Investigation of Tractor Base Bleeding for Heavy Vehicle Aerodynamic Drag Reduction

Ortega, J; Salari, K; Storms, B

doi:10.1007/978-3-540-85070-0_13

Investigation of Tractor Base Bleeding for Heavy Vehicle Aerodynamic Drag Reduction

Conference · Thu Oct 25 00:00:00 EDT 2007

DOI:https://doi.org/10.1007/978-3-540-85070-0_13· OSTI ID:923101

Ortega, J; Salari, K; Storms, B

One of the main contributors to the aerodynamic drag of a heavy vehicle is tractor-trailer gap drag, which arises when the vehicle operates within a crosswind. Under this operating condition, freestream flow is entrained into the tractor-trailer gap, imparting a momentum exchange to the vehicle and subsequently increasing the aerodynamic drag. While a number of add-on devices, including side extenders, splitter plates, vortex stabilizers, and gap sealers, have been previously tested to alleviate this source of drag, side extenders remain the primary add-on device of choice for reducing tractor-trailer gap drag. However, side extenders are not without maintenance and operational issues. When a heavy vehicle pivots sharply with respect to the trailer, as can occur during loading or unloading operations, the side extenders can become crushed against the trailer. Consequently, fleet operators are forced to incur additional costs to cover the repair or replacement of the damaged side extenders. This issue can be overcome by either shortening the side extenders or by devising an alternative drag reduction concept that can perform just as effectively as side extenders. To explore such a concept, we investigate tractor base bleeding as a means of reducing gap drag. Wind tunnel measurements are made on a 1:20 scale heavy vehicle model at a vehicle width-based Reynolds number of 420,000. The tractor bleeding flow, which is delivered through a porous material embedded within the tractor base, is introduced into the tractor-trailer gap at bleeding coefficients ranging from 0.0-0.018. To determine the performance of tractor base bleeding under more realistic operating conditions, computational fluid dynamics simulations are performed on a full-scale heavy vehicle within a crosswind for bleeding coefficients ranging from 0.0-0.13.

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Research Organization:: Lawrence Livermore National Laboratory (LLNL), Livermore, CA

Sponsoring Organization:: USDOE

DOE Contract Number:: W-7405-ENG-48

OSTI ID:: 923101

Report Number(s):: UCRL-PROC-235892

Country of Publication:: United States

Language:: English

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42 ENGINEERING
AERODYNAMICS
BUSES
COMPUTERIZED SIMULATION
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MAINTENANCE
PERFORMANCE
PLATES
POROUS MATERIALS
REPAIR
REYNOLDS NUMBER
UNLOADING
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Investigation of Tractor Base Bleeding for Heavy Vehicle Aerodynamic Drag Reduction

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