|
Thermally-Activated
Machines
Thermally
activated machines are based on technologies that primarily
use thermal energy, preferably heat from the exhaust gases
of power generation equipment, instead of electric energy
for providing heating, cooling, or humidity control for buildings.
There are two primary candidates for thermally-activated machines
for application in CHP systems:
Follow
the provided links for a Real Video streaming media presentation,
in 56K
or DSL/T1
formats, of an overview of cooling technologies that use thermal
energy.
Absorption
chillers
 Absorption
chillers are cooling machines that use heat as the primary
source of energy for driving an absorption
refrigeration cycle. These chillers require very little
electric power (0.02 kW/ton) compared to electric chillers
that need 0.47 to 0.88 kW/ton, depending upon the type of
electric chiller.
Absorption
chillers have fewer and smaller moving parts and are thus,
quieter during operation than electric chillers. These chillers
are also environmentally friendly in that they use water as
a naturally benign refrigerant.
Commercially
available absorption chillers can utilize one of the four
sources of heat:
-
Steam
-
Hot water
-
Exhaust gases
-
Direct combustion
All
absorption chillers, except those that use direct combustion,
are excellent candidates for providing some, or all, cooling
of the load in a CHP system for a building. Modern absorption
chillers can also work as boilers for providing heating during
winter and feature new electronic controls that provide quick
start-up, automatic purge and greater turndown capability
than many electric chillers. Maintenance contracts and extended
warranties are also available on absorption chillers at costs
similar to those for electric chillers. Many facilities across
the U.S. are already benefiting from the use of absorption
chillers.
Two
types of absorption chillers are commercially available:
Compared
to single-effect chillers, multiple-effect absorption chillers
cost more to own (higher capital cost) but are more energy
efficient and thus less expensive to operate (lower energy
cost). The overall economic attractiveness of each chiller
depends on many factors, including the cost of capital and
cost of energy.
A
Real Video streaming media presentation of absorption chillers
is provided here in (telephone
56K) or (broadband
DSL/T1) formats, courtesy of the American Gas Cooling
Center.
Back
To Top
Desiccant
dehumidifiers
There
are two separate aspects of space conditioning for comfort
cooling;
-
Lowering the temperature of the air (sensible cooling),
and
- Reducing
humidity in the air (latent cooling)
 It
is important to control humidity to below 60% Relative Humidity
(RH) to prevent growth of mold, bacteria and other harmful
microorganisms in buildings and prevent adverse health effects.
Traditionally,
lowering of temperature and humidity have been accomplished
using a single piece of equipment (either by an electric chiller
or an absorption chiller) that lowers the air temperature
below its dew point temperature. Moisture in the incoming
air condenses on the outside of a cooling coil over which
the air passes and cooler air, containing less moisture, is
sent to the space being conditioned. Reducing humidity in
the air by cooling, often requires lowering the air temperature
below a comfortable level and might necessitate some reheating
of the dehumidified air.
Desiccant
dehumidifiers reduce humidity in the air by using solid
desiccant materials or liquid
desiccant materials to attract and hold moisture. Desiccant
dehumidifiers can operate independently of the chiller operation
and can be operated in series with chillers. Recoverable heat
from the exhaust gases of turbines and engines for power generation
or engine-driven chillers can be used for regenerating desiccant
material in these dehumidifiers.
In a CHP system, it might be desirable to first reduce moisture
content of the air using a desiccant dehumidifier and then
cool the dehumidified air by using conventional cooling equipment.
By reducing moisture content of the air, desiccant dehumidifiers
take care of the latent cooling load and thus reduce the total
cooling load of the chillers to only the sensible cooling
(reducing the temperature). Alternatively, a desiccant dehumidifier
can be used to further dehumidify and partially reheat cool,
saturated air leaving a conventional cooling coil. By positioning
the desiccant dehumidifier after the cooling coil, dehumidification
performance of the desiccant is enhanced. This allows the
use of moderate or lower temperatures, typical of CHP systems,
for regenerating the desiccant.
More
information on desiccants is also available at the National
Renewable Energy Laboratory's Advanced
Desiccant Cooling and Dehumidification Program website
and the Oak Ridge National Laboratory's Building
Technology Center website. A Real Video streaming media
presentation, on desiccant dehumidifiers, is provided here
in (telephone
56K) or (broadband
DSL/T1) formats, courtesy of the American Gas Cooling
Center.
Back
To Top
|
