Abstract
Worldwide, high-speed rail is becoming an increasingly popular and efficient means of transport. However, increasing the speed of a train leads to major reductions in stability and ride comfort. Here, we develop a tubular permanent magnet actuator to overcome these problems. To increase actuator thrust, the electromagnetic circuit requires a high current and, thus, becomes hot. We use a water cooling system with 12 straight copper channels to reduce the temperature. We calculate heat transfer coefficients using empirical convection correlations between laminar flow in the channels and experimental results. The predicted, tube surface temperatures correlated well with the experimental data. We evaluated the effects of flow rate and initial water temperature on various design parameters. The cooling system allowed application of a current greater than 100 A, developing a thrust force of over 8000 N. Thus, the system was robust under harsh operating conditions. We measured the thrust and cogging forces and the performance of the water cooling system in terms of the maximum acceptable temperature. The thrust was high and the cogging torque was low, greatly reducing lateral vibration; the temperature remained below the acceptable maximum.
Highlights
A high-speed train is defined as one that operates at speeds of over 200 km/h (124 mile/h)
To compensate for the deterioration in riding comfort caused by the increased vehicle speed and inferior track conditions, we developed a tubular permanent magnet actuator (TPMA) featuring a waterforced convection cooling system; this served as an active secondary suspension
We first fabricated a TPMA with 12 circular copper tubes to investigate the feasibility of such a system in terms of TPMA thrust and cogging forces
Summary
A high-speed train is defined as one that operates at speeds of over 200 km/h (124 mile/h). They constructed a sequential magneto-thermal coupling model using a transient thermal equivalent-circuit model.[9] D Staton et al provided guidelines for choosing suitable thermal and flow network formulations and setting any calibration parameters These heat transfer and flow formulations were successfully applied to the thermal analysis of electrical machines.[10,11] the practical performance of a cooling system operating in conjunction with a tubular permanent magnet actuator (TPMA) when a high thrust is generated by a high input current has not been experimentally investigated. The heat transfer coefficients were calculated using empirical convection correlations related to the flow motion in the circular channels and were validated through experimentation on the fabricated TPMA featuring various input currents. The number is large at the entrance region, but asymptotically approaches the fully developed value of 3.66 as L!N when laminar flow is in play in a circular tube of uniform surface temperature
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