Now let us discuss each in detail in the following paragraphs. The compression may be isothermal, isentropic, or polytropic compression. The delivery of air takes place from 2-3.ġ-2 : suction stroke (air is drawn into the cylinder)Ģ-3 : compression stroke (air gets compressed inside the cylinder)Ĥ-1 : delivery closes and the suction valve opens for admitting fresh air inside the cylinder The air will be delivered when sufficient pressure has been reached so that the valves can be opened. Now, the pressure rises from P1 to P2 from 2-3. The air is compressed during the compression stroke (2-3) at constant temperature (T1=T2). In this diagram, the path 2-3 represents the polytropic compression and the path 2-3' represents the isothermal compression and the path 2-3" represents the isentropic compression.įrom the above diagram it is clear that the air is drawn in by the cylinder during the suction stroke (1-2). The energy density of a fluid can be expressed in terms of this potential energy density along with kinetic energy density and fluid pressure.Now let us discuss the PV and TS diagrams of a single acting, single stage reciprocating compressor without clearance volume, The potential energy of a moving fluid is more useful in applications like the Bernoulli equation when it is expressed as potential energy per unit volume Expressed in terms of the maximum velocity v m at the center of the flow, the kinetic energy is Across the cross-section of flow, the kinetic energy must be calculated using the average of the velocity squared, which is not the same as squaring the average velocity. When the kinetic energy is that of fluid under conditions of laminar flow through a tube, one must take into account the velocity profile to evaluate the kinetic energy. The kinetic energy of a moving fluid is more useful in applications like the Bernoulli equation when it is expressed as kinetic energy per unit volume The energy density which keeps a star from collapsing is expressed as radiation pressure. For example, the energy density of solvent molecules which leads to osmosis is expressed as osmotic pressure. The other side of the coin is that energy densities from other causes can be conveniently expressed as an effective "pressure". The most obvious application is to the hydrostatic pressure of a fluid, where pressure can be used as energy density alongside kinetic energy density and potential energy density in the Bernoulli equation. For a force exerted on a fluid, this can be seen from the definition of pressure: Pressure in a fluid may be considered to be a measure of energy per unit volume or energy density. This energy is related to other forms of fluid energy by the Bernoulli equation. Pressure in a fluid can be seen to be a measure of energy per unit volume by means of the definition of work. But when you deal with a gas pressure, it must be approached as an average pressure from molecular collisions with the walls. When you deal with the pressure of a liquid at rest, the medium is treated as a continuous distribution of matter. If you must get an injection, then pressure is the most important variable in getting the needle through your skin: it is better to have a sharp needle than a dull one since the smaller area of contact implies that less force is required to push the needle through the skin. If you are peeling an apple, then pressure is the key variable: if the knife is sharp, then the area of contact is small and you can peel with less force exerted on the blade. There are many physical situations where pressure is the most important variable. The standard unit for pressure is the Pascal, which is a Newton per square meter.įor an object sitting on a surface, the force pressing on the surface is the weight of the object, but in different orientations it might have a different area in contact with the surface and therefore exert a different pressure. It is usually more convenient to use pressure rather than force to describe the influences upon fluid behavior. Pressure is defined as force per unit area.
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