Thermo Lesson 2 Notes PDF

Summary

These notes cover topics in thermodynamics, including kinetic energy, potential energy, work, power, conservation of energy, and different types of processes. The notes discuss concepts like heat transfer, adiabatic processes, and convection, and include equations and diagrams.

Full Transcript

LESSON 2

What is Kinetic Energy, (KE)?

a scalar quantity [The value of work (W) depends on the
details of the interactions taking place
between the system and surroundings
during a process and not just the initial and
final states of the system]

[Work is not a property of the system or
What is Potential Energy, (PE)? the surroundings.]

What is Work?
What is Power?
Work = Force (distance)
The rate of energy transfer by work is
called POWER and is denoted by W ( with
“dot”, to indicate a time rate).

[ Energy and Work have the same units.]

What is Conservation of Energy?

[In THERMODYNAMICS, the concept of
energy is broadened to account for other
observed changes, and the principle of
conservation of energy is extended to
include a wide variety of ways in which What is Quasiequilibrium Process (or
systems interact with their surroundings] Quasistatic) Process?

departure from thermodynamic equilibrium
What is Work, (W)? is at most infinitesimal

The work done by, or on, a system
evaluated in terms of macroscopically
observable forces and displacements is What is a Polytropic Process?

A quasiequilibrium process described by

[Work is done by a system on its
surroundings if the sole effect on where n is a constant
everything external to the system could
have been the raising of a weight.]
What is Change in the total energy of a What is Heat flux, (q) ?
system?
the heat transfer rate per unit of system
surface area.

What is Internal Inergy, (U)?
where A represents the area on the
extensive property of the system boundary of the system where heat transfer
occurs

Units for the heat flux:

What is Energy Transfer by Heat?

When a gas in a rigid container interacts
with a hot plate, the energy of the gas is
increased even though no work is done. What is Adiabatic Process?

without heat transfer.

[If a system undergoes a process involving
no heat transfer with its surroundings, that
process is called an adiabatic process.]

What is Heat, (Q)? Three basic transfer mechanisms:

amount of energy transferred across 1. Conduction
the boundary of a system in a heat 2. Convection
interaction with the system’s surroundings 3. Thermal radiation

What is Conduction?
Energy transfer can take place in solids,
liquids, and gases.
[The value of a heat transfer depends on
the details of a process and not Transfer of energy from the more
just the end states.] energetic particles of a substance to
adjacent particles that are less energetic
[Heat is not a property] due to interactions between particles.

Follows Fourier’s law
What is Net rate of heat transfer, (Q)? that the rate of heat transfer across any
plane normal to the x direction, dT/dx
proportional to the wall area, A, and the
temperature gradient in the x direction,
dT/dx:
What is Fourier’s law? [ In general, the net rate of energy transfer
by thermal radiation between two surfaces
rate of heat transfer across any plane involves relationships among the properties
normal to the x direction, dT/dx proportional of the surfaces, their orientations with
to the wall area, A, and the temperature respect to each other, the extent to which
gradient in the x direction, dT/dx: the intervening medium scatters, emits, and
absorbs thermal radiation, and other factors.]

The net rate of radiant exchange between
the smaller surface, whose area is A and
emissivity is ε, and the larger surroundings
is:
[Substances with large values of thermal
conductivity such as copper are good
conductors, and those with
Small conductivities (cork and polystyrene
foam) are good insulators.]

What is Radiation? What is Convection?

Thermal radiation is emitted by matter as a energy transfer between a solid surface
result of changes in the electronic at a temperature Tb and an adjacent gas
configurations of the atoms or molecules or liquid at another temperature Tf. It plays
within it. a prominent role in the performance of many
devices of practical interest.
Energy is transported by
electromagnetic waves (or photons).
The rate of energy transfer from the surface
Requires no intervening medium to to the air can be quantified by the following
propagate and can even take place in a empirical expression which follows
vacuum. NEWTON’S LAW OF COOLING:

[Solid surfaces, gases, and liquids all emit,
absorb, and transmit thermal
radiation to varying degrees.]

[The heat transfer coefficient is not a
thermodynamic property.]
What is Stefan–Boltzmann Law Radiation
Equation? [It is an empirical parameter that
incorporates into the heat transfer
shows that the thermal radiation is relationship the nature of the flow pattern
associated with the fourth power of the near the surface, the fluid properties, and
absolute temperature of the surface, Tb. the geometry.]

Comparison of Heat and Work

Heat and work are both transient
phenomena.

Where: Systems never possess heat or work,
Emissivity (ε) - property of the surface that but either or both cross the system
indicates how effectively boundary when a system undergoes a
the surface radiates (0≤ ε ≤ 1.0) change of state.
 Both heat and work are boundary
phenomena. Both are observed only at the
boundary of the system, and both represent
energy crossing the boundary.

Both heat and work are path functions
and inexact differentials.

What is the First Law of Thermodynamics?

application of the conservation of energy
principle to heat and thermodynamic
processes:

[“The change in internal energy of a
system is equal to the heat added to
the system minus the work done by
the system.”]

Energy Balance

symbols

differential form

instantaneous time rate form

rate form