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Vehicle manufacturers are developing dynamically deploying upper interior head protection systems to provide added occupant protection in lateral crashes. These devices are used to protect the head and neck areas and to prevent ejection from the vehicle. The National Highway Traffic Safety Administration (NHTSA) has established requirements in Federal Motor Vehicle Safety Standard (FMVSS) 201 [1] for these systems. This paper will discuss testing methodologies in the areas of component testing of curtain-type side airbag systems and full scale side impact testing of a vehicle into a rigid pole. These testing methodologies have been created as a direct result of the development phase of several airbag systems. Prior to pole impact testing, tests have been developed which evaluate these types of systems for characteristics such as inflation time, fill capacity, and how long the system stays inflated during side impact and rollover simulations.

This paper describes the development of a new sled system that can address many safety-related issues pertaining to the racing industry. The system was designed to re-create acceleration and velocity levels similar to levels evident in race car crashes. The sled utilizes equipment typically used in passenger car crash research with the primary change to a specially designed lightweight carriage. This paper will overview the system and the types of crash events that can be simulated. Readers of this paper will gain a much broader understanding of accelerator sled testing and the issues related to the simulation of high speed crashes using physical testing.

Recently, the National Highway Traffic Safety Administration (NHTSA) revised the Final Rule for Federal Motor Vehicle Safety Standard (FMVSS 208) - Occupant Crash Protection [1]. This rule, which will first take effect during the 2004 model year, specifies a number of new compliance test requirements that advanced frontal protection airbags will have to meet. The goal of the new standard is to reduce the risk of serious airbag induced injuries, particularly for small women and young children, and provide improved frontal crash protection for all occupants. In response to this new rule, vehicles in the future will have electronic sensors located in the seat and other advanced sensor systems. These sensors will be designed to measure critical data, such as occupant weight and size, which will be used to control the airbag. The reliability of the sensors through the entire life of a vehicle is critical to its overall safety characteristics.

A comprehensive strategy to investigate the role of the body mounts on the passenger compartment response in a frontal crash event is presented. The activities of the study include quasi-static vehicle crush testing, development of a component-level dynamic body mount test methodology, lumped-mass computer modeling, as well as technical analysis. In addition, a means of investigating the effects the body mounts have on the passenger compartment response during a frontal barrier impact is addressed.

The National Highway Traffic Safety Administration (NHTSA) has issued a Notice of Proposed Rulemaking (NPRM) to upgrade the dynamic portion of FMVSS 214 - Side Impact Protection [1]. This notice adds an oblique pole test to the existing moving deformable barrier test and covers a wider range of occupant sizes in a broader range of seat positions. These upgrades will present several challenges to vehicle manufacturers and suppliers. This paper will provide an overview of the NPRM, review test data used in support of the NPRM, describe component-level tests used to develop ideal side impact properties, and overview the vehicle changes that will be needed to meet these requirements.

This paper presents the resultf a project concerning the development of a test procedure for evaluating rear impact guards installed on trailers. The procedure was based on requirements established in Federal Motor Vehicle Safety Standard (FMVSS) 223, Rear Impact Guards. Rear impact guards are required on trailers to prevent passenger vehicles from driving underneath the rear of a trailer, commonly referred to as underride. The National Highway Traffic Safety Administration (NHTSA) estimates that 11,551 rear-end crashes with trucks, trailers, and semi-trailers occur annually. These crashes result in approximately 423 passenger vehicle occupant fatalities and 5030 nonfatal injuries. The nonfatal injuries include lacerations to the head and neck area, severe brain trauma, and internal hemorrhaging. The objective of the test procedure was to present uniform formats for testing and data recording, and provide suggestions for the use of specific equipment.