Title :
Calculation and Experimental Study on Temperature Rise of a High OverLoad Tubular Permanent Magnet Linear Motor
Author :
Huang Xuzhen ; Liu Jiaxi ; Zhang Chengming ; Li Liyi
Author_Institution :
Jiangsu Key Lab. of New Energy Generation & Power Conversion, Nanjing Univ. of Aeronaut. & Astronaut., Nanjing, China
Abstract :
This paper presents a finite element method approach for motor thermal analysis. Specifically, the 2-D temperature field model of a slotless tubular permanent magnet linear motor is established. The heat convection coefficients of the mover are then calculated based on fluid field analysis. This paper focuses on the winding to obtain an accurate winding temperature gradient distribution and to the highest temperature region from the high overload motor. Therefore, the improved equivalent layered model of the ring-shaped winding is particularly applied to the temperature field simulation of the tubular linear motor. As verification, the temperature rise of the motor is calculated accordingly, and the results are compared with the actual experiments.
Keywords :
convection; finite element analysis; linear motors; machine windings; permanent magnet motors; temperature distribution; thermal analysis; 2D temperature field model; equivalent layered model; finite element method approach; fluid field analysis; high overload motor; high overload tubular permanent magnet linear motor; highest temperature region; motor thermal analysis; mover heat convection coefficients; ring-shaped winding; slotless tubular permanent magnet linear motor; temperature field simulation; temperature rise; winding temperature gradient distribution; Conductors; Heating; Iron; Permanent magnet motors; Plasma temperature; Thermal conductivity; Windings; Finite element method (FEM); high overload; linear motor; temperature field;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2013.2246872
