implementation manners of the safety airbag device according to the present invention will be described below with reference to the accompanying drawings. The following detailed description and accompanying drawings serve to exemplarily illustrate the principles of the present invention. The present invention is not limited to the described preferred embodiments, and the scope of protection of the present invention is defined by the claims.

In addition, spatially relative terms (such as "upper," "lower," "left," "right," etc.) are used to describe a relative positional relationship between one element and another element shown in the accompanying drawings. Therefore, spatially relative terms may be applied to directions different from the directions shown in the accompanying drawings when used. Obviously, although all of these spatially relative terms refer to the directions shown in the accompanying drawings for ease of description, those skilled in the art could understand that directions different from the directions shown in the accompanying drawings may be used.

<FIG> is a schematic perspective view of the safety airbag device according to an embodiment of the present invention. The safety airbag device according to the embodiment of the present invention is described below with reference to <FIG>.

As shown in <FIG>, a safety airbag device <NUM> includes a safety airbag <NUM> and a gas generator (not shown). The safety airbag <NUM> has an inflated state and a stowed state. In addition, the safety airbag <NUM> shown in <FIG> is in the inflated state. The gas generator is used to generate gas to inflate the safety airbag <NUM> so that the safety airbag <NUM> enters the inflated state.

In addition, as shown in <FIG>, the safety airbag device <NUM> further includes a deflector <NUM>. The deflector <NUM> is used to guide the gas generated by the gas generator before the gas generated by the gas generator enters the safety airbag <NUM>. Next, the deflector <NUM> is described in detail.

<FIG> is a schematic perspective view of the safety airbag device according to an embodiment of the present invention. The deflector in the safety airbag device according to the embodiment of the present invention is described below with reference to <FIG>.

As shown in <FIG>, the deflector <NUM> includes a first cavity <NUM> and a second cavity <NUM>. The first cavity <NUM> includes a first gas inlet 101A and a first gas outlet 101B. The second cavity <NUM> includes a second gas inlet 102A and a second gas outlet 102B. It can be seen from <FIG> that the first gas outlet 101B and the second gas inlet 102A are configured to be a common opening. Hence, as shown in <FIG>, the gas generated by the gas generator enters the first cavity <NUM> by means of the first gas inlet 101A, exits the first cavity <NUM> by means of the first gas outlet 101B, then enters the second cavity <NUM> by means of the second gas inlet 102A, exits the second cavity <NUM> by means of the second gas outlet 102B, and then enters the safety airbag <NUM>.

Continuing to refer to <FIG>, in the safety airbag device <NUM> according to the embodiment of the present invention, the first gas inlet 101A, the first gas outlet 101B, the second gas inlet 102A, and the second gas outlet 102B are configured so that the gas generated by the gas generator enters the first cavity <NUM> by means of the first gas inlet 101A in a first direction, exits the first cavity <NUM> by means of the first gas outlet 101B, enters the second cavity <NUM> by means of the second gas inlet 102A in a second direction, exits the second cavity <NUM> by means of the second gas outlet 102B in a third direction, and then enters the safety airbag <NUM>. The first direction is different from the second direction, and the second direction is different from the third direction. In <FIG>, three arrows are respectively used to represent the aforementioned first direction, second direction, and third direction. It can be seen from <FIG> that the gas generated by the gas generator enters the first cavity <NUM> by means of the first gas inlet 101A in a horizontal direction, exits the first cavity <NUM> by means of the first gas outlet 101B, enters the second cavity <NUM> by means of the second gas inlet 102A in a downward-left direction, exits the second cavity <NUM> by means of the second gas outlet 102B in a downward-right direction, and then enters the safety airbag <NUM>. Therefore, in <FIG>, the deflector <NUM> changes a flow direction of the gas generated by the gas generator from the horizontal direction to the downward-right direction, so that the gas generated by the gas generator enters the safety airbag <NUM> in the downward-right direction, thereby preventing an airflow from directly striking the safety airbag and causing the safety airbag to tear.

Continuing to refer to <FIG>, the first cavity <NUM> and the second cavity <NUM> are configured to be an upper and lower two-piece structure. It should be noted that in the safety airbag device according to the present invention, the upper and lower two-piece structure of the deflector should be understood in a broad sense. That is, the deflector has a two-piece structure. In addition, the upper and lower two-piece structure is named in the case of a certain specific placement orientation, but the name actually includes all placement orientations different from the certain specific placement orientation. Therefore, no limitation is set to the orientation, and this naming convention is used merely for ease of description. For example, a left-right two-piece structure and a front-rear two-piece structure are both included in the two-piece structure of the deflector in the safety airbag device according to the present invention. The deflector body <NUM> is specifically described below. The first cavity <NUM> includes a first lower member <NUM> and a first upper member <NUM>. The second cavity <NUM> includes a second upper member <NUM> and a second lower member <NUM>. It should be noted that a first portion 1011A of the first lower member <NUM> of the first cavity <NUM> serves merely as the first lower member of the first cavity <NUM>, but a second portion 1011B of the first lower member <NUM> of the first cavity <NUM> not only serves as the first lower member <NUM> of the first cavity <NUM> but also serves as the second upper member <NUM> of the second cavity <NUM>. In other words, the first lower member <NUM> of the first cavity <NUM> and the second upper member <NUM> of the second cavity <NUM> are configured to have the common portion 1011B, and the first gas outlet and the second gas inlet are configured to be located on the common portion and serve as a common opening. In addition, the first gas inlet 101A is arranged at a joint between the first upper member and the first lower member of the first cavity <NUM>. The joint is on a left side of the first cavity <NUM> in <FIG>. Moreover, the second gas outlet 102B is arranged at a joint between the second upper member and the second lower member of the second cavity <NUM>. The joint is on a right side of the second cavity <NUM> in <FIG>.

Therefore, in the safety airbag device according to the present invention, in addition to, as described above, changing the flow direction of the gas generated by the gas generator and preventing the airflow from directly striking the safety airbag and causing the safety airbag to tear, respective wall surfaces in the first cavity and the second cavity of the deflector contact the gas generated by the gas generator, such that high-temperature metal particles generated by the generator are captured on the wall surfaces by means of contacting. Since the gas generated by the gas generator firstly passes through the large first cavity and then passes through the small second cavity, in the second cavity, the wall surface of the cavity more fully contacts the gas, thus a capturing effect on the wall surface of the second cavity is better. In this way, improvements are made to the scenario in which the high-temperature metal particles strike the safety airbag and therefore result in the formation of melt holes in the safety airbag. Therefore, the safety airbag device according to the present invention is highly reliable.

<FIG> is a schematic unfolded view of the deflector in the safety airbag device according to an embodiment of the present invention. An unfolded structure of the deflector in the safety airbag device according to the embodiment of the present invention will be described below with reference to <FIG>.

As shown in <FIG>, in the deflector <NUM>, the first upper member <NUM> and the first lower member <NUM> of the first cavity <NUM> and the second upper member <NUM> and the second lower member <NUM> of the second cavity <NUM> are configured to be from different sections of the same piece of material. Specifically, section ABKL serves as a common portion, and is used as the second upper member <NUM> of the second cavity <NUM> and the portion 1011B of the first lower member <NUM> of the first cavity <NUM>. Section BCDIJK is used as the first upper member <NUM> of the first cavity <NUM>. Section DEHI is used as the portion 1011A of the first lower member <NUM> of the first cavity <NUM>. Section EFGH is used as the second lower member <NUM> of the second cavity <NUM>. The deflector <NUM> may be manufactured by bending section ABKL backwards until point A and point L respectively align with point E and point H, and point B and point K respectively align with point F and point G. Then, respective edges of all sections (AL and EH; AB, BC, and EF; LK, KJ, and HG) are connected to each other by means of stitching, gluing, etc..

As a preferred embodiment of the present invention, a size of the second gas outlet is configured to be greater than a size of the second gas inlet. However, those skilled in the art could understand that the safety airbag device according to the present invention is not limited to the above embodiments, and a size relationship between the second gas outlet and the second gas inlet may be designed differently according to actual requirements.

Although in the above embodiments, the first lower member of the first cavity and the second upper member of the second cavity are configured to have a common portion, the first gas outlet and the second gas inlet are designed to serve as a common opening, and the common opening is arranged on the common portion, those skilled in the art could understand that the safety airbag device according to the present invention is not limited to the above embodiments. The first lower member of the first cavity and the second upper member of the second cavity may be configured to be independent two-piece structures. The first lower member and the first upper member of the first cavity may be configured to be independent two-piece structures. The first gas outlet and the second gas inlet may be designed to be in fluid communication with each other and be respectively located at the first lower member of the first cavity and the second upper member of the second cavity.

Claim 1:
A safety airbag device (<NUM>), comprising:
a safety airbag (<NUM>), having an inflated state and a stowed state;
a gas generator, used to generate gas to inflate the safety airbag so that the safety airbag (<NUM>) enters the inflated state; and
a deflector (<NUM>), used to guide the gas generated by the gas generator before the gas generated by the gas generator enters the safety airbag (<NUM>),
wherein the deflector (<NUM>) comprises a first cavity (<NUM>) and a second cavity (<NUM>), the first cavity (<NUM>) comprises a first gas inlet (101A) and a first gas outlet (101B), the second cavity (<NUM>) comprises a second gas inlet (102A) and a second gas outlet (102B), the first gas outlet (101B) and the second gas inlet (102A) are in fluid communication with each other, and the gas generated by the gas generator enters the first cavity (<NUM>) by means of the first gas inlet (101A), exits the first cavity (<NUM>) by means of the first gas outlet (101B), then enters the second cavity (<NUM>) by means of the second gas inlet (102A) in fluid communication with the first gas outlet (101B), exits the second cavity (<NUM>) by means of the second gas outlet (102A), and then enters the safety airbag (<NUM>),
characterised in that a volume of the first cavity (<NUM>) in the inflated state is designed to be greater than a volume of the second cavity (<NUM>) in the inflated state.