Cooling Performance Analysis of Outside Fins of the Closed Circuit Axial Piston Transmission

Realizing conversion between fluid power and mechanical energy, the closed circuit axial piston transmission (CCAPT) plays a vital and indispensable role in miscellaneous industries. The frictional loss and leakage loss inside the system give rise to the inevitable temperature rise. In order to prolong the life of the device, a cooling structure on the outside of the CCAPT is designed for promoting heat dissipation. Based on the relevant heat transfer law and the temperature distribution of internal machinery elements, a spiral fin structure is designed at the shell side. With the help of numerical simulation, the effects of fin height, fin pitch, and fin thickness on the thermal performance are studied. The flow field and temperature field on the outside of the fin structure are obtained as a guidance for enhancing heat dissipation effect. Results indicate that the area of rotating elements tend to accumulate heat, where more attention should be paid for a better cooling effect. In addition to this, a moderate increase of fin height, fin pitch and fin thickness has a positive effect on heat transfer enhancement. The peak value of Nusselt number is obtained with a fin height of 7.5 mm, which is about 2.09 times that of the condition without the fin structure. An increase in fin pitch improves both heat transfer performance and comprehensive performance at the same. When fin pitch is 30 mm, Nusselt numberincreases 104% over the original condition.

Automated summary

The study investigates the influence of fin height, fin pitch, and fin thickness on the thermal performance of the closed circuit axial piston transmission (CCAPT) through designing a spiral fin structure and conducting numerical simulations. Attention should be paid to the heat accumulation in the area of rotating elements for better cooling effects. An increase in fin height, fin pitch, and fin thickness can enhance heat transfer, with optimal results obtained at a fin height of 7.5 mm and a fin pitch of 30 mm showing significant improvements in Nusselt number.