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Thermodynamics III: 2nd Law

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Engine: device that converts the thermal energy of the medium into work ... Closed, unheated engine: steam cycle. Open, heated engine: gasoline engine ... – PowerPoint PPT presentation

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Title: Thermodynamics III: 2nd Law


1
Thermodynamics III 2nd Law Cycles
  • It just dont get no better than this

2
Objectives
  • Understand types of state changes
  • Comprehend thermodynamic cycles
  • Comprehend the 2nd Law of Thermodynamics to
    include entropy, reversibility, the Carnot
    cycle
  • Determine levels of output and efficiency in
    theoretical situations

3
State Changes
  • In addition to using flow/no-flow classifications
    for thermo processes, it is helpful to look at
    what happens to a medium also
  • Isobaric pressure remains constant throughout
    process (some pistons)
  • q12 h2 - h1

4
State Changes
  • Isometric volume remains constant during entire
    process
  • q12 u2 - u1
  • Adiabatic no transfer of heat to or from medium
    during process -gt usually in a rapid process
  • w u2 - u1

5
Thermodynamic Cycles
  • Defn a recurring series of thermodynamic
    processes through which an effect is produced by
    transformation or redistribution of energy
  • One classification
  • Open working fluid taken in, used, discarded
  • Closed working medium never leaves cycle, except
    through leakage medium undergoes state changes
    returns to original state

6
Five Basic Elements of all Cycles
  • Working substance transports energy within
    system
  • Heat source supplies heat to the working medium
  • Engine device that converts the thermal energy
    of the medium into work
  • Heated heat added in engine itself
  • Unheated heat received in some device separate
    from engine

7
Five Basic Elements of all Cycles
  • Heat sink/receiver absorbs heat from the working
    medium
  • Pump moves the working medium from the
    low-pressure side to the high-pressure side of
    the cycle
  • Examples
  • Closed, unheated engine steam cycle
  • Open, heated engine gasoline engine

8
Basic Thermodynamic Cycle
9
Second Law of Thermodynamics
  • Reversibility
  • the characteristic of a process which would allow
    a process to occur in the precise reverse order,
    so that the system would be returned from its
    final condition to its initial condition, AND
  • all energy that was transformed or redistributed
    during the process would be returned from its
    final to original form

10
Second Law of Thermodynamics
  • Defn 1 (Clausius statement) no process is
    possible where the sole result is the removal of
    heat from a low-temp reservoir and the absorption
    of an equal amount of heat by a high temp
    reservoir
  • Defn 2 (Kelvin-Planck) no process is possible
    in which heat is removed from a single reservoir
    w/ equiv amount of work produced

11
Second Law of Thermodynamics
  • Overall NO thermodynamic cycle can have a
    thermal efficiency of 100 (i.e., cannot convert
    all heat into work)
  • Quick review
  • 1st Law Conservation/transformation of energy
  • 2nd Law Limits the direction of processes
    extent of heat-to-work conversions

12
Entropy
  • Defn theoretical measure of thermal energy that
    cannot be transformed into mech. Work in a
    thermodynamic system
  • It is an index of the unavailability of energy or
    the reversibility of a process
  • In all real processes, entropy never decreases -gt
    entropy of universe is always rising

13
Carnot Cycle
  • Second Law states that no thermo system can be
    100 efficient, and no real thermal process is
    completely reversible
  • A French engineer, Carnot, set out to determine
    what the max efficiency of a cycle would be if
    that cycle were ideal and completely reversible

14
Carnot Cycle
  • All heat is supplied at a single high temp and
    all heat is rejected at a single low temp
  • Carnot used a simple cycle

15
Carnot Cycle
16
Carnot Cycle
  • Carnot Principle the max thermal efficiency
    depends only on the difference between the source
    and sink temps
  • Does not depend on property of fluid, type of
    engine, friction, or fuel
  • Example

17
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