The conservation of energy is a fundamental concept of physics along
with the conservation of mass and the conservation of momentum. Within
some problem domain, the amount of energy remains constant and energy
is neither created nor destroyed. Energy can be converted from one form
to another (potential energy can be converted to kinetic energy) but
the total energy within the domain remains fixed. Thermodynamics is a
branch of physics which deals with the energy and work of a system. As
mentioned on the gas properties slide, thermodynamics deals only with
the large scale response of a system which we can observe and measure
in experiments. In rocketry, we are most interested in thermodynamics
in the study of propulsion systems and understanding high speed flows.
On some separate slides, we have discussed the state of a static gas,
the properties which define the state, and the first law of
thermodynamics as applied to any system, in general. On this slide we
derive a useful form of the energy conservation equation for a gas
beginning with the first law of thermodynamics. If we call the internal
energy of a gas E, the work done by the gas W, and the heat transferred
into the gas Q, then the first law of thermodynamics indicates that
between state "1" and state "2": E2 - E1 = Q - W Aerospace engineers
usually simplify a thermodynamic analysis by using intensive variables;
variables that do not depend on the mass of the gas. We call these
variables specific variables. We create a "specific" variable by taking
a property whose value depends on the mass of the system and dividing
it by the mass of the system. Many of the state properties listed on
this slide, such as the work and internal energy depend on the total
mass of gas. We will use "specific" versions of these variables.
Engineers usually use the lower case letter for the "specific" version
of a variable. Our first law equation then becomes: e2 - e1 = q - w
Because we are considering a moving gas, we add the specific kinetic
energy term to the internal energy on the left side. The normal kinetic
energy K of a moving substance is equal to 1/2 times the mass m times
the velocity u squared: K = (m * u^2) / 2 Then the specific kinetic
energy k is given by: k = (u^2) / 2 and the first law equation
becomes: e2 - e1 + k2 - k1 = q - w There are two parts to the
specific work for a moving gas. Some of the work, called the shaft work
(wsh) is used to move the fluid or turn a shaft, while the rest of the
work goes into changing the state of the gas. For a pressure p and
specific volume v, the work is given by: w = (p * v)2 - (p * v)1 + wsh
Substituting: e2 - e1 + k2 - k1 = q - (p * v)2 + (p * v)1 - wsh If we
perform a little algebra on the first law of thermodynamics, we can
begin to group some terms of the equations. : e2 + (p * v)2 - e1 - (p
* v)1 + [(u^2) / 2]2 - [(u^2) / 2]1 = q - wsh A useful additional
state variable for a gas is the specific enthalpy h which is equal to:
h = e + (p * v) Simplifying the energy equation: h2 - h1 + [(u^2) /
2]2 - [(u^2) / 2]1 = q - wsh or h2 + [(u^2) / 2]2 - h1 - [(u^2) / 2]1
= q - wsh By combining the velocity terms with the enthalpy terms to
form the total specific enthalpy "ht" we can further simplify the
equation. ht = h + u^2 / 2 The total specific enthalpy is analogous
to the total pressure in Bernoulli's equation; both expressions involve
a "static" value plus one half the square of the velocity. The final,
most useful, form of the energy equation is given in the red box. ht2
- ht1 = q - wsh For a compressor or power turbine, there is no
external heat flow into the gas and the "q" term is set equal to zero.
In the burner, no work is performed and the "wsh" term is set to zero.