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The application of polyalkylene glycol (PAG) as a base stock for engine oil formulation has been explored for substantial fuel economy gain over traditional formulations with mineral oils. Various PAG chemistries were explored depending on feed stock material used for manufacturing. All formulations except one have the same additive package. The friction performance of these oils was evaluated in a motored single cylinder engine with current production engine hardware in the temperature range 40°C-120°C and in the speed range of 500 RPM-2500 RPM. PAG formulations showed up to 50% friction reduction over GF-5 SAE 5W-20 oil depending on temperature, speed, and oil chemistry. Friction evaluation in a motored I-4 engine showed up to 11% friction reduction in the temperature range 40°C-100°C over GF-5 oil. The paper will share results on ASTM Sequence VID fuel economy, Sequence IVA wear, and Sequence VG sludge and varnish tests. Chassis roll fuel economy data will also be shared.

Field cracking in some instrument panels (IP) manufactured with a competitive grade of polycarbonate/acrylonitrile-butadiene-styrene (PC/ABS) material was observed in high temperature/high humidity geographies. OEMs and tier molders are: 1) questioning the thermal and hydrolytic stability of the various suppliers' PC/ABS resins, and 2) converting to grades with advantaged stability. A study was undertaken to compare the thermal and hydrolytic stability of two suppliers' high flow PC/ABS resins. Materials were aged at 90C/95% relative humidity up to 1000 hours. Samples were tested to compare the retention of properties. This paper will discuss the experimental procedures, resulting data, and the common factor in the PC/ABS resins showing the best stability.

To address the automotive industry's initiative to maximize the utility of each component by decreasing both weight and cost to improve the performance and value of its products, it is logical to try to minimize the thickness of any part whose main function is ostensibly decorative. A example of such a candidate part on the vehicle would be the fascia and body side claddings. The fascia and claddings of vehicles do provide some impact resistance and resiliency functionality to vehicles, but more and more, the energy management functionality is being taken on by improvements in the engineering design and support systems behind the exterior part. The function of these exterior parts then, is, to a large degree, to be aesthetically pleasing when painted, and maintain their high quality fit and finish over the life of the vehicle. These applications are therefore justifiably subject to investigations into the reduction of their wallstock.

It is difficult, if not impossible; to select any single test that will model the expected performance of any hydraulic fluid in a wide range of hydraulic pumps made by many different manufacturers. Increasing pressures often encountered in new hydraulic pump applications compounds this problem. However, some basic assessment of hydraulic fluid performance is necessary for numerous reasons such as: developing an appropriate fluid purchase policy, international standard development, fluid classification and others. Since the now-classic standard tests such as: ASTM D-2882, DIN 51389 and others are simply inadequate for this task and also since the manufacturer, Eaton Inc., no longer manufactures these pumps, it has been necessary to develop an alternative testing strategy [1, 2 and 3]. The Bosch-Rexroth Corporation has developed a high-pressure piston pump test that has been an excellent predictor of hydraulic fluid performance for many years.

For many years the ASTM D2882 test method, using the V-104C Vane pump, served the industry well to evaluate the lubricating properties of hydraulic fluids at low pressures (< 2000 psi). However, at higher pressures in different types of pumps (i.e. piston pumps), this method may not be reliable enough to predict satisfactory lubrication performance in commercial applications. In this paper the V-104C pump will be evaluated in terms of vane contact force and film thickness parameters to assertain the possibility of using a modified bench test to better predict hydraulic fluid performance at higher pressures.

The QUESTRA* Crystalline Polymer product family, based on syndiotactic polystyrene (SPS), has been improved to meet the needs of the automotive connector and light socket applications in a very cost effective manner. In this paper, the attributes of two new SPS formulations, SPS/polyamide (PA) blends and low gas SPS formulations, are compared to existing SPS formulations and competitive resins. It is shown that the SPS/PA blends have significantly improved strength and ductility over existing SPS formulations. This improves the SPS formulation technology to include the full range of strength and ductility options the designer of automotive connectors needs to achieve the terminal retention forces and latch deflection distances necessary for the smaller connectors like the .64 mm terminal systems that the automotive industry is migrating towards.

The challenging economic climate of today is causing many suppliers to develop new and creative ways to improve efficiency and meet the needs of customers without jeopardizing the quality of service and support. The Dow Automotive business group is evaluating a new mechanism for remotely supporting customers' injection molding trials by combining wireless video camera technology and traditional videoconference (VC) capabilities. The Video Response System™ (VRS), from Teleco Video Systems, incorporates a wireless remote camera on a wheeled tripod and a wireless audio connection to allow users to transmit a real-time video and audio signal from anywhere within a location to other sites around the globe. The video and audio signals generated by the VRS system are transmitted to a traditional VC unit in the molding shop which in turn transmits the signals over ISDN lines to an awaiting VC unit.

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.

Currently, throughout the automotive industry, a major emphasis is being placed on reducing costs of plastics part manufacturing. For example, manufacturers of plastics parts used for interior trim applications have traditionally painted parts, to improve part aesthetics and cover over such surface defects as weld lines. Part painting can typically add from $.60-$2.00 to the part costs for these applications. Furthermore, due to the loss in mechanical properties found at weld lines, structural integrity can also be sacrificed. This paper discusses the use of the multi-live feed molding process as a solution to minimize weld lines, improve mechanical properties and part aesthetics, and potentially reduce costs by eliminating steps in manufacturing operations such as painting.

The trend in the automotive industry to establish higher quality, comfort and safety levels, while at the same time reducing cost and weight, is pushing production techniques, materials and the development cycle to become as efficient as possible. The automotive supplier has to choose from a broad range of fabrication technologies and material alternatives to achieve the highest performance level at the lowest possible cost. This paper outlines the process followed by a multi-functional team to design and develop the interior door panels for the VW Golf, in ABS resin for large scale production. The team effort, headed by the Tier 1 (Sommer Allibert Industrie), with extensive interaction with the OEM, and the support of the material supplier and tool-maker, led to a thin-walled part with integrated mountings, high quality appearance and excellent dimensional stability.

The material data provided by resin suppliers in their product datasheets generally focuses on single point data only and does not include the data useful to the design engineers. Even though the single-point data bears little relevance to the end-use performance of the material and provides very little insight into its behavior, design engineers rely heavily on these data because it is readily available. However, to enhance their confidence in their material selection decisions, they ask for large quantity of data without taking into consideration the cost of data measurement. Today, as resin suppliers struggle to justify the cost of generating all the data requested against the tremendous pressure to reduce their cost, it is important to put the direct costs of material data measurement in perspective.

The major element of contact between the occupant, the vehicle and the road surface is the automobile seat. Flexible polyurethane foams are the material of choice for this application, not only because of the economies offered by large-scale molding operations, but also because the cushioning characteristics of the foam/seat assembly can be adjusted. The automotive original equipment manufacturers (OEM’s) worldwide are looking for optimization of the balance between foam weight and foam specifications, with more emphasis than ever on comfort and durability. This goes with specific requirements for the various foam pads, i.e., front cushion, rear cushion, front backrest and rear backrest. Commercially useful foams can be made from a variety of polyurethane molding chemistries.

The use of Low Pressure Moulding (LPM), in its many forms, is becoming more widespread in the Automotive Industry. Design and setup of this process generally relies on experience built up over years of working with the process and often several tool and process changes in the development phase in order to optimise the process. This paper outlines a method of designing for LPM using C-Mold® software from AC-Technology, and the experience of working with the process and materials, which will reduce the number of iterations required to design for LPM and further increase the benefits to be gained by use of the process. The paper shows some of the characteristics of the process and the extent to which this can be simulated using the software.

The drive to reduce costs and increase efficiency in the automotive industry is often the driving force for development of new technologies and methods of engineering. Polypropylene (PP) is widely used as a low cost alternative to “engineering” thermoplastics. This paper outlines the characterisation methods used to develop material models for talc-filled impact-modified PP, which are then used to increase the efficiency of the development process, by using engineering analyses to reduce the prototyping costs and potentially the development time for an application. Instrument panels (IPs), door panels and trim parts are usually subjected to heat requirements and must maintain dimensional tolerance levels for each application. This necessitates extensive prototype testing and often several design iterations in order to reach the requirements. This paper deals with the characterisation of PP creep behaviour and development of a model for use in Finite-Element (FE) - based codes.

A new RRIM system produces a polyurea polymer that is capable of going through a traditional assembly process including E-coat bakes of up to 200C. In order to achieve the necessary performance characteristics, the high temperature resistant polyurea RIM polymer requires post-cure temperatures between 180C and 200C. Existing ovens are designed to post-cure materials below 160C. Also, existing ovens may not be large enough to handle pickup truck rear fenders. The existing ovens need to be refurbished or new ones built to meet the new market demand. To reduce the cost of the post-cure process, infrared (IR) radiation was tested to determine its utility for post-curing RIM parts. It was demonstrated that a infrared radiation can be used to pre-heat the RIM part in 1/10th the time of a convection oven in the laboratory. The benefit of using infrared radiation is improved dimensional stability and impact properties with acceptable flexural modulus.