Working fluid

A working fluid is a pressurized gas or liquid that actuates a machine. Examples include steam in a steam engine, air in a hot air engine and hydraulic fluid in a hydraulic motor or hydraulic cylinder. More generally, in a thermodynamic system, the working fluid is a liquid or gas that absorbs or transmits energy.

Properties and states

The working fluid properties are essential for the full description of thermodynamic systems. Although working fluids have a very large number of physical properties which can be defined, the thermodynamic properties which are often required in engineering design and analysis are few. Pressure, temperature, enthalpy, entropy, specific volume and internal energy are the most common.

If at least two thermodynamic properties are known, the state of the working fluid can be defined. This is usually done on a property diagram which is simply a plot of one property versus another.

When the working fluid passes through engineering components such as turbines and compressors, the point on a property diagram moves due to the possible changes of certain properties. In theory therefore it is possible to draw a line/curve which fully describes the thermodynamic properties of the fluid. In reality however this can only be done if the process is reversible. If not, the changes in property are represented as a dotted line on a property diagram. This issue does not really affect thermodynamic analysis since in most cases it is the end states of a process which are sought after.

Work

The working fluid can be used to output useful work if used in a turbine. Also, in thermodynamic cycles energy may be input to the working fluid by means of a compressor. The mathematical formulation for this may be quite simple if we consider a cylinder in which a working fluid resides. A piston is used to input useful work to the fluid. From mechanics, the work done from state 1 to state 2 of the process is given by

W=-\int _{1}^{2}\mathbf {F} \cdot \mathrm {d} \mathbf {s}

Where ds is the incremental distance from one state to the next and F is the force applied. The negative sign is introduced since in this case a decrease in volume is being considered. The situation is shown in the figure which follows.

The force is given by the product of the pressure in the cylinder and its cross sectional area such that

$W=-\int _{1}^{2}{\mathit {pA}}\cdot \mathrm {d} \mathbf {s}$
$W=-\int _{1}^{2}{\mathit {p}}\cdot \mathrm {d} {\mathit {V}}$

Where A.ds = dV is the elemental change of cylinder volume. If from state 1 to 2 the volume increases then the working fluid actually does work on its surroundings and this is commonly denoted by a negative work. If the volume decreases the work is positive. By the definition given with the above integral the work done is represented by the area under a pressure - volume diagram. If we consider the case where we have a constant pressure process then the work is simply given by

$W=-{\mathit {p}}\int _{1}^{2}\mathrm {d} {\mathit {V}}$
$W=-{\mathit {p}}\cdot \mathrm {(V_{2}-V_{1})}$

Choice

Depending on the application, various types of working fluids are used. In a thermodynamic cycle it may be the case that the working fluid changes state from gas to liquid or vice versa. Certain gases such as Helium can be treated as ideal gases. This is not generally the case for superheated steam and the ideal gas equation does not really hold. At much higher temperatures however it still yields relatively accurate results. The physical and chemical properties of the working fluid are extremely important when designing thermodynamic systems. For instance, in a refrigeration unit, the working fluid is called the refrigerant. Ammonia is a typical refrigerant and may be used as the primary working fluid. Compared with water (which can also be used as a refrigerant), ammonia makes use of relatively high pressures requiring more robust and expensive equipment.

In air standard cycles as in gas turbine cycles, the working fluid is air. In the open cycle gas turbine, air enters a compressor where its pressure is increased. The compressor therefore inputs work to the working fluid (positive work). The fluid is then transferred to a combustion chamber where this time heat energy is input by means of the burning of a fuel. The air then expands in a turbine thus doing work against the surroundings (negative work).

Different working fluids have different properties and in choosing one in particular the designer must identify the major requirements. In refrigeration units, high latent heats are required to provide large refrigeration capacities.

Applications and examples

The following table gives typical applications of working fluids and examples for each:

Application	Typical working fluid	Specific example
Gas turbine cycles	Air
Rankine cycles	Water/steam, pentane, toluene
Vapor-compression refrigeration, heat pumps	Chlorofluorocarbons, hydrochlorofluorocarbons, fluorocarbons, propane, butane, isobutane, ammonia, sulfur dioxide	Commercial refrigerators, Air conditioners
Reusable launch vehicle extensible vertical-landing legs	Helium^[1]	SpaceX reusable launch system development program

References

↑ Lindsey, Clark (2013-05-02). "SpaceX shows a leg for the "F-niner"". Retrieved 2013-05-02. (subscription required (help)). F9R (pronounced F-niner) shows a little leg. Design is a nested, telescoping piston w A frame... High pressure helium. Needs to be ultra light.

General

Eastop & McConkey (1993). Applied Thermodynamics for Engineering Technologists (5th Edition. ed.). Singapore: Prentice Hall. pp. 9–12. ISBN 0-582-09193-4.

Steam engines

Operating cycle

Valves

Valves	Slide D slide Piston Drop Corliss Poppet Sleeve Bash

Valve gear	Gab Stephenson link Joy Walschaerts Allan Baker Corliss Lentz Caprotti Gresley conjugated Southern

Mechanisms

Boilers

Simple boilers	Haystack Wagon Egg-ended Box Flued Cornish Lancashire

Fire-tube boilers	Locomotive Scotch Launch

Water-tube boilers	Babcock & Wilcox Field-tube Sentinel Stirling Thimble tube Three-drum Yarrow

Boiler feed	Feedwater heater Feedwater pump Injector

Other

Savery Engine (1698)

Newcomen engine

Watt engine

Beam	Kinneil Engine (1768) Old Bess (1777) Chacewater Mine engine (1778) Smethwick Engine (1779) Resolution (1781)

Rotative beam	Soho Manufactory engine (1782) Bradley Works engine (1783) Whitbread Engine (1785) National Museum of Scotland engine (1786) Lap Engine (1788)

High-pressure

Richard Trevithick
- Puffing Devil (1801)
- London Steam Carriage (1803)
- "Coalbrookdale Locomotive" (1803)
- "Pen-y-Darren" locomotive (1804)

Compound

Woolf's compound engine (1803)

Murray

Murray's Hypocycloidal Engine (1805)
Salamanca (1812)

High-speed

Porter-Allen (1862)