BACKGROUND

Rollover crashes are one of the most significant safety problems for all classes of light vehicles especially light trucks (pickups, sport utility vehicles, and vans -- LTVs). For 1992 through 1996, there were an average of approximately 227,000 rollover crashes per year. (Rollover crashes are ones in which rollover is the first harmful event.) These rollovers resulted in an average of 9,063 fatalities per year (29 percent of all light vehicle fatalities) and over 200,000 non-fatal injuries per year. In terms of fatalities per registered vehicle, rollovers are second only to frontal crashes in their level of severity. The rollover problem is more serious for light trucks, especially sport utility vehicles. State crash data indicates that, for all types of collisions, LTV's are only in 68 percent as many crashes per registered vehicle as are passenger cars. However, for rollover crashes, LTV's are in 127 percent as many crashes per registered vehicle as are passenger cars.

Most rollovers result from the vehicle leaving the roadway and tripping. While unfortunate (and all too often tragic), the causes of tripped rollover are well understood. Any vehicle will roll over if it impacts a suitable tripping mechanism with sufficient lateral velocity.

On-road untripped rollovers due to vehicle maneuvering are responsible for only a small portion of the rollover safety problem. NHTSA's past research has estimated that less than 10 percent of all rollovers are on-road, untripped, events. Even though this is a small part of the overall rollover crash problem, considerable attention is given to this problem by proponents of rollover safety. This is because this type of rollover is considered to be egregious. Furthermore, there is a perception that on-road, untripped rollovers are primarily caused by vehicle-related factors and can be prevented by an appropriate safety standard.

In comparison with tripped, off-road rollover, the causes of untripped, on-road rollover are not well understood. Past NHTSA research has never found a light vehicle for which, when empty, the most severe attainable steady state turn exceeds the vehicle's rollover threshold. Since placing a load in a vehicle increases the load on the tires thereby decreasing the available tire-road coefficient of friction, loaded vehicles are also not expected to rollover due to steady state turns unless the load has a very high center of gravity. Note that this is not the case for heavy trucks of which many will rollover if they perform too severe a steady state turn.

OBJECTIVE

The objective of this project is to develop an objective test procedure for determining the on-road, untripped rollover propensity of a vehicle make-model. Having such a test procedure will support either the implementation of a Federal Motor Vehicle Safety Standard to establish a minimum acceptable level for a vehicle's on-road, untripped rollover propensity, or the development of a consumer information program to reduce the incidence of on-road, untripped rollover. The test procedure will be developed to the level that it can be presented to the public in the form of a notice in the winter of 1998/1999.

RESULTS TO DATE


RELATED DATA
SAE World Congress 2003 Presentations Public Workshop on Dynamic Rollover and Handling Test Techniques
  • On December 3, 2002, NHTSA conducted a public workshop to allow interested parties to learn details about the Agency's current techniques for evaluating dynamic rollover propensity and handling. The instrumentation, outrigger design, maneuver descriptions, and test procedures relating to these techniques was discussed.
  • Download the presentations given at the workshop. (Adobe Portable Document Format Version 5, 4.8 MB)

Rollover Resistance Ratings Information

Measured Vehicle Inertial Parameters - NHTSA's Data Through November, 1998
  • An updated version of NHTSA's Vehicle Inertial Parameter Measurement Database (VIPMD) is now available for download.
  • The National Highway Traffic Safety Administration's (NHTSA) Light Vehicle Inertial Parameter Database contains measured passenger vehicle inertial parameters. This updated database contains the original 414 entries (as described in SAE paper No. 930897) plus an additional 82 new entries, for a total of 496. The majority of the entries contain complete vehicle inertial parameters, some of the entries contain tilt table results only, and some entries contain both inertia and tilt table results. The noted SAE paper provides a brief discussion of the accuracy of inertial measurements as well as selected graphs of quantities listed in the database for some of the 1998 model year vehicles tested.
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