The subject invention relates to vehicles, more particularly to a positioning and reinforcement structure for a vehicle, and even more particularly to a structural fender having a multi-gage inner fender panel.
Vehicles, such as automobiles, are assembled by aligning and fastening numerous components and subassemblies to one another. One region of the automobile requiring assembly of such components and subassemblies is a front end region. This portion of the vehicle is frequently assembled as an assembly or subassembly referred to as a “front clip.” The front clip is commonly defined as the assembly comprising the portion of the vehicle extending from the A-pillar (the roof support pillar associated with the front windscreen) to the most forwardly disposed component, typically a front bumper. The front clip includes a structural frame, as well as a variety of vehicle components that collectively form the vehicle body.
Several efforts to directly or indirectly mount and/or fix the vehicle body components to each other, as well as to the vehicle frame, have relied on welded support structures or frames and machined body mounting locations for the body components. Front end clips that use welded frames to attach front clip components are effective, but they generally require very large capital investments to support automated, high volume mass production. Frameless approaches for assembly of the front end clip are very desirable because they have greatly reduced capital requirements, but have sometimes been subject to undesirably large variations in alignment and fastening of components to one other. These large variations may influence the aesthetic appearance of the automobile to a user by providing non-uniform or undesirably large or small gaps and spacings between components and may be the cause of functional deficiencies, such as undesirable large opening/closing efforts, alignment and mutilation of components due to misalignment and interference, and non-uniform gaps and spacings, which each may affect consumer satisfaction.
A frameless front clip assembly requires the use of structural fenders as compared to frame-based front end clip construction where the fender sheet metal may be attached directly to the frame and the frame provides much of the needed structural strength. One area of concern in frameless front clip assemblies that use structural fenders, such as the front end sheet metal of the floating structure of a full size truck, has been the development of structural fenders and methods of making and using them so as to set the structural fender in an optimal position to ensure predetermined requirements. These requirements include aesthetic requirements, such as gap, spacing, class A finish and other aesthetic requirements, as well as structural function requirements, such as strength and modal frequency response, and overall vehicle requirements, such as, for example, reduced mass. Mass reduction of structural fenders, particularly the inner fender panel has been difficult to achieve due to the structural requirements of the panel. High load locations, such as the fender attachment points, require load carrying capacity that determines the thickness and hence the weight of a monolithic metal sheet blank. The use of blanks having a reduced thickness with the addition of doubler plates welded at stress concentration locations or beta patches, (e.g. adhesive patches adhered to specific locations to increase the stiffness and frequency response of a panel at specific locations) require secondary manufacturing operations to add them. While providing the benefits described, their use has generally been very limited due to the added labor and material costs, as well as the weight that they add to the vehicle, thereby reducing fuel efficiency.
Accordingly, it is desirable to provide structural fenders, particularly inner fender panels, which meet the structural requirements while reducing the overall manufacturing cost and weight, thereby reducing vehicle cost and increasing vehicle fuel efficiency.
In one exemplary embodiment, an inner fender panel for a structural fender of an automotive vehicle comprising an outer surface configured for attachment to the inner surface of an outer panel of the fender and an inner surface; the inner fender panel comprising a plurality of abutting inner fender panel sections that are joined to one another, each inner fender panel section having a thickness, at least two abutting inner fender panel sections having thicknesses that are different is disclosed.
In another exemplary embodiment, a structural fender for an automotive vehicle is disclosed. The structural fender includes a formed outer panel having a viewable outer surface and an inner surface. The fender also includes a formed inner fender panel having an outer surface configured for attachment to the inner surface of the outer panel and an inner surface; the inner fender panel comprising a plurality of abutting inner fender panel sections that are joined to one another, each inner fender panel section having a thickness, at least two abutting inner fender panel sections having thicknesses that are different.
In yet another exemplary embodiment, a method of making an inner fender panel for a structural fender is disclosed. The inner fender panel includes an outer surface configured for attachment to the inner surface of an outer panel of the fender and an inner surface, the inner fender panel comprising a plurality of abutting inner fender panel sections that are joined to one another, each inner fender panel section having a thickness, at least two abutting inner fender panel sections having thicknesses that are different. The method includes forming a plurality of flat planar inner section blanks that are configured to abut one another and define an inner fender panel precursor, each inner section blank having a blank thickness, at least two abutting inner section blanks having thicknesses that are different. The method also includes joining abutting inner section blanks to form the inner fender panel precursor. The method further includes stamping the inner fender panel precursor to plastically deform the inner fender panel blanks and form the inner fender panel.
The above features and advantages and other features and advantages of the invention are readily apparent from the following detailed description of the invention when taken in connection with the accompanying drawings.
Other features, advantages and details appear, by way of example only, in the following detailed description of embodiments, the detailed description referring to the drawings in which:
The following description is merely exemplary in nature and is not intended to limit the present disclosure, its application or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.
In accordance with an exemplary embodiment the gage optimization of a structure supporting fender inner fender panel of an automotive vehicle by forming a gage optimized, multiple thickness, laser-welded, sheet metal blanks is disclosed. Using laser-welded blanks to form the fender inner fender panel provides mass and cost reduction for the automotive vehicle while maintaining efficiency of material utilization and structural performance. The fender inner fender panel may also be attached to a fender outer panel to form a structural fender, or as it may also be termed a structural fender assembly, for the vehicle as described herein.
Referring to
The vehicle 12 includes a frame 14 formed of several integrally formed or operably coupled components to provide a structural support configured to directly or indirectly support components and subassemblies for the vehicle 12. Supported components and subassemblies include a plurality of body components and the vehicle 12 is typically referred to as having a body-on-frame construction, based on the direct or indirect mounting and fixing of the various components to the frame 14. The front end assembly 10 is the region of the vehicle 12 that is defined by a portion of the vehicle 12 extending forward from what is known conventionally as an “A-pillar” to a forward most component, such as a front bumper 20. The front end assembly 10 may be interchangeably referred to as a “front clip” of the vehicle 12.
To facilitate assembly of the front end assembly 10, both with respect to components in relation to each other as well as to the frame 14, a positioning and reinforcement structure 30 is included. The positioning and reinforcement structure 30 generally refers to a structure configured to provide a foundation for inter-part dimensional relationships during the assembly process for all components of the front end assembly 10, thereby alleviating reliance on individual machined mounting locations. In one embodiment, the positioning and reinforcement structure 30 comprises a grill opening reinforcement (GOR) structure that acts to define and reinforce a grill opening. Since the positioning and reinforcement structure 30 may be formed as an assembly, it may also be referred to herein as a positioning and reinforcement structure 30 or a GOR assembly. As will be described in detail below, the positioning and reinforcement structure 30 includes locators, fastening features, and other critical dimensional relationship interfaces of several components and subassemblies. Such components and subassemblies typically include structural fenders or fender assemblies 76, 98, headlamps 122, grills 142, fascias 22, bumpers 20 and bumper attachment features, hoods 118, hood latches (not shown), hood bumpers 18 and under-hood closeout panels (not shown), air baffles (not shown) and radiator supports 60, for example. It is to be understood that the preceding list is merely illustrative of the numerous components and subassemblies which may be included in the front end assembly 10 and may benefit from the positioning and reinforcement structure 30. Exemplary components and subassemblies will be described in detail below. As used herein, an axial direction 26 refers to a direction that extends frontward and rearward along a central axis 25 of the vehicle, a cross-car direction 27 refers to a direction that extends laterally or across the vehicle and a vertical direction 28 refers to a direction that extends upwardly and downwardly. In one embodiment, these directions are mutually orthogonal with regard to one another.
Referring now to
The positioning and reinforcement structure 30 also includes a first brace 50 extending in a relatively diagonal manner from proximate the first side member bottom region 42 to a relatively central location along the top support member 32, to which the first brace 50 is operably coupled. The first brace 50 may be coupled to the first side member 36 or the bottom support member 34, or both. Similarly, a second brace 52 is included and extends in a relatively diagonal manner from proximate the second side member bottom region 46 to the top support member 32, to which the second brace 52 is attached. The second brace 52 may be coupled to the second side member 38 or the bottom support member 34, or both. The first brace 50 and the second brace 52 may be operably coupled to the top support member 32 in a relatively coaxial manner, such that the first brace 50 and the second brace 52 mount to a single location of the top support member 32. The first brace 50 and the second brace 52, both singularly and in combination, provide structural support for the overall positioning and reinforcement structure 30. Additionally, the first brace 50 and/or the second brace 52 include mounting and locating features corresponding to components integrated with, or associated with, the positioning and reinforcement structure 30.
Referring again to
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Each inner fender panel section 230 has a thickness, and the multi-gage inner fender panels disclosed herein are characterized by having at least two abutting inner fender panel sections 230 having thicknesses that are different. In one embodiment, only two abutting inner fender panel sections have different thicknesses. In other embodiments, more than two panels have thicknesses that are different. In one embodiment, all of the inner fender panel sections 230 have different thicknesses.
In one embodiment, the outer surface 210 of the inner fender panel 200 that engages the inner surface 320 of the outer fender panel 300 is substantially planar. That is, even though the inner fender panel 200 includes a plurality of inner fender panel sections 230, and outer surface 210 is a surface of complex curvature, the surface forms a continuous plane, and particularly does not have stepwise discontinuities at the interfaces between abutting inner fender panel sections, including those having different thicknesses. Stated differently, the outer surfaces 210 of abutting inner fender panel sections 230 having thicknesses that are different are substantially co-planar. In one embodiment, the thickness of the inner fender panel sections may range from about 0.75 mm to about 2.5 mm, and more particularly may range from about 0.8 mm to about 1.5 mm. These ranges may include the thicknesses of the formed inner panel sections that may include up to about 16% plastic strain (deformation), including a reduction in thickness from the flat planar inner fender panel blanks from which the formed inner panel sections are made of up to about 16%.
The inner fender panel 200 may be made from any suitable material. In one embodiment, each of the plurality of abutting inner fender panel sections 230 includes a metal sheet material having a material composition. Any formable metal sheet material and material composition that meets the structural and performance requirements of the vehicle, particularly the vehicle fender, may be used. Suitable material compositions of the metal sheet material include various steel alloys or aluminum alloys. Other lightweight, high strength sheet materials may also be used as the metal sheet, including various magnesium alloys and titanium alloys. In one embodiment, the metal sheet material of each of the plurality of abutting inner fender panel sections 230 may have the same material composition. In another embodiment, the metal sheet material of the plurality of abutting inner fender panel sections 230 may have different material compositions.
The abutting inner fender panel sections 230 may be joined to one another by any suitable joint or joining method. In one embodiment, the abutting panel sections are joined to one another by laser welding to form laser weld joints 240 between them. The laser weld joints 240 may be configured to extend in a substantially vertical direction 28 or a substantially axial direction 26, or a combination thereof, when the inner fender panel 200 is installed on an automotive vehicle 12. In one embodiment, the laser weld joints 240 may be selected so that they all in extend in the same direction (e.g., vertically or axially). This may be advantageous to increase the efficiency or accuracy, or both, by allowing the laser welding apparatus to index quickly from the end of one weld pass 242 to the beginning of the pass on the adjacent blank as shown schematically, for example, in the laser welded blank of
In one embodiment, illustrated in
In one embodiment, a structural fender or structural fender assembly 76, 98 for an automotive vehicle 12 includes a formed outer fender panel 300 having a viewable outer surface 310 and an inner surface 320. The structural fender assembly 76, 98 also includes a formed inner fender panel 200 having an outer surface 210 configured for attachment to the inner surface 320 of the outer panel 300 and an inner surface 220, where the inner fender panel 200 includes a plurality of abutting inner fender panel sections 230 that are joined to one another, with each inner fender panel section 230 having a thickness, and at least two abutting inner fender panel sections 230 having thicknesses that are different. The outer fender panel 300 and inner fender panel 200 may be attached to one another by any suitable attachments or attachment methods, including by a plurality of weld joints, such as a plurality of spot weld joints. The attachment of the outer fender panel 300 and inner fender panel 200 forms a structural fender assembly 76, 98 that provides the necessary vehicle structure to surround and enclose the associated members of the vehicle frame and front corner, including the various members of the braking assembly and wheel assembly as are known in the art, without the need for an attachment to a separate frame for the front clip. The structural fender assembly 76, 98 may also include additional braces 410 or struts that may be used to reinforce or strengthen portions of the assembly, as well as various brackets or braces, such as door attachment bracket, 412, positioning and reinforcement attachment bracket 414 and radiator support bracket 416 that may be used to attach and/or reinforce the structural fender assembly 76, 98 to other concomitant portions of the vehicle 12 structure.
As shown, for example, in
Referring to
The method 500 also includes joining 520 abutting inner section blanks 230′ to form the inner fender panel precursor 200′, such as by welding, including welding according to welding path 242. This may include a welding path 242 (
In one exemplary embodiment, the inner fender panel 200 is formed from four sections. The first panel section 230.1′ has a thickness of 1.5 millimeters. The second panel section 230.2′ has a thickness of 0.8 millimeters. The second panel being laser welded 240′ to first panel section 230.1′ along a straight path that allows the welding to be performed in a first direction. The third panel 230.3′ has a thickness of 1.5 millimeters and is laser welded 240′ to the second panel section 230.2′ along a second straight path in a second direction. In this embodiment, the second direction is substantially opposite the first direction. Finally, the fourth panel section 230.4′ has a thickness of 0.8 millimeters. The fourth panel section 230.4′ being laser welded to the third panel section 230.3′ along a straight path in a third direction.
It has been found that the disclosed inner fender panel 200 formed using multiple section panels of different thicknesses has a part weight of 4.83 kilograms. By way of comparison, the monolithic fender panel 199 has a weight of 6.81 kilograms. Further, due to the layout of the panel sections 230 on sheet stock, the material usage for the fender panel 200 is 13.0 kilograms while the monolithic fender panel 199 uses 17.5 kilograms of material. In another embodiment, the panel section 203.1′ uses a 2.4 millimeter thick material, this increases the material usage to 14.59 kilograms. Still less than that of the monolithic fender panel 199.
The method further includes stamping 530 the inner fender panel precursor 200′, once the inner section blanks 230′ have been welded together to form the inner fender panel precursor 200′, to plastically deform it and the inner fender panel blanks 230′ and form the inner fender panel 200. Stamping may be performed using conventional methods for stamping metal sheet, such as progressive stamping.
A method 500 of making a fender inner panel by forming gage optimized, multiple thickness, laser-welded, sheet metal blanks is disclosed. The structural fenders described herein are made by discrete placement and laser welding of thin gage sheet metal pieces of different thicknesses in areas where typical load paths do not require thicker material. The method includes performing a load path analysis of the inner fender panel of a structural fender using multi-gage sheet metal stampings. Forces and load paths are analyzed for optimum gage reduction of the sheet metal while maintaining strength where stress concentrations occur. The method also includes performing a formability and draw stretch thinning analysis of structural fender using a multi-gage sheet metal blank. Formability, seam-weld line placement and coil steel usage efficiency, are balanced within the stamping process. The method further includes performing a full body modal frequency effect of a multi-gage structural fender assembly that includes the multi-gage fender inner fender panel and the fender outer panel. Vehicle modal frequency improvements are also evaluated by eliminating non-structural mass. The method further includes blank utilization for optimization of coil fed trim to length sheet metal. Still further, the method includes assessment of blank to blank weld seam placement for stretch form, trim, and piercing operations. This may be used in some embodiments to avoid placing weld seams in heavily deformed areas of the blank, as well as avoiding placing weld seams that intersect cutouts, holes and other features. Usage of a laser welded blank provides opportunity for mass and cost reduction while maintaining efficiency of material utilization and structural performance. Yet further, the method includes incorporation of blank locating features to ensure weld seam placement during forming.
While the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the application.
This patent application is a continuation application of U.S. patent application Ser. No. 13/873,408 filed on Apr. 30, 2013, which claims priority to U.S. Provisional Patent Application Ser. No. 61/697,755, filed Sep. 6, 2012, the contents of both of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
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61697755 | Sep 2012 | US |
Number | Date | Country | |
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Parent | 13873408 | Apr 2013 | US |
Child | 14753850 | US |