Trane Air Conditioner TRG TRC003 EN User Manual

Air Conditioning  
Clinic  
Refrigeration Cycle  
One of the Fundamental Series  
TRG-TRC003-EN  
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THE TRANE COMPANY  
Attn: Applications Engineering  
3600 Pammel Creek Road  
La Crosse WI 54601-9985  
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IN THE  
UNITED STATES  
BUSINESS REPLY MAIL  
LA CROSSE, WI  
FIRST-CLASS MAIL  
PERMIT NO. 11  
POSTAGE WILL BE PAID BY ADDRESSEE  
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Attn: Applications Engineering  
3600 Pammel Creek Road  
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The Trane Company • Worldwide  
Applied Systems Group  
3600 Pammel Creek Road • La Crosse, WI 54601-7599  
An American-Standard Company  
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The Trane Company • Worldwide Applied Systems Group  
3600 Pammel Creek Road • La Crosse, WI 54601-7599  
An American-Standard Company  
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Preface  
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$ꢀ7UDQHꢀ$LUꢀ&RQGLWLRQLQJꢀ&OLQLF  
Figure 1  
The Trane Company believes that it is incumbent on manufacturers to serve the  
industry by regularly disseminating information gathered through laboratory  
research, testing programs, and field experience.  
The Trane Air Conditioning Clinic series is one means of knowledge sharing. It  
is intended to acquaint a nontechnical audience with various fundamental  
aspects of heating, ventilating, and air conditioning.  
We have taken special care to make the clinic as uncommercial and  
straightforward as possible. Illustrations of Trane products only appear in cases  
where they help convey the message contained in the accompanying text.  
This particular clinic introduces the concept of the vapor-compression  
refrigeration cycle. The absorption refrigeration cycle is the subject of a  
separate clinic.  
© 1999 American Standard Inc. All rights reserved  
TRG-TRC003-EN  
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Contents  
period one  
period two  
Heat and Refrigeration ....................................... 1  
What is Heat? ......................................................... 2  
Principles of Heat Transfer ...................................... 4  
Refrigerants ............................................................ 9  
Change of Phase ................................................... 12  
Modern Refrigerants ............................................. 16  
period three Refrigeration Cycle ............................................ 17  
Closing the Cycle .................................................. 18  
Basic Refrigeration System .................................... 22  
period four Pressure–Enthalpy Chart ................................. 26  
period five  
Review ................................................................... 35  
Quiz ......................................................................... 39  
Answers ................................................................ 42  
Glossary ................................................................ 44  
TRG-TRC003-EN  
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iv  
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period one  
Heat and Refrigeration  
notes  
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Figure 2  
Before discussing the refrigeration system, we need to understand the terms  
heat and refrigeration.  
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Figure 3  
The term refrigeration is commonly associated with something cold. A  
household refrigerator, for example, keeps food cold. It accomplishes this task  
by removing heat from the food. Therefore, refrigeration involves the removal  
of heat. The word cold describes a state of low heat content.  
To understand how refrigeration works, we first need to understand what heat  
is and how it is removed from a substance.  
TRG-TRC003-EN  
1
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period one  
Heat and Refrigeration  
notes  
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Figure 4  
What is Heat?  
Heat is a form of energy. Every object on earth contains heat energy in both  
quantity and intensity.  
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Figure 5  
Heat intensity is measured by its temperature, commonly in either degrees  
Fahrenheit (°F) or degrees Celsius (°C). If all heat were removed from an  
object, the temperature of the object would decrease to -459.6°F [-273.2°C].  
This temperature is referred to as “absolute zero” and is the temperature at  
which all molecular activity stops.  
The quantity of heat contained in an object or substance is not the same as its  
intensity of heat. For example, the hot sands of the desert contain a large  
quantity of heat, but a single burning candle has a higher intensity of heat.  
2
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period one  
Heat and Refrigeration  
notes  
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Figure 6  
These two different masses of water contain the same quantity of heat, yet the  
temperature of the water on the left is higher. Why? The water on the left  
contains more heat per unit of mass than the water on the right. In other words,  
the heat energy within the water on the left is more concentrated, or intense,  
resulting in the higher temperature. Note that the temperature of a substance  
does not reveal the quantity of heat that it contains.  
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Figure 7  
In the English system of units, the quantity of heat is measured in terms of the  
British Thermal Unit (Btu). The Btu is defined as the quantity of heat energy  
required to raise the temperature of 1 lb of water by 1°F.  
Similarly, in the metric system of units, the quantity of heat is measured in  
terms of the kilocalorie (kilogram-calorie or kcal). The kcal is defined as the  
amount of heat energy required to raise the temperature of 1 kg of water 1°C.  
Alternatively, in the Systeme International (SI) metric system, heat quantity can  
be expressed using the unit kiloJoule (kJ). One kcal is equal to 4.19 kJ.  
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period one  
Heat and Refrigeration  
notes  
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s +HDWꢀHQHUJ\ꢀFDQQRWꢀEHꢀGHVWUR\HG  
s +HDWꢀDOZD\VꢀIORZVꢀIURPꢀDꢀKLJKHUꢀWHPSHUDWXUH  
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s +HDWꢀFDQꢀEHꢀWUDQVIHUUHGꢀIURPꢀRQHꢀVXEVWDQFHꢀWR  
DQRWKHU  
Figure 8  
Principles of Heat Transfer  
Air-conditioning and refrigeration systems use the principles of heat transfer to  
produce cooling and heating. The three principles discussed in this clinic are:  
Heat energy cannot be destroyed; it can only be transferred to another  
substance  
Heat energy flows from a higher temperature substance to a lower  
temperature substance  
Heat energy is transferred from one substance to another by one of three  
basic processes  
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Figure 9  
To produce cooling, heat must be removed from the substance by transferring  
it to another substance. The first principle to discuss regarding heat transfer is  
that heat energy cannot be destroyed; it can only be transferred to another  
4
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period one  
Heat and Refrigeration  
substance. This is commonly referred to as the principle of “conservation of  
energy.”  
notes  
Ice cubes are typically placed in a beverage to cool it before it is served. As heat  
is transferred from the beverage to the ice, the temperature of the beverage is  
lowered. The heat removed from the beverage is not destroyed but instead is  
absorbed by the ice, changing the ice from a solid to a liquid.  
+HDWꢀ)ORZVꢀIURPꢀ+RWꢀWRꢀ&ROG  
Figure 10  
The second principle is that heat naturally flows from a higher temperature  
substance to a lower temperature substance; in other words, from hot to cold.  
Heat cannot flow from a cold substance to a hot substance.  
Consider the example of the beverage and the ice cubes. As long as the  
temperature of the beverage is higher than the temperature of the ice cubes,  
heat will always flow from the beverage to the ice cubes.  
TRG-TRC003-EN  
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period one  
Heat and Refrigeration  
notes  
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FRQYHFWLRQ  
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Figure 11  
The third principle is that heat is transferred from one substance to another by  
one of three basic processes: conduction, convection, and radiation. The device  
shown is a baseboard convector that is commonly used for heating a space. It  
can be used to demonstrate all three processes of transferring heat.  
Hot water flows through a tube inside the convector, warming the inside  
surface of the tube. Heat is transferred, by conduction, through the tube wall to  
the slightly cooler fins that are attached to outside surface of the tube.  
Conduction is the process of transferring heat through a solid.  
The heat is then transferred to the cool air that comes into contact with the fins.  
As the air is warmed and becomes less dense, it rises, carrying the heat away  
from the fins and out of the convector. This air movement is known as a  
convection current. Convection is the process of transferring heat as the result  
of the movement of a fluid. Convection often occurs as the result of the natural  
movement of air caused by temperature (density) differences.  
Additionally, heat is radiated from the warm cabinet of the convector and  
contacts cooler objects within the space. Radiation is the process of  
transferring heat by means of electromagnetic waves, emitted due to the  
temperature difference between two objects. An interesting thing about  
radiated heat is that it does not heat the air between the source and the object it  
contacts; it only heats the object itself.  
6
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period one  
Heat and Refrigeration  
notes  
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Figure 12  
In refrigeration, as in heating, emphasis is placed on the rate of heat transfer,  
that is, the quantity of heat that flows from one substance to another within a  
given period of time. This rate of heat flow is commonly expressed in terms of  
Btu/hr—the quantity of heat, in Btus, that flows from one substance to another  
over a period of 1 hour.  
Similarly, in the SI metric system of units, the rate of heat flow is expressed in  
terms of kilowatts (kW), which are equivalent to kJ/sec. Kilowatts describe the  
quantity of heat, in kJ, that flows from one substance to another over a period  
of 1 second.  
TRG-TRC003-EN  
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period one  
Heat and Refrigeration  
notes  
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Figure 13  
In the English system of units, there is a larger and more convenient measure of  
the rate of heat flow. It is called a ton of refrigeration. One ton of refrigeration  
produces the same cooling effect as the melting of 2000 lb of ice over a 24-hour  
period.  
When 1 lb of ice melts, it absorbs 144 Btu. Therefore, when 1 ton (2000 lb) of ice  
melts, it absorbs 288,000 Btu (2000 x 144). Consequently, 1 ton of refrigeration  
absorbs 288,000 Btu within a 24-hour period or 12,000 Btu/hr (288,000/24).  
So, 1 ton of refrigeration is defined as the transfer of heat at the rate of 12,000  
Btu/hr [3.517 kW].  
8
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period two  
Refrigerants  
notes  
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Figure 14  
In this period we will discuss refrigerants, the substances used to absorb and  
transfer heat for the purpose of cooling.  
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Figure 15  
Ice can be used to preserve food. Because heat flows from a higher temperature  
substance to a lower temperature substance, ice can be used in a frozen display  
case to absorb heat from the relatively warm food, cooling the food. As the ice  
absorbs heat, it melts and is drained away.  
Used in this manner, ice is a coolant. It absorbs heat from the food and  
transports the heat away from the food.  
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period two  
Refrigerants  
notes  
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Figure 16  
Pure ice, however, does have an important disadvantage. It absorbs heat and  
melts at 32°F [0°C]. Ice cream, for example, melts at a temperature lower than  
32°F [0°C]. In the same frozen display case, ice cannot keep the ice cream frozen  
because ice melts at a higher temperature than ice cream.  
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Figure 17  
There is another type of ice known as dry ice, which is solid (frozen) carbon  
dioxide (CO2). It evaporates directly from a solid phase to a vapor phase at  
-109.4°F [-78.6°C]. Used in the same frozen display case, dry ice would keep the  
ice cream frozen because it evaporates at a lower temperature than the  
temperature at which ice cream melts, but would result in an unnecessarily low  
temperature.  
Additionally, both pure ice and dry ice would be consumed in the cooling  
process, either melting away as a liquid or evaporating into a vapor. It would  
have to be continually replaced.  
10  
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period two  
Refrigerants  
notes  
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Figure 18  
Finally, Refrigerant-22 (R-22) is a chemical used in many refrigeration systems.  
If, hypothetically, an open container of liquid R-22 were placed in the frozen  
display case, when exposed to atmospheric pressure, it would absorb heat and  
boil violently at -41.4°F [-40.8°C].  
This is a hypothetical example because chemical refrigerants have  
environmental regulations that legally require the refrigeration system to be  
sealed. Any loss of refrigerant to the atmosphere is closely monitored and,  
generally speaking, not allowed.  
At atmospheric pressure, each of these three substances (pure ice, dry ice, and  
R-22) absorbs heat and changes phase at its own fixed temperature. Pure ice  
melts at 32°F [0°C], dry ice evaporates at -109.4°F [-78.6°C], and R-22 boils at  
-41.4°F [-40.8°C].  
Why do we want a substance to change phase while producing refrigeration?  
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period two  
Refrigerants  
notes  
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Figure 19  
Change of Phase  
This question is best answered by examining the effects of heat transfer on  
water. Consider 1 lb of 60°F water. By adding or subtracting 1 Btu of heat  
energy, the water temperature is raised or lowered by 1°F.  
Similarly, by adding or subtracting 1 kcal (4.2 kJ) of heat energy to a 1 kg  
container of 15°C water, the water temperature is raised or lowered by 1°C.  
(IIHFWꢀRIꢀ7UDQVIHUULQJꢀ+HDW  
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Figure 20  
Therefore, adding 152 Btu to 1 lb of 60°F water raises its temperature to 212°F.  
Although this is the boiling temperature of water at atmospheric pressure,  
adding 1 more Btu will not cause all of the water to evaporate.  
Similarly, adding 85 kcal (356 kJ) to 1 kg of 15°C water raises its temperature to  
100°C. Although this is the boiling temperature of water at atmospheric  
pressure, adding 1 more kcal (4.2 kJ) will not cause all of the water to  
evaporate.  
12  
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period two  
Refrigerants  
notes  
(IIHFWꢀRIꢀ7UDQVIHUULQJꢀ+HDW  
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Figure 21  
In fact, 970.3 Btu must be added to 1 lb of 212°F water to completely transform  
it to 1 lb of steam at the same temperature.  
Similarly, 244.5.3 kcal (1023 kJ) must be added to 1 kg of 100°C water to  
completely transform it to 1 kg of steam at the same temperature.  
(IIHFWꢀRIꢀ7UDQVIHUULQJꢀ+HDW  
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Figure 22  
Conversely, when 1 lb of 212°F steam condenses, it gives off 970.3 Btu of heat  
energy in the process. After the steam condenses completely, the removal of  
more heat will begin to lower the temperature of the water below 212°F.  
Similarly, when 1 kg of 100°C steam condenses, it gives off 244.5 kcal (1023 kJ)  
of heat energy in the process. After the steam condenses completely, the  
removal of more heat will begin to lower the temperature of the water below  
100°C.  
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period two  
Refrigerants  
notes  
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Figure 23  
The quantity of heat that must be added to the water in order for it to evaporate  
cannot be sensed by an ordinary thermometer. This is because both the water  
and steam remain at the same temperature during this phase change.  
This kind of heat is called latent heat, which is dormant or concealed heat  
energy. Latent heat is the energy involved in changing the phase of a  
substance—from a liquid to a vapor in this example.  
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Figure 24  
In contrast, sensible heat is heat energy that, when added to or removed from  
a substance, results in a measurable change in temperature.  
Refrigerants can absorb a significant amount of heat when they change phase;  
much more than if they just change temperature. Different substances have  
different specific temperatures at which these phase changes occur, and  
different quantities of heat are required for this change to take place. They also  
14  
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period two  
Refrigerants  
have different capacities for absorbing heat. This capacity is a property of the  
substance called specific heat.  
notes  
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$
%
Figure 25  
Suppose equal quantities of two different liquids, $ and %, both at room  
temperature, are heated. The gas burners are lighted and adjusted so that each  
is burning exactly the same quantity of gas over the same time period, ensuring  
that each container of liquid receives the same quantity of heat. After a period  
of time, the thermometer in the container of liquid $ indicates 140°F [60°C],  
while the thermometer in the container of liquid % indicates 200°F [93.3°C].  
Even though equal quantities of the two liquids were supplied with exactly the  
same quantity of heat, why does liquid % reach a higher temperature than  
liquid $?  
The reason is that liquid % has less capacity for absorbing heat than liquid $.  
This capacity for absorbing heat is called specific heat. The specific heat of a  
substance is defined as the quantity of heat, in Btus, required to raise the  
temperature of 1 lb of that substance 1°F.  
Similarly, in metric units, specific heat is defined as the quantity of heat, in kJs,  
required to raise the temperature of 1 kg of that substance 1°C.  
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period two  
Refrigerants  
notes  
0RGHUQꢀ5HIULJHUDQWV  
Figure 26  
Modern Refrigerants  
Refrigerants are substances that are used to absorb and transport heat for the  
purpose of cooling. When selecting a refrigerant to use for a given application,  
in addition to these heat transfer properties the manufacturer considers  
efficiency, operating pressures, compatibility with materials, stability, toxicity,  
flammability, cost, availability, safety, and environmental impact.  
The most common refrigerants used in mechanical refrigeration systems today  
are Refrigerant-123 (or R-123), R-134a, and R-22. Ammonia (R-717) and, under  
certain operating pressures, even water (R-718) and carbon dioxide (R-744) can  
be used as refrigerants.  
Refrigerant-22 has been the most widely used refrigerant in residential,  
commercial, and industrial applications since the 1940s. For the purposes of  
this clinic, it will be used as the refrigerant in the examples.  
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period three  
Refrigeration Cycle  
notes  
5HIULJHUDWLRQꢀ&\FOH  
SHULRGꢀWKUHH  
5HIULJHUDWLRQꢀ&\FOH  
Figure 27  
The frozen display case example used in the last period demonstrates that, at a  
given pressure, refrigerants absorb heat and change phase at a fixed  
temperature. It also shows how these refrigerants are “consumed” in the  
cooling process, either melting into a liquid or evaporating into a vapor.  
This period discusses how the refrigerant can be recovered and reused to  
continue the refrigeration cycle.  
5HIULJHUDWLRQꢀ6\VWHP  
DLUIORZ  
OLTXLGꢇUHIULJHUDQW  
ꢐ5ꢌꢈꢈꢑ  
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UHIULJHUDQW  
ꢌꢂꢀꢄꢂƒ)  
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Figure 28  
A rudimentary refrigeration system could hypothetically be constructed using a  
drum of liquid refrigerant at atmospheric pressure, a coil, a collecting drum,  
and a valve to regulate the flow of refrigerant into the coil. Opening the valve  
allows the liquid refrigerant to flow into the coil by gravity. As warm air is  
blown over the surface of the coil, the liquid refrigerant inside the coil will  
absorb heat from the air, eventually causing the refrigerant to boil while the air  
is cooled. Adjustment of the valve makes it possible to supply just enough  
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period three  
Refrigeration Cycle  
liquid refrigerant to the coil so that all the refrigerant evaporates before it  
reaches the end of the coil.  
notes  
One disadvantage of this system is that after the liquid refrigerant passes  
through the coil and collects in the drum as a vapor, it cannot be reused. The  
cost and environmental impacts of chemical refrigerants require the  
refrigeration process to continue without loss of refrigerant.  
Additionally, the boiling temperature of R-22 at atmospheric pressure is -41.4°F  
[-40.8°C]. At this unnecessarily low temperature, the moisture contained in the  
air passing through the coil freezes on the coil surface, ultimately blocking it  
completely.  
5HIULJHUDWLRQꢀ6\VWHP  
HYDSRUDWRU  
OLTXLG  
UHIULJHUDQW  
"
UHIULJHUDQW  
YDSRU  
Figure 29  
Closing the Cycle  
To solve the first problem, a system is needed to collect this used refrigerant  
and return it to the liquid phase. Then the refrigerant can be passed through the  
coil again.  
This is exactly what happens in a typical mechanical refrigeration system.  
Liquid refrigerant absorbs heat and evaporates within a device called an  
evaporator. In this example system, air is cooled when it passes through the  
evaporator, while the heat is transferred to the refrigerant, causing it to boil and  
change into a vapor. As discussed in the previous period, a refrigerant can  
absorb a large amount of heat when it changes phase. Because of the  
refrigerant changing phase, the system requires far less refrigerant than if the  
refrigerant was just increasing in temperature.  
The refrigerant vapor must then be transformed back into a liquid in order to  
return to the evaporator and repeat the process.  
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period three  
Refrigeration Cycle  
notes  
5HIULJHUDWLRQꢀ6\VWHP  
UHIULJHUDQW  
ꢇꢌꢇꢇKHDWꢇꢇ  
 
OLTXLG  
UHIULJHUDQW  
YDSRU  
ꢌꢂꢀꢄꢂƒ)  
>ꢌꢂꢁꢄꢎƒ&@  
VXEVWDQFH  
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ꢌꢂꢀꢄꢂƒ)  
>ꢌꢂꢁꢄꢎƒ&@  
Figure 30  
The liquid refrigerant absorbed heat from the air while it was inside the  
evaporator, and was transformed into a vapor in the process of doing useful  
cooling. Earlier in this clinic, we demonstrated that if the heat is then removed  
from this vapor, it will transform (condense) back to its original liquid phase.  
Heat flows from a higher temperature substance to a lower temperature  
substance. In order to remove heat from the refrigerant vapor, it must transfer  
this heat to a substance that is at a lower temperature. Assume that the  
refrigerant evaporated at -41.4°F [-40.8°C]. To condense back into liquid, the  
refrigerant vapor must transfer heat to a substance that has a temperature less  
than -41.4°F [-40.8°C]. If a substance were readily available at this cooler  
temperature, however, the refrigerant would not be required in the first place.  
The cooler substance could accomplish the cooling by itself.  
How can heat be removed from this cool refrigerant vapor, to condense it, using  
a readily-available substance that is already too warm for use as the cooling  
medium? What if we could change the temperature at which the refrigerant  
vapor condenses back into liquid?  
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period three  
Refrigeration Cycle  
notes  
%RLOLQJꢀ3RLQWꢀRIꢀ:DWHU  
ꢈꢀꢈƒ)  
>ꢀꢁꢁƒ&@  
ꢀꢂꢄꢋꢇSVLD  
SUHVVXUH  
Figure 31  
>ꢁꢄꢀꢁ03D@  
At higher pressures, refrigerant boils and condenses at higher temperatures.  
This can be explained by examining the properties of water.  
At atmospheric pressure (14.7 psia [0.10 MPa]), water boils and evaporates at  
212°F [100°C]. When pressure is increased, however, water does not boil until it  
reaches a much higher temperature. At a higher pressure there is a greater  
force pushing against the water molecules, keeping them together in a liquid  
phase.  
Recall that, at a given pressure, the temperature at which a liquid will boil into a  
vapor is the same temperature at which the vapor will condense back into a  
liquid.  
%RLOLQJꢀ3RLQWꢀRIꢀ5HIULJHUDQWꢂꢃꢃ  
ꢀꢈꢀꢄꢆƒ)  
>ꢂꢍꢄꢋƒ&@  
ꢂꢀꢄꢈƒ)  
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SUHVVXUH  
Figure 32  
This curve illustrates the pressures and corresponding temperatures at which  
R-22 boils and condenses. At a pressure of 85 psia [0.59 MPa], the liquid R-22  
will boil at 41.2°F [5.1°C]. As an example, assume that a compressor is used to  
20  
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period three  
Refrigeration Cycle  
increase the pressure of the resulting refrigerant vapor to 280 psia [1.93 MPa].  
This increase in pressure raises the temperature at which the vapor would  
condense back into liquid to 121.5°F [49.7°C].  
notes  
In order to condense the refrigerant vapor at this higher temperature, a  
substance at a temperature less than 121.5°F [49.7°C] is needed. Ambient air or  
water is generally available at temperatures less than this.  
9DSRUꢂ&RPSUHVVLRQꢀ&\FOH  
H[SDQVLRQ  
HYDSRUDWRU  
GHYLFH  
FRQGHQVHU  
FRPSUHVVRU  
Figure 33  
A compressor, condenser, and expansion device form the rest of the system  
that returns the refrigerant vapor to a low-temperature liquid, which can again  
be used to produce useful cooling. This cycle is called the vapor-compression  
refrigeration cycle.  
In this cycle, a compressor is used to pump the low-pressure refrigerant vapor  
from the evaporator and compress it to a higher pressure.  
This hot, high-pressure refrigerant vapor is then discharged into a condenser.  
Because heat flows from a substance at a higher temperature to a substance at  
a lower temperature, heat is transferred from the hot refrigerant vapor to a  
cooler condensing media, which, in this example, is ambient air. As heat is  
removed from the refrigerant, it condenses, returning to the liquid phase. This  
liquid refrigerant is, however, still at a high temperature.  
Finally, an expansion device is used to create a large pressure drop that  
lowers the pressure, and correspondingly the temperature, of the liquid  
refrigerant. The temperature is lowered to a point where it is again cool enough  
to absorb heat in the evaporator.  
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period three  
Refrigeration Cycle  
notes  
%DVLFꢀ5HIULJHUDWLRQꢀ6\VWHP  
&
GLVFKDUJH  
OLQH  
FRQGHQVHU  
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FRPSUHVVRU  
%
GHYLFH  
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Figure 34  
Basic Refrigeration System  
This diagram illustrates a basic vapor-compression refrigeration system that  
contains the described components. First, notice that this is a closed system.  
The individual components are connected by refrigerant piping. The suction  
line connects the evaporator to the compressor, the discharge line connects  
the compressor to the condenser, and the liquid line connects the condenser  
to the evaporator. The expansion device is located in the liquid line.  
Recall that the temperature at which refrigerant evaporates and condenses is  
related to its pressure. Therefore, regulating the pressures throughout this  
closed system can control the temperatures at which the refrigerant evaporates  
and then condenses. These pressures are obtained by selecting system  
components that will produce the desired balance. For example, select a  
compressor with a pumping rate that matches the rate at which refrigerant  
vapor is boiled off in the evaporator. Similarly, select a condenser that will  
condense this volume of refrigerant vapor at the desired temperature and  
pressure.  
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period three  
Refrigeration Cycle  
notes  
(YDSRUDWRU  
$
PL[WXUHꢇRI  
OLTXLGꢇDQGꢇYDSRU  
UHIULJHUDQW  
%
UHIULJHUDQW  
YDSRU  
DLU  
Figure 35  
At the inlet to the evaporator, the refrigerant exists as a cool, low-pressure  
mixture of liquid and vapor. In this example, the evaporator is a finned-tube coil  
used to cool air. Other types of evaporators are used to cool water.  
The relatively warm air flows across this finned-tube arrangement and the cold  
refrigerant flows through the tubes. The refrigerant enters the evaporator ($)  
and absorbs heat from the warmer air, causing the liquid refrigerant to boil. The  
resulting refrigerant vapor (%) is drawn to the compressor.  
&RPSUHVVRU  
%
&
KLJKꢌSUHVVXUH  
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WRꢇFRQGHQVHU  
ORZꢌSUHVVXUH  
UHIULJHUDQWꢇYDSRU  
IURPꢇHYDSRUDWRU  
Figure 36  
The compressor raises the pressure of the refrigerant vapor (%) to a pressure  
and temperature high enough (&) so that it can reject heat to another fluid, such  
as ambient air or water. There are several types of compressors. The type  
shown in this figure is a reciprocating compressor.  
This hot, high-pressure refrigerant vapor then travels to the condenser.  
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period three  
Refrigeration Cycle  
notes  
&RQGHQVHU  
&
UHIULJHUDQW  
YDSRU  
'
OLTXLG  
UHIULJHUDQW  
RXWGRRU  
DLU  
Figure 37  
The condenser is a heat exchanger used to reject the heat of the refrigerant to  
another medium. The example shown is an air-cooled condenser that rejects  
heat to the ambient air. Other types of condensers are used to reject heat to  
water.  
The hot, high-pressure refrigerant vapor (&) flows through the tubes of this  
condenser and rejects heat from the cooler ambient air that passes through the  
condenser coil. As the heat content of the refrigerant vapor is reduced, it  
condenses into liquid (').  
From the condenser, the high-pressure liquid refrigerant travels to the  
expansion device.  
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$
PL[WXUHꢇRI  
OLTXLGꢇDQGꢇYDSRU  
UHIULJHUDQW  
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'
Figure 38  
The primary purpose of the expansion device is to drop the pressure of the  
liquid refrigerant to equal the pressure in the evaporator. Several types of  
expansion devices can be used. The device shown is an expansion valve.  
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period three  
Refrigeration Cycle  
The high-pressure liquid refrigerant (') flows through the expansion device,  
causing a large pressure drop. This pressure drop reduces the refrigerant  
pressure, and, therefore, its temperature, to that of the evaporator. At the lower  
pressure, the temperature of the refrigerant is higher than its boiling point. This  
causes a small portion of the liquid to boil, or flash. Because heat is required to  
boil this small portion of refrigerant, the boiling refrigerant absorbs heat from  
the remaining liquid refrigerant, cooling it to the desired evaporator  
temperature.  
notes  
The cool mixture of liquid and vapor refrigerant then enters the evaporator ($)  
to repeat the cycle.  
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KLJKꢂSUHVVXUH  
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Figure 39  
Placing each component in its proper sequence within the system, the  
compressor and expansion device maintain a pressure difference between the  
high-pressure side of the system (condenser) and the low-pressure side of the  
system (evaporator).  
This pressure difference allows two things to happen simultaneously. The  
evaporator can be at a pressure and temperature low enough to absorb heat  
from the air or water to be cooled, and the condenser can be at a temperature  
high enough to permit heat rejection to ambient air or water that is at normally  
available temperatures.  
These major components are discussed in further detail in the “Refrigeration  
Compressors” and “Refrigeration System Components” clinics.  
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period four  
Pressure–Enthalpy Chart  
notes  
5HIULJHUDWLRQꢀ&\FOH  
SHULRGꢀIRXU  
3UHVVXUH¤(QWKDOS\ꢀ&KDUW  
Figure 40  
During this period we will again analyze the basic vapor-compression  
refrigeration cycle. However, this time we will use a graphic tool called the  
pressure–enthalpy chart.  
3UHVVXUH¤(QWKDOS\ꢀꢄ3¤Kꢅꢀ&KDUW  
HQYHORSH  
VXEFRROHG  
OLTXLG  
VDWXUDWHG  
PL[WXUHꢇRI  
YDSRUꢇOLQH  
OLTXLGꢇDQG  
YDSRU  
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VDWXUDWHG  
OLTXLGꢇOLQH  
WHPSHUDWXUH  
HQWKDOS\  
Figure 41  
The pressure–enthalpy (P-h) chart plots the properties of a refrigerant—  
refrigerant pressure on the vertical axis and enthalpy on the horizontal axis.  
Enthalpy is a measure of heat quantity, both sensible and latent, per pound  
[kg] of refrigerant. It is typically expressed in terms of Btu/lb [kJ/kg].  
The right-hand side of the chart indicates the conditions at which the refrigerant  
will be in the vapor phase. The left-hand side of the chart indicates the  
conditions at which the refrigerant will be in the liquid phase. In the middle of  
the chart is an envelope (curve). The left-hand boundary of the envelope  
indicates the saturated liquid condition. The right-hand boundary indicates the  
saturated vapor condition. If the enthalpy of the refrigerant lies inside the  
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period four  
Pressure–Enthalpy Chart  
envelope, the refrigerant exists as a mixture of liquid and vapor. If the enthalpy  
of the refrigerant lies to the right of the envelope, the vapor is superheated.  
Similarly, if the enthalpy of the refrigerant lies to the left of the envelope, the  
liquid is subcooled.  
notes  
Lines of constant temperature cross the P–h chart as shown.  
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Figure 42  
To further demonstrate the use of the P–h chart, let us look at the process of  
heating and boiling water, at a constant pressure, on a P–h chart for water.  
As discussed earlier, at atmospheric pressure (14.7 psia [0.10 MPa]) water boils  
at 212°F [100°C]. At $, the water temperature is 180°F [82.2°C]. As we add heat  
to the water, the temperature and enthalpy of the water increas as they move  
toward %. When the water reaches its saturated condition (%), at 212°F [100°C],  
it starts to boil and transform into vapor. As more heat is added to the water, it  
continues to boil while the temperature remains constant. A greater percentage  
of the water is transforming into vapor as it moves toward &.  
When the water reaches & on the saturation vapor line, it has completely  
transformed into vapor. Now, as more heat is added to the vapor, its  
temperature begins to increase again toward D, 240°F [115.6°C].  
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period four  
Pressure–Enthalpy Chart  
notes  
+HDWꢀRIꢀ9DSRUL]DWLRQꢀIRUꢀ:DWHU  
VXEFRROHG  
OLTXLG  
PL[WXUHꢇRI  
OLTXLGꢇDQG  
YDSRU  
KHDWꢇRI  
YDSRUL]DWLRQ  
VXSHUKHDWHG  
YDSRU  
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&
:DWHU  
ꢀꢎꢁꢄꢈꢇ%WXꢊOE  
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ꢀꢀꢆꢁꢄꢈꢇ%WXꢊOE  
>ꢈꢅꢋꢆꢄꢂꢇN-ꢊNJ@  
HQWKDOS\  
Figure 43  
The distance between the edges of the envelope indicates the quantity of heat  
required to transform saturated liquid into saturated vapor at a given pressure.  
This is called the heat of vaporization.  
For example, B represents the enthalpy of saturated liquid water at 14.7 psia  
[0.10 MPa] and C represents the enthalpy of saturated water vapor at the same  
pressure. The difference in enthalpy between B and C—970 Btu/lb  
[2256.3 kJ/kg]—is the heat of vaporization for water at this pressure.  
(YDSRUDWRU  
UHIULJHUDWLRQ  
HIIHFW  
ꢂꢀꢄꢈƒ)  
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Figure 44  
The P-h chart can be used to analyze the vapor-compression refrigeration cycle  
and determine the conditions of the refrigerant at any point in the cycle. The  
chart in this example is for R-22.  
Because the refrigeration cycle is a continuous process, defining the cycle can  
start at any point. This example begins in the lower left-hand portion of the P-h  
chart, where the refrigerant enters the evaporator.  
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period four  
Pressure–Enthalpy Chart  
At the inlet to the evaporator, the refrigerant is at a pressure of 85 psia  
[0.59 MPa] and a temperature of 41.2°F [5.1°C], and is a mixture of liquid and  
vapor (mostly liquid). This cool, low-pressure refrigerant enters the evaporator  
($) where it absorbs heat from the relatively warm air that is being cooled. This  
transfer of heat boils the liquid refrigerant inside the evaporator and  
superheated refrigerant vapor is drawn to the compressor (&).  
notes  
The change in enthalpy from A to C that occurs inside the evaporator is called  
the refrigeration effect. This is the amount of heat that each pound [kg] of  
liquid refrigerant will absorb when it evaporates.  
6XSHUKHDW  
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Figure 45  
Compressors are designed to compress vapor. Liquid refrigerant can cause  
damage if drawn into the compressor. In some refrigeration systems additional  
heat is added to the saturated vapor (%) in the evaporator to ensure that no  
liquid is present at the compressor inlet. This additional amount of heat, above  
saturation, is called superheat. This superheated vapor (&) is generally 8°F to  
12°F [4.4°C to 6.7°C] above the saturated vapor condition when it enters the  
compressor. In this example, the refrigerant vapor is superheated 10°F [5.6°C],  
from 41.2°F [5.1°C] to 51.2°F [10.7°C].  
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period four  
Pressure–Enthalpy Chart  
notes  
&RPSUHVVRU  
'
FRPSUHVVRU  
&
%
$
HQWKDOS\  
Figure 46  
The compressor draws in the superheated refrigerant vapor (&) and  
compresses it to a pressure and temperature (') high enough that it can reject  
heat to another fluid. As the volume of the refrigerant is reduced by the  
compressor, its pressure is increased. Additionally, the mechanical energy used  
by the compressor to accomplish this task is converted to heat energy. This  
causes the temperature of the refrigerant to also rise as its pressure is  
increased.  
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Figure 47  
When the refrigerant vapor is discharged from the compressor, its temperature  
is substantially higher than its saturation temperature (the temperature at  
which the refrigerant would condense). The increase in enthalpy from & to ' is  
due to heat added by the compressor, or the heat of compression.  
In this example, the refrigerant leaves the compressor at 280 psia [1.93 MPa]  
and 191.5°F [88.6°C]. At this higher pressure, the corresponding saturation  
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period four  
Pressure–Enthalpy Chart  
temperature is 121.5°F [49.7°C]. The refrigerant vapor leaving the compressor  
is therefore 70°F [38.9°C] above its saturation temperature.  
notes  
This hot, high-pressure refrigerant vapor then travels to the condenser.  
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Figure 48  
Inside of the condenser, heat is transferred from the hot, high-pressure  
refrigerant vapor (') to relatively cool ambient air. This reduction in the  
enthalpy of the refrigerant vapor causes it to desuperheat. It becomes saturated  
vapor, condenses into saturated liquid, and further subcools before leaving the  
condenser (*) to go to the expansion device.  
First, the refrigerant vapor is cooled (the line from ' to () to its saturation  
temperature of 121.5°F [49.7°C]. Next, as additional heat is removed by the  
condenser, the refrigerant vapor condenses to its saturated liquid condition (the  
line from ( to )). This saturated liquid refrigerant now passes through the area  
of the condenser called the subcooler. Here, the liquid refrigerant is further  
cooled (the line from ) to *), in this example, to 110°F [43.3°C]. Because the  
saturation temperature at the condensing pressure is 121.5°F [49.7°C], the  
refrigerant has been subcooled 11.5°F [6.4°C].  
With the temperature of the refrigerant in the condenser this high, air at normal  
ambient conditions can be used to absorb the heat from the refrigerant. From  
the condenser, the high-pressure, subcooled liquid refrigerant (*) travels to the  
expansion device.  
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period four  
Pressure–Enthalpy Chart  
notes  
([SDQVLRQꢀ'HYLFH  
'
(
*
)
H[SDQVLRQ  
GHYLFH  
&
%
$
HQWKDOS\  
Figure 49  
The primary purpose of the expansion device is to drop the pressure of the  
liquid refrigerant to equal the evaporator pressure. At this lower pressure, the  
refrigerant is now inside the saturation envelope where it exists as a mixture of  
liquid and vapor.  
The high-pressure liquid refrigerant (*) flows through the expansion device,  
causing a large pressure drop. This pressure drop reduces pressure and  
temperature of the refrigerant to that of the evaporator ($). At the lower  
pressure, the temperature of the refrigerant is higher than its boiling point. This  
causes a small portion of the liquid to boil, or flash. Because heat is required to  
boil this small portion of refrigerant, boiling refrigerant absorbs heat from the  
remaining liquid refrigerant, cooling it to the evaporator temperature. Notice  
that there is no change in enthalpy during the expansion process.  
The purpose of subcooling the liquid refrigerant in the condenser is to avoid  
flashing the refrigerant before it reaches the expansion device. If a valve is used  
as the expansion device, the presence of refrigerant vapor can cause improper  
operation and premature failure.  
32  
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period four  
Pressure–Enthalpy Chart  
notes  
([SDQVLRQꢀ'HYLFH  
ꢀꢀꢁƒ)  
>ꢂꢃꢄꢃƒ&@  
'
(
*
ꢈꢎꢁꢇSVLD  
>ꢀꢄꢍꢃꢇ03D@  
)
ꢎꢆꢇSVLD  
>ꢁꢄꢆꢍꢇ03D@  
&
%
$
ꢈꢀꢄꢎꢇ%WXꢊOE  
>ꢆꢁꢄꢋꢇN-ꢊNJ@  
ꢀꢁꢎꢄꢈꢇ%WXꢊOE  
>ꢈꢆꢀꢄꢋꢇN-ꢊNJ@  
ꢂꢈꢄꢂꢇ%WXꢊOE  
>ꢍꢎꢄꢅꢇN-ꢊNJ@  
HQWKDOS\  
Figure 50  
The temperature of the refrigerant entering the expansion device (*) is 110°F  
[43.3°C] and its pressure is 280 psia [1.93 MPa]. (The refrigerant condensed at  
121.5°F [49.7°C] and was subcooled to 110°F [43.3°C].) The enthalpy of the  
refrigerant at this condition is 42.4 Btu/lb [98.6 kJ/kg]. As mentioned previously,  
there is no change in enthalpy during the expansion process—it is the same at  
both * and $.  
The refrigerant leaves the expansion device ($) at evaporator conditions,  
85 psia [0.59 MPa] and 41.2°F [5.1°C]. At this pressure, the enthalpy of saturated  
liquid is 21.8 Btu/lb [50.7 kJ/kg] and the enthalpy of saturated vapor is  
108.2 Btu/lb [251.7 kJ/kg]. Because there is no change of enthalpy during the  
expansion process, the mixture of liquid and vapor leaving the expansion  
device must have the same enthalpy as the liquid entering the expansion  
device. This is true if 76.2% of the refrigerant is liquid and 23.8% of the  
refrigerant is vapor. This is determined as shown below:  
h
A hsaturated liquid  
ꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ  
% of Refrigerant Vapor at A =  
% of Refrigerant Vapor at A =  
% of Refrigerant Vapor at A =  
h
saturated vapor hsaturated liquid  
42.4 Btu/lb 21.8 Btu/lb  
ꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ  
= 23.8%  
108.2 Btu/lb 21.8 Btu/lb  
98.6 kJ/kg 50.7 kJ/kg  
ꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ  
= 23.8%  
251.7 kJ/kg 50.7 kJ/kg  
TRG-TRC003-EN  
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period four  
Pressure–Enthalpy Chart  
notes  
5HIULJHUDWLRQꢀ&\FOH  
ꢀꢀꢁƒ)  
>ꢂꢃꢄꢃƒ&@  
FRQGHQVHU  
'
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)
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>ꢂꢍꢄꢋƒ&@  
H[SDQVLRQ  
GHYLFH  
FRPSUHVVRU  
ꢎꢆꢇSVLD  
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%
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$
HYDSRUDWRU  
ꢂꢀꢄꢈƒ)  
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HQWKDOS\  
Figure 51  
This cool mixture of liquid and vapor refrigerant leaving the expansion device  
then enters the evaporator ($) to repeat the cycle.  
The vapor-compression refrigeration cycle has successfully recovered the  
refrigerant that boiled in the evaporator and converted it back into a cool liquid  
to be used again.  
34  
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period five  
Review  
notes  
5HIULJHUDWLRQꢀ&\FOH  
SHULRGꢀILYH  
5HYLHZ  
Figure 52  
We will now review the main concepts that were covered in this clinic reagrding  
the vapor-compression refrigeration cycle.  
5HYLHZ¥3HULRGꢀ2QH  
s +HDWꢀLVꢀDꢀIRUPꢀRIꢀHQHUJ\  
s +HDWꢀFDQꢀYDU\ꢀLQꢀTXDQWLW\ꢀDQGꢀLQWHQVLW\  
s +HDWꢀHQHUJ\ꢀFDQQRWꢀEHꢀGHVWUR\HG  
s +HDWꢀFDQꢀEHꢀWUDQVIHUUHGꢀIURPꢀRQHꢀVXEVWDQFHꢀWR  
DQRWKHU  
s +HDWꢀDOZD\VꢀIORZVꢀIURPꢀDꢀKLJKHUꢀWHPSHUDWXUH  
VXEVWDQFHꢀWRꢀDꢀORZHUꢀWHPSHUDWXUHꢀVXEVWDQFH  
s 5HIULJHUDWLRQꢀLVꢀDꢀPHWKRGꢀRIꢀUHPRYLQJꢀKHDW  
Figure 53  
Period One introduced the concept of heat and how it is transferred from one  
substance to another.  
Recall that heat is a form of energy and can vary in both quantity and intensity  
(temperature). Heat energy cannot be destroyed, however, it can be transferred  
to another substance. Heat flows from a higher temperature substance to a  
lower temperature substance.  
Refrigeration is a method of removing heat.  
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period five  
Review  
notes  
5HYLHZ¥3HULRGꢀ7ZR  
VHQVLEOH  
KHDW  
ꢇꢏꢇꢀꢎꢁꢇ%WXꢊOEꢇꢇ  
 
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ZDWHU  
ꢃꢈƒ)  
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ꢈꢀꢈƒ)  
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ODWHQW  
KHDW  
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ZDWHU  
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ꢈꢀꢈƒ)  
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Figure 54  
Period Two discussed refrigerants and how they are used in the process of  
removing and transporting heat.  
Remember that refrigerants absorb significant amounts of heat when they  
change phase (e.g., from a liquid to a vapor). Chemical refrigerants commonly  
evaporate at low temperatures when exposed to atmospheric pressure.  
Because of their cost and impact to the environment, however, refrigerants  
must be recovered in a closed system.  
5HYLHZ¥3HULRGꢀ7KUHH  
FRQGHQVHU  
H[SDQVLRQꢇ  
GHYLFH  
FRPSUHVVRU  
HYDSRUDWRU  
Figure 55  
Period Three presented the basic vapor-compression refrigeration cycle, and  
specifically the use of a compressor, condenser, and expansion device to  
“recover” the evaporated refrigerant and complete the cycle. The primary  
components of the vapor-compression refrigeration cycle include the  
evaporator, compressor, condenser, and expansion device.  
36  
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period five  
Review  
Refrigerant enters the evaporator as a cool, low-pressure mixture of liquid and  
vapor. It absorbs heat—from the relatively warm air or water to be cooled—and  
boils. The cool, low-pressure vapor is then pumped from the evaporator by the  
compressor. This increases the pressure and temperature of the refrigerant  
vapor. The resulting hot, high-pressure refrigerant vapor enters the condenser  
where it rejects heat to ambient air or water that is at a lower temperature, and  
condenses into a liquid.  
notes  
This liquid refrigerant flows from the condenser to the expansion device. The  
expansion device creates a pressure drop that reduces the pressure of the  
refrigerant to that of the evaporator. At this low pressure, a small portion of the  
refrigerant boils off, cooling the remaining liquid refrigerant to the evaporator  
temperature. The cool mixture of liquid and vapor refrigerant travels to the  
evaporator where it absorbs heat and boils, repeating the cycle.  
5HYLHZ¥3HULRGꢀ)RXU  
FRQGHQVHU  
H[SDQVLRQ  
GHYLFH  
FRPSUHVVRU  
HYDSRUDWRU  
HQWKDOS\  
Figure 56  
Period Four discussed the use of the pressure–enthalpy (P–h) chart to analyze  
the refrigeration system.  
The pressure–enthalpy chart plots the properties of a refrigerant—pressure  
versus enthalpy. Enthalpy is a measure of heat quantity per pound [kg] of  
refrigerant. The chart includes an envelope (curve) that indicates when the  
refrigerant exists as a subcooled liquid (to the left of the envelope), a mixture of  
liquid and vapor (inside the envelope), or a superheated vapor (to the right of  
the envelope).  
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period five  
Review  
notes  
Figure 57  
For more information, refer to the following references:  
Trane Air Conditioning Manual  
Trane Reciprocating Refrigeration Manual  
ASHRAE Handbook – Fundamentals  
ASHRAE Handbook – Refrigeration  
ASHRAE Handbook – Systems and Equipment  
For more information on additional educational materials available from Trane,  
contact your local Trane office (request a copy of the Educational Materials  
catalog – Trane order number EM-ADV1) or visit our online bookstore at  
38  
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Quiz  
Questions for Period 1  
1
2
3
Heat intensity is measured in terms of its __________?  
Heat quantity is measured with units of __________?  
Heat always flows from a substance of ________ (higher, lower) temperature  
to a substance of ________ (higher, lower) temperature.  
4
What are the three basic processes by which heat is transferred from one  
substance to another?  
Questions for Period 2  
5
Which process requires more heat energy: raising the temperature of a  
container of water from 50°F [10°C] to 200°F [93.3°C] or boiling the same  
quantity of 212°F [100°C] water to 212°F [100°C] steam?  
6
7
What type of heat energy, when added to or removed from a substance,  
results in a measurable change in temperature?  
What type of heat energy, when added to or removed from a substance,  
results in a change of state of the substance—from a liquid to a vapor or  
vice-versa?  
Questions for Period 3  
&
%
'
$
Figure 58  
8
9
Identify the four major components of the vapor-compression refrigeration  
cycle labeled in Figure 58.  
What is the state of the refrigerant when it enters the evaporator?  
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Quiz  
10 What is the state of the refrigerant when it enters the compressor?  
11 What is the state of the refrigerant when it enters the expansion device?  
Questions for Period 4  
12 What is enthalpy?  
&
'
$
%
HQWKDOS\  
Figure 59  
13 Using the pressure–enthalpy chart in Figure 59, identify the components of  
the vapor-compression refrigeration cycle:  
a
b
c
d
$ to %  
& to '  
% to &  
' to $  
40  
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Quiz  
(
'
*
)
ꢈꢎꢁꢇSVLD  
>ꢀꢄꢍꢃꢇ03D@  
+
ꢍꢁꢇSVLD  
&
%
$
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HQWKDOS\  
Figure 60  
14 Referring to Figure 60 and given the following conditions,  
A - 44.5°F, 90 psia, 41.6 Btu/lb [6.9°C, 0.62 MPa, 96.8 kJ/kg]  
B - 44.5°F, 90 psia, 108.5 Btu/lb [6.9°C, 0.62 MPa, 252.4 kJ/kg]  
C - 54.5°F, 90 psia, 110.3 Btu/lb [12.5°C, 0.62 MPa, 256.6 kJ/kg]  
D - 190°F, 280 psia, 128.4 Btu/lb [87.8°C, 1.93 MPa, 298.7 kJ/kg]  
E - 121.5°F, 280 psia, 112.8 Btu/lb [49.7°C, 1.93 MPa, 262.4 kJ/kg]  
F - 121.5°F, 280 psia, 46.2 Btu/lb [49.7°C, 1.93 MPa, 107.5 kJ/kg]  
G - 107.5°F, 280 psia, 41.6 Btu/lb [41.9°C, 1.93 MPa, 96.8 kJ/kg]  
H - 44.5°F, 90 psia, 22.7 Btu/lb [6.9°C, 0.62 MPa, 52.8 kJ/kg]  
How much superheat is in this system?  
a
b
c
d
How much subcooling is in this system?  
What is the refrigeration effect of this system?  
At the inlet to the evaporator, what percentage of the refrigerant exists  
as a vapor?  
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Answers  
1
2
3
4
5
Temperature or degrees Fahrenheit [degrees Celsius]  
British Thermal Unit (Btu) [kilocalorie (kcal) or kiloJoule (kJ)]  
Higher to lower  
Conduction, convection, and radiation  
Boiling the water requires more energy–970.3 Btu/lb [244.5 kJ/kg]. Raising  
the temperature of the water from 50°F [10°C] to 200°F [93.3°C] requires  
150 Btu/lb [83.3 kJ/kg].  
6
7
Sensible heat  
Latent heat  
8 a evaporator  
b
c
d
compressor  
condenser  
expansion device  
9
A mixture of liquid and vapor  
10 Vapor (possibly superheated vapor)  
11 Liquid (possibly subcooled liquid)  
12 The measure of heat quantity, both sensible and latent, per pound [kg] of  
refrigerant  
13 a evaporator  
b
c
d
condenser  
compressor  
expansion device  
42  
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Answers  
14 a 10°F [5.6°C] (temperature rise from % to &)  
b
c
d
14°F [7.8°C] (temperature drop from ) to *)  
68.7 Btu/lb [159.8 kJ/kg] (enthalpy difference between $ and &)  
22% refrigerant vapor  
Enthalpy at A Enthalpy at H  
Enthalpy at B Enthalpy at H  
ꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ  
% of Refrigerant Vapor at A =  
% of Refrigerant Vapor at A =  
% of Refrigerant Vapor at A =  
41.6 Btu/lb 22.7 Btu/lb  
108.5 Btu/lb 22.7 Btu/lb  
ꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ  
= 22%  
96.8 kJ/kg 52.8 kJ/kg  
252.4 kJ/kg 52.8 kJ/kg  
ꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ  
= 22%  
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Glossary  
ASHRAE American Society of Heating, Refrigerating and Air-Conditioning  
Engineers  
British Thermal Unit (Btu) A measure of heat quantity, defined as the quantity  
of heat energy required to change the temperature of 1 lb of water by 1°F.  
compressor A mechanical device in the refrigeration system used to increase  
the pressure and temperature of the refrigerant vapor.  
condenser A component of the refrigeration system where refrigerant vapor is  
converted to liquid as it rejects heat to air, water, or some other fluid.  
conduction The process of transferring heat through a solid.  
convection The process transferring heat through the movement of a fluid,  
often through the natural movement of air, caused by temperature (density)  
differences.  
discharge line Pipe that transports refrigerant vapor from the compressor to  
the condenser in a mechanical refrigeration system.  
enthalpy A measure of heat quantity, both sensible and latent, per pound [kg]  
of refrigerant.  
evaporator A component of the refrigeration system where cool, liquid  
refrigerant absorbs heat from air, water, or some other fluid, causing the  
refrigerant to boil.  
expansion device A component of the refrigeration system used to reduce the  
pressure and temperature of the refrigerant to the evaporator conditions.  
flash The process of liquid refrigerant being vaporized by a sudden reduction  
of pressure.  
heat of compression The amount of heat added to the refrigerant vapor by the  
compressor during the process of raising the pressure of the refrigerant to  
condenser conditions.  
heat of vaporization The amount of heat required to transform (evaporate)  
saturated liquid refrigerant to a saturated vapor, at a given pressure.  
kilocalorie A measure of heat quantity, defined as the quantity of heat energy  
required to change the temperature of 1 kg of water by 1°C.  
latent heat Heat energy that, when added to or removed from a substance,  
results in a change of state of the substance–from a liquid to a vapor, from a  
solid to a liquid, or vice-versa.  
liquid line Pipe that transports refrigerant vapor from the condenser to the  
evaporator in a mechanical refrigeration system.  
pressure–enthalpy chart A graphical representation of the properties of a  
refrigerant, plotting refrigerant pressure versus enthalpy.  
44  
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Glossary  
radiation The process transferring heat by means of electromagnetic waves  
emitted due to the temperature difference between two objects.  
refrigerant A substance used to absorb and transport heat for the purpose of  
cooling.  
refrigeration effect The change in enthalpy that occurs inside the evaporator a  
refrigeration cycle that indicates the amount of heat that each pound [kg] of  
liquid refrigerant will absorb when it evaporates.  
sensible heat Heat energy that, when added to or removed from a substance,  
results in a measurable change in temperature.  
specific heat The property of a substance describing its capacity for absorbing  
heat.  
subcooling The amount of heat removed from the liquid refrigerant after it  
has completely condensed within the condenser.  
suction line Pipe that transports refrigerant vapor from the evaporator to the  
compressor in a mechanical refrigeration system.  
superheat The amount of heat added to the refrigerant vapor after it has  
completely vaporized within the evaporator.  
ton of refrigeration A measure of the rate of heat flow, defined as a transfer of  
12,000 Btu/hr [3.517 kW].  
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Literature Order Number  
File Number  
TRG-TRC003-EN  
E/AV-FND-TRG-TRC003-1299-EN  
2803-1-1079  
The Trane Company  
Supersedes  
Worldwide Applied Systems Group  
3600 Pammel Creek Road  
La Crosse, WI 54601-7599  
Stocking Location  
Inland-La Crosse  
An American Standard Company  
Since The Trane Company has a policy of continuous product improvement, it reserves the right to change  
design and specifications without notice.  
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