Heat transfer, heat from current

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SUMMARY

The discussion focuses on the relationship between electrical current, material diameter, and efficient thermal energy transfer. It establishes that heat disperses radially in uniform materials and emphasizes the importance of understanding resistivity and temperature in this context. The efficiency of thermal energy transfer is mathematically defined by the equation η = I²R_L / (I²R_L + I²R_S), highlighting the significance of load resistance (R_L) and source resistance (R_S) in optimizing power transfer. The principle of power matching is crucial for maximizing efficiency in thermal applications.

PREREQUISITES
  • Understanding of electrical resistance and Ohm's Law
  • Familiarity with thermal energy transfer concepts
  • Knowledge of resistivity and its temperature dependence
  • Basic principles of power matching in electrical circuits
NEXT STEPS
  • Research "resistivity" and "temperature" relationships for specific materials
  • Study the principles of "power matching" in electrical systems
  • Explore the effects of "current load" on heat generation in conductors
  • Investigate "thermal conductivity" and its impact on heat transfer efficiency
USEFUL FOR

Electrical engineers, materials scientists, and anyone involved in optimizing thermal management in electrical systems will benefit from this discussion.

Frostfire
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Is there a relation that connects a current with the diameter of a material for efficient transfer of thermal energy.

I say diameter as I think its safe to assume heat leaves radially given a uniform material.

I am also looking for a relation between resistance of a material and heat generated under high current loads. I know the basic ones but I seem to remeber something about them not being accurate given high current

Any helps appreciated
 
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What exactly do you mean by "efficient transfer of thermal energy" here? (Highest temperature per unit power? Voltage? Something else?) It will affect how you attack the problem.

You may have some luck searching "resistivity" + "temperature" for your material of interest.
 
thermal energy per power was my first thought
 
OK, that's going to be relatively straightforward: the efficiency is just

\eta=\frac{I^2R_L}{I^2R_L+I^2R_S}=\frac{R_L}{R_L+R_S}=\frac{1}{1+R_SA/\rho L}

where I is the current, R_L=\rho L/A is the load resistance (the resistance of the heater), R_S is the source resistance (the resistance of the power supply and wiring), \rho is the resistivity of the heater material, and L and A are the length and cross-sectional area of the thermal heater.

This is essentially the principle of power matching; you maximize power transfer when the load resistance matches the source resistance and the source resistance is minimized. Does this answer your question?
 

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