JZUS - Journal of Zhejiang University SCIENCE

Frontiers of Information Technology & Electronic Engineering 2015 Vol.16 No.11 P.957-968

Optimization design of an interior permanent-magnet synchronous machine for a hybrid hydraulic excavator

Author(s): Qi-huai Chen, Qing-feng Wang, Tao Wang
Affiliation(s): 1State Key Laboratory of Fluid Power Transmission and Control, Zhejiang University, Hangzhou 310027, China; more
Corresponding email(s): 11025049@zju.edu.cn
Key Words: Analysis, Design, Hybrid hydraulic excavator (HHE), Finite element method (FEM), Interior permanent-magnet (PM) motor, PM synchronous machine (PMSM)

Share this article to： More <<< Previous Article \|Next Article >>>

Qi-huai Chen, Qing-feng Wang, Tao Wang. Optimization design of an interior permanent-magnet synchronous machine for a hybrid hydraulic excavator[J]. Frontiers of Information Technology & Electronic Engineering, 2015, 16(11): 957-968.

@article{title="Optimization design of an interior permanent-magnet synchronous machine for a hybrid hydraulic excavator",
author="Qi-huai Chen, Qing-feng Wang, Tao Wang",
journal="Frontiers of Information Technology & Electronic Engineering",
volume="16",
number="11",
pages="957-968",
year="2015",
publisher="Zhejiang University Press & Springer",
doi="10.1631/FITEE.1500056"
}

%0 Journal Article
%T Optimization design of an interior permanent-magnet synchronous machine for a hybrid hydraulic excavator
%A Qi-huai Chen
%A Qing-feng Wang
%A Tao Wang
%J Frontiers of Information Technology & Electronic Engineering
%V 16
%N 11
%P 957-968
%@ 2095-9184
%D 2015
%I Zhejiang University Press & Springer
%DOI 10.1631/FITEE.1500056

TY - JOUR
T1 - Optimization design of an interior permanent-magnet synchronous machine for a hybrid hydraulic excavator
A1 - Qi-huai Chen
A1 - Qing-feng Wang
A1 - Tao Wang
J0 - Frontiers of Information Technology & Electronic Engineering
VL - 16
IS - 11
SP - 957
EP - 968
%@ 2095-9184
Y1 - 2015
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/FITEE.1500056

Abstract
Chinese Summary
Academic Network
Reviewer Comment

Abstract: A hybrid power transmission system (HPTS) is a promising way to save energy in a hydraulic excavator and the electric machine is one of the key components of the system. In this paper, a design process for permanent-magnet synchronous machines (PMSMs) in a hybrid hydraulic excavator (HHE) is presented based on the analysis of the working conditions and requirements of an HHE. A parameterized design approach, which combines the analytical model and the 2D finite element method (FEM), is applied to the electric machine to improve the design efficiency and accuracy. The analytical model is employed to optimize the electric machine efficiency and obtain the stator dimension and flux density distribution. The rotor is designed with the FEM to satisfy the flux requirements obtained in stator design. The rotor configuration of the PMSM employs an interior magnet structure, thus resulting in some inverse saliency, which allows for much higher values in magnetic flux density. To reduce the rotor leakage, a disconnected type silicon steel block structure is adopted. To improve the air gap flux density distribution, the trapezoid permanent magnet (PM) and centrifugal rotor structure are applied to PMSM. Demagnetization and armature reactions are also taken into consideration and calculated by the FEM. A prototype of the newly designed electric machine has been fabricated and tested on the experimental platform. The analytical design results are validated by measurements.

混合动力挖掘机内置式永磁同步电机优化设计

目的：混合动力传动系统作为一种节能减排技术方案，可有效改善传统液压挖掘机的油耗和尾气排放。混合动力挖掘机中关键部件的研制，尤其是动力电机的研制，一直是阻碍混合动力系统应用和推广的难点。本文针对混合动力挖掘机实际工况和要求，对混合动力挖掘机的动力电机进行优化设计。
创新点：根据液压挖掘机实际工况特点，总结归纳了混合动力挖掘机动力电机的性能要求，提出一种动力电机结构；根据动力电机性能和工作环境要求，为提高电机设计效率和精度，提出一套采用模型法与有限元法相结合的电机设计方法。
方法：对传统液压挖掘机工况及实际载荷谱进行分析，总结归纳动力电机的性能要求。动力电机采用内置切向式和变气隙相结合的结构方案作为电机转子结构。电机的设计以安装尺寸为约束条件，以电机具有高效率、高响应及低转矩脉动等性能为设计目标，对电机定、转子结构进行优化设计。首先，建立电机定子参数化模型，确定电机定子尺寸和磁感应强度的分布关系；以电机安装尺寸极限作为边界条件，以电机额定工况下损耗最低为目标函数，对模型采用粒子群算法进行优化获取定子参数及磁感应强度分布。然后，以气隙磁感应强度的波形畸变最小为目标，利用有限元法对电机变气隙转子的离心率及永磁体尺寸进行优化设计，同时保证所获得的电机磁感应强度与定子的理论设计目标值一致。分别对电枢反应、永磁体最大去磁进行计算和校核。研制了动力电机样机并进行性能和参数测试。
结论：所设计动力电机样机具有齿槽转矩小和工作效率较高的特点。样机的试验参数测量值与理论设计值吻合度较高，验证了所提电机设计及优化方法的有效性。

关键词：混合动力液压挖掘机；模型法；有限元法；永磁同步电机

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1]Alberti, L., Barcaro, M., Pré, M.D., et al., 2010. IPM machine drive design and tests for an integrated starter-alternator application. IEEE Trans. Ind. Appl., 46(3):993-1001.

[2]Alberti, L., Bianchi, N., Bolognani, S., 2011. Variable-speed induction machine performance computed using finite-element. IEEE Trans. Ind. Appl., 47(2):789-797.

[3]Bianchi, N., Bolognani, S., Frare, P., 2006. Design criteria for high-efficiency SPM synchronous motors. IEEE Trans. Energy Conv., 21(2):396-404.

[4]Boglietti, A., Cavagnino, A., Lazzari, M., et al., 2003. Predicting iron losses in soft magnetic materials with arbitrary voltage supply: an engineering approach. IEEE Trans. Magn., 39(2):981-989.

[5]Cassimere, B.N., Sudhoff, S.D., Sudhoff, D.H., 2009. Analytical design model for surface-mounted permanent-magnet synchronous machines. IEEE Trans. Energy Conv., 24(2):347-357.

[6]Chan, C.C., 2002. The state of the art of electric and hybrid vehicles. Proc. IEEE, 90(2):247-275.

[7]Chau, K.T., Chan, C.C., Liu, C., 2008. Overview of permanent-magnet brushless drives for electric and hybrid electric vehicles. IEEE Trans. Ind. Electron., 55(6):2246-2257.

[8]Comanescu, M., Keyhani, A., Dai, M., 2003. Design and analysis of 42-V permanent-magnet generator for automotive applications. IEEE Trans. Energy Conv., 18(1):107-112.

[9]Dorrel, D.G., Knight, A.M., Popescu, M., 2011. Performance improvement in high-performance brushless rare-earth magnet motors for hybrid vehicles by use of high flux-density steel. IEEE Trans. Magn., 47(10):3016-3019.

[10]El-Refaie, A.M., 2010. Fractional-slot concentrated-windings synchronous permanent magnet machines: opportunities and challenges. IEEE Trans. Ind. Electron., 57(1):107-121.

[11]El-Refaie, A., Jahns, T.M., McCleer, P.J., et al., 2006. Experimental verification of optimal flux weakening in surface PM machines using concentrated windings. IEEE Trans. Ind. Appl., 42(2):443-453.

[12]Eriksson, S., Bernhoff, H., 2011. Loss evaluation and design optimisation for direct driven permanent magnet synchronous generators for wind power. Appl. Energy, 88(1):265-271.

[13]Kim, S., Park, S., Park, T., et al., 2014. Investigation and experimental verification of a novel spoke-type ferrite-magnet motor for electric-vehicle traction drive applications. IEEE Trans. Ind. Electron., 61(10):5763-5770.

[14]Laskaris, K.I., Kladas, A.G., 2010. Internal permanent magnet motor design for electric vehicle drive. IEEE Trans. Ind. Electron., 57(1):138-145.

[15]Markovic, M., Perriard, Y., 2009. Optimization design of a segmented Halbach permanent-magnet motor using an analytical model. IEEE Trans. Magn., 45(7):2955-2960.

[16]Morimoto, S., Ooi, S., Inoue, Y., et al., 2014. Experimental evaluation of a rare-earth-free PMASynRM with ferrite magnets for automotive applications. IEEE Trans. Ind. Electron., 61(10):5749-5756,

[17]Mutoh, N., 2012. Driving and braking torque distribution methods for front- and rear-wheel-independent drive-type electric vehicles on roads with low friction coefficient. IEEE Trans. Ind. Electron., 59(10):3919-3933.

[18]Nerg, J., Rilla, M., Ruuskanen, V., et al., 2014. Direct-driven interior magnet permanent-magnet synchronous motors for a full electric sports car. IEEE Trans. Ind. Electron., 61(8):4286-4294.

[19]Pellegrino, G., Vagati, A., Boazzo, B., et al., 2012a. Comparison of induction and PM synchronous motor drives for EV application including design examples. IEEE Trans. Ind. Appl., 48(6):2322-2332.

[20]Pellegrino, G., Vagati, A., Guglielmi, P., et al., 2012b. Performance comparison between surface-mounted and interior PM motor drives for electric vehicle application. IEEE Trans. Ind. Electron., 59(2):803-811.

[21]Phi, H.N., Hoang, E., Gabsi, M., 2011. Performance synthesis of permanent-magnet synchronous machines during the driving cycle of a hybrid electric vehicle. IEEE Trans. Veh. Technol., 60(5):1991-1998.

[22]Reddy, P.B., El-Refaie, A.M., Huh, K.K., et al., 2012. Comparison of interior and surface PM machines equipped with fractional-slot concentrated windings for hybrid traction applications. IEEE Trans. Energy Conv., 27(3):593-602.

[23]Sizov, G.Y., Ionel, D.M., Demerdash, N.A.O., 2012. Modeling and parametric design of permanent-magnet AC machines using computationally efficient finite-element analysis. IEEE Trans. Ind. Electron., 59(6):2403-2413.

[24]Vaez-Zadeh, S., Ghasemi, A.R., 2005. Design optimization of permanent magnet synchronous motors for high torque capability and low magnet volume. Electr. Power Syst. Res., 74(2):307-313.

[25]Wang, A., Jia, Y., Soong, W.L., 2011. Comparison of five topologies for an interior permanent-magnet machine for a hybrid electric vehicle. IEEE Trans. Magn., 47(10):3606-3609.

[26]Wang, D.Y., Guan, C., 2013. Optimal control for a parallel hybrid hydraulic excavator using particle swarm optimization. Sci. World J., 2013:831564.1-831564.6.

[27]Wang, T., Wang, Q.F., 2012. Optimization design of permanent magnet synchronous generator for a potential energy recovery system. IEEE Trans. Energy Conv., 27(4):856-863.

[28]Xiao, Q., Wang, Q.F., Zhang, Y.T., 2008. Control strategies of power system in hybrid hydraulic excavator. Autom. Constr., 17(4):361-367.

[29]Zhu, Z.Q., Howe, D., 2007. Electrical machines and drives for electric, hybrid, and fuel cell vehicles. Proc. IEEE, 95(4):746-765.

[30]Zhu, Z.Q., Wu, L.J., Xia, Z.P., 2010. An accurate subdomain model for magnetic field computation in slotted surface-mounted permanent-magnet machines. IEEE Trans. Magn., 46(4):1100-1115.

Open peer comments: Debate/Discuss/Question/Opinion

<1>

Similar articles

- Go to

混合动力挖掘机内置式永磁同步电机优化设计

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference