Laboratory Investigation Of Natural Air Convection In A Porous Medium In A Cylindrical Tank

Chen, Jianfeng

Unknown Date

No description available.

Laboratory Investigation

Natural Air Convection

Porous Medium

Cylindrical Tank

Laboratory Investigation Of Natural Air Convection In A Porous Medium In A Cylindrical Tank

Chen, Jianfeng

11 1900

Natural convection with high cooling effects is of increasing interest in cold region geotechnical engineering. To study natural air convection in a highly-permeable porous medium, convective and conductive heat transfer experiments were carried out using an insulated cylindrical tank filled with styrofoam chips. Convection and conduction were caused by controlling the temperatures at the top and bottom of the tank, and a series of cross-sectional conductive and convective isotherms were generated from collected temperature data. Additional convective patterns were obtained from tests by centrally localized heating below or cooling above. Flow velocities were measured at the center of the tank. Results showed that convective heat transfer rate was higher than thermal conduction. Convective isothermal patterns varied with various boundary conditions and could be influenced by small temperature perturbation. Given appropriate environmental conditions, efficient convective cooling effects can be used to enhance ground freezing or to protect permafrost from degradation. / Geotechnical Engineering

Laboratory Investigation

Natural Air Convection

Porous Medium

Cylindrical Tank

HEAT TRANSFER IN WASTE-ROCK PILES CONSTRUCTED IN A CONTINUOUS PERMAFROST REGION

Pham, Hoang Nam

Unknown Date

No description available.

Heat transfer

Waste rock piles

Acid Rock Drainage (ARD)

Natural air convection

Permafrost

Study on Lithium Battery Thermal Analysis For E-bike

Vijayan, Sreekuttan, Jaimon, Jais

January 2023

E-bikes, often known as electric bicycles, are becoming more and more well-liked as green modes of mobility. High-capacity lithium-ion (Li-ion) batteries are utilised to power these e-bikes because of their extended cycle life, high energy density, and low self-discharge rate. The performance and longevity of these batteries may be impacted by temperature fluctuations, however. To guarantee the safe and dependable functioning of Li-ion batteries used in e-bikes, it is crucial to do temperature analysis on the batteries. In this dissertation, the thermal behaviour of a 48V 60AH Li-ion battery used in an e-bike will be studied under various cooling scenarios. The research specifically contrasts forced convection cooling using fans with broad and limited outlet ports to natural air convection cooling with large and reduced outlet ports. The study sheds light on the ideal cooling setups that might increase battery longevity and performance. The results of this study have important ramifications for e-bike producers and designers, battery producers, and energy storage system researchers. Simulations based on computational fluid dynamics (CFD) are used to simulate the thermal behaviour of the Li-ion battery under various cooling settings for the investigation. 25°C has been selected as the ambient temperature. For forced convection, the airflow rate is set at 3.5 m/s, whereas the airflow rate for natural convection is set at 0.1 m/s. The study's findings demonstrate that both natural and forced convection cooling methods may successfully lower the temperature of a Li-ion battery. However, forced air convection cooling using fans is more efficient than natural air convection at dispersing heat. These findings suggest that, owing to the higher air velocity, shrinking the outlet ports in both cooling approaches improves thermal performance.

Lithium-ion battery

e-bike

thermal analysis

forced convection cooling

natural air convection

temperature distribution

outlet ports

computational fluid dynamics

Engineering and Technology

Teknik och teknologier