A hydraulic test stand for demonstrating the operation of Eaton’s energy recovery system (ERS)

Wang, Meng (Rachel), Danzl, Per, Mahulkar, Vishal, Piyabongkarn, Damrongrit (Neng), Brenner, Paul

27 April 2016

Fuel cost represents a significant operating expense for owners and fleet managers of hydraulic off-highway vehicles. Further, the upcoming Tier IV compliance for off-highway applications will create further expense for after-treatment and cooling. Solutions that help address these factors motivate fleet operators to consider and pursue more fuelefficient hydraulic energy recovery systems. Electrical hybridization schemes are typically complex, expensive, and often do not satisfy customer payback expectations. This paper presents a hydraulic energy recovery architecture to realize energy recovery and utilization through a hydraulic hydro-mechanical transformer. The proposed system can significantly reduce hydraulic metering losses and recover energy from multiple services. The transformer enables recovered energy to be stored in a high-pressure accumulator, maximizing energy density. It can also provide system power management, potentially allowing for engine downsizing. A hydraulic test stand is used in the development of the transformer system. The test stand is easily adaptable to simulate transformer operations on an excavator by enabling selected mode valves. The transformer’s basic operations include shaft speed control, pressure transformation control, and output flow control. This paper presents the test results of the transformer’s basic operations on the test stand, which will enable a transformer’s full function on an excavator.

hydraulic transformer

fluid power control

off-highway vehicle

ddc:620

rvk:ZQ 5460

A hydraulic test stand for demonstrating the operation of Eaton’s energy recovery system (ERS)

Wang, Meng (Rachel), Danzl, Per, Mahulkar, Vishal, Piyabongkarn, Damrongrit (Neng), Brenner, Paul

January 2016

Fuel cost represents a significant operating expense for owners and fleet managers of hydraulic off-highway vehicles. Further, the upcoming Tier IV compliance for off-highway applications will create further expense for after-treatment and cooling. Solutions that help address these factors motivate fleet operators to consider and pursue more fuelefficient hydraulic energy recovery systems. Electrical hybridization schemes are typically complex, expensive, and often do not satisfy customer payback expectations. This paper presents a hydraulic energy recovery architecture to realize energy recovery and utilization through a hydraulic hydro-mechanical transformer. The proposed system can significantly reduce hydraulic metering losses and recover energy from multiple services. The transformer enables recovered energy to be stored in a high-pressure accumulator, maximizing energy density. It can also provide system power management, potentially allowing for engine downsizing. A hydraulic test stand is used in the development of the transformer system. The test stand is easily adaptable to simulate transformer operations on an excavator by enabling selected mode valves. The transformer’s basic operations include shaft speed control, pressure transformation control, and output flow control. This paper presents the test results of the transformer’s basic operations on the test stand, which will enable a transformer’s full function on an excavator.

info:eu-repo/classification/ddc/620

ddc:620

Design and Control the Ancillary System for Hydraulic Hybrid Vehicle (HHV)

Abdelgayed, Mohamed E.

09 September 2010

No description available.

Mechanical Engineering

Hydraulic Hybrid Vehicle

Hydraulic Accessories

Desgin

Control

Hydraulic Transformer

Hydraulic intensifier

Hydrostatic Transmission

Matlab/simulink

pump

Hydraulic Motor