Carnot Cycle: Difference between revisions
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== Introduction == | == Introduction == | ||
# Isothermal expansion (No heat transfer / energy transfers): Heat is transferred from the hot reservoir to the gas. | |||
# Isentropic (reversible adiabatic: Heat transfers / no energy transfer) expansion: without transfer of heat to or from a system, so that Q = 0, is called adiabatic, and such a system is said to be adiabatically isolated. Eg. the compression of a gas within a cylinder of an engine is assumed to be rapid that little of the system's energy is transferred out as heat to the surroundings. | |||
# Isothermal compression | |||
# Isentropic compression | |||
== Ideal Gas == | == Ideal Gas == | ||
<math> pV = nRT</math> | [[File:CarnotCycle pvDiagram simple.png|thumb]] | ||
<math> pV = nRT</math>, or more generally polytropic process: <math>pV^\gamma = C</math>, where is different processes depending on the value of the ''n'': | |||
# n = 0: isobaric | |||
# n = ∞: isochoric | |||
# n = 1: isothermal | |||
# n = γ: isentropic (adiabatic) | |||
Adiabatic index <math>\gamma = c_p/c_v</math> is for the air 7/5. For the ideal gas we have | |||
<math>p^{1-\gamma} T^\gamma = C</math> and <math>TV^{\gamma-1} = C</math>. | |||
# (n=1) Isothermal compression: T is constant, thus we have <math>p =C/V </math>. | |||
# (n=γ) Isentropic <math>p=C/V^\gamma</math> | |||
Latest revision as of 09:31, 17 August 2024
Introduction
- Isothermal expansion (No heat transfer / energy transfers): Heat is transferred from the hot reservoir to the gas.
- Isentropic (reversible adiabatic: Heat transfers / no energy transfer) expansion: without transfer of heat to or from a system, so that Q = 0, is called adiabatic, and such a system is said to be adiabatically isolated. Eg. the compression of a gas within a cylinder of an engine is assumed to be rapid that little of the system's energy is transferred out as heat to the surroundings.
- Isothermal compression
- Isentropic compression
Ideal Gas
, or more generally polytropic process: , where is different processes depending on the value of the n:
- n = 0: isobaric
- n = ∞: isochoric
- n = 1: isothermal
- n = γ: isentropic (adiabatic)
Adiabatic index is for the air 7/5. For the ideal gas we have and .
- (n=1) Isothermal compression: T is constant, thus we have .
- (n=γ) Isentropic
