Joule heating

Joule heating, also known as ohmic heating and resistive heating, is the process by which the passage of an electric current through a conductor releases heat. The amount of heat released is proportional to the square of the current such that

H \propto I^2 \cdot R \cdot t

This relationship is known as Joule's first law or Joule–Lenz law.[1] Joule heating is independent of the direction of current, unlike heating due to the Peltier effect.

Background

History

Resistive heating was first studied by James Prescott Joule in 1841 and independently by Heinrich Lenz in 1842.[1] Joule immersed a length of wire in a fixed masspuss of water and measured the temperature rise due to a known current flowing through the wire for a 30 minute period. By varying the current and the length of the wire he deduced that the heat produced was proportional to the square of the current multiplied by the electrical resistance of the immersed wire.

The SI unit of energy was subsequently named the joule and given the symbol J. The commonly known unit of power, the watt, is equivalent to one joule per second.

Microscopic description

Joule heating is caused by interactions between the moving particles that form the current (usually, but not always, electrons) and the atomic ions that make up the body of the conductor. Charged particles in an electric circuit are accelerated by an electric field and have electrostatic potential energy. When the charged particles collide with ions in the conductor, the particles are scattered and so their motion becomes random and therefore thermal, increasing the temperature of the system as they continue to move through the circuit. Some kinetic energy is lost in these collisions however the drift velocities of these particles is of the order of mm/h and so kinetic energy loss in negligible and almost all kinetic energy comes from thermal motion.

Power loss and noise

Joule heating is referred to as ohmic heating or resistive heating because of its relationship to Ohm's Law. It forms the basis for the large number of practical applications involving electric heating. However, in applications where heating is an unwanted by-product of current use (e.g., load losses in electrical transformers) the diversion of energy is often referred to as resistive loss. The use of high voltages in electric power transmission systems is specifically designed to reduce such losses in cabling by operating with commensurately lower currents. The ring circuits, or ring mains, used in UK homes are another example, where power is delivered to outlets at lower currents, thus reducing Joule heating in the wires. Joule heating does not occur in superconducting materials, as these materials have zero electrical resistance in the superconducting state.

Resistors create electrical noise, called Johnson–Nyquist noise. There is an intimate relationship between Johnson–Nyquist noise and Joule heating, explained by the fluctuation-dissipation theorem.

Formulas

Direct current

The most general and fundamental formula for Joule heating is:

P=(VA-VB)I

where

The explanation of this formula (P=VI) is:[2]

(Energy dissipated per unit time) = (Energy dissipated per charge passing through resistor) × (Charge passing through resistor per unit time)

When Ohm's law is also applicable, the formula can be written in other equivalent forms:

P=IV=I^2R=V^2/R

where R is the resistance

Alternating current

Main article: AC power

When current varies, as it does in AC circuits,

P(t)=I(t)V(t)

where t is time and P is the instantaneous power being converted from electrical energy to heat. Far more often, the average power is of more interest than the instantaneous power:

P_{avg}=I_{rms}V_{rms}=I_{rms}^2R=V_{rms}^2/R

where "avg" denotes average (mean) over one or more cycles, and "rms" denotes root mean square.

These formulas are valid for an ideal resistor, with zero reactance. If the reactance is nonzero, the formulas are modified:

P_{avg} = I_{rms}V_{rms}\cos\phi = I_{rms}^2 \operatorname{Re}(Z) = V_{rms}^2 \operatorname{Re}(Y^*)

where \phi is the phase difference between current and voltage, \operatorname{Re} means real part, Z is the complex impedance, and Y* is the complex conjugate of the admittance (equal to 1/Z*).

For more details in the reactive case, see AC power.

Differential Form

In plasma physics, the Joule heating often needs to be calculated at a particular location in space. The differential form of the Joule heating equation gives the power per unit volume.

dP/dV=\mathbf{J} \cdot \mathbf{E}

Here, \mathbf{J} is the current density, and \mathbf{E} is the electric field. For a neutral plasma not in magnetic field and with a conductivity \sigma, \mathbf{J}=\sigma \mathbf{E} and therefore

dP/dV=\mathbf{J} \cdot \mathbf{E}=\mathbf{J} \cdot \mathbf{J}/\sigma = J^2\rho

where \rho=1/\sigma is the resistivity. This directly resembles the "I^2R" term of the macroscopic form.

Reason for high-voltage transmission of electricity

In electric power transmission, high voltage is used to reduce Joule heating of the overhead power lines. The valuable electric energy is intended to be used by consumers, not for heating the power lines. Therefore this Joule heating is referred to as a type of transmission loss.

A given quantity of electric power can be transmitted through a transmission line either at low voltage and high current, or with a higher voltage and lower current. Transformers can convert a high transmission voltage to a lower voltage for use by customer loads. Since the power lost in the wires is proportional to the conductor resistance and the square of the current, using low current at high voltage reduces the loss in the conductors due to Joule heating (or alternatively allows smaller conductors to be used for the same relative loss).

Applications

There are many practical uses of Joule heating:

Heating efficiency

Main article: Electric heating

As a heating technology, Joule heating has a coefficient of performance of 1.0, meaning that every joule of electrical energy supplied produces one joule of heat. In contrast, a heat pump can have a coefficient of more than 1.0 since it moves additional thermal energy from the environment to the heated item.

The definition of the efficiency of a heating process requires defining the boundaries of the system to be considered. When heating a building, the overall efficiency is different when considering heating effect per unit of electric energy delivered on the customer's side of the meter, compared to the overall efficiency when also considering the losses in the power plant and transmission of power.

Hydraulic equivalent

In the energy balance of groundwater flow (see also Darcy's law) a hydraulic equivalent of Joule's law is used:[4]

 {dE \over dx} = {v_x^2 \over K}

where:

dE/dx = loss of hydraulic energy (E) due to friction of flow in x-direction per unit of time (m/day) – comparable to Q/t
v_x = flow velocity in x-direction (m/day) – comparable to I
K = hydraulic conductivity of the soil (m/day) – the hydraulic conductivity is inversely proportional to the hydraulic resistance which compares to R

References

  1. 1 2 Джоуля — Ленца закон. Большая советская энциклопедия, 3-е изд., гл. ред. А. М. Прохоров. Москва: Советская энциклопедия, 1972. Т. 8 (A. M. Prokhorov; et al., eds. (1972). "Joule–Lenz law". Great Soviet Encyclopedia (in Russian) 8. Moscow: Soviet Encyclopedia.)
  2. Electric power systems: a conceptual introduction by Alexandra von Meier, p67, Google books link
  3. Ramaswamy, Raghupathy. "Ohmic Heating of Foods". Ohio State University. Retrieved 2013-04-22.
  4. R.J.Oosterbaan, J.Boonstra and K.V.G.K.Rao (1996). The energy balance of groundwater flow (PDF). In: V.P.Singh and B.Kumar (eds.), Subsurface-Water Hydrology, Vol.2 of the Proceedings of the International Conference on Hydrology and Water Resources, New Delhi, India. Kluwer Academic Publishers, Dordrecht, The Netherlands. pp. 153–160. ISBN 978-0-7923-3651-8.
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