TY - JOUR
T1 - Development of an Integrated Electro-Hydraulic Machine to Electrify Off-highway Vehicles
AU - Nishanth, F. N.U.
AU - Bohach, Garrett
AU - Nahin, Md Minal
AU - Van De Ven, James
AU - Severson, Eric L.
N1 - Publisher Copyright:
© 1972-2012 IEEE.
PY - 2022
Y1 - 2022
N2 - Electrification of off-highway vehicles is notoriously challenging due to extreme power density requirements. This article proposes and develops an axial flux machine integrated with a hydraulic pump to realize a single modular, electro-hydraulic machine to electrify off-highway vehicle implements. This integrated machine eliminates redundant bearings, couplings, and shaft seals, reuses surfaces, and enables direct cooling of the electric machine with the hydraulic fluid, to significantly increase power density. Three popular axial flux machine variants are first compared using a finite element analysis based design optimization approach. The single rotor, single stator variant is identified to be the most promising for integration with the hydraulic pump. Next, a multiphysics framework of the complete integrated hydraulic pump and axial flux machine is developed to characterize the design space. The results indicate promising potential for this concept to realize efficiency over 85% and power density over 5 kW/kg for the complete machine (electric machine, hydraulic pump, and thermal management system), while utilizing conventional materials (thin gauge silicon steel, N45 magnets, and enamelled copper wire). A prototype axial flux machine has been experimentally characterized and integrated with a hydraulic pump to demonstrate the integrated electro-hydraulic machine concept.
AB - Electrification of off-highway vehicles is notoriously challenging due to extreme power density requirements. This article proposes and develops an axial flux machine integrated with a hydraulic pump to realize a single modular, electro-hydraulic machine to electrify off-highway vehicle implements. This integrated machine eliminates redundant bearings, couplings, and shaft seals, reuses surfaces, and enables direct cooling of the electric machine with the hydraulic fluid, to significantly increase power density. Three popular axial flux machine variants are first compared using a finite element analysis based design optimization approach. The single rotor, single stator variant is identified to be the most promising for integration with the hydraulic pump. Next, a multiphysics framework of the complete integrated hydraulic pump and axial flux machine is developed to characterize the design space. The results indicate promising potential for this concept to realize efficiency over 85% and power density over 5 kW/kg for the complete machine (electric machine, hydraulic pump, and thermal management system), while utilizing conventional materials (thin gauge silicon steel, N45 magnets, and enamelled copper wire). A prototype axial flux machine has been experimentally characterized and integrated with a hydraulic pump to demonstrate the integrated electro-hydraulic machine concept.
KW - Axial flux machine
KW - electric machine design
KW - hydraulic-electric integration
KW - multiphysics optimization
KW - off-highway vehicle electrification
KW - power density
KW - radial piston pump
UR - http://www.scopus.com/inward/record.url?scp=85134256455&partnerID=8YFLogxK
U2 - 10.1109/TIA.2022.3189609
DO - 10.1109/TIA.2022.3189609
M3 - Article
AN - SCOPUS:85134256455
SN - 0093-9994
VL - 58
SP - 6163
EP - 6174
JO - IEEE Transactions on Industry Applications
JF - IEEE Transactions on Industry Applications
IS - 5
ER -