基于改进人工蜂群算法的轮毂电机多目标优化

Multi-Objective Optimum Design for in-Wheel Motor Based on Improved Artificial Bee Colony Algorithm

为了提高轮毂电机功率密度、降低其材料成本,提出一种改进的人工蜂群算法对轮毂电机性能进行优化设计.首先利用磁路法建立外转子永磁式轮毂电机各项性能的表达式;其次通过引入个体极值、群体极值以及一对异步缩放因子来克服传统人工蜂群算法收敛速度较慢、探索与开发能力不平衡等缺点;以磁极对数、气隙长度、永磁体厚度等电磁参数为设计变量,将电机的有效质量、功率损耗和材料成本线性加权组成单目标函数,并采用障碍函数法将有约束的非线性目标函数转化为非约束的形式;最后利用遗传算法、传统人工蜂群算法和改进的人工蜂群算法对轮毂电机进行优化设计,并通过有限元法和样机实验验证了计算结果的正确性.研究结果表明:相较于传统人工蜂群算法,改进的人工蜂群算法使目标函数收敛速度更快;相较于遗传算法和传统人工蜂群算法,改进后的算法使目标函数值最小;相较于原设计方案,优化后轮毂电机有效质量降低13.4%,材料成本降低34.4%,功率损耗降低44.2%,电机效率提高12.0%.

In order to improve the power density of the in-wheel motor and reduce its material cost,an improved artificial bee colony(IABC)algorithm was proposed to optimize the performance of the in-wheel motor.Firstly,the expressions for the performances of the permanent-magnet in-wheel motor with outer rotor were established by magnetic circuit method.Secondly,individual extremum,population extremum and a pair of asynchronous scaling factors were introduced to overcome the shortcomings of traditional artificial bee colony(ABC)algorithm,such as slow convergence speed,and imbalance in exploration and development.The effective mass,power loss and material cost of the motor were linearly weighted to form a single objective function with the electromagnetic parameters such as number of pole pairs,air-gap clearance and permanent magnet thickness as design variables,and the constrained non-linear objective function was transformed into a non-constrained one by the barrier function method.Finally,the genetic algorithm(GA),traditional ABC algorithm and IABC algorithm were used to optimize the design of the in-wheel motor respectively.The correctness of the calculation results was verified by finite element method and prototype experiment.The results show that the IABC algorithm makes the objective function converge faster than the traditional ABC algorithm.Compared with the GA and traditional ABC algorithm,the IABC algorithm minimizes the objective function value.Compared with the original design,the effective quality of the in-wheel motor is reduced by 13.4%,material cost is reduced by 34.4%,power loss is reduced by 44.2%,and the efficiency is increased by 12.0%.