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As part of the National Highway Traffic Safety Administration’s (NHTSA) Light Vehicle Antilock Brake System (ABS) Research Program a study was conducted to examine driver crash avoidance behavior and the effects of ABS on drivers’ ability to avoid a collision in a crash-imminent situation. The test track study, described in detail in the SAE paper “Driver Crash Avoidance Behavior with ABS in an Intersection Incursion Scenario on Dry Versus Wet Pavement” [1], was designed to examine the effects of ABS versus conventional brakes, ABS brake pedal feedback level, and ABS instruction on driver behavior and crash avoidance performance. Exponent has obtained the electronic data collected by NHTSA in the dry pavement study and analyzed the steering inputs to better understand how drivers respond to emergency avoidance situations.

The mechanics of on-road, friction-induced rollovers were studied with the aid of a three-dimensional computer code specifically derived for this purpose. Motions of the wheels, vehicle body, occupant torso, and head were computed. Kane's method was utilized to develop the dynamic equations of motion in closed form. On-road rollover kinematics were compared to a dolly-type rollover at lesser initial speed, but generating a similar roll rotation rate. The simulated on-road rollover created a roof impact on the leading (driver's) side, while the dolly rollover simulation created a trailing-side roof impact. No head-to-roof contacts were predicted in either simulation. The first roof contact during the dolly-type roll generated greater neck loads in lateral bending than the on-road rollover. This work is considered to be the first step in developing a combined vehicle and occupant computational model for studying injury potential during rollovers.

Testing techniques for creating rollovers have been a subject of much study and discussion, although previous work has concentrated on creating a repeatable laboratory test for evaluating and comparing vehicle designs. The two testing methodologies presented here address creating rollover tests that closely mimic a specific accident scenario, and are useful in accident reconstruction and evaluation of vehicle performance in specific situations. In order to be able to recreate accidents on off-road terrain, a test fixture called the Roller Coaster Dolly (RCD) was developed. With the RCD a vehicle can be released at speed onto flat or sloping terrain with any desired initial roll, pitch and yaw angle. This can be used to create rollover collisions from the trip stage on, including scenarios such as furrow trip on an inclined road edge.

Testing methods and SAE Recommended Practices were developed for evaluating both the ability of a truck cab to resist roof loading in a rollover environment and the occupant kinematics and injury potential for occupants in a 90-degree heavy truck rollover. In evaluating a heavy truck roof for its ability to resist rollover loads, real-world accident data was analyzed and full-scale tests were performed to define the rollover environment. It was found that testing methods currently in place for passenger cars were not sufficient to represent the loading mechanisms that typically occur in a heavy truck rollover. An SAE Recommended Practice (RP) for both dynamic and quasi-static roof load testing was developed, and tests were conducted to evaluate their use. To evaluate heavy truck occupant safety in a 90-degree rollover, independent of roof intrusion, a rollover simulator was developed. The simulator allows occupant restraints, seats, and interiors to be evaluated for injury mechanisms.

Lateral directional dynamic response properties and handling characteristics of All-Terrain Vehicles (ATVs) have been the subject of several investigations. Experimentally measured steady-state and transient handling response parameters of four ATVs are presented, reflecting two traditional automobile handling tests, the circle-turn and the J-turn test. Two three-wheel and two four-wheel ATVs were tested. One of the three-wheel and one of the four-wheel ATVs were equipped with conventional, but lockable differentials. The J-turn tests yielded transient response properties including lateral acceleration and yaw rate response times to step steer inputs, and steady-state response properties such as understeer coefficient, steering sensitivity and yaw response gain. ATV J-turn test results are compared to J-turn test results from selected automobiles.

In the United States, exhaust emission performance has improved dramatically since the precontrol days of the 1960's with emission reductions typically exceeding 90 percent. However, these emission reductions and emission compliance in general have traditionally been evaluated at warm ambient conditions with a nominal test temperature of 75°F. This paper examines the emission performance of current technology vehicles under colder ambient test conditions. Emission levels at 20°F are found to be three to four times the 75°F levels. The bulk of this emission increase occurs during the cold start portion of the test where increased fuel enrichment and decreased emission control system efficiency combine to raise the tailpipe emission levels. In comparison to precatalyst vehicle designs, emission reductions have not been as great at colder ambients as at the normal, warm test conditions.

Surface area data, steady-state hydrocarbon conversion efficiency data, and hydrocarbon emissions results have been determined for catalysts collected by the U.S. Environmental Protection Agency from properly maintained 1981 and 1982 model year vehicles. Catalysts covered in this study were limited to those with three-way-plus-oxidation monolith technologies. Catalyst surface areas were measured using the BET method, conversion efficiencies were measured on an exhaust gas generator, and emissions results were determined using the Urban Driving Schedule of the Federal Test Procedure. Results indicate that correlation of catalyst surface area data with hydrocarbon conversion efficiency data and hydrocarbon emissions results is significant for the sample studied.

A test program to evaluate the performance of catalytic converters from fifty-six 1981 and 1982 model year high mileage properly maintained in-use vehicles (from 21 engine families) was performed by the Certification Division of the Office of Mobile Sources (EPA). The program is called the Catalyst Change Program. All program vehicles were screened for proper maintenance and for mileages that ranged from 35,000 to 60,000 miles. Among vehicles belonging to 21 high sales volume and high technology engine and emission control system designs tested, poor catalyst performance was determined to be a significant contributor to emissions failure of properly-maintained vehicles at or near their warranted useful life mileage.