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The effect of cross-section and type of alloy on the performance of aluminum extrusions as door beams was investigated. As a result, aluminum door beams were developed which have bending properties comparing favorably with those of door beams made of high tensile strength steel with a tensile strength of 1470 N/mm2. Furthermore, a technology to design door beams with the required performance and bending properties dealing with various car models was developed by making the most of the versatility of aluminum extrusions produced in various types of cross-sections.

Filiform corrosion phenomenon and its prevention method for 5000 series aluminum alloy sheet have been investigated. The painted aluminum alloy sheets were subject significantly to filiform corrosion caused by formation of a mottled and coarse zinc phosphate film during chemical conversion process. On the other hand, galvanized aluminum alloy sheet showed an uniform and fine phosphate film in a brief time and the filiform corrosion resistance was improved markedly. The test results of press-forming and corrosion for the prototype engine hoods made of this newly developed galvanized sheets have revealed a good formability and an excellent filiform corrosion resistance.

This paper reports a method to evaluate structural performance of extruded aluminum thin-walled box section beams for automobile bumper reinforcement. According to U. S. Federal safety performance requirements for automobile bumper systems, the systems should be able to bear the dynamic load of pendulum impact. To evaluate performance of the bumper system, two stages of research were executed: (1) Bending tests and analyses under quasi-static loading, and (2) Dynamic pendulum tests and their simulation using the finite element method. As a result of these investigations, the relationship between the collapse moment of the beam and the permanent set caused by pendulum test, the effect of absorbers, and the effect of torsional force are discussed.

This paper studies the influence of welding parameters on the mechanical properties of butt joints, using aluminum plates, extrusion and casting by CO2 laser. As a result of this study, good welds have been obtained by optimum power output of laser and welding speed for each material. It also shows that the feeding of filler metal can improve joint efficiency and can perform tensile failure position away from weld metal and can extend the tolerance of root gap for butt joints. These technique lead to improve joint strength of laser welds as strong as that of arc welds. Also bending property and fatigue strength are equal to that of other conventional welds. This investigation confirms that laser welding for joining of aluminum alloys can be used, and that the techniques in this study will be able to be applied for automobile structures.

This paper discusses a portion of a larger program on filiform corrosion concentrating on test methodologies and environmental mechanisms that contribute to filiform corrosion. It is organized into four sections, the first covers background of filiform corrosion, materials used in the study, and procedures for the sample preparation and testing. Following this, there are sections on outdoor testing, accelerated testing, and environmental parameters all of which include some procedural information, results and conclusions.

Increasing use of aluminum in automotive components has led to lower fuel consumption and enhanced performance of automotive designs. From a manufacturing standpoint, aluminum provides the additional advantage of utilizing same processes as steel. Performance and durability of painted aluminum cars, however, is dependent on proper optimization of process conditions. As part of an extensive study of factors influencing corrosion resistance of painted aluminum, the present study deals with the influence of pretreatment and coating variables and the interaction of alloy composition with zinc phosphate and electrocoat. Interfacial analysis of corrosion products indicates the relative influence of alloying elements on stability of the metal/phosphate/electrocoat interface. As a result, guidelines and recommendations on aluminum processing in an automotive manufacturing floor have been developed.

In order to simulate the perforation corrosion of an automobile, hem model samples made of various kinds of coated steel sheets were set inside of the door outer panel and the door was exposed in the open air with once a week 5% salt spraying. After two years, the model samples were disassembled for investigation. Perforation corrosion occurred most severely just above the lapped portion of outer and inner specimens. Red rust samples taken from the hem model and from a field vehicle run in Detroit did not show clear pearks of spectra by X-ray diffraction analysis, whearas the one formed by a conventional cyclic corrosion test showed peaks of Fe3O4. These facts indicate that this new test well simulates the corrosion environment of an actual automobile hem portion. Corrosion resistance of many kinds of coated steel sheets was studied by this new test method. Perforation depth became smaller as a coating weight of pure zinc electroplated steel sheet increased.

A thin organic coated steel sheet (HI-SUPER-DN) has been recently developed for automotive body panel applications. The steel sheet consists of a Zn-Ni alloy-plated layer, a chromate film and a thin organic coated layer, which is composed of colloidal silica, organic polymer and an organic additive. Corrosion resistance, formability of the coated layer, weidability and electropaintability of the steel sheet required for automotive body panel were studied. An increase in the colloidal silica in the organic coated layer improves corrosion resistance. However, the formability of the organic coated layer deteriorates with such as increase in the colloidal silica. We have optimized the ratio of colloidal silica to organic polymer so as to balance both the corrosion resistance and the formability of the organic coated layer. Futhermore, the bake-hardenability of the steel sheet was maintained by a relatively low temperature baking of the chromate film and the organic coated layer.

Amidst of the recent concerns on depletion of natural resources, a new heat resistant titanium alloy has been developed using the minimum amount of rare metals. Using Ti-811 as a basis and modifying the alloy composition to Ti-7Al-2Mo-0.2Si-0.15C-0.2Nb, the mechanical property, the creep resistance and the oxidation resistance at high temperatures are improved. At the same time, with the β transformation point shifted to a higher temperature, the hot formability is also improved. The newly developed alloy has made it possible to expand the application of titanium material to exhaust valves in reciprocating engines.