JP3304674B2 - Pillar connection structure of vehicle body - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle body pillar connecting structure.

[0002]

2. Description of the Related Art In general, a vehicle body comprises an upper structure having a roof, pillars and the like, and a lower structure having side members and side sills. The pillars of the upper structure are connected to the side sills of the lower structure.

As a conventional structure for connecting a pillar to a side sill, for example, there is a structure as shown in FIG. 13 (see Japanese Patent Application Laid-Open No. 6-504033). The side sill 1 is a member having a closed cross section disposed in the front-rear direction of the vehicle body.
e is provided with a mounting port 2. The pillar 3 is a member having a closed cross section arranged in the vertical direction, and the lower portion thereof is the mounting port 2.
From the lower end of the pillar 3 and the bottom surface of the side sill 1, and the side surface of the pillar 3 and the mounting opening 2
Are connected by seam welding Y.

[0004]

However, in such a conventional technique, the pillar 3 is inserted from the mounting opening 2 of the side sill 1 and seam welding is performed. The weld of the side sill 1 may be thermally deformed by the influence of heat. Especially recently,
In order to reduce the weight of the vehicle body, there has been proposed a structure in which the vehicle body is formed of a light alloy extruded material. However, when such an extruded material is welded, distortion due to heat shrinkage is particularly remarkable. Once the distortion occurs, a great deal of man-hours need to be spent to correct the distortion, which is very disadvantageous in terms of workability.

The present invention focuses on such a conventional technique. Even if the present invention is applied to a vehicle body made of extruded material, no distortion due to welding heat occurs, and the pillar can be securely connected to the side sill. It is intended to provide a pillar connection structure of a vehicle body.

[0006]

According to the first aspect of the present invention,
In a pillar coupling structure for a vehicle body in which a lower end of a pillar formed of an extruded material having a closed cross section is coupled to an upper surface portion of a side sill formed of an extruded material having a closed cross section, a lower end of a front portion and a lower portion of a rear surface portion of the pillar are formed of a side sill. A part to which the lower end of the pillar is welded at least while the lower end of the pillar is welded to the upper surface part while the flange formed at the lower end of the inner surface part and the outer surface part of the pillar is engaged with the groove formed at the upper part of the side sill in a vertically immovable state. The upper surface of the side sill is connected to the lower surface facing the upper surface by a rib.

According to a second aspect of the present invention, the front and rear surfaces of the pillar are made thicker than the inner and outer surfaces.

According to a third aspect of the present invention, there is provided a vehicle body pillar coupling structure in which a lower portion of a pillar formed of an extruded material having a closed cross section is inserted into an interior through a mounting opening formed in an upper surface of a side sill and coupled. The sill inner of the side sill is formed of an extruded material having a closed cross section, and the front and rear ends of the inner surface of the pillar are welded to the outer surface of the sill inner along the vertical direction, and at least the outer surface of the sill inner to which the inner surface of the pillar is welded. And an inner surface portion facing the outer surface portion connected by a rib.

According to a fourth aspect of the present invention, there is provided a pillar connecting structure for a vehicle body, wherein a lower portion of a pillar formed of an extruded material having a closed cross section is inserted into an inner portion of a mounting hole formed in an upper portion of a side sill. The sill inner of the side sill is formed of an extruded material having a closed cross section, an opening having a front-rear width corresponding to a pillar is formed on an outer surface of the sill inner, and a front part and a rear part corresponding to the front and rear edges of the opening are formed in the opening. The brace is inserted, and the front and rear ends of the inner surface of the pillar are welded to the front and rear edges of the opening and the front and rear surfaces of the brace, respectively.

[0010]

According to the first aspect of the present invention, since the upper surface and the lower surface of the side sill are connected by the rib, the side sill becomes a large heat capacity portion that easily dissipates welding heat. Therefore, heat when the lower end of the pillar is welded to the upper surface of the side sill is transmitted from the upper surface to the ribs and the like and is radiated to the entire side sill. Even if welding heat accumulates and the pillar attempts to shrink the shaft, the flange at the lower end of the pillar is engaged with the groove in the upper surface of the side sill, so that the shaft shrinkage is prevented. Further, even if the upper surface of the side sill attempts to be deformed downward due to the influence of welding heat, the deformation of the upper surface is prevented because the rib is formed below the upper surface. Furthermore, the rigidity of the pillar in the front-back inclination direction is improved by increasing the rigidity of the upper surface of the side sill, which is the root of the pillar by forming the rib, and the coupling rigidity in the inside / outside inclination direction is the engagement between the flange and the groove. To improve.

According to the second aspect of the present invention, since the front and rear surfaces of the pillar are made thicker than the inner and outer surfaces, the pillar itself becomes a large heat capacity portion and heat is easily radiated to the pillar. .

According to the third aspect of the present invention, since the sill inner of the side sill is a large heat capacity portion having a rib added to the closed cross section, and the pillar is welded to the outer surface of the sill inner, the welding heat is reduced by the rib. And the like, is scattered throughout the side sill, and hardly causes welding distortion. In addition, the pillar is welded to the outer surface of the sill inner, and the input applied to the pillar can be transmitted as an in-plane force of the outer surface, so that the coupling strength in the forward and backward inclination directions is high, and the coupling rigidity in the inside and outside inclination directions is a rib. As a result, the rigidity of the outer surface of the sill inner is increased, thereby improving the performance.

According to the fourth aspect of the present invention, since the front and rear ends of the inner surface of the pillar are welded to the front and rear edges of the opening and the front and rear surfaces of the brace, welding heat is applied to the front and rear surfaces of the brace. Easily diverges from the entire brace, and hardly causes welding distortion. In other words, since the brace itself is a large heat capacity part, the sill inner becomes a large heat capacity part only by providing a brace inside, even with a mere closed cross-section sill inner where no rib is formed. Further, if the brace is provided inside the sill inner on which the rib is formed, the sill inner becomes a larger heat capacity portion, and the divergence of welding heat is further enhanced.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the drawings. In the following description, A in the figure indicates the front side, B
Is described on the rear side, C is outside, and D is inside.

FIGS. 1 to 3 show a first embodiment of the present invention. The vehicle body of this embodiment comprises an upper structure 4 and a lower structure 5, each of which is formed mainly of an extruded material made of an aluminum light alloy (see FIG. 1). Upper structure 4
Has a structure in which various panels and glass can be attached, but is not shown. Strut housings 6a, 6 which receive suspension input before and after the upper structure 4
b is provided. And 7 is the front pillar, 8
Is a center pillar, and 9 is a rear pillar. Lower structure 5
In FIG. 1, a front side member 10 is provided in the front, a floor side member 11 extending from the vehicle compartment to the rear portion is disposed in the rear, and side sills 12 are disposed on both left and right sides of the vehicle compartment. The lower structure 5 includes a plurality of cross members 1.
3, 14, 15, 16, 17 and the like are also provided. The pillars 7, 8, 9 are connected to the side sill 12 of the lower structure 5.

Next, the side sill 1 of each of the pillars 7, 8, 9 is used.
2 will be described using the case of the front pillar 7 as an example (see FIGS. 2 and 3). The front pillar 7 is vertically arranged by a trapezoidal extruded material, and the front part 7a and the rear part 7b are inclined surfaces, and the outer part 7c and the inner part 7d are flat with each other in the front-rear direction. Has become. The lower ends of the front surface portion 7a and the rear surface portion 7b are portions to be welded, and are formed thicker than the outer surface portion 7c and the inner surface portion 7d. A flange 18 is formed on the rear side of the inner surface 7d. Further, flanges 19 and 20 bent in the opening direction are formed at lower ends of the outer surface portion 7c and the inner surface portion 7d, respectively.

The side sill 12 also has a closed cross-sectional structure made of extruded material and is disposed along the front-rear direction. This side sill 12
The upper surface 12e of the front pillar 7 has a flange 1
Grooves 21 and 22 with which 9 and 20 engage are formed along the front-back direction. These grooves 21 and 22 are
In the engaged state, the flanges 19 and 20 can slide in the front-rear direction, but cannot move up and down in the engaged state. The intermediate portion of the upper surface portion 12e and the intermediate portion of the lower surface portion 12f are connected by a rib 23. The rib 23 is formed in parallel with the inner surface portion 12d and the outer surface portion 12c of the side sill 12 and continuously along the front-rear direction (longitudinal direction). Therefore, the upper surface portion 12e and the lower surface portion 12f of the side sill 12 form the inner surface portion 12d and the outer surface portion 1d.
2c and the ribs 23 are connected by three parallel “vertical walls”. An upward flange 24 is formed at a position adjacent to the inner groove 22. Further, an end of the floor panel 25 and an end of the cross member 14 are joined to the inner surface 12d of the side sill 12 (see FIG. 3).

Next, a procedure for connecting the front pillars 7 will be described. First, the flange 19 at the lower end of the front pillar 7,
20 are formed in the grooves 21, 2 of the upper surface 12e of the side sill 12.
2 is inserted from the front side and engaged. Then, after the front pillar 7 is positioned at a predetermined front and rear position, the lower ends of the front surface portion 7a and the rear surface portion 7b of the front pillar 7 are welded and joined to the upper surface portion 12e of the side sill 12. In this connection state, the flange 24 of the upper surface 12 e of the side sill 12 contacts the inner surface 7 d of the front pillar 7. still,
Outfitting components such as kicking plates are attached to portions of the upper surface 12e of the side sill 12 other than the joint of the front pillar 7.

Next, the operation relating to the prevention of thermal distortion and the operation relating to the coupling rigidity will be described.

Thermal distortion prevention:

A part of the welding heat H applied to the welding portion Y between the front pillar 7 and the side sill 12 is firstly radiated above the front pillar 7 via the front portion 7a and the rear portion 7b of the front pillar 7. . Since the front part 7a and the rear part 7b of the front pillar 7 are formed to be thick and have a large heat capacity part, the diffusion of the welding heat H to the front pillar 7 is performed reliably and sufficiently.

The welding heat H is also dissipated to the side sill 12 side. The side sill 12 of this embodiment includes an upper surface 1
Since the rib 23 connecting the lower surface portion 2f and 2e is formed, it is a large heat capacity portion that easily dissipates the welding heat H as compared with a simple closed-section structure without the rib 23.
Therefore, the welding heat H applied to the upper surface portion 12e of the side sill 12 is transmitted through the three vertical walls of the inner surface portion 12d, the outer surface portion 12c, and the ribs 23, and is radiated to the entire side sill 12. The front pillar 7 and the side sill 12 are hardly distorted.

Even if welding heat accumulates in the vicinity of the welded portion Y and the front pillar 7 attempts to contract axially, the flanges 19 and 20 at the lower end of the front pillar 7 are engaged with the grooves 21 and 22 of the side sill 12. Therefore, axial contraction of the front pillar 7 is prevented. Further, even if the upper surface 12e of the side sill 12 is deformed downward due to the influence of the welding heat H, it is prevented by the ribs 23 formed below the upper surface 12e.

Bonding rigidity:

The front pillar 7 is attached to the front pillar 7.
Moment M like tilting forward and backward ₁Is added,
Its moment M₁Is on the side sill 12 from the weld Y
Acts intensively on the surface portion 12e, but the upper surface portion 12e is
The rib 23 as a vertical wall along the rear direction is
Connected to prevent deformation of the upper surface portion 12e.
The front pillar 7 may fall down
And the joint rigidity in the front-back tilt direction is high.

When a moment M ₂ is applied to the front pillar 7 such that the front pillar 7 is tilted inward or outward, the moment M ₂ concentrates on the flanges 19 and 20 at the lower end of the front pillar 7. Flange 19,
20 is engaged in the grooves 21 and 22 of the side sill 12 and cannot move up and down, so that the front pillar 7 does not fall inward and outward, and the coupling rigidity in the direction of falling inside and outside falls. high. In particular, two grooves 2
1 and 22 are formed near the inner surface 12d and the outer surface 12c of the side sill 12, respectively, so that the force applied to the grooves 21 and 22 is immediately transmitted to the inner surface 12d and the outer surface 12c. This also contributes to the improvement of the coupling rigidity of the front pillar 7 in the inward and outward falling directions. Further, the fact that the upward flange 24 formed on the upper surface 21 e of the side sill 21 is in contact with the inner surface 7 d of the front pillar 7 also contributes to preventing the front pillar 7 from falling down.

FIGS. 4 and 5 show a second embodiment of the present invention. The side sill 26 of this embodiment is a sill outer 27 made of a press-formed steel plate (a resin molded product is also acceptable).
And a sill inner 28 formed of an extruded material having a closed cross section are joined to form an integrated structure. This sil outer 27
The sill inner 28 is joined to the sill inner 28 by rivet means (not shown) (bolt means, adhesive means, welding means may be used).
Further, the front pillar 29 has a front part 2 having an even cross-sectional thickness.
9a, a rear surface 29b, an outer surface 29c, and an inner surface 29d, and the front surface 29a and the rear surface 29b as in the previous embodiment.
Only the thickness is not formed.

In the upper surface of the sill outer 27, a portion which is joined to the sill inner 28 and serves as an attachment port 30 is recessed. Flanges 31 are formed above and below the outer surface 28c of the sill inner 28 so as to be continuous with the outer surface 28c. Also, the outer surface portion 28c of the sill inner 28
The central portions of the inner surface 28d and the inner surface 28d are connected by a horizontal rib 32. Further, a horizontal flange 33 connected to the rib 32 is formed in a central portion of the inner surface portion 28d so as to protrude inward. And this horizontal flange 33
The end of the floor panel 25 is connected to the
The end of the cross member 14 is connected to the lower surface 28f.

The lower part of the front pillar 29 is the mounting opening 3
The front pillar 29 is inserted into the side sill 26 from the front and the front and rear ends of the inner surface 29d of the front pillar 29 are welded to the outer surface 28c of the sill inner 28 in the vertical direction.

Next, the operation relating to the prevention of thermal distortion and the operation relating to the coupling rigidity will be described.

Heat distortion prevention:

Part of the welding heat H applied to the welding portion Y is
As in the previous embodiment, the light is transmitted through the front pillar 29 and diverged upward.

The welding heat H is also diverted to the side sill 26 side. Sill inner 2 of side sill 26 of this embodiment
8 is a rib 32 connecting the outer surface portion 28c and the inner surface portion 28d.
Is formed, the large heat capacity portion easily dissipates the welding heat H as compared with a simple closed-section structure without the rib 32. Therefore, the outer surface portion 28c of the sill inner 28
Is transmitted to the three inner walls of the upper surface portion 28e, the lower surface portion 28f, and the rib 32, and
8 is diverged to the floor panel 25 and the cross member 14, so that the front pillar 29 and the sill inner 28 in the vicinity of the welded portion Y are not easily distorted.

Even if welding heat accumulates in the vicinity of the welded portion Y and the outer surface portion 28c of the sill inner 28 is likely to be distorted, the distortion force is generated by the three sheets of the upper surface portion 28e, the rib 32, and the lower surface portion 28f of the sill inner 28. Of the floor panel 2d from the inner surface 28d through the inner surface 28d.
5 and the cross members 14, the occurrence of distortion is suppressed.

Coupling rigidity:

The front pillar 2 is attached to the front pillar 29.
If 9 moment M ₁ as tilted in the front-rear direction applied, sill inner 28 from the moment M ₁ is welded portion Y
Is transmitted as an in-plane force to the outer surface portion 28c, the front pillar 29 does not fall in the front-rear direction, and the coupling rigidity in the front-rear inclination direction increases. Further, even if the out-of-plane deformation due to the moment M ₁ is about to fail, the ribs 3
2, the deformation can be suppressed.

FIG. 6 is a diagram showing a third embodiment of the present invention. In the side sill 34 of this embodiment, a sill inner 35
The shape of the inner rib 36 is V-shaped in the horizontal direction. By making the shape of the rib 36 in this manner, the divergence of welding heat and the joint rigidity are improved as compared with the horizontal rib 32 of the second embodiment.

FIG. 7 is a diagram showing a fourth embodiment of the present invention. In the side sill 37 of this embodiment, a sill inner 38
The shape of the rib 39 inside is X-shaped in cross section. With such a shape of the rib 39, the divergence of welding heat and the joint rigidity are further improved as compared with the V-shaped rib 36 of the third embodiment.

FIG. 8 is a diagram showing a fifth embodiment of the present invention. The sill inner 41 of the side sill 40 of this embodiment is:
The inner surface 41d of the sill inner 41 has a shape in which a horizontal rib 42 is added to a closed section of a modified pentagon set lower than the outer surface 41c. According to this embodiment, since the upper surface portion 41e of the sill inner 41 has a slope, the space in the vehicle interior can be increased accordingly.

FIGS. 9 to 11 show a sixth embodiment of the present invention. The sill inner 44 of the side sill 43 according to this embodiment has a mere closed cross section, and has no rib inside. The outer surface 44c of the sill inner 44
An opening 45 is formed in a portion corresponding to the front pillar 29 of FIG. The opening 45 has a front-rear width corresponding to the width of the inner surface 29d of the front pillar 29, and has a vertical width from the upper surface 44e to the lower surface 44f of the sill inner 44.

In the opening 45, a brace 46 is provided.
Is inserted. The brace 46 has an inner surface portion 45 d and an outer surface portion 45 c having shapes substantially corresponding to the opening 45, and a front surface portion 45 a and a rear surface portion 45 b having widths substantially corresponding to the sill inner 44.
And a closed section member comprising: By inserting the brace 46 from the opening 45 into the sill inner 44, the inner surface 46 d of the brace 46 becomes the inner surface 44 of the sill inner 44.
d, and the outer surface portion 46c of the brace 46 becomes flush with the outer surface portion 44c of the sill inner 44. And
The front and rear ends of the inner surface 29d of the front pillar 29 are
5 and the front and rear portions 46a and 46b of the brace 46, and the corresponding portions are welded along the vertical direction. To combine. Also, the brace 4 on the inner surface portion 44d of the sill inner 44 is formed.
6, a slit 46 is formed at a portion corresponding to the front surface portion 46a and the rear surface portion 46b.
6, the inner surface portion 44 of the sill inner 44
d and front part 46a of brace 46 (and rear part 46b)
Are welded.

According to this embodiment, the front surface 46a and the rear surface 46b of the brace 46 housed in the opening 45 are
Since the front and rear ends of the inner surface portion 29d of the front pillar 29, which is the welded portion Y, match, the heat is transferred to the front portion 4 of the brace 46.
6a and the rear surface portion 46b are easily diverged from the entire brace 46, and welding distortion hardly occurs. As described above, even with the sill inner 44 having a simple closed section in which no “rib” is formed, the sill inner 44 becomes a large heat capacity portion by providing such a brace 46 inside.

FIG. 12 is a view showing a seventh embodiment of the present invention. Sill inner 49 of the side sill according to this embodiment
Has a structure having an X-shaped rib 50 inside similarly to the fourth embodiment, and an opening 51 similar to the previous embodiment is formed in the outer surface portion 49c of the sill inner 49. And
In the opening 51, a three-dimensional brace 52 corresponding to an internal space having a triangular cross section facing the opening 51 is inserted. The brace 52 has a closed container shape having a space inside, and the front part 52a and the rear part 52b have front and rear ends of the opening 51 and the front and rear ends of the inner part 29d of the front pillar 29, similarly to the sixth embodiment. It is designed to be welded to the end.

Therefore, also in this embodiment, the welding heat is easily radiated from the front surface 52a and the rear surface 52b of the brace 52 to the entire brace 52, and welding distortion hardly occurs. The sill inner 49 of this embodiment has an X-shaped rib 5 inside.
0 is provided, and since the welding heat is also radiated to the entire sill inner 49 via the rib 50, the heat radiating property is particularly excellent.

In each of the above embodiments, the front pillar 7,
Although the example in which 29 is connected to the side sills 12, 26,... Is shown, other center pillars 8 and rear pillars 9 are also connected in the same structure.

In the above description of each embodiment, the ribs 23 formed in the side sill 12 and the ribs 23 formed in the sill inner 28 and the like are continuously arranged in the front-rear direction (longitudinal direction). Although the ribs are formed, it is only necessary that the “ribs” be formed at least at portions where the “pillars” are welded.

[0047]

According to the first aspect of the present invention, since the upper surface and the lower surface of the side sill are connected by the rib, the side sill becomes a large heat capacity portion that easily dissipates welding heat. Therefore, the heat when welding the lower end of the pillar to the upper surface of the side sill is
Since the ribs and the like are transmitted from the upper surface and are scattered to the entire side sill, welding distortion is less likely to occur near the welded portion. By any chance
Even if welding heat accumulates and the pillar attempts to shrink the shaft, the shaft shrinkage is prevented because the flange at the lower end of the pillar is engaged with the groove on the upper surface of the side sill. Also, even if the upper surface of the side sill tries to be deformed downward due to the effect of welding heat,
Since the rib is formed below the upper surface, deformation of the upper surface is prevented. Furthermore, the rigidity of the pillar in the front-back inclination direction is improved by increasing the rigidity of the upper surface of the side sill, which is the root of the pillar by forming the rib, and the coupling rigidity in the inside / outside inclination direction is the engagement between the flange and the groove. To improve.

According to the second aspect of the present invention, since the front and rear portions of the pillar are made thicker than the inner and outer surfaces, the pillar itself becomes a large heat capacity portion and heat is easily radiated to the pillar. .

According to the third aspect of the present invention, since the sill inner of the side sill is a large heat capacity portion having a rib added to the closed cross section, and the pillar is welded to the outer surface of the sill inner, the welding heat is reduced by the rib. And the like, is scattered throughout the side sill, and hardly causes welding distortion. In addition, the pillar is welded to the outer surface of the sill inner, and the input applied to the pillar can be transmitted as an in-plane force of the outer surface, so that the coupling strength in the forward and backward inclination directions is high, and the coupling rigidity in the inside and outside inclination directions is a rib. As a result, the rigidity of the outer surface of the sill inner is increased, thereby improving the performance.

According to the fourth aspect of the present invention, since the front and rear ends of the inner surface of the pillar are welded to the front and rear edges of the opening and the front and rear surfaces of the brace, welding heat is applied to the front and rear surfaces of the brace. Easily diverges from the entire brace, and hardly causes welding distortion. In other words, since the brace itself is a large heat capacity part, the sill inner becomes a large heat capacity part only by providing a brace inside, even with a mere closed cross-section sill inner where no rib is formed. Further, if the brace is provided inside the sill inner on which the rib is formed, the sill inner becomes a larger heat capacity portion, and the divergence of welding heat is further enhanced.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an overall structure of a vehicle body according to a first embodiment of the present invention.

FIG. 2 is an enlarged exploded perspective view of a DA portion in FIG. 1 showing a state where a front pillar is coupled to a side sill.

FIG. 3 is a cross-sectional view taken along line SA-SA shown in FIG.

FIG. 4 is a perspective view, corresponding to FIG. 2, showing a second embodiment of the present invention.

FIG. 5 is a sectional view taken along line SB-SB shown in FIG. 4;

FIG. 6 is a sectional view, corresponding to FIG. 5, showing a third embodiment of the present invention.

FIG. 7 is a sectional view, corresponding to FIG. 5, showing a fourth embodiment of the present invention.

FIG. 8 is a sectional view, corresponding to FIG. 5, showing a fifth embodiment of the present invention.

FIG. 9 is a perspective view corresponding to FIG. 4, showing a sixth embodiment of the present invention.

10 is a sectional view taken along the line SC-SC shown in FIG. 9;

11 is a sectional view taken along the line SD-SD shown in FIG.

FIG. 12 is a perspective view corresponding to FIG. 9 showing a seventh embodiment of the present invention.

FIG. 13 is a perspective view showing a conventional pillar connection structure of a vehicle body.

[Explanation of symbols]

 7, 29 Front pillar 8 Center pillar 9 Rear pillar 12, 26, 34, 37 Side sill 19, 20 Flange 21, 22 Groove 23 Rib 40, 43 Side sill

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) B62D 25/04 B62D 25/20

Claims (4)

(57) [Claims] 1. A pillar coupling structure of a vehicle body for coupling a lower end of a pillar formed of an extruded material having a closed cross section to an upper surface portion of a side sill formed of an extruded material having a closed cross section, wherein a front portion and a rear portion of the pillar are provided. Is welded to the upper surface of the side sill, and the flanges formed on the lower surfaces of the inner surface and the outer surface of the pillar are engaged with the grooves formed on the upper surface of the side sill in a vertically immovable state. A pillar connection structure for a vehicle body, characterized in that an upper surface of a side sill where a portion is welded and a lower surface facing the upper surface are connected by a rib. 2. The vehicle body pillar coupling structure according to claim 1, wherein the front and rear surfaces of the pillar are thicker than the inner and outer surfaces. 3. A pillar coupling structure for a vehicle body in which a lower portion of a pillar formed of an extruded material having a closed cross section is inserted into an inside of a mounting hole formed in an upper surface portion of a side sill to be connected thereto, wherein a sill inner of the side sill is closed in cross section. And the front and rear ends of the inner surface of the pillar are welded vertically to the outer surface of the sill inner, and at least the outer surface of the sill inner to which the inner surface of the pillar is welded, and the outer surface A pillar connection structure for a vehicle body, wherein an inner surface portion facing the vehicle is connected by a rib. 4. A pillar coupling structure for a vehicle body in which a lower portion of a pillar formed of an extruded material having a closed cross section is inserted into a mounting hole formed in an upper surface portion of a side sill and connected to the inside thereof, wherein the sill inner of the side sill is closed in cross section. An extruded material is formed, and an opening having a front and rear width corresponding to the pillar is formed in the outer surface of the sill inner, and a brace having a front surface and a rear surface matching the front and rear edges of the opening is inserted into the opening, A pillar connection structure for a vehicle body, wherein front and rear ends of an inner surface of the pillar are welded to front and rear edges of the opening and a front and rear surface of a brace, respectively.