Vehicle Panel Research Articles

Reduced order modeling for the skin panels of hypersonic vehicles and nonlinear normal modes

The skin panels on concept hypersonic (Mach > 5) vehicles are subjected to intense acoustic and thermal loading. As a result, nonlinear structural dynamic models are needed to predict their response with the required level of accuracy. Vehicles such as this carry a large amount of fuel and so the structure must be very light if the overall vehicle is to meet its performance requirements. This talk will discuss the reduced order modeling frameworks that are being used to create models for these types of structures and discuss how nonlinear normal modes are being used to understand how the structure’s response changes with the loading amplitude. Nonlinear modes are also being used to evaluate the reduced order models in order to predict the frequency bandwidth and the range of forcing amplitude over which they will be valid. This approach allows the analyst to develop a considerable level of confidence in the reduced order model without having to compute time responses of the full nonlinear finite element model; time response simulations are far too expensive to be used in practice on the structures of interest.

Discrimination of acoustic and turbulent components from aeroacoustic wall pressure field

The investigation of the wall pressure excitations over transportation vehicle panel is of great interest to improve the knowledge of vehicle interior noise transmission and also for future noise reduction strategies. A particularly useful task concerns the characterization and the separation of both acoustic and turbulent components of the wall pressure excitation. A new application of the Proper Orthogonal Decomposition (POD) is tested from two different databases: (i) wall pressure fields synthesized from theoretical average models and (ii) wall pressure fields obtained from Lattice Boltzmann Method numerical simulation. In each case, POD application leads to an energetic partitioning of the wall pressure field that permits to well decouple both acoustic and turbulent fields, especially for mid and high frequencies under interest. To validate such separation and to demonstrate the effectiveness of the POD method, the wavenumber spectrum analysis as well as phase analysis is successively performed. Such a new splitting method provides an instantaneous acoustic-turbulent separation of an inhomogeneous wall pressure field, suggesting many useful future applications.

Rapid 3D Modeling and Parts Recognition on Automotive Vehicles Using a Network of RGB-D Sensors for Robot Guidance

This paper presents an approach for the automatic detection and fast 3D profiling of lateral body panels of vehicles. The work introduces a method to integrate raw streams from depth sensors in the task of 3D profiling and reconstruction and a methodology for the extrinsic calibration of a network of Kinect sensors. This sensing framework is intended for rapidly providing a robot with enough spatial information to interact with automobile panels using various tools. When a vehicle is positioned inside the defined scanning area, a collection of reference parts on the bodywork are automatically recognized from a mosaic of color images collected by a network of Kinect sensors distributed around the vehicle and a global frame of reference is set up. Sections of the depth information on one side of the vehicle are then collected, aligned, and merged into a global RGB-D model. Finally, a 3D triangular mesh modelling the body panels of the vehicle is automatically built. The approach has applications in the intelligent transportation industry, automated vehicle inspection, quality control, automatic car wash systems, automotive production lines, and scan alignment and interpretation.

A study on mechanical characteristics of the friction stir welded A6005-T5 extrusion

In this paper, A6005-T5 extruded aluminum alloy sheets which are used for floor, roof or wall panels of railroad vehicles were welded by the friction stir welding (FSW) and gas metal arc welding (GMAW) techniques. The mechanical characteristics including the tensile strength, micro-hardness and fatigue strength of the FSW joint were compared to those of the base metal and GMAW joints. In order to determine the relationship between the welding variables of FSW and the mechanical characteristics of the joint, the response function was derived using the least square method and the sensitivity analysis was performed. The rotational speed, welding speed and tilting angle of the welding tool were chosen as design variables. On the basis of the Plackett-Burman design table, eight different FSW experiments were done, and then the effects of design variables on the mechanical characteristics of the FSW joint were analyzed. The result showed that the welding speed has a most significant effect on the tensile and fatigue strength. In the case of the micro-hardness, the effect of the tilting angle was the biggest.

Integrated multiscale product and process control of polymeric coating curing

In automotive coating manufacturing, control of curing of thin films of wet paint on vehicle panels is always a very challenging operational task. This is especially true when both process efficiency and product quality need to be controlled simultaneously. The challenges in this task are multiple. First, coating quality is not measurable online and its characterization is multiscale in length and time. Second, coating curing is a multistage process where heat and mass transfer and polymerization take place also in multiscale of length and time, most of which are not measurable online either. In this paper, we introduce an integrated multiscale product and process control (IMPPC) scheme that can be used to control effectively the reactive drying process. By resorting to this scheme, a set of advanced methodologies for multiscale modeling, model simplification, and multiscale controller synthesis can be seamlessly integrated to construct a high-performance control system. It is demonstrated that this control system has extraordinary performance on set-point tracking and disturbance rejection. Most importantly, it offers unique opportunities to achieve all-time on-aim control of both coating quality and process performance covering a wide range of time and length scales.

Mechanical Behaviour of Duplex Phase Structures in a Medium Carbon Low Alloy Steel

The mechanical behaviour of duplex phases produced in a medium carbon low alloy steel with potentials for use as machine body parts and vehicle panels, has been investigated. A representative composition of the steel (C: 0.3; Si: 0.28; Mn: 0.97; Cr: 0.15) was utilized to produce ferrite – martensite duplex phases of varied proportions by intercritical annealing treatment. The tensile, hardness, and rotating bending fatigue behaviour of the structures were studied; and optical and SEM microscopy utilized to characterize the microstructures and their fracture characteristics. The duplex phase structures exhibited continuous yielding behaviour; and were characterised by high strain hardenability, high tensile strength, total elongation, toughness and superior fatigue strength (endurance limit) in comparison with the normalised structure. The fatigue fracture was observed to be characterized by mixed mode of ductile (dimple) fracture and intergranular brittle cleavage for the duplex structures. Superior tensile and fatigue property combinations were better harnessed when treatment was performed at 760 0 C and 780 0 C in comparison to 740 0 C.

MATERIALS SCIENCE: Bringing Biolubricants to Industry

Up to 50% of lubricants used around the world are lost to the environment through evaporation, spills, leaks, and improper disposal, and contaminate soil and groundwater. “It’s an underappreciated source of pollution,” says Brajendra K. Sharma, a visiting research chemist at the U.S. Department of Agriculture (USDA) National Center for Agricultural Utilization Research in Peoria, Illinois. Now vegetable-based biolubricants offer an alternative to petroleum-based lubricants in a range of machinery, from elevators to ski lifts to chainsaws. Vegetable oils have inherent disadvantages that limit their use in industrial applications, mainly destruction by oxygen, deterioration at high temperatures, and solidifying at low temperatures. Sharma and his colleagues designed a process to overcome these problems that requires a few simple steps such as adding an antioxidant. According to the researchers, the process generates no toxic products and uses existing equipment at facilities that manufacture petroleum-based lubricants. “Simple chemistry and compatibility with existing operations are keys to getting industry to adopt our lubricants,” says Sevim Erhan, formerly a chemist at the Peoria center and now director of the USDA Eastern Regional Research Center in Wyndmoor, Pennsylvania. She adds, “Our main goal is to make 100% biodegradable lubricants with nonpolluting processes to replace petroleum products.” One antioxidant that has proven especially effective, zinc dialkyldithiocarbamate, is “not considered hazardous,” according to its Material Safety Data Sheet but nonetheless should be kept out of contact with soil, waterways, drains, and sewers. Because performance requirements of lubricants differ for various industries, the team is exploring additional chemical modifications. In the September 2009 issue of the Journal of Agricultural and Food Chemistry, for instance, Sharma and colleagues described how they converted oleic acid to a stable form by adding formic acid and hydrogen peroxide, using aniline as a catalyst, and heating the mixture for several hours. This “one pot” synthesis was easily performed and gave good yields, and the liquids used were recovered and recycled. A few industries have adopted biolubricants. Since 2002, elevators in the Statue of Liberty have run on biodegradable hydraulic fluid. Hydraulic systems are prone to leaks, leaving puddles at the bottom of elevator shafts that run deep underground, raising the risk of ground water contamination. “But soybean oil readily degrades, and there’s little harm to the environment,” says Jack Stover, president of Agri-Lube, Inc., in Defiance, Ohio, who licensed the USDA technology. The soybean-based hydraulic fluid shows excellent anti-friction and anti-wear properties and is less flammable than petroleum-based counterparts. Penn State University in University Park switched all campus elevators and farm equipment to biodegradable hydraulic fluid. “About 35,000 gallons of oil in elevators has been replaced, and that’s a significant amount,” says Joseph Perez, a senior research scientist in the university’s Department of Chemical Engineering. Aluminum producer Alcoa, Inc., changed to biolubricants for its flat-rolling operations. During rolling, thick slabs of aluminum are flattened under heavy rollers into thin sheets that are shaped into vehicle panels, doors, beverage cans, and more. Lubricants are used in such operations to hold the aluminum and rollers together and dissipate heat. Ronald Reich, a technical consultant at Alcoa, collaborated with the USDA to create a biolubricant to replace petroleum-based lubricants that emit volatile organic compounds, which can cause eye and airway irritation, headaches, and other health problems. Because biolubricants are less volatile than petroleum-based lubricants, “we use less biolubricant to do the same job at a cost savings,” says Reich. Generally, biolubricants cost about twice as much as petroleum-based products, which hinders their adoption by more industries. “Biodegradable lubricants are a niche market right now,” says Perez. However, a rise in crude oil prices could make biolubricants more cost-competitive. “Ultimately, it all boils down to cost,” says Sharma.

The Application of Reverse Engineering in the Design of Electric Vehicle Panel

Reverse engineering is a new modern product design technology, which is suitable for designing complex curve and surface, has been becoming a practical and widely-available engineering tool in panel design of automotive, motorcycle and electric vehicle. This paper first expatiates on the basic theory of structured light measurement system, registration algorithm of multi-view point cloud data and the basic principle of curve and surface reverse design, and then gives an application example in the 3D design of electric vehicle front panel.

Structural-Acoustic Optimization of Sandwich Panels

Sandwich panels comprising face sheets enclosing a core are increasingly common structural elements in a variety of applications, including aircraft fuselages, flight surfaces, vehicle panels, lightweight enclosures, and bulkheads. This paper presents the optimization of various innovative sandwich configurations for minimization of their structural-acoustic response. Laminated face sheets and core geometries comprising honeycomb and trusslike structures are considered. The design flexibility associated with the class of considered composite structures and with truss-core configurations provides the opportunity of tailoring the structure to the load and dynamic response requirements of a particular application. The results demonstrate how the proper selection of selected key parameters can achieve effective reduction of the radiated sound power and how the identified optimal configurations can achieve noise reduction over different frequency ranges and for various source configurations.

Application of electromagnetic-assisted stamping (EMAS) technique in incremental sheet metal forming

The application of high velocity electromagnetic-assisted stamping (EMAS) technique in incremental sheet metal forming has been proposed. EMAS whose principle is based on Lorenz force is a hybrid forming process that uses both quasi-static conventional stamping technique and electromagnetic forming actuators built into sharp corners and other difficult-to-form contours to form metals. The recent push to use more artificial intelligent (AI) aluminum alloys in automobile and aircraft industries as a result of increasing demand for fuel efficient cars and aircrafts, large size vehicle panels, improved formability limit of materials and weight reduction have placed EMAS as one of the best high velocity forming technique. It is believed that the end result of this vision will lead to more cost effective land and aerospace vehicles.

Developments in structural-acoustic optimization for passive noise control

Low noise constructions receive more and more attention in highly industrialized countries. Consequently, decrease of noise radiation challenges a growing community of engineers. One of the most efficient techniques for finding quiet structures consists in numerical optimization. Herein, we consider structural-acoustic optimization understood as an (iterative) minimum search of a specified objective (or cost) function by modifying certain design variables. Obviously, a coupled problem must be solved to evaluate the objective function. In this paper, we will start with a review of structural and acoustic analysis techniques using numerical methods like the finite- and/or the boundary-element method. This is followed by a survey of techniques for structural-acoustic coupling. We will then discuss objective functions. Often, the average sound pressure at one or a few points in a frequency interval accounts for the objective function for interior problems, wheareas the average sound power is mostly used for external problems. The analysis part will be completed by review of sensitivity analysis and special techniques. We will then discuss applications of structural-acoustic optimization. Starting with a review of related work in pure structural optimization and in pure acoustic optimization, we will categorize the problems of optimization in structural acoustics. A suitable distinction consists in academic and more applied examples. Academic examples iclude simple structures like beams, rectangular or circular plates and boxes; real industrial applications consider problems like that of a fuselage, bells, loudspeaker diaphragms and components of vehicle structures. Various different types of variables are used as design parameters. Quite often, locally defined plate or shell thickness or discrete point masses are chosen. Furthermore, all kinds of structural material parameters, beam cross sections, spring characteristics and shell geometry account for suitable design modifications. This is followed by a listing of constraints that have been applied. After that, we will discuss strategies of optimization. Starting with a formulation of the optimization problem we review aspects of multiobjective optimization, approximation concepts and optimization methods in general. In a final chapter, results are categorized and discussed. Very often, quite large decreases of noise radiation have been reported. However, even small gains should be highly appreciated in some cases of certain support conditions, complexity of simulation, model and large frequency ranges. Optimization outcomes are categorized with respect to objective functions, optimization methods, variables and groups of problems, the latter with particular focus on industrial applications. More specifically, a close-up look at vehicle panel shell geometry optimization is presented. Review of results is completed with a section on experimental validation of optimization gains. The conclusions bring together a number of open problems in the field.

Designing inner hood panels through a shape grammar based framework

A framework for a design tool based on shape grammars is presented as an effective means for supporting the early stages of design. The framework uses a shape grammar interpreter to implement parametric shape grammars, allowing the grammar to be used interactively by a designer or optimization routine. A shape grammar to design inner hood panels of vehicles is introduced as an example of a parametric engineering shape grammar, and it is used with the framework to create standard and novel designs made possible by rules that take advantage of shape emergence.

First-order zig-zag sublaminate plate theory and finite element model for laminated composite and sandwich panels

A refined laminated plate theory and three-dimensional finite element based on first-order zig-zag sublaminate approximations has been developed. The in-plane displacement fields in each sublaminate are assumed to be piecewise linear functions and vary in a zig-zag fashion through-the-thickness of the sublaminate. The zig-zag functions are evaluated by enforcing the continuity of transverse shear stresses at layer interfaces. This in-plane displacement field assumption accounts for discrete layer effects without increasing the number of degrees of freedom as the number of layers is increased. The transverse displacement field is assumed to vary linearly through-the-thickness. The transverse normal strain predictions are improved by assuming a constant variation of transverse normal stress in each sublaminate. In the computational model, each finite element represents one sublaminate. The finite element is developed with the topology of an eight-noded brick, allowing the thickness of the plate to be discretized into several elements, or sublaminates, where each sublaminate can contain more than one physical layer. Each node has five engineering degrees of freedom, three translations and two rotations. Thus, this element can be conveniently implemented into general purpose finite element codes. The element stiffness coefficients are integrated exactly, yet the element exhibits no shear locking due to the use of an interdependent interpolation scheme and consistent shear strain fields. Numerical performance of the current element is investigated for a composite armored vehicle panel and a sandwich panel. These tests demonstrate that the element is very accurate and robust.

A combined experimental/FEM model for predicting vehicle panel acoustic noise contribution

Radiated acoustic noise contributions from the structural panels that form the inner shell of the vehicle body to the interior sound pressure response are modeled using an approximate spectral formulation. The approach essentially utilizes the theoretical interior acoustic sensitivity terms derived from a finite element model and measured spatial-averaged structural-acoustic spectra. The finite element calculation is validated by comparison to a set of experimental acoustic transfer functions. In addition, an experimental setup for measurement of the sound intensity and structural-acoustic response is used to acquire the cross and auto power spectra needed to predict the relative mean-squared velocity term of each control plane near the panel surface. These velocity functions are then combined with the acoustic sensitivity terms to compute the individual panel contribution function. The proposed approach is applied to a specific case of a passenger car to compute the acoustic noise spectra in 1/12 octave band form at selected positions in the passenger compartment. The calculations show excellent match with the overall experimental results. Also through this example, the approximate computational scheme is proven to be generally quite robust and effective for analyzing higher frequency interior noise problems.

Thermal Effects on Chaotic Vibrations of Plates

In recent years the investigation of dynamical behavior of plates under thermal loads has become important because of the high temperatures reached on external skin panels of hypersonic vehicles. Other researchers have indicated that the skin panels may encounter chaotic vibrations about their thermally buckled positions. In this research the chaotic vibrations of simply supported plates under thermal and sinusoidal excitation is studied to determine the predictability of the vibratory behavior of a representative class of such skin panels. The boundaries of regular and chaotic regions of motion are defined in force-temperature and force-frequency planes and the sensitivity of these boundaries to changes in design parameters is explored for the purpose of developing useful design criteria The onset of chaos is predicted through the computation of Lyapunov exponents. The effects of thermal moment and thermal buckling on chaos are studied. The results of the research are presented as a contribution to the panel design of hypersonic vehicles.

Article Reviews : ON THE HYDRODYNAMIC DESIGN OF ACTIVE PANELS OF MARINE VEHICLES M.E. McCormick and S.E. Mouring ASME J. of Offshore Mechanics and Arctic Engineering, 117, pp 1-5 (Nov 1995)

Article Reviews : ON THE HYDRODYNAMIC DESIGN OF ACTIVE PANELS OF MARINE VEHICLES M.E. McCormick and S.E. Mouring ASME J. of Offshore Mechanics and Arctic Engineering, 117, pp 1-5 (Nov 1995)

Matching vehicle parts back to the vehicle: a study of the process

Some elaborate car theft schemes have involved the removal of vehicle panels. Matching vehicle panels back to the chassis from which they have been stripped typically relies on the comparison of the paint layers on the panel and the car. A new method of comparison involves comparison of the areas of close contact between the panels and the chassis. In these areas, patterns can be formed by the capillary action of the surface coatings into the gaps between the panels and the chassis. These patterns are random and therefore unique to each different contact area allowing panels to be conclusively matched back to the chassis. A study of the manufacturing process in a vehicle assembly plant in New Zealand was conducted and confirmed the uniqueness of the patterns.

Experience predicting structure‐borne noise within a prototype rectangular acoustical enclosure

Approximately 10 years ago a large rectangular enclosure was designed and constructed using a steel super‐structure and sand‐filled, double‐panel plywood walls. The enclosure is approximately the size of a transportation vehicle passenger cabin (1.85 m by 1.05 m by 1.05 m). The enclosure was built such that any of the walls could be replaced with more realistic structures such as vehicle panel constructions. The enclosure has been modified many times to accommodate various experimental apparatus. In this paper, the design of the enclosure will be described and some of the original data used to verify its characteristics will be shown. Recently, the enclosure has been modified to resemble structure (f) described by the Structure‐borne Noise Committee of INCE‐USA. One wall of the structure has been replaced by a simply supported panel. Experimental results have been compared to analytical and numerical predictions for both internal acoustic excitation and mechanical excitation of the panel. These results will be discussed. In addition, an effort has been made to design a small version of this enclosure which could be used for round robin testing. Preliminary results of this effort will also be discussed.

Improvement of noise reduction performance by decreasing air-flow resistance ff sound insulation materials

Conventionally, sound insulation materials have been applied to control interior noise above 500 Hz, and damping materials to control interior noise below 500 Hz. In this paper, the acoustical materials for vehicle panels, which consists of damping materials and sound insulation materials, are investigated by using a two-degrees-of-freedom system. The investigation shows that sound insulation materials can become effective to reducing interior noise below 500 Hz byducin their stiffness. This stiffness depends on not only the spring of the material itself but also on the pneumatic spring which is determined by air-flow resistance. This paper concludes with applications of techniquws to reduce interior noise below 500 Hz by improving sound insulation materials.

Supersonic flutter of laminated circular cylindrical shell panels

OMPOSITE materials are used in the construction of curved panels of aircraft and space vehicles. Only a few works1'3 are available on panel flutter analysis of shell panels. In this investigation, circular cylindrical shell panels of rectangular planform, with edges clamped laterally and free from in-plane stresses (movable edges), are considered. The panel is subjected to supersonic flow parallel to the generator on one side only. The aerodynamic forces are approximated by using two-dimensional quasisteady aerodynamic theory. The problem is solved by using the integral equation technique. Formulation A typical cross-ply laminated panel is shown in the inset of Fig. 1. Two fourth-order aeroelastic governing differential equations, based on DonnelPs shallow shell approximation, can be derived in terms of the transverse displacement w and stress function F.4 They are