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Back to the non Flex Fuel vehicles, the knock control system was designed and calibrated to absorb differences between engines (mainly compression ratio) and to protect the engine against knock damage (a correction up to 4 degrees BTDC was usually enough). But now, two new variables get in the scene: Flexible Fuel strategy, working from E22 to E100 (all blends in between) and small displacement (1.0 liter) high compression ratio engines. In this new scenario the system must be capable of correcting all spark advance differences, once knock control system acts as a safety feature, protecting the engine even if the fuel learning shows some deviation. In addition to that, we have the compression ratio variation between minimum and maximum limits. Since the engine is small (as well its combustion chamber), each tenth of a millimeter difference during manufacturing process, results in an important final compression ratio variation.

In the engine management systems field, there is lack of sensors locally built and available for sale in Brazil. Therefore, many auto parts companies have to import them affecting directly the final products costs (technology know-how/development costs, import taxes and other material handling/custom related costs). This paper was motivated to study an alternative for a simple, cheaper and locally made throttle position sensor. The choose of this part was because the fact that it is one of the most expensive in the throttle body bill of. For developing this new alternative, it was used a tool called value analysis and value engineering. The outcome of this study was a throttle position sensor function integrated to the throttle body manufacturing line with the advantages that 100% components can be locally purchased, improved robustness against humidity and component quantity reduction by 40%. Therefore achieving more value added.

It is the overall objective in the development of automotive climate control systems to guarantee a subjective feeling of thermal comfort for each passenger. The fulfillment of all physical specification parameters of a HVAC unit, such as airflow, temperature, etc., does not automatically achieve this goal. Engineers need to ensure that the consequences of the HVAC design lead to the desired demands inside the passenger compartment. In this paper a method will be presented that enables a time dependent detailed prediction of personal thermal comfort for each passenger in standard cooldown or warm-up tests. In addition to calculating overall comfort ratings for each passenger, transient local body segment comfort ratings can be calculated to determine local variations in comfort. It is therefore possible to discover reasons for potential discomfort in a much more detailed way. To accomplish this, mannequins are added to the CFD model of the cabin.

The analysis of airflow in an automotive HVAC cowl box is complicated by the cross sectional variations and abrupt changes in airflow direction. In this study, the complex three-dimensional turbulent flow found in a generic road vehicle cowl box is investigated experimentally and computationally. An optical anemometer is used to acquire the experimental data within a white metal sheet of a cowl box. The results are then used to validate and tune a Computational Fluid Dynamics (CFD) numerical cowl model.

The analysis of airflow in an automotive HVAC cowl box is complicated by the cross sectional variations and abrupt changes in airflow direction. In this study, the complex three-dimensional turbulent flow found in a generic road vehicle cowl box is investigated experimentally and computationally. An optical anemometer is used to acquire the experimental data within a white metal sheet of a cowl box. The results are then used to validate and tune a Computational Fluid Dynamics (CFD) numerical cowl model.

The drive to reduce weight, simplify assembly, and cut total system cost in today's vehicles is relentless. Replacing metal systems with thermoplastics has been of considerable interest in the engineering community. The current generations of engineering thermoplastic resins are enabling the use of plastic systems in demanding underhood applications. Technical data and discussion regarding the materials, design, molding, and assembly of lightweight composite throttle bodies will be presented in this paper. Comparisons with machined aluminum throttle housings are drawn to establish a baseline with the throttle body housing component that is most common in production today. Design flexibility and process simplification are some of the approaches highlighted. Much of the technical information provided in the paper applies to both cable driven mechanical throttle bodies as well as electronic throttle bodies under development.

A closed loop full-scale automotive climatic wind tunnel is described. The tunnel simulates wind and rain as well as several road conditions. It generates under controlled heat loading, wind speeds of up to 50kmh with different approach boundary conditions, rains from drizzle to cloudburst and road inclines up to 15° in any direction. The design and optimization process of the tunnel functions is outlined and examples of its use in vehicle development are given. The size constraint and the need for a compact design are important features of the tunnel. The tunnel provides an important test bed for close scrutiny of the relationship between rain ingress, vehicle speed, road condition, heat loading and vehicle geometry. The tunnel can also be used to study vehicle thermal management, vehicle thermal comfort, engine cold starting, and wipers efficiency in sever cold weather.

An accelerated seat durability test was developed to identify potential problems in areas with traditionally high warranty cost and customer dissatisfaction: squeak & rattle and mechanism looseness & efforts. The test inputs include temperature, humidity, road vibration, occupant movements, and mechanism cycling. These inputs were combined into a single 14-day test profile that simulates 10 years and 250,000 km. (approximately 150,000 miles) of 95th percentile customer usage. Various components of the seat assembly are tested together as a system. The test was performed on two current production programs. The test produced issues similar to those found in warranty repair data and evaluations of used seats from high-mileage customer-owned vehicles.

A building-block method, often used for simulating automotive systems, is described in this paper for simulating a driveline system. In the method, a driveline supplier's design responsible components are modeled with explicit FE models. Model accuracy is verified by testing and correlating the components in a free-free condition. Non-design responsible components are modeled using lumped parameters and/or modal models. These components and the validated design responsible components are integrated into a system model and connected using simple lumped parameter connections. Correlation at the system level is performed by making adjustments to the connection parameters and to the parameters of the non-design responsible components. The resulting system model has been used to accurately predict operating responses in a driveline system.

A design framework based on the principles of lean manufacturing and axiomatic design was used as a guideline for designing an automotive component manufacturing system. A brief overview of this design decomposition is given to review its structure and usefulness. Examples are examined to demonstrate how this design framework was applied to the design of a gear manufacturing system. These examples demonstrate the impact that low-level design decisions can have on high-level system objectives and the need for a systems-thinking approach in manufacturing system design. Results are presented to show the estimated performance improvements resulting from the new system design.

Plastics manufacturing technology is rapidly changing. The use of process simulation to increase competitiveness has proliferated. Visteon Automotive Systems is committed to developing competent workforce and niche capabilities in plastics processing simulation. In this paper the current capabilities and future development plan for plastic process simulation are discussed. An integrated concurrent engineering process has been developed and implemented to deliver high quality robust plastics automotive products and systems. This paper highlights the technological advancements achieved by Visteon in the field of analytical simulation of common manufacturing processes. In addition, future development initiatives towards the technical competency in plastics manufacturing simulation are discussed throughout the manuscript.

In a joint effort between Ford Motor Company, Visteon Automotive Systems, Textron Automotive Company, and Dow Automotive the 1999 Mercury Cougar instrument panel (IP) was designed and engineered to reduce the weight and overall cost of the IP system. The original IP architecture changed from a traditional design that relied heavily upon the steel structure to absorb and dissipate unbelted occupant energy during frontal collisions to a hybrid design that utilizes both plastic and steel to manage energy. This design approach further reduced IP system weight by 1.88 Kg and yielded significant system cost savings. The hybrid instrument panel architecture in the Cougar utilizes a steel cross car beam coupled to steel energy absorbing brackets and a ductile thermoplastic substrate. The glove box assembly and the driver knee bolster are double shell injection molded structures that incorporate molded-in ribs for added stiffness.

The work described in this paper was carried out on a specialist engine dynamometer which allows accurate simulation of in-vehicle conditions. This is achieved by the use of a clutch between the engine and dynamometer which allows realistic simulation of gearchanges. The presence of a clutch means that the dynamometer has two distinct modes of operation, corresponding to a engaged or disengaged clutch. This paper describes the design of a speed control scheme, providing bumpless transfer between two controllers, which has been developed to satisfy the differing control requirements of disengaged and engaged operation. Brief discussion of the controllers and bumpless transfer scheme is followed by presentation of test results. Finally, the performance of this scheme is compared with that of an existing hardware controller.

Microprocessors and microcontrollers are now widely used in automobiles. Microprocessor systems contain sources of interrupt and interrupt service routines, which are software components executed in response to the assertion of an interrupt in hardware. A major problem in designing the software of microprocessor systems is the analytical treatment of interrupt latency. Because multiple interrupt service routines are executed on the same CPU, they compete for the CPU and interfere with each other's latency requirements. Here, interrupt latency is defined as the delay between the assertion of the interrupt in hardware and the start of execution of the associated interrupt service routine. It is estimated that 80% of intermittent bugs in small microprocessor software loads are due to improper treatment of interrupts. Until this work, there is no analytic method for analyzing a particular system to determine if it may violate interrupt latency requirements.

Visteon Automotive Systems has developed an Electro-Hydraulic Power Assist Steering (EHPAS) System. This low-cost system uses conventional hydraulic power steering components with an electrically-driven and electronically-controlled power steering pump. This paper presents the Visteon EHPAS system and its development process. This process began with analytical modeling of the EHPAS system and integration of these models with a two degree of freedom (2DOF) vehicle model. These models were critical for system analysis and control strategy design. The EHPAS system sizing procedure and control strategy performance optimization were verified with the use of a real-time computer designed by Ford Motor Company, and by specially-designed Visteon test benches. Finally, EHPAS equipped test vehicles were tuned for high performance, providing better feel and fuel economy than conventionally equipped base line vehicles.

This paper highlights the application of design optimization in reducing product manufacturing cost without compromising product performance. By using a topology optimization method, the manufacturing cost of a clam shell has been reduced by approximately one-third, while maintaining the NVH performance of the steering column that is connected to the instrument panel (IP) through the clam shell. Two different optimization approaches and two different topological weld deployments are investigated. It is found that a fully-deployed seam weld approach with automatic optimization provides the best design results.

This paper reviews the physics-of-failure model for accelerated thermal cycle tests of solder joints associated with various electronics components, summarizes the parameters of the automotive environment, and discusses the methods for developing thermal cycle tests for reliability validation for automotive electronics. The paper proposes an approach to develop the requirements for validation tests based on the customer usage profiles and the desired product life goal. This requirement determines the nominal testing duration based on the equivalent damage generated from the worst-case field applications.

During the conceptual design stages of an instrument panel (IP) structure, various alternatives in architecture need to be evaluated. This entails being able to obtain a quick assessment of how the designs roughly compare in structural performance. The current climate of reduced cycle times dictates that quick and inexpensive CAE techniques be employed for this purpose. This paper describes the background of a design process in which Computer Aided Engineering (CAE) models, fully associative with the underlying 3D solid model, are rapidly generated for use in structural vibration, thermal and crash analysis.

This paper describes a method for calculating the temperature of a semi-infinite heat sink plate of a given thickness, subjected to transient heating by a D2Pak power IC. Accurate prediction of the heat sink temperature over time then allows for more accurate calculation of the IC junction temperature. A set of curves have been developed for the time variation of heat sink plate temperature. This has been achieved by the use of finite element methods, and modeling a large range of configurations. The system variables were put into dimensionless form, and the model results plotted. The resulting plot indicates an effective thermal resistance of a given heat sink plate at a given point in time. A curve fit has also performed on the results. The results of the finite element model have been compared with laboratory data.