12 Heat Pumps, Heat Recovery, Gas Cooling and Cogeneration


39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.1
CHAPTER 12
HEAT PUMPS, HEAT
RECOVERY, GAS COOLING,
AND COGENERATION SYSTEMS
12.1 BASICS OF HEAT PUMP AND HEAT Groundwater Heat Pump Systems for
Residences 12.15
RECOVERY 12.1
Heat Pumps 12.1 12.4 GROUND-COUPLED AND SURFACE
Heat Pump Cycle 12.2
WATER HEAT PUMP SYSTEMS 12.17
Classification of Heat Pumps 12.3
12.5 AIR-TO-AIR HEAT RECOVERY 12.19
HVAC&R Heat Recovery Systems 12.3
Types of Air-to-Air Heat Recovery 12.19
Heat Balance and Building Load
Effectiveness 12.19
Analysis 12.4
Fixed-Plate Heat Exchangers 12.20
12.2 AIR-SOURCE HEAT PUMP
Runaround Coil Loops 12.21
SYSTEMS 12.5 Rotary Heat Exchangers 12.21
System Components 12.6 Heat Pipe Heat Exchangers 12.22
Suction Line Accumulator 12.8 Comparison between Various Air-to-Air
Operating Modes 12.9 Heat Exchangers 12.25
System Performance 12.9
12.6 GAS COOLING AND
Cycling Loss and Degradation Factor
COGENERATION 12.25
12.11
Gas Cooling 12.25
Minimum Performance 12.12
Cogeneration 12.25
Defrosting 12.12
Gas-Engine Chiller 12.27
Controls 12.13
Gas Engines 12.27
Capacity and Selection 12.13
Exhaust Gas Heat Recovery 12.28
12.3 GROUNDWATER HEAT PUMP
Engine Jacket Heat Recovery 12.28
SYSTEMS 12.13 Cogeneration Using a Gas Turbine 12.29
Groundwater Systems 12.14
REFERENCES 12.29
Groundwater Heat Pump System for a
Hospital 12.14
12.1 BASICS OF HEAT PUMP AND HEAT RECOVERY
Heat Pumps
A heat pump extracts heat from a heat source and rejects heat to air or water at a higher tempera-
ture. During summer, the heat extraction, or refrigeration effect, is the useful effect for cooling,
whereas in winter the rejected heat alone, or rejected heat plus the supplementary heating from a
heater, forms the useful effect for heating.
A heat pump is a packaged air conditioner or a packaged unit with a reversing valve or other
changeover setup. A heat pump has all the main components of an air conditioner or packaged unit:
fan, filters, compressor, evaporator, condenser, short capillary tube, and controls. The apparatus for
changing from cooling to heating or vice versa is often a reversing valve, in which the refrigerant
flow to the condenser is changed to the evaporator. Alternatively, air passage through the evaporator
may be changed over to passage through the condenser. A supplementary heater is often provided
when the heat pump capacity does not meet the required output during low outdoor temperatures.
12.1
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.2
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12.2 CHAPTER TWELVE
TX A heat pump system consists of heat pumps and piping work; system components include heat
exchangers, heat source, heat sink, and controls to provide effective and energy-efficient heating
and cooling operations. HCFC-22, HFC-134a, and HFC-407C are the most widely used refrigerants
in new heat pumps. According to the data in the EIA s Commercial Buildings Characteristics, for
the 57 billion ft2 (5.3 m2) of air conditioned commercial building floor area in the United States in
1992, the use of heat pumps for heating and cooling was about 15 percent (by floor space).
Heat Pump Cycle
A heat pump cycle comprises the same processes and sequencing order as a refrigeration cycle ex-
cept that the refrigeration effect q1 4 or qrf, and the heat pump effect q2 3 , both in Btu/ lb (J/kg), are
the useful effects, as shown in Fig. 12.1. As defined in Eqs. (9.7) and (9.9), the coefficient of perfor-
mance of a refrigeration system COPref is
h1 h4 q1 4
COPref (12.1)
W Win
where h4, h1 enthalpy of refrigerant entering and leaving evaporator, respectively, Btu/lb (J/kg)
Win work input, Btu / lb (J/ kg)
The coefficient of performance of the heating effect in a heat pump system COPhp is
q2 3
COPhp (12.2)
Win
and the useful heating effect q2 3 can be calculated as
q2 3 h2 h3 h1 h4 h2 h1 (12.3)
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FIGURE 12.1 Heat pump cycle: (a) schematic diagram; (b) cycle on p-h diagram.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.3
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.3
where h2 enthalpy of hot gas discharged from compressor, Btu/ lb (J/kg)
h3 enthalpy of subcooled liquid leaving condenser, Btu/lb (J/kg)
Here polytropic compression is a real and irreversible process. Both the subcooling of the liquid
refrigerant in the condenser and the superheating of the vapor refrigerant after the evaporator
increase the useful heating effect q2 3 . Excessive superheating, which must be avoided, leads to a
too-high hot-gas discharge temperature and to a lower refrigeration capacity in the evaporator.
Classification of Heat Pumps
According to the types of heat sources from which heat is absorbed by the refrigerant, currently
used heat pump systems can be mainly classified into two categories: air-source and water-source
heat pump systems. Water-source heat pumps can again be subdivided into water-source, ground-
water, ground-coupled, and surface water heat pump systems. Water-source heat pump systems are
discussed in Chap. 29.
Heat pump systems are often energy-efficient cooling/heating systems. Many new technologies
currently being developed, such as engine-driven heat pumps, may significantly increase the system
performance factor of the heat pump system. Ground-coupled heat pumps with direct-expansion
ground coils provide another opportunity to increase the COP of the heat pump system.
HVAC&R Heat Recovery Systems
An HVAC&R heat recovery system converts waste heat or cooling from any HVAC&R process to
useful heat or cooling. Here heat recovery is meant in a broad sense. It includes both waste heat and
cooling recovery. An HVAC&R heat recovery system includes the following:

The recovery of internal heat loads  such as heat energy from lights, occupants, appliances, and
equipment inside the buildings  by reclaiming the heat rejected at the condenser and absorber of
the refrigeration systems

The recovery of heat from the flue gas of the boiler

The recovery of heat from the exhaust gas and water jacket of the engine that drives the
HVAC&R equipment, especially engine-driven reciprocating vapor compression systems

The recovery of heat or cooling from the exhaust air from air conditioning systems
Although heat pump systems sometimes are used to recover waste heat and convert it into a
useful effect, a heat recovery system is different from a heat pump system in two ways:

In a heat pump system, there is only one useful effect at a time, such as the cooling effect in sum-
mer or the heating effect during winter. In a heat recovery system, both its cooling and heating
effects may be used simultaneously.

From Eq. (12.2), the coefficient of performance of the useful heating effect in a heat pump is
COPhp q2 3 /Win, whereas for a heat recovery system, the coefficient of performance COPhr is
always higher if both cooling and heating are simultaneously used and can be calculated as
q1 4 q2 3
COPhr (12.4)
Win
A heat pump is an independent unit. It can operate on its own schedule, whereas a heat recovery
system in HVAC&R is usually subordinate to a refrigeration system or to some other system that
produces the waste heat or waste cooling.
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.4
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12.4 CHAPTER TWELVE
TX Heating or cooling produced by a heat recovery system is a by-product. It depends on the opera-
tion of the primary system. A heat recovery system can use waste heat from condenser water for
winter heating only if the centrifugal chiller is operating.
A centrifugal chiller that extracts heat from a surface water source (e.g., a lake) through its evap-
orator and uses condensing heat for winter heating is a heat pump, not a heat recovery system. Heat
recovery systems that are subordinate to a centrifugal or absorption refrigeration system are dis-
cussed in Chaps. 13 and 14, respectively. Recovery of waste heat from industrial manufacturing
processes to provide heating shows great potential for saving energy. These heat recovery systems
must be closely related to the specific requirements of corresponding manufacturing processes and
are not discussed here.
Heat Balance and Building Load Analysis
The building load consists of transmission gain or loss, solar radiation, ventilation load and infil-
tration load, people, electric lights, appliances (or equipment), and heat gains from fans and
pumps. Building load is actually the load of the cooling or heating coil in an air-handling unit, or
DX coil in a packaged unit or air conditioner. On hot summer days, solar radiation and the latent
ventilation load must be included in the building load. However, both sunny and cloudy days may
occur in cold weather; therefore, building load is calculated and analyzed with and without solar
radiation in cold weather, especially for the control zones facing south in a building in northern
latitudes, or facing north in southern latitudes, where solar radiation is often a primary cooling
load on sunny days.
Figure 12.2 shows the building load analysis of a typical floor of a multistory building without
solar radiation in winter. In this figure, line ABCDE represents the building load curve at various
outdoor temperatures To, in F (C). Point A on this curve represents the summer design refrigera-
tion load Qrl, in MBtu/h (kW). During summer design load, all the space cooling loads are offset
by the cold supply air, and the condensing heat of the refrigeration system is rejected to the cooling
tower.
When the outdoor temperature To drops below 75F (23.9C) on the left side of point B on the
building load curve, then the following things occur:

The perimeter zone may suffer a transmission loss.

Solar radiation is excluded.

The latent load of the outdoor ventilation air is no longer included in the building load because
the outdoor air is often drier than the space air.
If the outdoor temperature To TF, hot condenser water is supplied to the heating coils in the
perimeter zone to satisfy the heating load. Here TF indicates the outdoor temperature at point F.
When the outdoor temperature drops to TD, the heat recovered from the interior zone plus the
power input to the compressor is exactly equal to the heating load of the perimeter zone. No supple-
mentary heating is needed. Point D is called the break-even point of the building. When To TD,
supplementary heating is necessary to maintain a desirable space temperature.
As the outdoor temperature falls to TH, the cooling coil load in the interior zone becomes
zero. The refrigeration compressors are turned off. No recovery of condensing heat is possible.
When To TH, all the heat needed for the perimeter zone will be provided by the supplementary
heating.
The area of triangle FGH indicates the heat energy recovered from the internal loads in the
interior zone, which is used to offset the heat losses in the perimeter zone by means of hot
condenser water. Similar building load curves with solar radiation for the entire building and for
the south-facing zones in the building should be calculated and analyzed in winter. For building
SH__ load with solar radiation, break-even point D will move to a lower To. Recovered heat will be
ST__ greater, and supplementary heating will be less. For south-facing zones in buildings in northern
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.5
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.5
FIGURE 12.2 Building load analysis of a typical floor in a multistory building without solar radiation.
climates, cold supply air may be required during sunny days in the perimeter zone even in
winter.
12.2 AIR-SOURCE HEAT PUMP SYSTEMS
In an air-source heat pump system, outdoor air acts as a heat source from which heat is extracted
during heating, and as a heat sink to which heat is rejected during cooling. Since air is readily avail-
able everywhere, air-source heat pumps are the most widely used heat pumps in residential and
many commercial buildings. The cooling capacity of most air-source heat pumps is between 1 and
30 tons (3.5 and 105 kW).
Air-source heat pumps can be classified as individual room heat pumps and packaged heat
pumps. Individual room heat pumps serve only one room without ductwork. Packaged heat pumps
can be subdivided into rooftop heat pumps and split heat pumps.
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.6
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12.6 CHAPTER TWELVE
TX System Components
Most air-source heat pumps consist of single or multiple compressors, indoor coils through which
air is conditioned, outdoor coils where heat is extracted from or rejected to the outdoor air, capillary
tubes, reversing valves that change the heating operation to a cooling operation and vice versa, an
accumulator to store liquid refrigerant, and other accessories. A typical rooftop packaged heat
pump that uses HCFC-22 as refrigerant is shown in Fig. 12.3. In this heat pump, dual circuits,
consisting of two compressors, two indoor coils, two outdoor coils, two throttling devices, and two
reversing valves, are often used for better capacity control and better defrosting control for larger
heat pumps.
Compressor. Reciprocating and scroll compressors are widely used in heat pumps. In Bucher
et al. (1990) the median service life of the compressor in a heat pump is 14.5 years, and the median
service life of a heat pump system is 19 years, depending on the conditions of operation and
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FIGURE 12.3 A typical rooftop heat pump: (a) schematic diagram;
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(b) reversing valve, cooling mode; (c) reversing valve, heating mode.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.7
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.7
FIGURE 12.3 (Continued)
maintenance. Median service life is the age at which 50 percent of the units have been removed
from service and 50 percent remain in service.
Indoor Coil. In an air-source heat pump, the indoor coil is not necessarily located inside the
building. The indoor coil in a rooftop packaged heat pump is mounted on the rooftop. However, an
indoor coil always heats and cools the indoor supply air. During cooling operation, the indoor
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.8
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12.8 CHAPTER TWELVE
TX coil acts as an evaporator. It provides the refrigeration effect to cool the mixture of outdoor and
recirculating air when the heat pump is operating in the recirculating mode. During heating
operation, the indoor coil acts as a condenser. The heat rejected from the condenser raises the
temperature of the conditioned supply air. For heat pumps using halocarbon refrigerants, the indoor
coil is usually made from copper tubing and corrugated aluminum fins.
Outdoor Coil. The outdoor coil acts as a condenser during cooling and as an evaporator to extract
heat from the outdoor atmosphere during heating. When an outdoor coil is used as a condenser, a
series-connected subcooling coil often subcools the refrigerant for better system performance. An
outdoor coil always deals with outdoor air, whether it acts as a condenser or an evaporator. Like the
indoor coil, an outdoor coil is usually made of copper tubing and aluminum fins for halocarbon
refrigerants. Plate or spine fins are often used instead of corrugated fins to avoid clogging by dust
and foreign matter.
Reversing Valve. Reversing valves are used to guide the direction of refrigerant flow when cool-
ing operation is changed over to heating operation or vice versa. The rearrangement of the connec-
tions between four ways of flow  compressor suction, compressor discharge, evaporator outlet,
and condenser inlet  causes the functions of the indoor and outdoor coils to reverse. It is therefore
called a four-way reversing valve.
A typical four-way reversing valve consists of a hollow cylinder with an internal slide to posi-
tion the flow paths of the refrigerant. The slide is driven by the differential between the discharge
and suction pressure. Both are introduced to opposite ends of the cylinder by a pilot valve that is
energized by a solenoid coil. The operation of this typical four-way reversing valve is shown in
Fig. 12.3b and c.
A reversing valve is a highly reliable system component. The efficiency losses altogether includ-
ing leakage, heat transfer, and the pressure drop across the reversing valve cause a decrease of 4 to
7 percent in heat pump performance. Other accessories, such as a filter dryer, sight glass, strainer,
liquid level indicator, solenoid valves, and manual shutoff valves as well as refrigerant piping are
the same as described in Chap. 11.
Suction Line Accumulator
An accumulator is usually installed on the suction line prior to the inlet of the compressor in a heat
pump system to store the liquid refrigerant prior to the defrosting process. Bivens et al. (1997)
conducted tests on a 2.5-ton (8.8-kW) split residential heat pump with a scroll compressor and an
accumulator using HFC-407C and HCFC-22 as refrigerant. Only a slight change in concentration
shift occurred when there was no liquid refrigerant in the accumulator. There were significant
changes in concentration shift during heating when the temperatures in the evaporator and accumu-
lator were lower. The accumulator contained about 30 percent of the refrigerant as liquid during
high-temperature heating (outdoor air temperature at 47F, or 8.3C) and about 50 percent of the
refrigerant as liquid during low-temperature heating (outdoor air temperature at 17F, or 8.3 C).
Compared with HCFC-22 as refrigerant, the capacity of the HFC-407C heat pump increased to 101
to 105 percent of the HCFC-22 capacity during high-temperature heating, and increased to 106 to
109 percent of the HCFC-22 capacity during low-temperature heating. The COP of the HFC-407C
heat pump dropped to 0.96 to 0.97 of the HCFC-22 COP during cooling and dropped to 0.94 and
0.95 of the HCFC-22 COP during heating.
Nutter et al. (1996) conducted experiments on a scroll heat pump of 3-ton (10-kW) cooling ca-
pacity. The heat pump was operated at heating mode of ambient air of 1.7F ( 16.8C) dry-bulb
temperature and 80 percent relative humidity in a psychrometric room. Test results showed that the
COP is higher for the heat pump without an accumulator first until a power surge at 40-min opera-
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tion. This caused the integrated cyclic COP for the heat pump without an accumulator of 2.08
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which fell below that of the COP of the heat pump system with an accumulator of 2.12. Such a
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.9
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.9
phenomenon may be the result of entrained liquid refrigerant that began to adversely affect the
compressor performance by reducing discharge temperature and pressures.
Operating Modes
The operation of an air-source heat pump can be divided into cooling mode and heating mode.
Cooling Mode. When the discharge air temperature sensor detects an increase in the air
temperature above a predetermined limit at the exit of the indoor coil, cooling is required in the
air-source heat pump. The direct digital controller (DDC) unit deenergizes the pilot solenoid
valve, as shown in Fig. 12.3b. The low-pressure suction vapor is now connected to the left-hand
end of the slide, and the high-pressure hot gas between the pistons of the slide then pushes
the piston toward the left end of the cylinder. The indoor coil now acts as an evaporator and
extracts heat from the conditioned air flowing through the indoor coil. After evaporation, vapor
refrigerant from the indoor coil passes through the sliding connector of the slide and flows to the
suction line. Hot gas discharged from the compressor is led to the outdoor coil, which now acts
as a condenser.
An economizer cycle can be used when an outdoor air sensor detects the outdoor temperature
dropping below a specific limit during cooling mode. The DDC unit controller opens and modu-
lates the outdoor damper to admit cold outdoor air to maintain a preset discharge air temperature.
Heating Mode. When the discharge air sensor detects a drop in air temperature below a predeter-
mined limit at the exit of the indoor coil, heating is required. The DDC unit controller energizes the
pilot solenoid valve as shown in Fig. 12.3c. The plunger of the solenoid valve moves upward and
connects the right-hand end of the slide to the low-pressure suction line. High-pressure hot gas then
pushes the pistons toward the right-hand end of the cylinder. Consequently, the hot gas from the
compressor is discharged to the indoor coil, which now acts as a condenser. Heat is rejected to the
recirculating air, and then the hot gas is condensed into liquid form. Liquid refrigerant flows
through the capillary tube and then vaporizes in the outdoor coil, which extracts heat from outdoor
air. The outdoor coil now acts as an evaporator.
Electric heating can be used for supplementary heating. When the discharge air temperature
sensor detects a drop in air temperature further below preset limits, the electric heater can be
energized in steps to maintain the required discharge air temperature. Supplementary heating
is energized only when the space heating load cannot be offset by the heating effect of the
heat pump.
ASHRAE / IESNA Standard 90.1-1999 mandates that heat pumps equipped with internal electri-
cal resistance heaters shall have controls to prevent supplemental heater operation when the heating
load can be met by the heat pump alone during heating or setback recovery.
System Performance
System performance of an air-source heat pump can be illustrated by plotting the heating
coil load Qch, the cooling coil load Qcc, the heating capacity of the heat pump Qhp, the cooling
capacity of the heat pump Qrc, the coefficient of performance of the heat pump during heating
COPhp, and the energy efficiency ratio of the heat pump during cooling EERhp against the outdoor
temperature, as shown in Fig. 12.4. Coil loads and heat pump capacities all are expressed in
Btu/h (W).
The heating capacity of an air-source heat pump using a reciprocating or a scroll compressor can
be calculated as
Ł Ł
Qhp 60Vp suc v(q1 4 q2 3 ) 60Vp suc v[(h1 h4) (h2 h3 )] (12.5)
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.10
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12.10 CHAPTER TWELVE
TX
FIGURE 12.4 System performance of a rooftop heat pump.
Ł
where Vp piston displacement of reciprocating compressor or suction volume flow rate, cfm
[m/(60 s)]
h1 , h4 enthalpy of refrigerant leaving and entering evaporator, Btu/lb (J/kg)
h2 , h3 enthalpy of hot gas discharged from compressor and enthalpy of refrigerant leaving
condenser, Btu/lb (J/kg)
suc density of suction vapor, lb/ft3 (kg/m3)
v volumetric efficiency
The cooling capacity of an air-source heat pump Qrc can be calculated from Eq. (9.25) as described
in Chap. 9. The cooling coil load Qcc should be offset by the cooling capacity Qrc of the heat pump,
and the heating coil load Qch should be offset by the heating capacity Qhp provided by the heat
pump. All Qcc, Qrc, Qch, and Qhp are expressed in Btu/h (W).
When an air-source heat pump is operated in cooling mode during summer, the condensing tem-
perature Tcon and condensing pressure pcon drop as the outdoor temperature To falls. These decreases
result in higher v and therefore an increase in the cooling capacity of the heat pump Qcc as well as
the energy efficiency ratio of the heat pump during cooling EERhp. The fall of To also causes a de-
crease in the space cooling load and the cooling coil load Qcc. The intersection of the Qrc and Qcc
curves, point D, indicates the maximum cooling coil load that can be offset by the cooling capacity
of the selected heat pump.
When the heat pump is operated in heating mode, a fall of To causes a decrease in the evaporat-
ing temperature Tev. A lower Tev results in a lower v, a smaller refrigeration effect q1 4, and a lower
density of suction vapor suc. All these effects result in a smaller heating capacity of the heat pump
Qhp. Although the work input Win increases as To and Tev decrease, the effect of the increase in Win
on the increase of Qhp is small.
The fall of To also causes a rise in space heating load Qrh and the heating coil load Qch. The in-
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tersection of the heating capacity Qhp curve and the heating coil load Qch curve, at point B, is the
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balance point at which the heating capacity of the heat pump is equal to the required heating coil
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.12
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12.12 CHAPTER TWELVE
TX Minimum Performance
To encourage the use of energy-efficient air conditioners and heat pumps, ASHRAE/IESNA Stan-
dard 90.1-1999 mandates the minimum efficiency requirements for air-source heat pumps at various
cooling capacities during cooling and heating mode as follows:
Cooling Minimum Efficency as of Heating Minimum
Size description efficiency 10/29/2001 rating condition efficiency 10/29/2001
65,000 Btu/h Split system 10.0 SEER 10.0 SEER Split system 6.8 HSPF 6.8 HSPF
Single package 9.7 SEER 9.7 SEER Single package 6.6 HSPF 6.6 HSPF
65,000 Btu/h and Split system and 8.9 EER 10.1 EER 47Fdb/43Fwb 3.0 COP 3.2 COP
135,000 Btu/h single package outdoor air
135,000 Btu/h and Split system and 8.5 EER 9.3 EER 47Fdb/43Fwb 2.9 COP 3.1 COP
240,000 Btu/h single package outdoor air
( 135,000 Btu/h)
240,000 Btu/h Split system and 8.5 EER 9.0 EER
single package 7.52 IPLV 9.22 IPLV
Single-phase packaged units 65,000 Btu/h (19 kW) are regulated by U.S. National Appliance
Energy Conservation Act (NAECA) of 1987, whose HSPF rating includes all usage of internal elec-
tric resistance heating and meets the requirements. For details, refer to ASHRAE/IESNA Standard
90.1-1999. ILPVs and part-load rating conditions are only applicable to equipment with capacity
modulation. Deduct 0.2 from the required EERs and IPLVs for units with heating devices other
than electric resistance heating.
Defrosting
Most air-source heat pumps use the reverse cycle to melt the frost that formed on the outdoor coil
during heating mode operation in cold weather. The reverse cycle defrost switches the heating mode
operation, in which the outdoor coil acts as an evaporator, to cooling mode operation, where the
outdoor coil acts as a condenser. Hot gas is forced into the outdoor coil to melt the frost that
accumulated there. After the frost is melted, the heat pump is switched back to normal heating
mode operation.
O Neal and Peterson (1990) described the defrosting process of an air-source heat pump using
HCFC-22 as refrigerant with a short capillary tube of 0.059-in. (1.5-mm) diameter as the throttling
device. When the reversing valve was energized, the outdoor fan stopped and the defrosting cycle
began. The suction and discharge pressures equalized. The sudden decrease in pressure in the in-
door coil caused the liquid refrigerant to vaporize. The compressor became temporarily starved and
pulled the pressure in the indoor coil down to 23 psia (159 kPa abs.) about 1 min after defrosting
started. Once the suction pressure had fallen low enough, refrigerant flow began to increase. In the
interval from 1.0 to 3.5 min after defrosting, the refrigerant changed from vapor to saturated liquid
upstream of the short capillary tube. This change caused a substantial increase in refrigerant flow,
and frost was melted at the outdoor coil. After 6 min, the refrigerant flow fell 30 percent because of
the subcooling in the outdoor coil. Defrosting usually lasts a few minutes up to about 10 min, de-
pending on the frosting accumulation.
During defrost, a cold supply air from the indoor coil may cause a low space temperature and a
draft. Supplementary electric heating should be considered to maintain an acceptable indoor tem-
perature. ASHRAE Standard 90.1-1999 permits supplementary heating to be used during outdoor
coil defrost cycles.
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Defrosting only takes place on the outdoor coil. The initiation and control of defrosting can be
ST__
performed by a clock or an intelligent or adaptive timer. It can also be controlled by measuring the
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.13
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.13
capacity of the unit or by measuring the temperature differential between the refrigerant inside the
outdoor coil and the ambient air. Defrosting terminates when the temperature of liquid refrigerant
leaving the outdoor coil (or the coil temperature) rises above 60F (15.6C).
Having or not having a suction line accumulator also affects the performance of the heat pump.
Nutter et al. (1996) showed that the refrigerant flow rate averaged 18 percent higher and had a
7 percent shorter defrost cycle for heat pumps without an accumulator than those with an accumu-
lator.
Controls
For reciprocating heat pumps, on/off, speed modulation, and cylinder unloading (as described in
Sec. 11.5) capacity controls are generally used. For scroll heat pumps, on/off, variable-speed, and
variable-displacement modulation capacity control are usually used.
Either the discharge air temperature or the return temperature can be used as the criterion to
change automatically from cooling mode to heating mode and vice versa. A dead band of 2 to 3F
(1.1 to 1.7C) and a time delay are always required between cooling and heating mode operations
to prevent short cycling.
Most of the packaged heat pumps provide specific safety controls of high pressure, low pres-
sure, head pressure, or low ambient control; freezing protection of indoor coil; protection from
overloading; and supplementary heating. The principle and operation of these controls are the same
as described in Sec. 11.5. A microprocessor-based DDC system controller may be used to integrate
all the controls in one package and to add time delay, compressor lockout, loss of refrigerant
charge, and short-cycling protection controls to the sequence control of heat pump and gas furnace
in heating mode operation, and air economizer and refrigeration capacity control in cooling mode
operation.
Capacity and Selection
Air-source heat pump capacity is selected according to its cooling capacity because supplemen-
tary heating may be required under winter design conditions. Also, the rated cooling capacity
at summer design conditions is often greater than the rated heating capacity at winter design
conditions.
When an air-source heat pump is installed directly inside or above the conditioned space, the
noise generated by the heat pump must be taken into consideration. Attenuation remedies should be
provided if necessary to maintain an NC curve at an acceptable level in the conditioned space.
Sound control is discussed in Chap. 19. In 1992, air-source heat pump products were available
ranging in cooling capacity from a fraction of a ton to about 40 tons (few kilowatts to 140 kW) with
an indoor airflow of 16,000 cfm (7550 L/s).
12.3 GROUNDWATER HEAT PUMP SYSTEMS
Groundwater heat pump (GWHP) systems use well water as a heat source during heating and as a
heat sink during cooling. When the groundwater is more than 30 ft (9 m) deep, its year-round tem-
perature is fairy constant. Groundwater heat pump systems are usually open-loop systems. They are
mainly used in low-rise residences in northern climates such as New York or North Dakota. Some-
times they are used for low-rise commercial buildings where groundwater is readily available and
local codes permit such usage.
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.14
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12.14 CHAPTER TWELVE
TX Groundwater Systems
For commercial buildings, the design engineer must perform a survey and study the site and sur-
roundings to define the available groundwater sources. The design engineer should be fully aware
of the legalities of water rights.
A test well should be drilled to ensure the availability of groundwater. If water is corrosive, a
plate-and-frame heat exchanger may be installed to separate the groundwater and the water entering
the water coil in the water-source heat pump (WSHP).
Usually, two wells are drilled. One is the supply well, from which groundwater is extracted by
submersible pump impellers and supplied to the WSHPs. The other well is a recharge or injection
well. Groundwater discharged from the WSHP is recharged to this well. The recharged well should
be at least 100 ft (30 m) away from the supply well. Using a recharge well provides for resupply to
the groundwater and prevents the collapse of the building foundation near the supply well due to
subsidence. If the quality of groundwater meets the requirement and if local codes permit, ground-
water discharged from the WSHP can be used as the service water or can be drained to the nearby
river, lake, or canal. The groundwater intake water screen of the supply well may be located in sev-
eral levels where water can be extracted. For a small supply well for residences, the pump motor is
directly connected to the submersible pump underneath the impellers, whereas for large wells, the
motor is usually located at the top of the supply well. Information regarding groundwater use regu-
lations and guidelines for well separation and for the construction of supply and recharge wells are
included in Donald s (1985) Water Source Heat Pump Handbook, published by the National Water
Well Association (NWWA).
If the temperature of the groundwater is below 50F (10C), direct cooling of the air in the
WSHP should be considered. If the groundwater temperature exceeds 55F (12.8C) and is lower
than 70F (21.1C), precooling of recirculating air or makeup air may be economical.
Because the groundwater system is an open-loop system, it is important to minimize the vertical
head to save pump power. Air-conditioning and Refrigeration Institute (ARI) Standard 325-85 rec-
ommends that the groundwater pump power not exceed 60 W/gpm (950 W s/L). If the pump effi-
ciency is 0.7, the allowable head for the well pump, including static head, head loss across the
water coil or heat exchanger, valves, and piping work losses, should preferably not exceed 220 ft
WC (66 m WC). If a recharge well is used and the discharge pipe is submerged under the water
table level in the recharge well, as shown in Fig. 12.6, the groundwater system is most probably a
closed-loop system, depending on whether the underground water passage between the supply and
recharge well is connected or broken.
Groundwater Heat Pump System for a Hospital
A groundwater heat pump system described in Knipe (1983) was a 1980 retrofit project for a hospi-
tal in Albany, New York (see Fig. 12.5). Altogether, 540 gpm (34 L/s) of groundwater was supplied
from a 12-in.- (300-mm-) diameter, 500-ft- (150-m-) deep well. During summer, the groundwater
temperature was 58F (14.4C), and in winter it dropped to 46F (7.8C). About one-third of the
groundwater was supplied to a makeup air-handling unit. The other two-thirds was sent to a heat
pump which had the following operating characteristics:
Summer:

Well : condenser : discharged to nearby river

Evaporator : chilled water to AHU and terminals : evaporator
Winter:

Well : evaporator : chilled water to AHU and terminals : discharged to nearby river

Condenser : domestic hot water preheat : perimeter heating : condenser
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.15
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.15
FIGURE 12.5 A typical groundwater heat pump system for a hospital.
In summer, groundwater entered the condenser at 58F (14.4C) and left at 68F (20C). In winter,
groundwater entered the evaporator at 46F (7.8C), and left at 43F (6.1C).
The original installation had two 200-ton (700-kW) absorption chillers. Winter heating was sup-
plied from gas-fired boilers. After retrofit, this groundwater heat pump system, including precooling
and preheating, saved 30 percent of the energy used compared to the previous year s expense.
Groundwater Heat Pump Systems for Residences
A typical groundwater heat pump system for a residence is shown in Fig. 12.6. Such a heat pump
system usually has a rated heating capacity from 24,000 to 60,000 Btu/h (7030 to 17,580 W).
Groundwater is extracted from a supply well by means of a submersible well pump and is forced
through a precooler or direct cooler. Then groundwater enters the water coil in the water-source
heat pump. After that, groundwater is discharged to a recharge well. If the recharge pipe is sub-
merged underneath the water table, as described in the previous section, such a groundwater system
is most probably a closed-loop system. In the recharge well, the water level is raised in order to
overcome the head loss required to force the groundwater discharging from the perforated pipe wall
through the water passage underground. The vertical head required is the difference between the
water levels in the supply and recharge wells, as shown in Fig. 12.6.
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.16
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12.16 CHAPTER TWELVE
TX
FIGURE 12.6 A typical residential groundwater heat pump system.
The water-source heat pump for residential GWHP systems has a structure similar to the WSHP
in the water-source heat pump system (which is discussed in Chap. 29) except that a precooler or a
direct cooler may be added.
Operating parameters and characteristics for a groundwater heat pump system are as follows:

The groundwater flow rate for a water-source heat pump should vary from 2 to 3 gpm per 12,000
Btu/h (0.036 to 0.054 L/s per kW) heating capacity. The well pump must be properly sized. A
greater flow rate and an oversized well pump are not economical.

The pressure drop of the groundwater system should be minimized. The pressure drop per 100 ft
(30 m) of pipe should be less than 5 ft/100 ft (5 m/100 m) of length. Unnecessary valves should
not be installed. Gate valves or ball valves should be used instead of globe valves to reduce
pressure loss. A water tank is not necessary.

Direct cooling or precooling of recirculating air by means of groundwater increases significantly
the EER of the GWHP system.

Water containing excessive concentrations of minerals causes deposits on heat pump water coils
that reduce the heat pump performance.
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In locations where the number of annual heating degree-days HDD65 exceeds 7000, more than
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80 percent of the operating hours of the GWHP systems are for space heating.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.17
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.17

An electric heater may be used for supplementary heating in cold climates or in other locations
where it is necessary. When the heating capacity of GWHP is equal to or even greater than the
heating load operation of the electric heater must be avoided.

Water-source heat pumps should be properly sized. They should not be operated for short-cycle dura-
tions (cycles less than 5 min) in order to prevent cycling losses and excessive wear and tear on the
refrigeration system components. Cycle durations between 10 and 30 min are considered appropriate.

Extraction and discharge of groundwater must comply with local codes and regulations.

The temperature of groundwater tends to increase with its use.
A parameter called the seasonal performance factor (SPF) is often used to assess the perfor-
mance of a groundwater heat pump system. SPF is defined as
Qsup
SPF (12.9)
Qcons
where Qsup all heat supplied by GWHP during heating season, Btu (kJ)
Qcons energy consumed during heating season, Btu (kJ)
For groundwater heat systems with a cooling capacity Qrc 135,000 Btu/h (40 kW),
ASHRAE/IESNA Standard 90.1-1999 mandates the minimum efficiency requirements of 11.0
EER for water-source heat pumps using groundwater during cooling mode when the entering water
is 70F (21.1C). As of October 29, 2001, the minimum efficiency requirement is 16.2 EER when
the entering water is 59C (15C). During heating mode, the minimum efficiency requirement is 3.4
COP when the entering water temperature is 70F (21.1C). As of October 29, 2001, the minimum
efficiency requirement is 3.6 COP when the entering water temperature is 50F (10C).
A groundwater heat pump system has a fairly constant COP even if the outdoor air temperature
varies. According to Rackliffe and Schabel (1986), the SPF and EER for 15 single-family houses in
New York State from 1982 to 1984 were as follows:
System SPF (heating) 1.9 to 3 average 2.3
System average EER (cooling) 5.6 to 14 average 9.2
In many locations, groundwater heat pump systems usually have a higher SPF and seasonal EER
than air-source heat pumps. GWHP system capacity remains fairly constant at very low and very
high outdoor temperatures.
The main disadvantage of a groundwater heat pump system is its higher initial cost. More main-
tenance is required for systems using water with high mineral content. If the water table is 200 ft
(60 m) or more below ground level, the residential groundwater heat pump system is no longer
energy-efficient compared to high-efficiency air-source heat pumps.
12.4 GROUND-COUPLED AND SURFACE WATER
HEAT PUMP SYSTEMS
Ground-coupled heat pump systems can be categorized as ground coil heat pump systems and
direct-expansion ground-coupled heat pump systems. Of the ground coil heat pump systems, both
horizontal and vertical coils are used. Many types of direct-expansion ground-coupled heat pump
systems are still being developed. In fact, horizontal ground coil heat pump systems are the most
widely used ground-coupled heat pump systems. A horizontal ground coil heat pump system is
shown in Fig. 12.7. It is actually a closed-loop water-source heat pump system. The water-source
heat pump has a heating capacity between 24,000 and 60,000 Btu/h (7030 and 17,580 W).
A horizontal ground coil is often made of polyethylene or polybutylene tubes of 1- to 2-in. (25-
to 50-mm) external diameter in serpentine arrangement. In Ball et al. (1983) the horizontal coil is
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.18
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12.18 CHAPTER TWELVE
TX
FIGURE 12.7 Ground-coupled heat pump system: (a) Schematic diagram; (b) grid-type ground coil.
buried in two layers in a trench, typically at 4 and 6 ft (1.2 and 1.8 m) deep. Spacing between the
tubes varies from 2 to 8 ft (0.6 to 2.4 m). A general guideline is to use 215 to 430 ft (65 to 130 m)
of copper/steel tubing for each ton (3.5 kW) of capacity for cooling. When a horizontal ground coil
SH__ heat pump used in cooling mode was subjected to a heat rejection temperature that exceeded 100F
ST__ (37.8C), some cracking of polybutylene pipe occurred.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.19
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.19
A vertical ground coil is buried from 30 to 200 ft (6 to 60 m) deep in drilled holes. About 200 to
250 ft (60 to 75 m) of pipe is needed for each 12,000 Btu/h (3.5 kW) of heating capacity. A vertical
ground coil requires less land area than a horizontal ground coil.
If the temperature of the fluid circulated in the water coil and the horizontal ground coil could
drop below 32F (0C), then aqueous solutions of ethylene, propylene glycol, or calcium chloride
should be used to protect the system from freezing. A water flow rate between 2 and 3.5 gpm per
12,000 Btu/h (0.036 and 0.063 L/s per kW) heating capacity is usually used.
In northern climates, horizontal ground coil heat pump systems have a heating SPF of 2.5 to 3
and a cooling seasonal EER of 10.5 to 13.5. There is no significant difference in SPF between
horizontal and vertical ground coils. According to Hughes et al. (1985), for newly constructed
projects in upstate New York, a ground coil heat pump system has a simple payback period of 5 to
10 years.
Based on ASHRAE RP-863 data, Cane et al. (1996) summarized and analyzed 12 ground-
coupled heat pump systems. The average installed heat pump capacity per 1000 ft2 (93 m2) of gross
floor area is 2.4 tons/1000 ft2 (0.091 kW/m2), the average length of the ground coil pipe per ton of
cooling capacity is 287 ft (88 m), the average electric energy use was 14.7 kWh/ft2 year, and the
capital cost for the HVAC&R system was $6.6/ft2.
For water-source heat pumps that use surface water such as lake water as a heat source and sink,
a plastic or copper coil, or sometimes a plate-and-frame heat exchanger, is often used to form a
closed-loop system to prevent fouling of the water coil.
12.5 AIR-TO-AIR HEAT RECOVERY
Types of Air-to-Air Heat Recovery
In HVAC&R systems, it is always beneficial if the cooling effect of the exhaust air can be used to
cool and dehumidify the incoming outdoor air during summer, and if the heating effect can be used
to heat the cold outdoor air during winter. Air-to-air heat recovery is used to recover the cooling and
heating energy from the exhaust air for the sake of saving energy. In an air-to-air heat recovery
system, the exhaust air is the airstream used to provide cooling capacity or heating energy. The
other airstream used to extract heat energy from or release heat energy to the exhaust airstream is
the outdoor airstream, which has a greater temperature and enthalpy difference between these
airstreams than the supply airstream (which is often a mixture of outdoor and recirculating
airstreams).
ASHRAE/IESNA Standard 90.1-1999 specifies individual air systems that have both a design
air supply capacity of 5000 cfm (2360 L/s) or greater and have a minimum outside air supply of 70
percent or greater of the design supply volume flow rate shall have an energy (heat) recovery sys-
tem with at least 50 percent recovery effectiveness. This means that the change of the enthalpy of
the outdoor air supply is equal to 50 percent of the difference between the outdoor and exhaust air
during design conditions.
Exceptions to having an energy recovery system include the contamination of the intake outdoor
airstream or the energy recovery system is not cost effective.
Currently used air-to-air heat recovery devices are mainly divided into the following categories:
fixed-plate heat exchangers, runaround coil loops, rotary wheel, and heat pipes.
Effectiveness
According to ASHRAE Standard 84-1991, Method of Testing Air-to-Air Heat Exchangers, the
performance of the sensible energy transfer (dry-bulb temperature), latent energy transfer (humidity
ratio), and total energy transfer of an air-to-air heat recovery device is assessed by its effectiveness
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.20
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12.20 CHAPTER TWELVE
TX
, which is defined as
actual transfer (moisture or energy)
(12.10)
maximum possible transfer between airstreams
The effectiveness of sensible heat recovered T can be calculated as
Ch(The Thl)
T
Cmin(The Tce)
Cc(Tcl Tce)
(12.11)

Cmin(The Tce)
and Ch Ahcpa,h, Cc Accpa,c, Cmin Amincpa,min (12.12)
where The, Thl air temperature of warm airstream entering and leaving heat exchanger,
F(C)
Tce, Tcl air temperature of cold airstream entering and leaving heat exchanger, F (C)
Ch, Cc heat capacity rate of warm and cold airstream, Btu/h F (W/C)
Cmin heat capacity rate of airstream of smaller mass flow rate among these two
airstreams, Btu/h F (W/C)
Ah Ac, Amin mass flow rate of warm and cold airstreams and of airstream of smaller mass
flow rate, lb/h (kg/s)
cpa, h, cpa, c, cpa, min specific heat of warm and cold airstreams and of airstream of smaller mass
flow rate, Btu/lb F (J/kg C)
During summer cooling, the outdoor air intake in an AHU or packaged unit (PU) is the warm
airstream in an air-to-air heat recovery heat exchanger and the cold airstream in the exhaust
airstream. The exhaust airstreams is usually the smaller mass flow rate of these two airstreams
because of the space positive pressure and additional space exhaust systems. During winter heating,
the exhaust airstream is the warm airstream and is also the airstream of smaller mass flow rate. The
outdoor airstream is the cold airstream.
The effectiveness of total heat recovered in an air-to-air heat recovery heat exchanger h can also
be calculated by Eq. (12.11), except that the air temperature T, in F (C), should be replaced by air
enthalpy h, in Btu/lb (J/kg). If effectivenesses T and h are known (from manufacturer s data), the
latent heat recovered can then be calculated and is the difference between the total and sensible heat
recovered in the air-to-air heat recovery heat exchanger.
Fixed-Plate Heat Exchangers
The schematic diagram of a fixed-plate heat exchanger is shown in Fig. 12.8a. Alternate layers of
fixed plates are separated and sealed and form two isolated airstream passages, outdoor and exhaust
air. Only sensible heat is transferred from the warm airstream to the cold airstream. A counterflow
or crossflow airflow arrangement is often used.
Aluminum and plastic are the most commonly used materials for plates because of their corro-
sive resistance and ease of fabrication. Steel alloys are used for higher-temperature applications.
They are spaced from 0.1 to 0.5 in. (2.5 to 13 mm) apart. Heat resistance through the plates is small
compared to their surface resistance. Condensate drains are often equipped in fixed-plate heat
exchangers. These drains are also used to drain the wastewater after a water wash. Face air velocity
through the fixed plates are usually between 200 and 1000 fpm (1 and 5 m/s) with a pressure drop
from 0.1 to 1 in. (25 to 250 Pa) WC. Most fixed-plate heat exchangers have a capacity of 50 to
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10,000 cfm (24 to 4720 L/s). Fixed-plate heat exchangers have a sensible heat recovered effective-
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ness between 0.5 and 0.8.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.11
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.11
load. When the outdoor temperature To drops below this balance point (such as To 10F or
12.2C), as shown in Fig. 12.4, supplementary heating from the electric heater or other heat
source is required to maintain a preset discharge air temperature. The coefficient of performance of
the heat pump during heating COPhp also drops as To falls. The heat pump and supplementary heat-
ing operate simultaneously until the COPhp drops below a certain value, such as below 1 when the
use of an electric heater is more cost-effective than to operate the heat pump. The heat pump should
be turned off. As discussed in Sec. 11.10, a scroll heat pump has a flatter capacity curve when out-
door air temperature To varies than a reciprocating heat pump. During heating mode operation, a
flatter heating capacity Qhp curve reduces the amount of supplementary heating. During cooling
mode operation in hot summer, when To exceeds the design value, the increase of the space temper-
ature will be less for a flatter capacity curve Qrc than for a steeper one.
Cycling Loss and Degradation Factor
For split packaged air-source heat pumps, indoor coils are located inside the building and outdoor
coils are mounted outdoors. When an on/off control is used for the compressor, during the off pe-
riod, refrigerant tends to migrate from the warmer outdoor coil to the cooler indoor coil in summer
and from the warmer indoor coil to the cooler outdoor coil during winter. When the compressor
starts again, the transient state performance shows that a 2- to 5-min operating period of reduced
capacity is required before the heat pump can operate at full capacity. Such a loss due to cycling of
the compressor is called cycling loss.
According to the Department of Energy (DOE) test procedure (1986) and O Neal et al. (1991),
cycling losses are illustrated by the following parameters: part-load factor (PLF), cooling load
factor (CLF), and degradation coefficient Cd. PLF can be calculated as
EERcyc
PLF (12.6)
EERss
where EERcyc energy-efficiency ratio (EER) of air-source heat pump during a whole cycle,
Btu/h W(COP)
EERss EER of air-source heat pump if it is operated at steady-state, i.e., when compres-
sors and fans are operated continuously, Btu/h W(COP)
The cooling load factor can be calculated as
Hcyc
CLF (12.7)
Qss t
where Hcyc total energy (cooling or heating) delivered during a cycle, Btu
Qss steady state cooling or heating rate, Btu/h (W)
t time of a cycle, h
The degradation coefficient Cd can be calculated as
1 PLF
Cd (12.8)
1 CLF
Cycling losses depend on (1) the cycling rate (whether it is 2, 3, 4, or 5 cycles per hour), (2)
the indoor-outdoor temperature difference, and (3) the fraction of on-time per cycle. At design
conditions, theoretically, PLF 1. In Baxter and Moyers (1985), field tests of a typical heat
pump in an unoccupied single-family house in Knoxville, Tennessee, between 1981 and 1983
showed that the degradation coefficient Cd in the heating season is 0.26, and Cd in the cooling
season is 0.11.
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.21
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.21
1
1
T
Circulating
Outdoor
Exhaust
pump
airstream
airstream
Expansion
Exhaust
Outdoor
tank
airstream
airstream
Exhaust
Outdoor air coil
air coil
(a)
(b)
Outdoor Exhaust
air air
FIGURE 12.8 (a) A fixed-plate heat exchanger; (b) a runaround coil loop heat exchanger.
There is no moving part in a fixed-plate heat exchanger. Because two airstreams are in indirect
contact with each other, neither airstream will contaminate the other. No cross-leakage occurs
between these two airstreams.
Runaround Coil Loops
A runaround coil loop is also called a coil energy recovery loop and is shown in Fig. 12.8b. There
are two extended surface finned-tube water coils. One is located in the outdoor air passage and the
other in the exhaust air passage. These two coils are connected by water pipes and form a closed-
loop system with a circulating water pump and an expansion water tank.
For locations where the outdoor air temperature is lower than 32F (0C), antifreeze fluid should
be used to prevent freezing. A three-way control valve is often installed to prevent frosting of the
exhaust air coil. This control valve will supply water to the exhaust air coil at a temperature of 30F
( 1.1C) or above, or other preset temperatures by mixing a portion of bypassing warm water from
the exhaust air coil with the cold water from the outdoor air coil during winter heating.
Runaround coil loops recover sensible heat only. They are more flexible vis-ą-vis the layout of
the outdoor air and exhaust air passages. The face velocity of outdoor air and exhaust air coils is
usually between 300 and 600 fpm (1.5 and 3 m/s), and their pressure drops often range from 0.4 to
1.0 in. WC (100 to 250 Pa). Runaround coil loops usually have a sensible heat effectiveness be-
tween 0.45 and 0.65.
Rotary Heat Exchangers
Rotary heat exchangers, also called rotary wheels, can be classified into rotary sensible heat ex-
changers, in which only sensible heat is recovered, and rotary enthalpy exchangers, in which both
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.22
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12.22 CHAPTER TWELVE
TX
sensible heat and latent heat are recovered. A rotary heat exchanger is a rotary wheel with a depth
of 4 to 8 in. (100 to 200 mm); Fig. 12.9a and b shows a rotary heat exchanger. The wheel has sup-
port spokes, typically 16, and its front surface is cut into segments. A rotary heat exchanger is often
equally divided into two separately sealed sections: an outdoor airstream section and an exhaust
airstream section. In a rotary sensible heat exchanger, it is filled with an air-penetrable medium with
a large internal surface area such as aluminum, monel metal, or stainless-steel corrugated wire
mesh, at a density of about 4 lb/ft3 (64 kg/m3). In an enthalpy exchanger, a desiccant such as
lithium chloride is impregnated in the porous fiberglass matrix, or solid desiccants such as silica
gels in granular form are lined with substrate sheets at a center-to-center spacing of about 30 mil.
To prevent the dripping of LiCl from the fiberglass matrix, the ratio of absorbed water to the mass
of desiccant should be less than 10 lb H2O/lb LiCl (10 kg H2O/kg LiCl). Each 1 lb (1 kg) of fiber-
glass matrix holds about 0.10 lb (0.10 kg) of LiCl. The rotating speed of a rotary enthalpy heat
exchanger varies from 0.5 to 10 rph (revolutions per hour).
There are two airstreams in a rotary heat exchanger: an outdoor airstream and an exhaust
airstream. In summer cooling, the outdoor airstream is the warm airstream and the exhaust airstream
is the cold airstream, whereas in winter heating, the outdoor airstream is the cold airstream and the
exhaust airstream is the warm airstream. Outdoor and exhaust airstreams flow in parallel but opposite
directions for a counterflow heat transfer. The sensible heat-transfer process of a rotary sensible heat
exchanger is shown in Fig. 12.9c, and the enthalpy transfer process of a rotary enthalpy heat
exchanger is shown in Fig. 12.9d.
The blockage of the face area by desiccant, substrates, of support spokes for an enthalpy heat
exchanger is about 28 percent. The face velocity of rotary heat exchangers varies from 500 to 700
fpm (2.5 to 3.5 m/s). At a face velocity of 500 fpm (2.5 m/s), the pressure drop of air flowing
through the rotary heat exchanger varies from 0.45 to 0.65 in. WC (112 to 162 Pa), depending
mainly on the structure of the heat-transfer medium.
At a face velocity of 500 to 1000 fpm (2.5 to 5 m/s), the sensible heat effectiveness of a rotary
heat exchanger varies from 0.5 to 0.8, and the total heat effectiveness varies from 0.55 to 0.85. The
rotating speed of a rotary sensible heat exchanger is between 10 and 25 rpm, whereas for a rotary
total heat exchanger, its rotating speed varies between 0.5 and 10 rph. A higher face velocity means
that a higher rate of transfer, higher pressure drop, and a larger volume flow rate result in a lower
effectiveness. A lower face velocity results in a lower pressure drop, smaller volume flow rate, and a
higher effectiveness.
The maximum diameter of a rotary heat exchanger is 14 ft (4.2 m). The upper limit of the
volume flow rate for a single unit is about 65,000 cfm (30,670 L/s). A wheel larger than that would
be too difficult to ship and install.
Heat Pipe Heat Exchangers
A heat pipe is often used as a sensible indirect heat exchanger. It consists of many heat pipes
arranged in rows along the direction of airflow, as shown in Fig. 12.10a. Each sealed heat pipe
contains a volatile fluid, as shown in Fig. 12.10b. When one end of the pipe, the hot end or evapora-
tive section, absorbs heat from the airstream flowing over the pipe, then the volatile fluid inside the
pipe vaporizes. The vapor then moves to the other end (the cold end or condensation section)
because of high saturated pressure in the evaporative section. After condensing heat is released
to another airstream that flows over the other end of the pipe, the vapor inside the pipe condenses
to liquid form and is drawn back to the evaporative section by gravity. It has then completed an
evaporation/condensation cycle. The heat pipes are often slightly tilted to enable the condensed
liquid to flow back to the evaporation section.
Heat pipes have an inner capillary wick structure. The outer tube is often made of aluminum,
with fins of the same material for a large heat-transfer surface. The volatile fluid inside the heat pipe
is usually a halocarbon compound refrigerant.
SH__
When two separate airstreams flow over the heat pipe heat exchanger, the warmer airstream
ST__
flows over the evaporation section and the colder airstream flows over the condensation section.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.23
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.23
FIGURE 12.9 Rotary heat exchangers: (a) isometric view; (b) outdoor and exhaust airstreams; (c) sensible heat-
transfer process; (d) enthalpy-transfer process.
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.24
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12.24 CHAPTER TWELVE
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FIGURE 12.10 A heat pipe heat exchanger: (a) heat exchanger and airstreams; (b) heat pipe.
These two airstreams flow in a counterflow arrangement for greater effectiveness. The airstreams
are separated by a sealed partition to prevent cross-contamination.
The performance of a heat pipe heat exchanger is indicated by its sensible heat effectiveness T.
Both the effectiveness and the airstream pressure drop p of a heat pipe heat exchanger depend
mainly on its face velocity vface, fin spacing, and the number of rows of heat pipes in the direction of
airflow. If two heat pipe heat exchangers are connected in series, the number of rows of such a
series is the total number of rows of the two heat exchangers.
The greater the total number of rows of heat pipe and fins per inch, the higher the T and p.
The lower the face velocity vface of the heat pipe exchanger, the higher the T and the lower the p.
However, the volume flow rate and the capacity of the heat pipe heat exchanger will also be smaller.
The design face velocity of a heat pipe heat exchanger is between 400 and 800 fpm (2 and 4
m/s). The total number of heat pipe rows varies from 6 to 10 rows. Sensible heat effectiveness
varies from 0.45 to 0.75. For a heat pipe with 14 fins/in. (1.8-mm fins) and a total of 8 rows with
a face velocity vface 500 fpm (2.5m/s), its sensible heat effectiveness T 0.65 and its pres-
sure drop p is about 0.6 in. WC (150 Pa). Refer to the manufacturer s data for detailed
information.
The capacity and rate of heat transfer of a heat pipe can be controlled by varying the slope or tilt
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of the heat pipe. This adjustment increases or decreases the liquid flow inside the heat pipe and,
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therefore, its capacity.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.25
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.25
Comparison between Various Air-to-Air Heat Exchangers
According to ASHRAE Handbook 1996, HVAC Systems and Equipment, among the air-to-air heat
recovery heat exchangers:

Fixed-plate, runaround coil loop, and rotary sensible heat exchangers are all limited to sensible
heat transfer and recovery; only the rotary enthalpy exchangers can recover latent heat from the
exhaust airstream.

There are no moving parts in fixed-plate and heat pipe heat exchangers.

Both heat pipe and runaround coil loop heat exchangers show no cross-contamination or cross-
leakage. Fixed-plate heat exchangers have a cross-contamination and cross-leakage from 0 to 5
percent, and rotary heat exchangers from 0 to 10 percent. If cross-contamination is strictly prohib-
ited, a purge section can be installed to reduce it.

The effectivenesses of fixed-plate and rotary heat exchangers are higher than those of heat pipe
and runaround coil loop heat exchangers.

Rotary heat exchangers show the lowest air pressure drop among the various types of heat ex-
changer.
12.6 GAS COOLING AND COGENERATION
Gas Cooling
High electricity demand charges, high peak electricity rates, and the development of high-efficiency
direct-fired equipment, highly reliable gas engines, and more sophisticated and cost-effective
desiccant-based air conditioning systems enable gas cooling systems to compete with electric
compressors after the decline of gas cooling in the 1970s. Current gas cooling systems include the
following:

Double-effect, direct-fired, lithium bromide (LiBr) absorption chillers and chiller/heaters

Desiccant-based air conditioning using evaporative cooling, refrigeration, and direct-fired gas
heaters for regeneration

Gas engine chiller systems and cogeneration
Usually, a gas cooling system has a higher initial cost and a lower operating cost than an electricity-
driven refrigeration system. Accurate calculation of the operating costs of a gas cooling system is
important in this comparison.
The LiBr absorption chillers are discussed in Chap. 14, and desiccant cooling systems are
discussed in Chap. 29. Gas-engine chiller systems and cogeneration are discussed in this section.
Cogeneration
Cogeneration is the sequential use of energy from a primary source, including natural gas, oil, and
coal, to produce power and heat. Power can be electric or mechanical power, or both. In a cogenera-
tion system, the sequential use of the heat released from the flue gas and engine jacket significantly
increases system efficiency and makes the cogeneration system economically attractive.
In 1978 in the United States, the Public Utility Regulatory Policies Act (PURPA) permitted the
interconnection of electric power lines of cogeneration systems with electric utility systems. This
provides flexibility for cogeneration plants. They can either use or sell their electric power to the
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.26
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12.26 CHAPTER TWELVE
TX
FIGURE 12.11 Energy flow in (a) gas-engine chiller and (b) electricity-driven chiller.
utility and optimize the size of the cogeneration plant by reducing or eliminating its standby gener-
ation capacity. During the 1990s, many states, such as California and New York, were leading the
way in utility deregulation. Utility deregulation will stimulate competition in the electricity market
for lower consumer rates.
Since 1990, hundreds of cogeneration systems were developed for internal use. Internal use
means the production of both power and heat for use in settings such as hospitals, medical
centers, university campuses, public buildings, and industrial facilities, and in their installed air
conditioning systems. A successfully developed cogeneration system often relies on site technical
and economic analysis, especially for local electricity demand and electricity rates. Two kinds
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of prime movers are widely used in these internal use cogeneration systems: gas engines and gas
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turbines.
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.27
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.27
Gas-Engine Chiller
A gas-engine chiller is often a combination of a gas cooling system and a cogeneration system.
Heat released from the exhaust gas and the engine jacket cooling water are all recovered to in-
crease system efficiency. Figure 12.11a shows the energy flow of a gas-engine chiller system.
If the efficiency of the gas engine is 35 percent, the mechanical efficiency including the trans-
mission gear train is 95 percent, and the chiller s COP 4.5, then for every 10,000 Btu (10,550 kJ)
of fuel energy input to the gas-engine chiller, there is a cooling output Qrf of
Qrf 10,000 0.35 0.95 4.5 15,000 Btu (15,825 kJ)
In addition, there is a heating output of 4000 Btu (4220 kJ) from the exhaust gas and engine
jacket to supply hot water or low-pressure steam for an absoption, space heating, or domestic hot
water unit.
A gas-engine chiller has a prominent advantage over a motor-driven chiller because the former
can vary its speeds at various operating conditions: high speed at overloads and low speeds at part-
load operation. Engine reliability is the key to user acceptance for gas-engine chillers. Several
hundred engine-driven chillers were installed in the 1960s and early 1970s. According to reliability
records of these systems reported in Davidson and Brattin (1986), the reliability of gas-engine
chillers matches the requirements of HVAC&R systems.
Gas engines can be used to drive screw, reciprocating, or centrifugal compressors. Gas-engine-
driven screw chillers are becoming more and more popular. Many manufacturers offer packaged
units for easier field installation. The capacity of gas-engine chiller packaged units varies from 30
to 500 tons (105 to 1760 kW). Gas-engine cooling systems can also be coupled to direct-expansion
(DX) refrigeration systems and rooftop packaged units. Gas-fired internal combustion engines for
cooling in buildings follow the developments of gasoline and diesel engine technology. There are
two kinds of gas engines: heavy-duty industrial applications and light-duty automotive engines. In-
dustrial heavy-duty gas engines run a minimum of 30,000 h of full-load service between major
overhauls, and cost about 5 times as much as automotive engines. The service life of an automobile
engine is only 2000 to 5000 h.
Recently, manufacturers have produced packaged automotive gas-engine chillers of 150-ton
(525-kW) capacity. One manufacturer also offers one 150-ton (525-kW) gas-engine chiller and
integrated hot water absorption chiller to give a total maximum output of 180 tons (630 kW).
Automotive gas engines are suitable for compressors that require speeds far above 1800 rpm. This
packaged gas-engine chiller is also equipped with microprocessor-based controls to coordinate and
monitor the operation of the engine and chiller. An operating cost as low as one-half that of similar-
size electricity-driven units is claimed, depending on the local utility rate structure.
Engine-driven chillers are maintenance-intensive. The maintenance cost of a gas-engine chiller
may be between 10 and 20 percent of the energy cost, and it should be added to the operating cost
during economic analysis. D zurko and Epstein (1996) made a cost analysis between gas-engine
chiller and electric chillers for offices, schools, restaurants, retail stores, and hospitals in New York
State. Most have a simple payback of 2.1 to 11.9 years.
For a gas-engine chiller with a cooling output of 15,000 Btu (15,825 kJ), if its by-product, 4000-
Btu (4220-kJ) heat output from the exhaust gas and engine jacket is also counted, then the simple
payback period is usually between 2 and 5 years.
Gas Engines
Two types of automotive engines are used to drive the chillers: gas engines operated on diesel cycle
and operated on an Otto cycle. Because a diesel engine has a higher thermal efficiency than an Otto
engine, more diesel engines are used in gas-engine chillers. Most diesel engines are operated on a
four-stroke cycle, i.e., an intake stroke, a compression stroke, a power stroke, and an exhaust stroke,
to produce power. A diesel engine can also operate on a two-stroke cycle, an intake stroke and an
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.28
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12.28 CHAPTER TWELVE
TX exaust stroke, which is slightly cheaper than a four-stroke engine; however, a two-stroke engine is
less efficient and experiences greater wear than a four-stroke engine.
Reciprocating gas engines can be categorized according to the manner in which the engine is as-
pirated: natural aspiration and turbocharging. A natural aspiration engine supplies air or the fuel/air
mixture to the engine cylinder at atmopheric pressure, whereas a turbocharging engine supplies
higher-pressure air or fuel/air mixture to the cylinder. Turbocharging uses the engine exhaust gas to
drive a small turbine which is connected with a centrifugal compressor. This compressor raises the
intake air pressure and quantity and thus the engine s capacity.
In a gas engine, the primary function of a heat recovery system is to reject excess heat produced
and to exhaust flue gas during the power generation process. Effective heat rejection from the en-
gine jacket and the exhaust of adequate flue gas must be emphasized. The secondary function is to
recover heat from the exhaust gas and engine jacket and to use the recovered heat efficiently and
economically.
Exhaust Gas Heat Recovery
According to Orlando s Cogeneration Design Guide (1996), the exhaust gases of the reciprocating
gas engine contain about one-third of the engine s heat output, and approximately 50 to 75 percent
of the sensible heat can be recovered. Heat may be recovered in the form of steam or hot water.
The sensible heat recovered Qex,r, in Btu/h (W), can be calculated as
Ł
Qex,r 60Vex excpa (Tex Trec) (12.13)
Ł
where Vex volume flow rate of exhaust gas at outlet of gas engine, cfm [m3/(60 s)]
ex density of exhaust gas at outlet of gas engine, lb/ft3 (kg/m3)
cpa specific heat of exhaust gas, Btu/lb F (J/kg C)
Tex temperature of exhaust gas at outlet of gas engine, F (C)
Trec temperature of exhaust gas leaving heat recovery heat exchanger, F (C)
It is more economical to have a minimum temperature difference between the exhaust gas and the
generated steam inside the recovery heat exchanger of 100F (55C).
According to ASHRAE Handbook 1996, HVAC Systems and Equipment, the temperature of the
recovered steam or hot water for absorbing chillers is between 190 and 245F (88 and 118C),
for space heating between 120 and 250F (49 and 120C), and for domestic hot water between
120 and 200F (49 and 93C). For steam, a maximum pressure up to 8 psig (55 kPag) may be
produced.
Exhaust gas heat recovery heat exchangers are often designed to reduce engine noise transmitted
along with the exhaust gas and are called heat recovery mufflers. Heat recovery mufflers should
minimize engine backpressure to 6 in. WG (1500 Pag) for natural aspiration reciprocating engines
and to 25 to 30 in. WG (6.25 to 7.5 kPag) for turbocharged engines.
Many heat recovery mufflers are designed based on a minimum exhaust temperature of 300F
(149C) to avoid condensation. The temperature of the exhaust gas at part-load operation is impor-
tant. The construction of the exhaust heat recovery mufflers should provide access for inspection,
cleaning, and soot removal for diesel engines.
Engine Jacket Heat Recovery
Approximately one-third of the heat input to the reciprocating gas engine is rejected from the en-
gine block, heads, and exhaust manifolds to the engine jacket water coolant. Heat energy can be re-
SH__ covered by either the hot water with a temperature at 250F (120C) or low-pressure steam at a
ST__ maximum pressure of 15 psig (103 kPag).
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39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.29
HEAT PUMPS, HEAT RECOVERY, GAS COOLING, AND COGENERATION SYSTEMS 12.29
When the engine jacket water is routed through the heat recovery muffler where additional heat
is extracted from the exhaust gas, an engine jacket heat recovery system is then combined with the
exhaust gas heat recovery system. At least a water circulating pump is required to circulate the hot
water flowing through the engine jacket and the heat recovery muffler as soon as the engine is oper-
ating. To avoid excessive thermal stress, the temperature difference between the cooling water en-
tering and leaving the engine jacket should not exceed 15F (8.3C).
Steam can be produced at the top part of the heat recovery muffler with a steam separator and is
distributed to various process loads. Hot water from the bottom of the heat recovery muffler is then
mixed with the condensate returned from the remote steam loads. The mixture is forced through the
engine jacket and the heat recovery muffler by the circulating pump.
Sometimes, the engine coolant circuit in a heat recovery loop is separated from the process
loads by heat exchangers and forms a primary and secondary loop. A primary-secondary loop
isolates and protects the engine coolant circuit from process loads, leaks, and failures in the distrib-
ution systems. A primary-secondary loop is especially useful for a multiple-engine installation.
A cooling tower can be connected to a heat recovery loop through a heat exchanger for the sake
of maintaining a required entering temperature of the engine jacket coolant at system part-load
operation. A coolant heater can be installed to preheat the coolant during start-up.
For space heating, hot water from the heat recovery muffler can be supplied directly to the
heaters in the conditioned space. For space cooling, an absorption chiller using recovered steam or
hot water should be installed to provide cooling for the conditioned space.
Cogeneration Using a Gas Turbine
Many cogeneration plants use a combustion gas turbine instead of a gas engine as the prime mover.
A gas turbine usually consists of a compressor section to raise the air pressure, a fuel/air mixing
and combustion chamber, and an expanding turbine section. The compressor and turbine are joined
by the same shaft. Capacity may vary from several hundred brakehorsepower (bhp) to more than
100,000 bhp (75,000 kW). Gas turbines are often connected to induction generators to produce
electric power through gear trains.
Steam boilers are often used as heat recovery units to produce steam at a pressure typically 15
psig (103 kPag) from the gas-turbine exhaust gas. Recovered heat can often be used as process heat
to operate an absorption chiller.
REFERENCES
ASHRAE, ASHRAE Handbook 1996, HVAC Systems and Equipment , ASHRAE Inc., Atlanta, GA, 1996.
Ayres, J. M., and Lau, H., Comparison of Residential Air-to-Air Heat Pump and Air-Conditioner/Gas Furnace
Systems in 16 California Climatic Zones, ASHRAE Transactions, 1987, Part II, pp. 525  561.
Ball, D. A., Fischer, R. D., and Hodgett, D. L., Design Methods for Ground-Source Heat Pumps, ASHRAE
Transactions, 1983, Part II B, pp. 416 440.
Baxter, V. D., and Moyers, J. C., Field-Measured Cycling Frosting and Defrosting Losses for a High-Efficiency
Air Source Heat Pump, ASHRAE Transactions, 1985, Part IIB, pp. 537 554.
Bivens, D. B., Patron, D. M., and Yokozeki, A., Performance of R-32/R-125/R-134a Mixtures in Systems with
Accumulators or Flooded Evaporators, ASHRAE Transactions, 1997, Part I, pp. 777 780.
Black, G. D., An Overview of the Four-Way Refrigerant Reversing Valve, ASHRAE Transactions, 1987, Part I,
pp. 1147 1151.
Brown, M. J., Hesse, B. J., and O Neil, R. A., Performance Monitoring Results for an Office Building
Groundwater Heat Pump System, ASHRAE Transactions, 1988, Part I, pp. 1691 1707.
Cane, R. L. D., Clemes, S. B., and Morrison, A., Operating Experience with Commercial Ground-Source Heat
Pumps Part I, ASHRAE Transactions, 1996, Part I, pp. 911 916.
39445 Wang (MCGHP) Ch_12 SECOND PASS bzm 6/12/00 pg 12.30
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12.30 CHAPTER TWELVE
Carrier Corporation, Packaged Rooftop Heat Pumps, Carrier Corporation, Syracuse, NY, 1980.
TX
Davidson, K., and Brattin, H. D., Gas Cooling for Large Commercial Buildings, ASHRAE Transactions, 1986,
Part I B, pp. 910 920.
Department of Energy, 1986 Proposed Standard Test Procedure, Docket No. CAS-RM-79-102, 1986.
D zurko, D. C., and Epstein, G. J., Comparative Analysis for Natural Gas Cooling and Space Conditioning
Technologies in New York State, ASHRAE Transactions, 1996, Part I, pp. 275 283.
Eckman, R. L., Heat Pump Defrost Controls: A Review of Past, Present, and Future Technology, ASHRAE
Transactions, 1987, Part I, pp. 1152 1156.
Goldschmidt, V. W., Effect of Cyclic Response of Residential Air Conditioners on Seasonal Performance,
ASHRAE Transactions, 1981, Part II, pp. 757 770.
Hughes, P. J., Loomis, L., O Neil, R. A., and Rizzuto, J., Result of the Residential Earth-Coupled Heat Pump
Demonstration in Upstate New York, ASHRAE Transactions, 1985, Part II B, pp. 1307 1325.
Johnson, W. S., McGraw, B. A., Conlin, F., Wix, S. D., and Baugh, R. N., Annual Performance of a Horizontal-
Coil Ground-Coupled Heat Pump, ASHRAE Transactions, 1986, Part I A, pp. 173 185.
Kavanaugh, S. P., Groundwater Heat Pump Performance Enhancement with Precoolers and Water Pump
Optimization, ASHRAE Transactions, 1987, Part II, pp. 1205 1218.
Knipe, E. C., Applications of Heat Pumps Using Groundwater Resources, ASHRAE Transactions, 1983,
Part II B, pp. 441 451.
Mathen, D. V., Performance Monitoring of Select Groundwater Heat Pump Installations in North Dakota,
ASHRAE Transactions, 1984, Part I B, pp. 290 303.
Mohammad-zadeh, Y., Johnson, R. R., Edwards, J. A., and Safemazandarani, P., Model Validation for Three
Ground-Coupled Heat Pumps, ASHRAE Transactions, 1989, Part II, pp. 215 221.
Mulroy, W. J., The Effect of Short Cycling and Fan Delay on the Efficiency of a Modified Residential Heat
Pump, ASHRAE Transactions, 1986, Part I B, pp. 813 826.
Niess, R. C., Applied Heat Pump Opportunities in Commercial Buildings, ASHRAE Transactions, 1989, Part II,
pp. 493  498.
Nutter, D. W., O Neal, D., and Payne, W. V., Impact of the Suction Line Accumulator on the Frost/Defrost
Performance of an Air-Source Heat Pump with a Scroll Compressor, ASHRAE Transactions, 1996, Part I,
pp. 284  290.
O Neal, D. L., and Katipamula, S., Performance Degradation during On-Off Cycling of Single-SP Conditioners
and Heat Pump: Model Development and Analysis, ASHRAE Transactions, 1991, Part II, pp. 316 323.
O Neal, D. L., and Peterson, K., A Comparison of Orifice and TXV Control Characteristics during the Reverse-
Cycle Defrost, ASHRAE Transactions, 1990, Part I, pp. 337 343.
Orlando, J. A., Cogeneration Design Guide, ASHRAE Inc., Atlanta, GA, 1996.
Rackliffe, G. B., and Schabel, K. B., Groundwater Heat Pump Demonstration Results for Residential
Applications in New York State, ASHRAE Transactions, 1986, Part II A, pp. 3  19.
Rasmussen, R. W., MacArthur, J. W., Grald, E. W., and Nowakowski, G. A., Performance of Engine-Driven
Heat Pumps under Cycling Conditions, ASHRAE Transactions, 1987, Part II, pp. 1078 1090.
Robertson, W. K., Electricity and Competition, Engineered Systems, no. 11, 1996, pp. 34  41.
Virgin, D. G., and Blanchard, W. B., Cary School 25 Years of Successful Heat Pump/Heat Reclaim System
Operation, ASHRAE Transactions, 1985, Part I A, pp. 40 45.
Weinstein, A., Eisenhower, L. D., and Jones, N. S., Water-Source Heat Pump System for Mount Vernon
Unitarian Church, ASHRAE Transactions, 1984, Part I B, pp. 304 312.
Wurm, J., and Kinast, J. A., History and Status of Engine-Driven Heat Pump Developments in the U.S.,
ASHRAE Transactions, 1987, Part II, pp. 997 1005.
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