The present invention relates to impact beams where optimal impact properties and low weight are important, and more particularly relates to a hybrid impact beam constructed from a combination of an extruded aluminum section, fiber-reinforced polymeric material, and adhesive, where the materials are optimally located to manage compressive, tensile, and torsional stress during an impact.
Bumper reinforcement beams for vehicle bumper systems have stringent functional requirements. Low weight is important due to its effect on vehicle gas mileage, but strength and impact properties are important given the government (FMVSS) and insurance industry (IIHS) safety standards for bumper systems. One dilemma is that no single material or process satisfies all design goals. For example, aluminum has low weight, but is not as strong as high strength steel, nor as light as polymeric material. Also, aluminum material tends to perform acceptably under compressive stress but not as well under tensile stress. Aluminum extruding processes can eliminate some manufacturing steps, but extruding processes limit the beam shapes that can be produced, and further limit the types and strengths of aluminum materials that can be used. Polymeric material has very low weight, but is not as strong as steel nor aluminum. Also, reinforced polymeric materials tend to provide significantly poorer impact strength than metals, especially when formed into thin walls. Polymeric materials tend to perform acceptably under tensile stress but not as well under compressive stress.
A subtle but significant design problem is that when a beam is “beefed up” in order to meet government and insurance industry standards, other areas will have “excess” material or will provide an “overkill” of strength and function. In some words, more material or strength is provided in some areas than is optimally required to meet the standards, thus leading to unnecessarily high cost or weight where “excess” material is located in unnecessary areas. For example, a center of a bumper reinforcement beam is spaced from the vehicle's bumper mounts such that it sees much higher/different bending requirements than ends of the beam which are located directly over/near the bumper mounts. Also, a front wall (face) of a bumper beam must be designed to receive direct contact during a vehicle impact (such that it undergoes high compressive forces and relatively sharp impact load peaks), while a rear wall receives stresses indirectly passed from the front wall through other walls/components of the beam to the rear wall. As a result, that load peaks may not be as sharp. Thus, bumper beams made of a single material often cannot be optimally designed for particular vehicles' bumper systems in terms of best localized strength properties (which needs vary along a bumper's length), low weight, and maximum value per unit weight and per unit function.
An improvement is desired that provides the advantages of extruded sections (e.g. extruded aluminum sections), and that also takes advantage of most-desired properties of aluminum, while also minimizing the least-desired properties of the aluminum. An improvement is desired that maintains a flexibility of design, yet that optimizes use of materials and their properties, including the properties of metal (aluminum) and plastic (esp. fiber-reinforced polymeric materials), especially at localized regions along a bumper beam. A design is desired that provides savings and improvements in terms of impact strength, functional and dimensional properties, and efficiency of manufacture.
In one aspect of the present invention, a bumper impact beam adapted for impact comprises an extruded aluminum section having a constant cross section; a long-fiber-reinforced polymeric elongated section positioned against a rear side of the aluminum section to define at least one closed cavity; and an adhesive integrally securing the elongated section to the aluminum section so that when impacted anywhere along a front side of the beam, the aluminum section is primarily compressed and the polymeric elongated section is primarily tensioned.
In a narrower aspect of the present invention, the aluminum section forms a forward portion of the beam and the polymeric elongated section forms a rearward portion of the beam, with abutting surfaces of the aluminum section and polymeric elongated section lying along a neutral plane, the neutral plane being defined by type of stress during an impact directed against the front side of the beam, with the type of stress being primarily compressive stress in the extruded aluminum section and primarily tensile stress in the polymeric elongated section.
In another aspect of the present invention, a beam adapted for impact, comprises an extruded section including parallel walls defining at least one rear concavity, at least one of the walls including a rearwardly-facing tip; a continuous-fiber-reinforced polymeric elongated section with forwardly-facing walls that abut the parallel walls to close the at least one rear concavity; and at least one fastener securing the polymeric elongated section to the extruded section including at the rearwardly-facing tip.
In another aspect of the present invention, a bumper impact beam adapted for impact comprises an extruded aluminum section with a rearwardly-extending wall having a rear tip defining a longitudinal channel; a long-fiber-reinforced polymeric elongated section including a forwardly-extending wall having a front tip extending into the longitudinal channel and fixed thereto.
In another aspect of the present invention, a bumper impact beam adapted for side impact, comprises an extruded aluminum section including walls defining at least one tubular concavity; and a long-fiber-reinforced polymeric elongated sheet bonded to a rear one of the walls along a center portion thereof.
In a narrower aspect of the aspect noted immediately above, a fastener secures the elongated sheet to the aluminum section, the fastener including one or both of adhesive and mechanical fasteners.
In another aspect of the present invention, a bumper impact beam adapted for impact, comprises a plurality of long-fiber-reinforced polymeric sheets with abutting edges arranged to form a geometric polygon with flat walls and corners and at least one tubular concavity; and extruded aluminum angles securing the abutting edges together at each of the corners.
In another aspect of the present invention, a method of constructing a vehicle bumper beam comprises extruding an aluminum section; forming a long-fiber-reinforced elongated polymeric section; and securing the polymeric section to the aluminum section to form at least one closed cavity; the step of securing including applying and curing adhesive.
In another aspect of the present invention, a method of forming a bumper impact beam adapted for impact, comprises providing an extruded aluminum section including walls defining at least one tubular concavity; and adhering a long-fiber-reinforced polymeric elongated sheet to a rear one of the walls along at least a center portion of the aluminum section.
An object of the present invention is to construct a beam with metal material (e.g. aluminum) in an optimal location to undergo compression during an impact against the beam, and with polymeric material (e.g. long-fiber-reinforced polymeric material) in an optimal location to undergo tension during the impact, and with adhesive and dissimilar bonded materials in an area of low stress during the impact (i.e. along a neutral plane).
An object of the present invention is to construct a beam of extruded aluminum and fiber-reinforced polymeric material, and with mechanical fasteners that hold the aluminum and polymeric material together until an adhesive cures and fully bonds abutting/adjacent materials, the fasteners also providing additional retaining strength during an impact in the fully cured beam.
An object of the present invention is to incorporate mechanical locking and adhesive-enabling features that can be integrally formed when extruding aluminum sections.
An object of the present invention is to extrude aluminum sections that are open sections (i.e. not closed tubes), thus allowing increased manufacturing efficiency when extruding the aluminum sections, yet providing a beam incorporating the aluminum sections that is a closed section so that, when impacted, it provides optimal impact bending strengths, high energy absorbing properties, high strength-to-weight ratios, high energy-absorption-to-weight ratios, and reduced total mass.
These and other aspects, objects, and features of the present invention will be understood and appreciated by those skilled in the art upon studying the following specification, claims, and appended drawings.
The present innovative system comprises an impact beam, such as can be used as a bumper reinforcement beam in vehicle bumper systems. The illustrated beam 50 of
The present innovation focuses/facilitates optimizing beams during design while maintaining flexibility of design, with the beam having optimal properties of: high impact strength at peak load, high energy absorption and acceptable energy absorption profile during an impact stroke, high impact strength per unit weight, and low total weight, while optimally meeting localized functional and strength requirements along the beam without providing “excess” material in localized areas where it is not required, and while also providing excellent and cost-effective manufacturability. In preferred embodiments, the extruded section is a high strength aluminum, which provides excellent compressive strength and excellent impact properties upon receiving a “sharp” direct impact, and which contributes to an excellent strength to weight ratio.
In a preferred embodiment, the aluminum section is an open section, such as shown in
Extruded aluminum sections incorporated into the present innovation can have many different shapes. A part of the present innovation is based on the fact that simple non-tubular extruded shapes (sometimes referred to as “open sections” or “solid profile” or “semi-hollow” profiles) can be made from classes of extrudable aluminum having a higher tensile strength than those classes of aluminum required for tubular extruded shapes. For example, the present extruded aluminum section in
Metal and FRP materials have different properties, and the present innovation is based in part on the fact that it is desirable to construct a beam optimally using these materials for localized optimal properties. In particular, extruded aluminum materials can provide good/high compressive strength and are resistant to catastrophic immediate collapse upon sharp impact loading, but they tend to have less acceptable tensile properties. Contrastingly, carbon (or other fibers such as Kevlar, etc.) fiber reinforced polymeric (CFRP) materials (also called “carbon fiber composites” herein) can provide good/high tensile strengths, but tends to have less acceptable compressive strengths, especially at high stress locations. Also, structural adhesives can provide good/high retention strength, but are susceptible to failure when unacceptably compressed or tensioned. The present innovation places extruded aluminum sections in forward locations of the beam where a front impact results primarily in compressive stresses and sharp loading, and places FRP materials in rear locations of the beam where a front impact results primarily in tensile stresses, and places adhesive close to “boundaries” of neutral stress during an impact against a side of the beam.
It is noted that the present innovation can incorporate many different types of adhesives, and that are generally well known and commercially available. The type of adhesive selected is based on functional and process requirements of the hybrid beam being constructed. However, it is noted that the structural adhesive used in the present prototype parts was a Methacrylate Adhesive, which is a two part curing adhesive. All testing was done after the adhesive was fully cured.
In the following descriptions, different embodiments use identical numbers to label identical or similar features, characteristics, aspects, and attributes, but also include a letter (e.g. “A”, “B”, “C”, etc). This is done to reduce and/or eliminate redundant discussion. Thus, a description of a first embodiment applies to and also describes later embodiments, and vice versa.
The vehicle bumper reinforcement beam 50 (
The walls 60-63 define a section having two rearwardly-facing open channels. The CFRP section 52 is C-shaped, and includes a vertical rear wall 70, a top wall 71, and a bottom wall 72. A tip of the polymeric top wall 71 extends into the channel 65 of the extrusion's top wall 61. It is contemplated that it can simply fit matably into the channel 65; or be configured to snap into an interlocked position; or be configured to rotate/tip into an interlocked position to generate self-holding friction. A two-part structural adhesive 53 in the channel 65 fills an area around the abutting material and, when cured, secured the sections 51 and 52 together. The preferred adhesive 53 is two part and cures over time and with heat. A tip of the polymeric bottom wall 72 also extends into a channel in the extrusion's bottom wall 62 and is similarly secured. A tip of the extrusion's middle wall 63 has a transverse flange 81 (also called a foot herein) that abuts the inner surface of the polymeric section 52 along its centerline. Adhesive 53 is squeezed between the transverse flange 81 and the polymeric section 52 during assembly so that, when cured, it provides good holding power. During an impact, impact forces are transmitted directly through the interface into the middle wall 63 with minimal shear, such that the abutting contact along with adhesive 53 is believed to be sufficient. It is noted that the extrusion process allows the walls 60-63 of the extruded aluminum section 51 to have different thicknesses. Thus, for example, the middle wall 63 may be made thinner, since its stresses during an impact are relatively linear and parallel to a length of the middle wall 63. Also, the middle wall 63 does not contribute as much to torsional stability of the beam 50. Contrastingly, the top and bottom walls 61 and 62, and also the front wall 60, may undergo different impact forces (e.g. bending and/or torsional and/or shearing forces), and further they must provide torsional strength to pass government (FMVSS) and insurance (IIHS) industry test standards, such that these walls will typically be thicker.
It is noted that in beam 50, the extruded aluminum section 51 is positioned on a front of the beam 50 so that, when impacted anywhere along a front half of the beam, the aluminum section 51 is primarily compressed due to bending forces on the beam. Contrastingly, the polymeric elongated section 52 is positioned so that when impacted, the polymeric elongated section 52 is primarily tensioned. Contrastingly, the adhesive 53 at the top, middle, and bottom interface joints is located along a vertical longitudinal plane of neutral stress, where stress is minimized between tension and compression.
The beam 50 can be any size required for a particular application, and can be longitudinally swept or made curvilinear to match a shape and aesthetics of a vehicle front end. For example, the illustrated beam's cross sectional size is about 120 mm high by 40 mm wide. As noted above, wall thickness depends on selection of materials and functional requirements of a particular application. In illustrated beam 50 (
Beam 50A (
Beam 50B (
Beam 50C (
Beam 50D (
Beam 50E (
Beam 50F (
Beam 50G (
Beam 50H (
Beam 50J (
In the
Beam 50K (
The beam 50K was tested to develop a curve similar to that shown in
Our testing showed that beam 50K (i.e. an aluminum extrusion forming a closed section, and including a patch of CFRP adhered partially along its rear wall) provides a very surprising and unexpected result in terms of strength and performance, even with a weight reduction. Specifically, using computer aided design analysis, we compared a beam 50K (closed aluminum section with CFRP adhered along rear wall) to a similar all-aluminum beam (i.e. similar shape and size, but no CFRP). Our testing showed that beam 50K could be made 2 kg lighter in weight yet provide an identical bending strength and performance to the all-aluminum beam. Specifically, a weight of the 50K beam was calculated to be 5.7 kg, while a weight of the all-aluminum beam was 7.7 kg, where both provided equivalent performance. This weight savings of 2 kg in view of identical performance is very surprising and unexpected to us.
Beam 50L (
The beam 50L was tested to develop a curve similar to that shown in
Thus, it is to be understood that variations and modifications can be made on the aforementioned structure without departing from the concepts of the present invention, and further it is to be understood that such concepts are intended to be covered by the following claims unless these claims by their language expressly state otherwise.
This application claims benefit under 35 USC section 119(e) of U.S. Provisional Patent Application Ser. No. 62/087,950 entitled BEAM USING ALUMINUM EXTRUSION AND LONG-FIBER REINFORCED PLASTIC, filed Dec. 5, 2014, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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62087950 | Dec 2014 | US |