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Hybridization of heavy off-highway working vehicles brings considerable energy savings in form of downsized internal combustion engine (ICE) by means of elimination of no-load losses. In this paper a novel energy saving possibility in working hydraulics at the end of long booms of working vehicles is proposed. In traditional off-highway working vehicles the working hydraulics is supplied through pipes, hoses and valves by a hydraulic pump which is located near the main engine. Significant amount of energy is lost in long pipelines and hoses as well as in valve throttles. A new topology is…mehr

Produktbeschreibung
Hybridization of heavy off-highway working vehicles brings considerable energy savings in form of downsized internal combustion engine (ICE) by means of elimination of no-load losses. In this paper a novel energy saving possibility in working hydraulics at the end of long booms of working vehicles is proposed. In traditional off-highway working vehicles the working hydraulics is supplied through pipes, hoses and valves by a hydraulic pump which is located near the main engine. Significant amount of energy is lost in long pipelines and hoses as well as in valve throttles. A new topology is introduced for supplying the power along the long boom - the power of a hydraulic actuator is supplied by an integrated electro-hydraulic energy converter (IEHEC) which is located at the boom end. The electrical energy to the converter is supplied via electrical cables which have losses negligibly small compared to conventional fluid power supply with long pipelines. The converter transforms theelectrical energy into hydraulic energy at the end of the boom, and can recuperate excessive hydraulic energy.
Autorenporträt
Paula Immonen was born in 1986 in Finland. She received the D. Sc. (Technology) Degree in 2013 from Lappeenranta University of Technology. She is currently working in the Department of Electrical Engineering at LUT. Her current research interest is the diesel-electric hybrid drive systems.