KR20120019738A - Linkage structure of a-filla - Google Patents

Abstract

PURPOSE: A pillar connection structure is provided to reduce deformation of a vehicle body by minimizing moment because members of the pillar connection structure can be directly connected to smoothly deliver load. CONSTITUTION: A pillar connection structure comprises an pillar upper joint node(100) and a pillar lower joint node(500). The pillar upper joint node is located in a cowl member. The upper part of the pillar upper joint node is connected to one end of a pillar upper member and the lower part of thereof is connected to the upper part of a pillar lower member. The side of the pillar upper joint node is connected to a front upper member. The upper part of the pillar lower joint node is connected to the lower part of the pillar lower member. A side sill(600) is connected to one side of the pillar lower joint node. The other side of the pillar lower joint node is connected to one end of a front cross member(700).

Description

LINKAGE STRUCTURE OF A-FILLA}

The present invention relates to an A-pillar connecting structure, and more particularly, to an A-pillar connecting structure for directly connecting members constituting the A-pillar to form a load transfer structure.

In general, the A-pillar connection structure is composed of members forming the skeleton and panels defining the appearance and the inner tube.

This A-pillar connection structure is determined by how the member cross-sections forming the skeleton and how the members are connected, while limiting the size of the cross-section due to the burden on the vehicle layout and weight, effectively increases the members. There is a need for research on how to connect.

That is, in order to have an ideal member connection structure, the A-pillar connection structure should be a structure that can reduce the deformation of the vehicle body connection part by minimizing the generation of moments when a load is applied through direct connection of members. There was a problem that can not be directly connected between members due to the constraints when manufacturing the vehicle.

Therefore, the parts that cannot be directly connected between members forming the A-pillar connection structure must be connected by separate flanges between members. If this connection is made, excessive connection deformation occurs because load transfer is not performed smoothly, and thus passenger safety There was a problem of lowering.

The present invention has been made to solve the above problems, the object of the present invention is to improve the direct connection of the members of the A-pillar connection structure to facilitate the load transfer to minimize the generation of moments to reduce the deformation of the vehicle body Therefore, it is to provide an A-pillar connection structure that increases the rigidity of the vehicle body, thereby increasing the safety of the passengers.

A-pillar connection structure of the present invention for achieving the above object is provided in the cowl member, the upper end is connected to the end of the A-pillar upper member, the lower end is connected to the upper end of the A-pillar lower member, the side An A-pillar upper joint node to which the front upper member is connected; And an A-pillar lower joint node having an upper end connected to a lower end of the A-pillar lower member, a side seal connected to one side, and a front cross member end connected to the other side.

The A-pillar upper member and the A-pillar lower member are fitted to the A-pillar upper joint node and then joined together by riveting or welding.

The A-pillar lower member is fitted to the A-pillar lower joint node and then joined by riveting or welding.

The A-pillar upper joint node is formed of a closed cross section having a box (□), and a diaphragm is formed therein.

The A-pillar upper joint node is formed with a pipe in the inner center.

The A-pillar lower joint node is formed of a closed cross-section having a box (□), a pipe is formed in the longitudinal direction therein, and a diaphragm is formed between the pipe and the inside of the A-pillar lower joint node.

The present invention, the A-pillar connection structure directly connects the members of the A-pillar by using the A-pillar upper joint node and the A-pillar lower joint node, thereby minimizing the generation of moments when the load is applied, thereby reducing the deformation of the vehicle body, thereby increasing the body rigidity. There is an effect that can increase the safety of the passengers in the event of a vehicle crash.

1 is a perspective view showing an A-pillar connection structure of the present invention.
Figure 2 is a front view showing an A-pillar connection structure of the present invention.
3 is a cross-sectional view taken along the line AA shown in FIG.
4 is a cross-sectional view taken along line BB shown in FIG. 2.
5 is a cross-sectional view taken along line CC shown in FIG. 2.
6 is a sectional view taken along the line DD shown in FIG. 2;
Figure 7 is a perspective view of the A-pillar upper joint node of the present invention.
Figure 8 is a perspective view of the A-pillar lower joint node of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

The A-pillar connection structure of the present invention directly connects the A-pillar upper member 200, the A-pillar lower member 400, and the front upper member 300 through the A-pillar upper joint node 100. By directly connecting the A-pillar lower member 400, the side seal 600, and the front cross member 700 through the pillar lower joint node 500, the load is smoothly transferred to the rear during frontal collision to minimize the occurrence of moment. It is possible to increase the safety by reducing the body deformation.

As shown in FIG. 1 and FIG. 2, the A-pillar connection structure of the present invention has a load transfer of the A-pillar upper member 200, the A-pillar lower member 400, and the front upper member 300. A-pillar lower joint node 100 capable of connecting the A-pillar upper joint node 100 and the A-pillar lower member 400, the side seal 600, and the front cross member 700 to be capable of load transfer. 500.

The A-pillar upper joint node 100 is a cowl member between the A-pillar upper member 200, the A-pillar lower member 400, and the front upper member 300, as shown in FIGS. 3 to 5. It is provided in (10), the three ends are formed on the outside, the upper end is fitted into the A-pillar upper member 200, then joined by riveting or welding (see Fig. 3), the lower end is the A-pillar lower member The upper end of the 400 is coupled and then joined by riveting or welding (see FIG. 4), and the side end is fitted by being joined to the end of the front upper member 300 and then joined by riveting or welding (see FIG. 5).

That is, the A-pillar upper joint node 100 is connected to the three ends of the A-pillar upper member 200, the A-pillar lower member 400, and the front upper member 300, respectively. It is possible to form a member, so that the load transmitted to the front upper member 300 in the frontal collision through the A-pillar upper joint node 100 through the A-pillar upper member 200, the A-pillar lower member 400 And the cowl member 10, respectively, to reduce the impact force.

Meanwhile, as illustrated in FIG. 7, the A-pillar upper joint node 100 is formed in a closed cross-section having a box shape (□), and there is formed a diaphragm 110 in a honeycomb shape, and the diaphragm 110 is formed therein. ) Increases the rigidity of the A-pillar upper joint node 100.

On the other hand, the A-pillar upper joint node 100 has a circular pipe 120 is formed in the inner center of the closed cross-section, the rigidity of the torsion of the A-pillar upper joint node 100 through the pipe 120 Increase

Therefore, the A-pillar upper joint node 100 increases the connectivity between the A-pillar upper member 200, the A-pillar lower member 400, and the front upper member 300 and the cowl member 10 to face the front collision. The load input at the time can be transmitted smoothly to the rear.

The A-pillar lower joint node 500 is provided between the A-pillar lower member 400, the side seal 600, and the front cross member 700, and the A-pillar lower joint node 200 is the A-pillar lower joint node 200. The lower member 400, the side chamber 600, and the front cross member 700 are connected to each other.

That is, the A-pillar lower joint node 500 is formed in a 'ㅗ' shape, three ends are formed, the upper end is fitted to the lower end of the A-pillar lower member 400 is coupled and then riveted or welded And then, one side is fitted into the side seal 600, and then joined by riveting or welding (see Fig. 6), the other side is connected to the front cross member 700 end.

On the other hand, the A-pillar lower joint node 500, as shown in Figure 8, is formed in a closed cross-section of the box (□), the inside of the pipe 510 is formed from one end to the other end, A honeycomb diaphragm 520 is formed between the pipe 510 and the inside of the A-pillar lower joint node 500 so as to divide the cross section vertically and horizontally.

That is, the A-pillar lower joint node 500 may increase the torsional and support rigidity by the pipe 510 and the diaphragm 520 formed therein.

Therefore, the A-pillar lower joint node 500 effectively reduces the load by separately transferring the load transmitted through the front cross member 700 to the A-pillar lower member 400 and the side seal 600 during a frontal collision. You can.

As described above, the A-pillar upper joint node 100 and the A-pillar lower joint node 500 may include the A-pillar upper member 200, the A-pillar lower member 400, and the front upper member 300. A load transmission structure including the cowl member 10, the A-pillar lower member 400, the side seal 600, and the front cross member 700 may be formed.

Meanwhile, a reinforcement member 800 is provided between the front upper member 300 and the A-pillar lower member 400 to increase the rigidity of the front upper chamber 300 and the A-pillar lower member 400. One end of the member 800 is connected to the side of the front upper chamber 300, and the other end is connected to the side of the A-pillar lower member 400.

That is, through the reinforcement member 800 when the front collision of the front upper member 300 reduces the amount of sliding, thereby minimizing the deformation between the members to increase the safety.

100: A-pillar upper joint node
200: A-pillar upper member
300: front upper member
400: A-pillar lower member
500: A-pillar lower joint node
600: side seal
700: front cross member
800: reinforcement member

Claims (6)

An A-pillar upper joint node provided at the cowl member, an upper end of which is connected to an end of an A-pillar upper member, a lower end of which is connected to an upper end of an A-pillar lower member, and a side end of which is connected to a front upper member; And
An A-pillar connection structure comprising an A-pillar lower joint node connected to a lower end of the A-pillar lower member, a side seal connected to one side, and a front cross member end connected to the other end. The method according to claim 1,
And the a-pillar upper member and the a-pillar lower member are fitted to the a-pillar upper joint node, and then joined together by riveting or welding. The method according to claim 1,
The A-pillar lower member is coupled to the A-pillar lower joint node, and then joined by riveting or welding. The method according to claim 1,
The A-pillar upper joint node is made of a closed cross-section of the box (□), the inside of the A-pillar connection structure is formed a diaphragm. The method of claim 4,
The A-pillar upper joint node is an A-pillar connection structure in which a pipe is formed in the inner center. The method according to claim 1,
The A-pillar lower joint node is formed of a closed cross-section (□), a pipe is formed in the longitudinal direction therein, and an A-pillar connection structure in which a diaphragm is formed between the pipe and the inside of the A-pillar lower joint node. .

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