This episode dives deep into thermal management and refrigeration systems, connecting heat transfer physics to real engineering control and system design. Learn how conduction, convection, radiation, and phase change govern temperature rise in electronics and industrial equipment, and how thermal resistance networks simplify complex heat paths from junction to coolant. We break down dimensionless correlations like Nusselt, Reynolds, and Rayleigh numbers to explain when natural convection fails and forced flow becomes mandatory. Explore heat sinks, fin efficiency, cold plates, thermoelectric coolers, and liquid cooling strategies that reduce junction temperatures and prevent thermal runaway.

On the refrigeration side, we walk through the vapor-compression cycle step by step, covering compressors, condensers, expansion devices, and evaporators, along with compound and cascade systems used for deep and cryogenic cooling. Discover how pressure ratios, refrigerant properties, and control strategies determine efficiency and operating limits. Built for mechanical, HVAC, and thermal engineers who want to model heat flow accurately, optimize cooling performance, and design systems that survive real operating conditions instead of just looking good on paper.