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Hydraulic, mechanical, and electro-magnetic technologies have been the primary means for torque management in today's drivetrains. Recent advances in electronic controls have provided even greater performance benefits for these base technologies. These facts coupled with an extended period of design and development for these drivetrain systems make the introduction of a new technology very challenging. However, recent developments at Borg Warner's Powertrain Technical Center have shown that a new technology, hydro-mechanical technology, may hold great promise in solving some of the fundamental problems and limitations of today's torque management technologies. This paper illustrates drivetrain applications where hydro-mechanical technology offers new and improved performance benefits for some of drivetrain's oldest problems. The opportunity to bring a new technology to the market in drivetrains also provides a new opportunity for powdered metallurgy (P/M) content in same.

In the NVH design optimization of automotive structures, the spectral properties of dynamic forces transmitted from rotating machinery to its housing is of primary interest. This paper describes the application of an indirect dynamic force estimation technique, more commonly known as transfer path analysis, to an operational transfer case. Through the implementation of an inverse transfer matrix technique, dynamic forces transmitted to a transfer case housing are estimated at a discrete number of locations. This paper describes the experimental and analytical methodology employed for dynamic force estimation as well as statistical techniques for solution optimization. Good correlation is shown to exist between frequencies of known physical phenomena and estimated dynamic forces for a total of nine (9) operational variations of transfer case speed and torque.