Analysis and Comparison of the Performance of an Inverted Brayton Cycle and Turbocompounding With Decoupled Turbine and Continuous Variable Transmission Driven Compressor for Small Automotive Engines

Lu, Pengfei; Brace, Chris; Hu, Bo; Copeland, Colin

doi:10.1115/1.4035600

Cited by 11 publications

(1 citation statement)

References 14 publications

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“…Condensation improved the IBC efficiency to close to the Stirling efficiency for high IBC turbomachinery polytropic efficiency. Lu et al [18] compared the performance of a turbocharged engine with IBC versus a turbocompounding system with decoupled turbine and continuously variable transmission driven compressor. They found that both systems offered a significant improvement in fuel efficiency and power output at full load.…”

Section: Figure 1: Inverted Brayton Cyclementioning

confidence: 99%

Experimental Investigation of an Inverted Brayton Cycle for Exhaust Gas Energy Recovery

Kennedy

Chen

Ceen

et al. 2018

Volume 8: Microturbines, Turbochargers, and Small Turbomachines; Steam Turbines

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Exhaust gases from an internal combustion engine (ICE) contain approximately 30% of the total energy released from combustion of the fuel. In order to improve fuel economy and reduce emissions, there are a number of technologies available to recover some of the otherwise wasted energy. The inverted Brayton cycle (IBC) is one such technology. The purpose of the study is to conduct a parametric experimental investigation of the IBC. Hot air from a turbocharger test facility is used. The system is sized to operate using the exhaust gases produced by a 2 litre turbocharged engine at motorway cruise conditions. A number of parameters are investigated that impact the performance of the system such as turbine inlet temperature, system pressure drop and compressor inlet temperature. The results confirm that the output power is strongly affected by the turbine inlet temperature and system pressure drop. The study also highlights the packaging and performance advantages of using a 3D printed heat exchanger to reject the excess heat. Due to rotordynamic issues, the speed of the system was limited to 80,000 rpm rather than the target 120,000 rpm. However, the results show that the system can generate a specific work of up to 17 kJ/kg at 80,000 rpm. At full speed it is estimated that the system can develop approximately 47 kJ/kg, which represents a thermal efficiency of approximately 5%.

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Section: Figure 1: Inverted Brayton Cyclementioning

confidence: 99%