Compressor

 ( Heating, Ventilation, And Air Conditioning ) 

The degree of flexing and the material constituting the diaphragm affects the maintenance life of the equipment. Generally stiff metal diaphragms may only displace a few cubic centimeters of volume because the metal cannot endure large degrees of flexing without cracking, but the stiffness of a metal diaphragm allows it to pump at high pressures. Rubber or silicone diaphragms are capable of enduring deep pumping strokes of very high flexion, but their low strength limits their use to low-pressure applications, and they need to be replaced as plastic embrittlement occurs.

Diaphragm compressors are used for hydrogen and compressed natural gas (CNG) as well as in a number of other applications.

The photograph on the right depicts a three-stage diaphragm compressor used to compress hydrogen gas to for use in a prototype compressed hydrogen and compressed natural gas (CNG) fueling station built in downtown Phoenix, Arizona by the Arizona Public Service company (an electric utilities company). Reciprocating compressors were used to compress the natural gas. The reciprocating natural gas compressor was developed by Sertco.

The prototype station was built in compliance with all of the prevailing safety, environmental and building codes in Phoenix to demonstrate that such fueling stations could be built in urban areas.

This type of compressor, along with screw compressors, are extensively used in large refrigeration and air conditioning systems. Magnetic bearing (magnetically levitated) and air bearing centrifugal compressors exist.

Many large snowmaking operations (like ski resorts) use this type of compressor. They are also used in internal combustion engines as and . Centrifugal compressors are used in small gas turbine or as the final compression stage of medium-sized gas turbines.

Centrifugal compressors are the largest available compressors, offer higher efficiencies under partial loads, may be oil-free when using air or magnetic bearings which increases the heat transfer coefficient in evaporators and condensers, weigh up to 90% less and occupy 50% less space than reciprocating compressors, are reliable and cost less to maintain since less components are exposed to wear, and only generate minimal vibration. But, their initial cost is higher, require highly precise CNC machining, the impeller needs to rotate at high speeds making small compressors impractical, and surging becomes more likely. Surging is gas flow reversal, meaning that the gas goes from the discharge to the suction side, which can cause serious damage, specially in the compressor bearings and its drive shaft. It is caused by a pressure on the discharge side that is higher than the output pressure of the compressor. This can cause gases to flow back and forth between the compressor and whatever is connected to its discharge line, causing oscillations.

The arrays of airfoils are set in rows, usually as pairs: one rotating and one stationary. The rotating airfoils, also known as blades or rotors, accelerate the fluid. The stationary airfoils, also known as stators or vanes, decelerate and redirect the flow direction of the fluid, preparing it for the rotor blades of the next stage. Axial compressors are almost always multi-staged, with the cross-sectional area of the gas passage diminishing along the compressor to maintain an optimum axial Mach number. Beyond about 5 stages or a 4:1 design pressure ratio a compressor will not function unless fitted with features such as stationary vanes with variable angles (known as variable inlet guide vanes and variable stators), the ability to allow some air to escape part-way along the compressor (known as interstage bleed) and being split into more than one rotating assembly (known as twin spools, for example).

Axial compressors can have high efficiencies; around 90% polytropic at their design conditions. However, they are relatively expensive, requiring a large number of components, tight tolerances and high quality materials. Axial compressors are used in medium to large gas turbine engines, natural gas pumping stations, and some chemical plants.

In hermetic and most semi-hermetic compressors, the compressor and motor driving the compressor are integrated, and operate within the pressurized gas envelope of the system. The motor is designed to operate in, and be cooled by, the refrigerant gas being compressed. Open compressors have an external motor driving a shaft that passes through the body of the compressor and rely on rotary seals around the shaft to retain the internal pressure.

The difference between the hermetic and semi-hermetic, is that the hermetic uses a one-piece welded steel casing that cannot be opened for repair; if the hermetic fails it is simply replaced with an entire new unit. A semi-hermetic uses a large cast metal shell with gasketed covers with screws that can be opened to replace motor and compressor components. The primary advantage of a hermetic and semi-hermetic is that there is no route for the gas to leak out of the system. The main advantages of open compressors is that they can be driven by any motive power source, allowing the most appropriate motor to be selected for the application, or even non-electric power sources such as an internal combustion engine or steam turbine, and secondly the motor of an open compressor can be serviced without opening any part of the refrigerant system.

An open pressurized system such as an automobile air conditioner can be more susceptible to leak its operating gases. Open systems rely on lubricant in the system to splash on pump components and seals. If it is not operated frequently enough, the lubricant on the seals slowly evaporates, and then the seals begin to leak until the system is no longer functional and must be recharged. By comparison, a hermetic or semi-hermetic system can sit unused for years, and can usually be started up again at any time without requiring maintenance or experiencing any loss of system pressure. Even well lubricated seals will leak a small amount of gas over time, particularly if the refrigeration gasses are soluble in the lubricating oil, but if the seals are well manufactured and maintained this loss is very low.

The disadvantage of hermetic compressors is that the motor drive cannot be repaired or maintained, and the entire compressor must be replaced if a motor fails. A further disadvantage is that burnt-out windings can contaminate the whole systems, thereby requiring the system to be entirely pumped down and the gas replaced (This can also happen in semi hermetic compressors where the motor operates in the refrigerant). Typically, hermetic compressors are used in low-cost factory-assembled consumer goods where the cost of repair and labor is high compared to the value of the device, and it would be more economical to just purchase a new device or compressor. Semi-hermetic compressors are used in mid-sized to large refrigeration and air conditioning systems, where it is cheaper to repair and/or refurbish the compressor compared to the price of a new one. A hermetic compressor is simpler and cheaper to build than a semi-hermetic or open compressor.

The enthalpy change for a flow process can be calculated.

dH = VdP +TdS

Isentropic dS is zero.

dH = VdP

Non flow isentropic processes like some positive displacement compressors may use a different equation.

dH = PdV

By defining the compression cycle as isentropic, an ideal efficiency for the process can be attained, and the ideal compressor performance can be compared to the actual performance of the machine. Isotropic Compression as used in ASME PTC 10 Code refers to a reversible, adiabatic compression process

Isentropic efficiency of Compressors:

$\backslash eta\; \_C\; =\; \backslash frac\{\backslash rm\; Isentropic\; \backslash ;Compressor\backslash ;Work\}\{\backslash rm\; Actual\backslash ;Compressor\backslash ;\; Work\}=\backslash frac\{W\_s\}\{W\_a\}\; \backslash cong\; \backslash frac\{h\_\{2s\}-h\_1\}\{h\_\{2a\}-h\_1\}$

$h\_1$ is the enthalpy at the initial state

$h\_\{2a\}$ is the enthalpy at the final state for the actual process

$h\_\{2s\}$ is the enthalpy at the final state for the isentropic process

Let $q$ be heat, $w$ be work, $ke$ be kinetic energy, and $pe$ be potential energy.

Actual Compressor:

$\backslash delta\; q\_\{act\}\; -\; \backslash delta\; w\_\{actelta\; q\_\{act\}\}\{T\}\; \backslash geq\; 0$

or
$w\_\{rev\}\; \backslash geq\; w\_\{act\}$

Therefore, work-consuming devices such as pumps and compressors (work is negative) require less work when they operate reversibly.

By making the following assumptions the required work for the compressor to compress a gas from $P\_1$ to $P\_2$ is the following for each process:

$P\_1$ and $P\_2$

Flow processes VdP

All processes are internally reversible

The gas behaves like an ideal gas with constant specific heats

Isentropic ($Pv^k\; =\; constant$, where $k\; =\; C\_p/C\_v$):

$W\_\{comp,in\}=\; \backslash frac\{kR(T\_2-T\_1)\}\{k-1\}=\backslash frac\{kRT\_1\}\{k-1\}\; \backslash left$

Polytropic ($Pv^n\; =\; constant$):

$W\_\{comp,in\}=\; \backslash frac\{nR(T\_2-T\_1)\}\{n-1\}=\backslash frac\{nRT\_1\}\{n-1\}\; \backslash left$

Isothermal ($T\; =\; constant$ or $Pv\; =\; constant$):

$W\_\{comp,in\}=\; RT\; ln\; \backslash left\; (\; \backslash frac\{P\_2\}\{P\_1\}\backslash right\; )$

By comparing the three internally reversible processes compressing an ideal gas from $P\_1$ to $P\_2$, the results show that isentropic compression ($Pv^k\; =\; constant$) requires the most work in and the isothermal compression($T\; =\; constant$ or $Pv\; =\; constant$) requires the least amount of work in. For the polytropic process ($Pv^n\; =\; constant$) work decreases as the exponent, n, decreases, by increasing the heat rejection during the compression process. One common way of cooling the gas during compression is to use cooling jackets around the casing of the compressor.

For a polytropic transformation of a gas:

$\backslash begin\{cases\}$

The work done for polytropic compression (or expansion) of a gas into a closed cylinder.

$W\; =\; \backslash int\_\{V\_1\}^\{V\_2\}\; p\; dV\; =\; p\_1\; V\_1^n\; \backslash int\_\{V\_1\}^\{V\_2\}\; V^\{-n\}\; dV\; =\; \backslash frac\{p\_1\; V\_1^n\}\{1-n\}\; (V\_2^\{1-n\}\; -\; V\_1^\{1-n\})\; =\; \backslash frac\{p\_1\; V\_1^n\}\{1-n\}\; V\_1^\{1-n\}\; \backslash left(\; \backslash frac\{V\_2^\{1-n\}\}\{V\_1^\{1-n\}\}\; -1\; \backslash right)\; =\; \backslash frac\{p\_1\; V\_1\}\{1-n\}\; \backslash left(\; \backslash frac\{V\_2^\{1-n\}\}\{V\_1^\{1-n\}\}\; -1\; \backslash right)\; =$

$=\; \backslash frac\{p\_1\; V\_1\}\{1-n\}\; \backslash left(\; \backslash left(\; \backslash frac\{V\_1\}\{V\_2\}\; \backslash right)^\{n-1\}\; -1\; \backslash right)\; =\; \backslash frac\{p\_1\; V\_1\}\{1-n\}\; \backslash left(\; \backslash left(\; \backslash frac\{p\_2\}\{p\_1\}\; \backslash right)^\{\backslash frac\{n-1\}\{n\}\}\; -1\; \backslash right)\; =\; \backslash frac\{p\_1\; V\_1\}\{1-n\}\; \backslash left(\; \backslash frac\{T\_2\}\{T\_1\}\; -1\; \backslash right)$

so

$W\; =\; -\; \backslash frac\{p\_1\; V\_1\}\{n-1\}\; \backslash left(\; \backslash left(\; \backslash frac\{p\_2\}\{p\_1\}\; \backslash right)^\{\backslash frac\{n-1\}\{n\}\}\; -1\; \backslash right)$

in which p is pressure, V is volume, n takes different values for different compression processes (see below), and 1 & 2 refer to initial and final states.

• Adiabatic – This model assumes that no energy (heat) is transferred to or from the gas during the compression, and all supplied work is added to the internal energy of the gas, resulting in increases of temperature and pressure. Theoretical temperature rise is: Perry's Chemical Engineer's Handbook 8th edition