JP5952596B2 - Dissimilar panel structure and manufacturing method thereof - Google Patents

Description

  The present invention relates to a dissimilar panel structure used for an automobile body and the like, and a method for manufacturing the same.

  In order to improve the running performance, operability, and fuel consumption of an automobile, it is effective to reduce the weight of the automobile body. For this reason, the application of aluminum alloys to various automobile body parts is progressing. Among these, automobile panel structures such as a hood (bonnet), a door, and a trunk are hollow structures composed of an outer panel (outer plate) and an inner panel (inner plate). These hollow structures include an outer panel press-molded into a predetermined shape such as a flat plate from a plate, an inner wall facing the outer panel, a vertical wall bent toward the outer panel on the outer peripheral side of the inner wall, and the vertical wall. It consists essentially of an inner panel that is press-formed from a plate in a cross-sectional hat shape including a flange that extends around the periphery and faces the outer panel.

  In some cases, both the outer and inner panels are changed from a steel plate to an aluminum alloy plate. However, the outer panel that requires design, light weight, or impact energy absorption is made of aluminum alloy, and the inner panel with a complex shape and deep molding depth is made of steel with excellent formability. In some cases, a different material panel structure (hybrid structure) is formed by combining materials having characteristics according to required characteristics.

  And when it is set as such a dissimilar panel structure of an aluminum alloy outer panel and a steel inner panel, the outer panel peripheral portion is folded back, and an epoxy that serves both as insulation and adhesion for electrolytic corrosion prevention By hem processing (hemming processing, also called helix folding processing) sandwiching the flange peripheral part of the inner panel through a thermosetting resin layer (adhesive layer) such as a resin system, a polyester resin system, a phenol resin system, Integrate.

  However, in such a dissimilar panel structure, the linear expansion coefficient of the aluminum outer panel and the steel inner panel when assembled and painted on an automobile body and then heated during baking at a high temperature of 170 to 200 ° C. Along with the difference, the problem of thermal deformation that warps and deforms easily occurs on the aluminum outer panel side.

  This thermal deformation mechanism is schematically shown in FIG. In the dissimilar panel structure shown on the upper left side of FIG. 11, the upper aluminum outer panel (shown simply as an aluminum plate in the figure) is a lower steel inner panel (shown simply as a steel plate in the figure). Also has a large linear expansion coefficient. For this reason, in the normal temperature state, as the hem processing portion (also referred to as a hem portion or a hemming processing portion) shown on the lower left side of FIG. 11, the outer panel peripheral portion sandwiching the flange peripheral portion of the inner panel at a predetermined position, When the coating is baked (in the figure, simply indicated as heat treatment), as shown in the lower part of the center of FIG. 11, the line expands greatly outward (left side of the figure). As a result, as shown in the lower right side of FIG. 11, the outer panel peripheral edge portion is displaced as a hem-processed portion so as to be displaced from the position sandwiching the inner panel toward the outside of the panel.

  On the other hand, since the adhesive resin applied between the outer panel and the inner panel in the hem processing portion starts thermosetting when the coating is baked, in the hem processing portion shown in the lower right side of FIG. The inner panel becomes more restrictive. For this reason, even if it returns to normal temperature after completion | finish of the said baking coating, the said hem processing part of an outer panel cannot return to the original shape position (state which pinched | interposed the inner panel), and the state where the said hem shift | offset | difference has arisen It becomes. Then, this is a change in the line length of the outer panel, which causes the dissimilar panel structure (outer panel) to warp upward as indicated by an arrow on the upper right side of FIG. As a result, there is a problem that the dissimilar material panel structure (whole or corner portion) is deformed and an automobile panel with high shape accuracy cannot be obtained.

  In order to prevent such a hem shift, after the assembly by hem processing, by performing friction stir welding (FSW) from the edge side of the outer panel the folded flange portion formed by this hem processing, A technique for joining the end edge of the outer panel and the end edge of the inner panel has been proposed (see, for example, Patent Document 1). Specifically, as shown in the front view of the automobile door in FIG. 12, the peripheral part of the door panel is surrounded by two-dot chain lines, the left and right sides, the lower three sides, the lower left and right corners, etc. In addition, friction stir welding is performed.

  However, in order to implement FSW as disclosed in Patent Document 1, it is necessary to reliably restrain the workpiece. However, the folded flange portion formed by hem processing is small as a restraint area for performing FSW, and sufficient joining cannot be performed. In the worst case, the folded flange portion may be broken.

  Further, considering the required strength requirement of the hybrid structure door as described above, the thickness of the steel inner panel is usually thinner than the thickness of the aluminum alloy outer panel. For example, the thickness of the inner panel is about 0.65 to 0.70 mm while the thickness of the outer panel is about 1 to 1.2 mm. As described above, when an aluminum alloy outer panel having a thickness of about 1 mm with poor bending workability is subjected to hemming as disclosed in Patent Document 1 during mass production, excessive strain is applied to the outermost peripheral portion of the folded flange portion. There is also a problem that a crack is caused (that is, hemmability cannot be ensured), resulting in a defective product.

  In order to solve such a problem, a hem joining method for an automobile panel configured by joining an outer panel and an inner panel made of a combination of different materials has also been proposed (for example, see Patent Document 2). In this method, a thermosetting adhesive filled between a steel inner panel and an aluminum alloy outer panel is preliminarily used with a heater or the like, for example, in the hem processing step before painting and baking of the automobile body. Then, the panels are heated and cured, and the panels are restrained (joined) to suppress the hem shift of the aluminum alloy outer panel during coating baking.

JP 2007-185690 A JP 2011-2112712 A

  However, when carrying out the above-mentioned Patent Document 2, there is a large heater for partially heating only the hem-processed portion (thermosetting adhesive) over the periphery of the dissimilar panel structure integrally joined by hem processing. Necessary. Incidentally, if not only the hem-processed portion but also the entire dissimilar panel structure is heated in a heating furnace, it becomes the same as the above-described coating baking process, and the warpage of the outer panel and the deformation of the dissimilar panel structure occur. In addition, the heating operation of the hem-processed portion (thermosetting adhesive) requires a time of 20 to 30 minutes per place for the thermosetting of the adhesive resin as in the above-described coating baking process. For this reason, the efficiency of the panel assembly process such as hem processing is significantly hindered.

  Moreover, in the said patent document 1, the friction stir welding part is intermittently provided in several places and predetermined joining length over the full length of the peripheral part of a dissimilar material panel structure. More specifically, as shown in the embodiment of the door panel of FIG. 3, the bottom of the peripheral portion and the three sides of the two side sides of the dissimilar door panel structure excluding the upper side on which the door glass is mounted. Friction stir welds are provided intermittently at a predetermined joining length at a plurality of locations over the entire length of the sides and two corners (corner portions) of both sides and the bottom. However, in this way, not only the friction stir joint, but also the weld joint, even if it is provided over the entire length of the peripheral edge of the dissimilar panel structure, the panel at the time of painting and baking the automobile body The mutual restraint (joining) cannot always suppress the occurrence of hem shift and warpage of the aluminum alloy outer panel. In other words, there is no guarantee that the panel can be restrained (joined) between the panels that can suppress the occurrence of hem shift and warpage of the aluminum alloy outer panel.

  The object of the present invention is to solve the above-mentioned problems, and when producing a vehicle body using the dissimilar panel structure, the dissimilar panel structure that can suppress the occurrence of hem shift and warpage of the aluminum alloy outer panel. And providing a manufacturing method thereof.

In order to achieve the above object, the gist of the dissimilar panel structure according to the present invention is that an aluminum alloy outer panel formed into a predetermined shape, an inner wall facing the outer panel, and an outer peripheral side of the inner wall bend toward the outer panel. And a steel inner panel formed in a cross-sectional hat shape having a flange extending opposite to the outer panel around the vertical wall, and the outer panel has a hem processing portion. The hem-processed portion is a panel structure in which the peripheral edge of the outer panel is folded in a state where the peripheral edge of the flange of the inner panel is sandwiched via an adhesive resin layer. The shortest distance from each corner to the vertical wall of the inner panel is the center of each side of the panel structure. Wherein only the hemming unit in the corner portion is at least twice that highest among the shortest distance from the vertical wall of the inner panel to the periphery of the panel structure has a welded portion and the welding The hem-processed portion having a portion reaches, in plan view, an intersection with the peripheral portion of the tangent panel structure passing through the point of the vertical wall of the inner panel that is the shortest distance from the tip of the corner portion.

  In order to achieve the above object, the gist of the manufacturing method of the dissimilar panel structure according to the present invention is that an aluminum alloy outer panel formed into a predetermined shape, an inner wall facing the outer panel, and an outer peripheral side of the inner wall Combined with a steel inner panel formed into a cross-sectional hat shape having a vertical wall bent toward the outer panel and a flange extending around the vertical wall so as to face the outer panel. When integrating as a panel structure by hem processing that sandwiches the flange peripheral edge of the inner panel through the adhesive resin layer, of the corner parts of the panel structure, this corner part in plan view The shortest distance from the tip to the vertical wall of the inner panel is the vertical wall of the inner panel at the center of each side of the panel structure. Only the hem-worked part at the corner part that is twice or more the largest of the shortest distances to the peripheral part of the panel structure is welded, and the hem-worked part to be welded is In plan view, it is to reach the intersection with the peripheral part of the panel structure of the tangent line passing through the point of the vertical wall of the inner panel which is the shortest distance from the tip of the corner part.

  According to the present invention, the hem shift and warp of the aluminum alloy outer panel at the time of paint baking of the automobile body can be generated only by welding and joining only the necessary portions of the hem-worked portion of the corner portion of the dissimilar panel structure. Can be suppressed. In other words, the hem shift and warpage of the aluminum alloy outer panel can be caused by extremely practical means such as arc welding or spot welding by laser welding only at the necessary part of the hem processing part at the corner of the dissimilar panel structure. The restraint (joining) force between the panels in the hem processing region that can be suppressed can be ensured.

  As a result, there is an advantage that an automobile panel with high shape accuracy can be obtained without significantly reducing the cost and efficiency of the process such as hem processing of the dissimilar panel structure and without causing deformation of the dissimilar panel structure.

It is a perspective view which shows one aspect | mode of this invention dissimilar panel structure. It is a perspective view which shows the other aspect of this invention dissimilar panel structure. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG. It is an example of analysis of a dissimilar material panel structure explaining the regulation meaning of the present invention. It is explanatory drawing which shows the analysis result of FIG. It is explanatory drawing which shows the analysis result of FIG. It is explanatory drawing which shows the analysis result of FIG. It is explanatory drawing which shows the analysis result of FIG. It is explanatory drawing which shows the analysis result of FIG. It is explanatory drawing which shows the thermal deformation mechanism of a dissimilar material panel structure. It is a side view of the motor vehicle door which shows the thermal deformation prevention technique of the conventional different material panel structure.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

Dissimilar panel structure:
FIG. 1 and FIG. 2 are perspective views each showing an automobile panel having hem processing portions around four sides such as a hood and a trunk, which are automobile body members, as an example of the dissimilar panel structure according to the present invention. As shown in FIGS. 1 and 2, the dissimilar panel structure includes an aluminum alloy outer panel 1 and a steel inner panel 2 as a main body, and these are joined and integrated at the peripheral edge by hem processing. . 1 and 2, the aluminum alloy outer panel 1 is located on the other side (outside of the vehicle body) of each figure, and only the hem-processed peripheral edge 6 is visible. Moreover, the steel inner panel 2 is located on the front side (inner side of the vehicle body) in each figure, and the main body excluding the peripheral portion folded by hem processing is visible.

  1 and 2, the aluminum alloy outer panel 1 has a predetermined shape as a flat outer panel that is curved in an arc shape toward the outside of the vehicle body as shown in the cross-sectional views of FIGS. Is formed by press-molding an aluminum alloy plate described later.

  On the other hand, the steel inner panel 2 is formed by press-molding a material steel plate, which will be described later in detail, into a predetermined shape as an inner panel having a cross-sectional hat shape (the cross-sectional shape is also referred to as a hat type or a HAT type). That is, the inner wall 3 facing the inner side of the vehicle body on the near side of FIGS. 1 and 2 and facing the outer panel 1, and the vertical wall bent toward the outer panel 1 side (the back side in each figure) on the outer peripheral side of the inner wall 3 4 and a flange 5 extending opposite to the outer panel 1 over the periphery of the vertical wall 4 is press-molded into a predetermined shape.

  These dissimilar panel structures shown in FIGS. 1 and 2 are common in that they are rectangular panel structures each having corners 8, 9, 10, and 11 around four sides. However, the length of the vertical wall 4 of the inner panel at each corner and the character lines at the four peripheral edges around the four are different from each other. The dissimilar panel structure according to the present invention is not limited to an automobile panel having a hem processing part around four sides such as the illustrated hood (bonnet) and trunk, but also the upper side where the glass as shown in FIG. The present invention can be applied to panel structures as various vehicle body members such as door panels (having a hem processing portion around the periphery). Therefore, as a matter of course, the three-dimensional shape, the planar shape, and the construction range of the hem processing differ depending on these panel uses.

Hem processing:
3 and 4, the aluminum alloy outer panel 1 and the steel inner panel 2 are joined together by hem processing of the peripheral edge of the panel, and integrated as the dissimilar panel structure shown in FIGS. That is, as shown in FIGS. 3 and 4, the peripheral portion 6 of the outer panel 1 is folded back and integrated by hem processing that sandwiches the peripheral portion 7 of the flange 5 of the inner panel 2 via the adhesive resin layer 20. As a result, the hemming portion 21 having a laminated structure is formed by combining the peripheral edge portion 6 of the outer panel 1 and the peripheral edge portion 7 of the flange 5 of the inner panel 2 via the adhesive resin layer 20, and is integrated as a dissimilar panel structure. Is done.

  In the hem processing (hemming processing, in particular flat hem processing), the outer panel 1 peripheral edge 6 is folded back, and before the flange peripheral edge 7 of the inner panel 2 is sandwiched, the inner panel 2 is opposed to the inner peripheral portion 6 of the outer panel 1. A thermosetting resin adhesive 20 is applied. The thermosetting resin adhesive 20 is used to prevent the electrolytic corrosion caused by direct contact between different materials of aluminum and iron, and to increase the bonding strength between different materials (different material panel structure). It is applied over the entire peripheral edge 6 of (in a manner surrounding). As the thermosetting resin adhesive 20 to be used, an epoxy resin adhesive, a polyester resin adhesive, a phenol resin, which can be cured at the time of paint baking and curing of an automobile body panel and exhibit the required adhesive strength as a panel structure. An adhesive etc. are mentioned.

Corner welds:
In the hybrid structure such as the dissimilar panel structure, as explained with reference to FIG. 11, the hem shift of the aluminum alloy outer panel caused by the difference in aluminum / steel linear expansion at the time of paint bake hardening is constrained. The problem is that the outer panel is thermally deformed. Therefore, in order to suppress the thermal deformation of the outer panel, it is known from Patent Documents 1 and 2 that the prevention of the hem shift of the outer panel is effective.

  Here, even if it is not FSW like the said patent document 1, if the aluminum alloy outer panel hem shift | offset | difference prevention can be prevented by restraint by the welding construction of the hem processing part 21, a thermosetting adhesive like the said patent document 2 will be carried out. Is more efficient and practical than preventing the shift of hem due to the trouble of heating and restraining during hem processing.

  However, even if it is restraint (joining) by welding construction of the hemming portion 21, the restraining effect, that is, the effect of preventing the hem shift of the outer panel is greatly different depending on the hemming portion restrained by welding. I found out. For example, as shown in FIG. 12, as shown in FIG. 12, the peripheral portion of the panel structure is surrounded by two-dot chain lines, the left and right sides and the lower three sides, and the lower left and right two locations. Even if intermittently or continuously welded over a corner portion or the like, it is not always possible to suppress the occurrence of hem shift and warpage of the aluminum alloy outer panel. In other words, even when restraint (joining) is performed by welding, the restraining effect varies greatly depending on the restrained part. If the welded part is inappropriate, the occurrence of hem shift and warpage of the aluminum alloy outer panel cannot be suppressed. For example, also in FIG. 12, hem-worked portions at two corners on the left and right corners on the lower side of the panel structure where hem shift is likely to occur are welded (friction stir welding). However, in particular, the length of the inner panel from the vertical wall is long, and the welding range of the hem-worked portion of the right corner portion, which should suppress the occurrence of hem shift of the outer panel, is based on the welding range of the present invention described later, Obviously too small and lack of bounds. For this reason, it is not possible to suppress the occurrence of hem shift or warpage of the outer panel at least in the right corner.

  In this regard, the present invention is characterized in that a corner portion to be welded is selected from each corner portion 8, 9, 10, 11 of the panel structure in FIGS. And each distance (length) l (l1, l2, l3, l4) from corner A (A1, A2, A3, A4) of each corner to the vertical wall 4 of the inner panel 2 is a certain value or more. Only corner portions that meet a long condition are selected and welded over a range or region of a specific hemming portion to be described later.

  Here, the corner portions 8, 9, 10 and 11 of the panel structure are different from the peripheral edge 6 of the outer panel 1 of the panel structure and the vertical wall 4 of the inner panel in the dissimilar panel structure of FIGS. Bends (the flange 5 of the inner panel 2 also bends). However, depending on the design and design of the dissimilar panel structure, the inner panel vertical wall 4 is not always bent.

Selection of corners to be welded:
The corner portion (hem processing portion) as shown in FIG. 3 has a long distance (length) from the vertical wall 4 of the inner panel, which is referred to in the present invention, and welds the hem processing portion to restrain the outer panel. It is a corner part which should suppress the said thermal expansion. 3 is an AA cross section of the corner portion 11 shown on the lower left side of FIG. 1. The corner portion of FIG. 3 is viewed from the tip (corner portion) A of the corner portion in a plan view from the lower side of the drawing. , The shortest distance L1 to the vertical wall 4 of the inner panel 2 is from the points E of the vertical wall 4 of the inner panel 2 at the center of each side of the panel structure in FIG. This is a corner portion that is at least twice the largest (longest) of the shortest distances l5, l6, l7, and l8 to each point D.

  The restraint by welding only the corner portion having the “longest (longest) shortest distance to the vertical wall” as shown in FIG. 3 can suppress the occurrence of hem shift and warpage of the aluminum alloy outer panel. As described later in FEM analysis, only such a hem-processed portion of the corner portion having a “longest (longest) shortest distance to the vertical wall” is greatly related to occurrence of hem shift and warpage of the aluminum alloy outer panel.

Here, as the definitions of the respective words, the tips A or the corners A (A1, A, A) of the corner portions (corner portions of the outer panel 1) 8, 9, 10, 11 of the panel structure, which are referred to in FIGS. A2, A3, and A4) are the most distal or corner portions where the radius of curvature is the smallest at each of these corners, and more specifically, the points on the outside (thickness) of the periphery of each of these corners.
The shortest distance L1 from the tip (corner) A of the corner of the panel structure to the vertical wall 4 of the inner panel 2 is the shortest from the tip (corner) A of the corner to the intersection B of the vertical wall 4. It can also be said to be the length of a normal or perpendicular l (l1, l2, l3, l4) as a distance.
3 and 4 (or FIGS. 1 and 2) in a plan view, not on the middle or top of the vertical wall 4 but on the boundary line with the flat flange 5 on the lower end side of the vertical wall 4 ( The distance between the intersection (B) and the tip (corner) A of the corner is the shortest.
Further, the central part of each side of the panel structure means a point at the center (middle) of the distance (length) between the tip A or the corners A of each corner part at both ends of each side of the panel structure. 1-4, which are the points of the vertical wall position E (E1, E2, E3, E4) of the inner panel 3 and the peripheral edge position D (D1, D2, D3, D4) of the panel structure. . Here, the position E of the vertical wall 3 at the central part of each side and the peripheral part position D of the panel structure body are the shortest distances between the vertical wall 3 and the peripheral part of the panel structure body at the central part of each side. Position. The position E of the vertical wall 3 at the center of each side is not in the middle or top of the vertical wall 4 but with the flat flange 5 on the lower end side of the vertical wall 4 when viewed in plan, as in B above. A point (intersection) on the boundary line. Further, the peripheral edge position D of the panel structure is a point on the outer side (thickness) of the peripheral edge.
The length l from the vertical wall position E to the peripheral edge position D of the inner panel 3 at the center of each side is the panel in FIGS. 1 and 2 in plan view from the upper side (front side) of the figure. The shortest distances l5, l6 from the vertical wall positions E1, E2, E3, E4 of the inner panel 3 to the peripheral positions D1, D2, D3, D4 at the center of each of the four sides of the structure, l7 and l8.

  On the other hand, FIG. 4 shows that the shortest distance (length of the perpendicular or normal l) L2 to the vertical wall 4 of the inner panel 2 is small (short), the hem-processed portion is welded, the outer panel is restrained, and the heat The corner part (hem processing part) which does not need to suppress expansion is shown. 4 is a BB cross section of the corner portion 9 shown on the upper right side of FIG. 1. The corner portion of FIG. 3 is a front end (corner) of the corner portion in plan view from the lower side of the drawing. Part) The shortest distance L2 from A to the vertical wall 4 of the inner panel 2 is determined from each E point of the vertical wall 4 of the inner panel 2 at the center of each side of the panel structure in FIG. It is a short corner part that is less than twice the largest (longest) of the shortest distances L to each point D of the peripheral part.

  Such a hem-processed portion of the corner portion having a small (shortest) short distance is not greatly related to the occurrence of hem shift or warpage of the aluminum alloy outer panel. The same applies to the hem-processed portions on each side of the panel structure (four sides if the planar shape of the panel structure is rectangular). Therefore, in the present invention, the corner portion of the panel structure other than the corner portion that does not satisfy the length regulation and the hem processing region other than the hem processing region to be welded on each side are not welded. It is also preferable from the viewpoint of preventing deformation due to the heat effect of welding and preventing strength reduction.

In the dissimilar material panel structure of FIG. 1, only the two left and right corner portions 8 and 11 on the lower side of the drawing meet the perpendicular length condition shown in FIG. For this reason, the hem-processed areas of the corner portions 8 and 11 that are hatched and reach the left and right sides and the lower side of the dissimilar panel structure are welded to each other, and the peripheral portion 6 of the outer panel 1 is welded. Is restrained. Then, the two hemmed portions of the left and right corner portions 9 and 10 in the upper side of the other drawings, and the four sides of the rectangle of the dissimilar material panel structure (in the figure), which deviate from the perpendicular length condition shown in FIG. The hem-processed areas other than the hem-processed areas indicated by the diagonal lines welded and joined at the corner parts 8 and 11 are not welded.
Further, in the dissimilar panel structure of FIG. 2, as in FIG. 3, the left and right corner parts 8 and 11 on the lower side of the figure, and further, the corner part 10 on the upper left side of the figure has a total of three places, This satisfies the perpendicular length condition shown in FIG. For this reason, these corner portions 8, 10, and 11 are welded and joined to the four sides of the dissimilar panel structure, respectively, and the hem-worked portion regions with hatched lines are welded to restrain the peripheral portion 6 of the outer panel 1. Yes. Then, one hem-worked portion region of the corner portion 9 on the upper right side of the figure that deviates from the perpendicular length condition shown in FIG. The hem processing regions other than the hem processing regions welded and joined at the corner portions 8, 10, 11 of the side) are not welded.

Handling of hem-worked parts other than hem-worked parts at corners to be welded:
In the case of a dissimilar panel structure such as a door panel in which the upper side where the glass is mounted as shown in FIG. 12 is not hemmed (having a hemming portion around three sides), the hemming portion on the upper side and the left and right sides of the upper side In many cases, there is no corner portion, and only the hem-processed portion remains near the upper end of both sides on the left and right sides. In order to secure the strength by the shape and structure of the panel structure, such hem processing parts and hem processing parts other than the corner part which is the object to be welded in the present invention, “the shortest distance to the vertical wall is large (long)” In addition, spot welding or wire welding is allowed by shortening the welding line within a range that does not cause deformation or strength reduction due to the heat effect of welding. Further, if necessary, welding for joining the outer panel and the inner panel at a panel portion other than the hem-worked portion is allowed as long as it is not deformed or reduced in strength due to the influence of the welding heat.

Range of hem-worked part of the corner to be welded:
The construction range to be welded and constrained at the hem-worked portion in the corner portion of the dissimilar panel structure is indicated by diagonal lines in each corner portion selected in FIGS. The range indicated by the oblique lines is a range in which the out-of-plane bending deformation occurs due to the load during thermal expansion of the aluminum alloy outer panel, as will be described later by FEM analysis. When this range is expressed quantitatively, the intersection B with the vertical wall 4 of the inner panel with respect to the perpendicular or normal l that is the shortest distance from each corner portion tip A in a plan view from above in FIGS. Is a range that reaches the intersections C1 and C2 of the tangent line passing through the periphery of the panel structure.

More specifically, the range of the hem-processed portion of the hatched portion to be welded can be determined by the following procedure.
First, in the plan view from the upper side of FIGS. 1 and 2, the distance from each end A1, A2, A3, A4 of each corner portion 8, 9, 10, 11 selected to be welded to the vertical wall 4 of the inner panel Is drawn to the shortest perpendicular line or normal line l, and the intersection points B1, B2, B3, B4 that are the shortest distances of the vertical wall 4 on the inner panel 2 side with respect to the perpendicular lines or normal lines l1, l2, l3, l4 are respectively drawn. Decide.
Next, in the same plan view, tangent lines (tangent lines to the plane R) passing through the intersections B1, B2, B3, and B4 to the perpendicular lines l1, l2, l3, and l4 are drawn, respectively, and the peripheral edges of each of the four sides of the panel structure Intersection points C1 and C2 with the part (hem processing part) are determined respectively.
And hem processing from each tip A1, A2, A3, A4 of each corner part 8, 9, 10, 11 to intersection C1, C2 of the peripheral part (hem processing part) of each four sides of this panel structure The partial ranges (the hatched regions) A to C1 and A to C2 are defined as ranges (regions) to be restrained by welding.

Thermal deformation analysis by FEM analysis:
The reason for selecting the corner portion to be welded as described above under the perpendicular length condition and determining the range of the hem-worked portion of the hatched portion to be welded will be described below. Although the actual dissimilar panel structure shown in FIGS. 1 and 2 was simulated, the flat shape was subjected to thermal deformation analysis by FEM analysis for the dissimilar panel structure having a simple rectangular shape shown in FIG. It was.

  In this analysis, the shape condition of the panel structure having the rectangular planar shape shown in FIG. 6 is that the aluminum alloy outer panel is a simple rectangular flat plate, and the steel inner panel is also a hat in cross section. The wall or the peripheral part also has a simple rectangular shape. The outer panel was made of a 6000 series aluminum alloy plate having a long side length of 350 mm, a short side length of 250 mm, a plate thickness of 1.00 mm, and a proof stress of 140 MPa. Further, the inner panel was made of a normal mild steel plate, the plate thickness was 0.60 mm, the length of the long side in the horizontal direction in the figure of the inner wall was 310 mm, and the length of the short side in the vertical direction in the figure was 210 mm.

  Furthermore, the height of the vertical wall of this inner wall is 15 mm, and the length from the inner panel vertical wall surface at the center of each side of the panel structure to the peripheral edge of the outer panel (hem processing edge) (each side of the panel structure) The largest one of the shortest distances from the inner panel vertical wall to the peripheral edge of the panel structure in the central portion of each of the upper and lower left and right sides was 20 mm in common. On the other hand, the lengths of the perpendiculars of the hem-worked portions at the corners of the four corners are commonly 50 mm, and the length from the inner panel vertical wall surface to the peripheral edge of the outer panel at the center of each side is 2. 5 times, more than 2 times as specified. The solver used was ABAQUS, which is a general-purpose finite element code.

  FIG. 5 shows the load distribution acting on the hem-processed portion and FIG. 6 shows the deformation distribution when the dissimilar panel structure is heated and the aluminum alloy outer panel is thermally expanded. Here, the precondition of the analysis is a state in which all of the hem-processed portions over the entire peripheral edge of the panel structure are rigidly coupled (conditions in which hem shift does not occur), assuming heating during baking at 170 ° C., The analysis is performed under the condition that the aluminum alloy outer panel is heated from room temperature to 20 ° C to 170 ° C.

  From these FIGS. 5 and 6, the load acting on the hem-processed portion is conspicuous at the corner portions at the four corners of the dissimilar panel structure both on the long side and the short side of the panel structure, and if the hem shift at this portion can be suppressed. It can be seen that the thermal deformation of the aluminum alloy outer panel can be suppressed.

  Further, from FIG. 5, the load acting on the hem-processed portion at the time of thermal expansion of the aluminum alloy outer panel is maximized at the position of the corner portion tip A where the horizontal axis is 0 mm, and is about 70 mm away. It can be seen that the load at the time of thermal expansion of the outer panel made of aluminum alloy acts over the range of the hem-worked portion up to the side.

  The corner portions at the four corners of the dissimilar panel structure on which the load at the time of thermal expansion of the outer panel made of aluminum alloy is applied are the corners of the panel structure in a plan view from the lower side of the figure as shown in FIG. The length L1 of the perpendicular or normal l that is the shortest distance from the corner A of the part to the intersection B of the inner panel vertical wall 4 is from the vertical wall E of the inner panel 3 at the center of each side of the panel structure. It is a corner portion that is at least twice as long as the largest one of the lengths l with the shortest distance to the peripheral portion D.

  According to the further knowledge of the present invention, the corner portion as shown in FIG. 4 or “less than or equal to the shortest distance” is less than this, or the center portion of each side of the panel structure body. In the side part of the dissimilar panel structure where the shortest distance from the vertical wall E to the peripheral part D of the inner panel 3 is small, the load at the time of thermal expansion of the aluminum alloy outer panel that affects the hem shift does not act much. Therefore, only the hem-processed portion of the corner portion of the “shortest distance to the vertical wall is large (long)” as shown in FIG. 3 is affected by the load at the time of thermal expansion of the aluminum alloy outer panel that affects the hem shift. Can be restrained by. Therefore, in the present invention, the length of the normal line 1 or the length L1 of the normal line 1 which is the shortest distance is the longest one of the lengths 1 which are the shortest distance. It is defined as more than twice. That is, the hemming portion of the corner portion where the magnification is further increased to 3 times or more, or 4 times or more, and the necessity to be restrained by welding increases.

  Further, based on the range of 70 mm in which the load at the time of thermal expansion of the aluminum alloy outer panel is acting, it is generalized to various panel structures used in the vehicle body structure, and the hem-worked portion at the corner portion In the region, the construction range in which the outer panel made of aluminum alloy (hem shift) is to be restrained by welding is the range indicated by hatching at each selected corner in FIGS. That is, in a plan view from the top of FIGS. 1 and 2, an intersection C <b> 1 of each corner portion tip (corner portion) A with a peripheral portion of the tangent panel structure passing through an intersection B of the vertical wall 4 of the inner panel. , C2 range.

  In this way, the above-mentioned “large (long)” corner portion is coated and baked only by performing dissimilar material joining by welding only in the vicinity of the above-mentioned corner portion, particularly in the range where out-of-plane bending deformation occurs, in order to prevent hem shift. Even in the process, it is possible to prevent the hem portion from being displaced due to the difference in linear expansion of aluminum / steel. Thereby, the thermal deformation of the aluminum alloy outer panel, the dissimilar panel structure or the corner portion can be suppressed. It will be. In addition, when the hem-worked part of the entire periphery or the entire peripheral part of the dissimilar panel structure is constructed, it is likely that the welding time will be lengthened and thermal deformation and strength reduction due to welding heat input will become secondary problems. In addition, if only the construction of the corner portion is performed, a sufficient thermal deformation suppressing effect can be obtained without causing such a secondary problem.

  On the other hand, from FIGS. 5 and 6, another thing can be said that the load at the time of thermal expansion of the outer panel made of an aluminum alloy extends to the range of the hem processing portion of the side part of the dissimilar panel structure that exceeds 70 mm from the corner center point. In other words, at least the amount causing the displacement deformation of the hem portion is not loaded. The range in which the load at the time of thermal expansion of these aluminum alloy outer panels does not affect (does not act) is the hem-processed portion of the corner portion as described above, as shown in FIG. These are the four sides of the dissimilar panel structure excluding the hem-worked portion of the corner portion where the shortest distance is large (long). Such hem-processed portions at the corners and sides are not greatly related to the occurrence of hem shift or warpage of the aluminum alloy outer panel.

  In this respect, except for the above-mentioned “large (long)” corner portion, the above-mentioned “shortest distance is small (short)” corner portion, and the hem processing region excluding the hem processing region to be welded on each side, There is no need to restrain the outer panel (hem shift) made of aluminum alloy by welding the hem-processed portion. For this reason, in this invention, it is preferable not to weld-join (restrain) the hem processing part of the site | part of these panel structures. In this way, the corner part of the hem part of the actual panel structure that causes the displacement deformation of the hem part and that should be welded and restrained is the design part of the actual part of the panel structure and the vehicle body used. It can be said that it varies greatly depending on the design.

  FIG. 8 shows the amount of residual deformation in the case where the hem-worked portions of the corners of the four corners are constrained by spot welding in the thermal deformation analysis by FEM analysis of the dissimilar panel structure having the rectangular planar shape shown in FIG. Show the distribution. Similarly, FIG. 7 shows the residual deformation distribution in the case of the conventional example in which all the hem-processed portions at the four corners are not joined by welding, and the original hem-processed state is not constrained. In these drawings, the upper side of the figure is a plan view of the panel structure, and the lower side is a perspective view of the panel structure.

  As shown in the plan view on the upper side of FIG. 7, when there is no restraint on the hem processing portion of the corner portion, as shown in the perspective view on the lower side of FIG. Is seen. However, as shown in the plan view on the upper side of FIG. 8, when the hem-worked portions at the corners of the four corners are constrained by spot welding, the hem shift at the corner portions can be prevented as shown in the perspective view on the lower side of the figure. It can be seen that the thermal deformation can be efficiently suppressed. In addition, the said spot-like weld part is displayed on the upper panel top view of FIG. 8 as the dotted line shape which protrudes slightly from the periphery to the corner part of each corner part as FCW construction range (-).

Welding means for hem processing part:
It is preferable that the welding of the hem-worked portion of the corner portion to be welded is joined in a spot shape by arc welding or laser welding. Spot welding is possible because spot welding can be performed, but it is not practical for an outer panel that requires a struck impression due to a spot electrode particularly on the soft aluminum alloy outer panel side, and requires appearance and aesthetics. Further, in the FSW as disclosed in Patent Document 1, as described above, there is a possibility that the folded flange portion due to restraint may break.

  On the other hand, in linear welding by arc welding or laser welding, if the welding line or welding time becomes long, a problem of thermal deformation of the hem-processed portion due to welding heat input is likely to occur. For this reason, it is preferable to set it as the point joining by the point welding by these arc welding or laser welding. As the arc welding, efficient TIG welding which is widely used for joining ordinary car bodies is preferable. Also in this TIG welding, TIG welding using a flux cored wire (FCW) formed by filling a flux inside the aluminum material outer shell is preferable.

Aluminum alloy outer panel:
As the aluminum alloy plate for the outer panel, an aluminum alloy such as 5000 series or 6000 series defined by JIS or AA standards can be used according to the required characteristics of the vehicle body structure to be applied, such as strength, molding, or corrosion resistance. From the standpoint of reducing the thickness of automobiles such as automobiles, an aluminum alloy with high strength and excellent formability is preferable, and Si / Mg in the composition is 1 or more, and Si is contained in excess of the Mg content. Preferred are Si-rich 6000 series aluminum alloys such as 6N01, 6016, 6111, 6022. These 6000 series aluminum alloys ensure the formability by lowering the strength (yield strength) at the time of forming into the outer panel, and the low temperature of 150 to 180 ° C. and the short time of 10 to 50 minutes during the subsequent coating baking process. It has the characteristics (bake hardness, BH property) that the strength (yield strength) is increased by age hardening by artificial aging treatment of time. These aluminum alloy materials are subjected to solution treatment and quenching treatment (quality symbol T4), subsequent aging treatment (quality symbol T6), and overaging treatment (quality symbol T7) after cold rolling and hot extrusion. And used as a material for press-molding the outer panel.

  The thickness (plate thickness) of the aluminum alloy plate is selected in the range of 0.5 to 3 mm in consideration of the required characteristics of the outer panel such as weight reduction, strength, rigidity, and formability of the automobile body. If the thickness of the aluminum alloy plate is too thin, the necessary strength and rigidity as an automobile member cannot be ensured, and if the thickness is too thick, the weight reduction of the automobile body is sacrificed. The welded joint itself becomes difficult.

Steel inner panel:
The steel plate for the inner panel may be coated with a commonly used zinc-based or aluminum-based coating layer by plating or the like, or may be bare. As the steel material, an inexpensive mild steel plate is used as in the case of a conventional steel inner panel, but cold-rolled steel plates such as high-tensile steel (high ten) and stainless steel can also be applied. The thickness (plate thickness) of the steel plate is also selected in the range of 0.3 to 3 mm in consideration of the required characteristics of the inner panel such as weight reduction, strength, rigidity, and formability of the automobile body.
If the thickness of the steel sheet is too thin, the necessary strength and rigidity as an automobile member cannot be ensured, and if the thickness is too thick, the weight reduction of the automobile body will be sacrificed, and welding described later will be performed. Joining itself becomes difficult.

  The dissimilar panel structure was actually manufactured under the same material conditions and shape conditions as the dissimilar panel structure having the rectangular planar shape of FIG. 6 used for the thermal deformation analysis by the FEM analysis. That is, the peripheral part of the steel inner panel that was press-molded under the same material conditions and shape conditions as in the above analysis and formed into a cross-sectional hat shape was folded back at the peripheral part of the aluminum alloy outer panel that was in the same material and shape conditions as in the above analysis. Then, a dissimilar panel structure integrated by hem processing for sandwiching the peripheral edge of the flange of the inner panel through a commercially available epoxy resin adhesive resin layer was manufactured.

  By the way, the shortest distance L to the vertical wall of the hem-worked portion at the four corners of the manufactured dissimilar panel structure is 50 mm in common, and all of the peripheral edge of the outer panel from the inner panel vertical wall surface at the center of each side. 2.5 times the largest of the shortest distances to the part. That is, as in the analysis example, the height of the vertical wall of the inner wall is 15 mm, and the largest of the shortest distances from the inner panel vertical wall to the peripheral edge of the panel structure at the center of each side of the panel structure is: It was 20 mm in common for each of the four sides of the top, bottom, left and right.

  Then, as shown in FIG. 6, at the corners of the four corners of the dissimilar panel structure, the hem-processed portion from the position of each corner portion tip A to the side of the dissimilar panel structure is welded over a length of 70 mm. TIG welding was performed at a bead length of 10 mm and a welding interval of 10 mm. At the time of welding, the FCW wire contains 5% by mass of a K-Al-F system (Noroclock flux) as a powder flux, and the skin material (hoop) is an aluminum alloy to which 1.25% by mass of Si is added, A commercially available wire having a wire diameter of φ1.2 mm was used. The welding conditions were DC TIG welding, the current was 100 A, the welding speed was 30 cm / min, the filler supply speed was 7 m / min, and the shielding gas was 20 L / min with Ar. Further, a tungsten electrode was used, and the position of the electrode tip was set to a position just above the peripheral edge 6 of the aluminum alloy outer panel 1 and 1.6 mm above. The advance angle α of the electrode was set to 10 degrees, and the length range of 70 mm was intermittently joined in the form of dots.

  9 and 10, the produced dissimilar panel structure is placed in a heating furnace, heated from room temperature 20 ° C. to 170 ° C. for 30 minutes, and then allowed to cool to room temperature and cooled. The result of having measured the curvature (on the outer panel side made of aluminum alloy) as a three-dimensional shape with a commercially available three-dimensional shape measuring instrument is shown. In these drawings, the upper side of the figure is a plan view of the panel structure, and the lower side is a perspective view of the panel structure.

  As shown in the plan view on the upper side of FIG. 9, when there is no restraint on the hem-worked portion of the corner portion, the upper side of the same figure (aluminum alloy) A warp deformation of up to about 4 mm toward the outer panel side) can be seen. On the other hand, as shown in the plan view on the upper side of FIG. 10, when the hem-worked portions at the four corners of the dissimilar panel structure are constrained by spot welding within the range defined by the present invention, As shown in the perspective view, large warp deformation is not seen at the corners of the four corners of the dissimilar panel structure, and it can be seen that hem shift at the corners can be prevented and thermal deformation can be efficiently suppressed. In addition, the said spot-like weld part is displayed on the upper panel top view of FIG. 10 as the dotted line shape which protrudes slightly from the periphery in the corner part of each corner part as FCW construction range (-).

  As described above, according to the present invention, the aluminum alloy outer panel at the time of painting and baking an automobile body is obtained by extremely practical means for welding and joining only the necessary portions of the hem-worked portion of the corner portion of the dissimilar panel structure. Generation of hem shift and warpage can be suppressed. As a result, the dissimilar panel structure is not deformed without significantly reducing the cost and efficiency of processes such as hem processing of the dissimilar panel structure, and an automobile panel with high shape accuracy can be obtained. Therefore, it is suitable for making the automobile body into a dissimilar panel structure.

  1: Outer panel made of aluminum alloy, 2: Inner panel made of steel, 3: Inner panel inner wall, 4: Inner panel vertical wall, 5: Inner panel flange, 6: Outer panel peripheral edge, 7: Inner panel flange peripheral edge, 8, 9 DESCRIPTION OF SYMBOLS 10, 11: Corner part, 20: Resin layer, 21: Hem process part, l: Perpendicular of corner part, A: Corner part front-end | tip, B: Inner panel vertical wall intersection, C: Periphery edge part of dissimilar material panel structure , D: side center point of the inner panel vertical wall, E: side center point of the peripheral edge of the dissimilar panel structure

Claims (3)

  An aluminum alloy outer panel formed into a predetermined shape, an inner wall facing the outer panel, a vertical wall bent toward the outer panel on the outer peripheral side of the inner wall, and facing the outer panel around the vertical wall. A steel inner panel formed into a hat shape in cross section having a flange extending in the direction, the outer panel having a hem-processed portion, and the hem-processed portion having a flange peripheral portion of the inner panel having an adhesive resin layer. A peripheral structure of the outer panel folded in a state of being sandwiched between the corners of the panel structure, and the inner corners of the corners of the panel structure from the tip of the corners in plan view. The shortest distance to the vertical wall of the panel is from the vertical wall of the inner panel to the peripheral edge of the panel structure at the center of each side of the panel structure. Only the hemmed portion in the corner portion that is twice or more the largest of the short distances has a welded portion, and the hemmed portion having the welded portion is the tip of the corner portion in plan view. A dissimilar panel structure characterized in that it reaches the intersection with the peripheral edge of the panel structure of a tangent line passing through the point of the vertical wall of the inner panel that is the shortest distance from the center. The dissimilar panel structure according to claim 1, wherein the hem-processed portion has a point- like welded portion.   An outer panel made of an aluminum alloy formed in a predetermined shape, an inner wall facing the outer panel, a vertical wall bent toward the outer panel on the outer peripheral side of the inner wall, and facing the outer panel around the vertical wall In combination with a steel inner panel formed into a cross-sectional hat shape having an extending flange, the peripheral portion of the outer panel is folded, and the hem processing that sandwiches the peripheral edge portion of the flange of the inner panel via an adhesive resin layer, When integrating as a panel structure, the shortest distance from the end of the corner portion to the vertical wall of the inner panel is the center of each side of the panel structure in plan view among the corner portions of the panel structure. More than twice the shortest distance from the vertical wall of the inner panel to the peripheral edge of the panel structure Only the hem-processed part at a certain corner part is welded and the hem-processed part to be welded is a point on the vertical wall of the inner panel that is the shortest distance from the tip of the corner part in plan view. A method for producing a dissimilar panel structure, characterized in that it reaches an intersection with a peripheral portion of the panel structure having a tangent line passing therethrough.