(C)HILLER
What are
Chiller Systems?
·
Commercial buildings use Heating, Ventilation and
Air Conditioning (HVAC) systems to dehumidify and to cool the building. Modern
commercial buildings seek efficient HVAC systems and components as part of
broader initiatives centered on building performance and sustainability.
Building occupants similarly carry great expectations, that the HVAC system will function as intended . . . to create a
comfortable interior environment regardless of the conditions external to the building.
· Chillers have become an essential HVAC component of a wide variety of commercial facilities, including hotels, restaurants, hospitals, sporting arenas, industrial and manufacturing plants, etc. The industry has long recognized that chiller systems represent the single largest consumer of electrical usage in most facilities. They can easily consume more than 50% of the total electrical usage during seasonal periods. According to the US Department of Energy (DOE), chillers can combine to use approximately 20% of the total electric power generated in North America. Moreover, the DOE estimates that chillers can expend up to 30% in additional energy usage due to various operational inefficiencies. These acknowledged inefficiencies cost companies and building facilities billions of dollars annually.
·
In general, a chiller facilitates the transfer of
heat from an internal environment to an external environment. This heat-
transfer device relies on the physical state of a refrigerant as it
circulates through the chiller system. Certainly, chillers can function as the
heart of any central HVAC system.
How Does a Chiller Work?
· A chiller works on the principle of vapor compression or vapor absorption. Chillers provide a continuous flow of coolant to the cold side of a process water system at a desired temperature of about 50°F (10°C). The coolant is then pumped through the process, extracting heat out of one area of a facility (e.g., machinery, process equipment, etc.) as it flows back to the return side of the process water system.
·
A chiller uses a vapor compression mechanical
refrigeration system that
connects to the process water system through a device called an evaporator.
Refrigerant circulates through an evaporator, compressor, condenser and
expansion device of a chiller. A thermodynamic process occurs in each of above
components of a chiller. The evaporator functions as a heat exchanger such that
heat captured by the process coolant flow transfers to the refrigerant. As the
heat-transfer takes place, the refrigerant evaporates, changing from a
low-pressure liquid into vapor, while the temperature of the process coolant reduces.
· The refrigerant then
flows to a compressor, which performs multiple functions. First, it removes
refrigerant from the evaporator and ensures
that the pressure in the evaporator remains low enough to absorb heat at
the correct rate. Second, it raises the pressure in outgoing refrigerant vapor
to ensure that its temperature remains high enough to release heat when it
reaches the condenser. The refrigerant returns to a liquid state at the
condenser. The latent heat given up as the refrigerant changes from vapor to
liquid is carried away from the environment by a cooling medium (air or water).
Types of
Chillers:
There are two
types of chillers -
1)
Water-Cooled Condensers
2) Air-Cooled
Condensers
1)
Water-Cooled
Chillers :
· Water-cooled chillers feature a water-cooled condenser connected with a cooling tower. They have commonly been used for medium and large installations that have a sufficient water supply. Water- cooled chillers can produce more constant performance for commercial and industrial air conditioning because of the relative independence to fluctuations of the ambient temperature. Water- cooled chillers range in size from small 20-ton capacity models to several thousand-ton models that cool the world’s largest facilities such as airports, shopping malls and other facilities.
· A typical water-cooled chiller uses recirculating condenser water from a cooling tower to condense the refrigerant. A water-cooled chiller contains a refrigerant dependent on the entering condenser water temperature (and flow rate), which functions in relation to the ambient wet-bulb temperature. Since the wet-bulb temperature is always lower than the dry-bulb temperature, the refrigerant condensing temperature (and pressure) in a water-cooled chiller can often operate significantly lower than an air-cooled chiller. Thus, water-cooled chillers can operate more efficiently.
·
Water-cooled chillers typically
reside indoors in an environment protected from the elements. Hence,
water-cooled chiller can offer a longer lifespan.
Water-cooled chillers typically
represent the only option
for larger installations. The additional cooling tower system will require
additional installation expense and maintenance as compared to air-cooled chillers.
2) Air-Cooled Chillers :
·
Air-cooled chillers rely on a condenser cooled by
the environment air. Thus air-cooled chillers may find common application in smaller or medium
installations where space constraints may exist. An air-cooled chiller can
represent the most practical choice in scenarios where water represents a scarce resource.
·
A typical air-cooled chiller can feature propeller
fans or mechanical refrigeration cycles to draw ambient air over a finned coil
to condense the refrigerant. The
condensation of the refrigerant vapor in the air- cooled condenser enables the
transfer of heat to the atmosphere.
· Air cooled chillers offer the significant advantage of
lower installation costs. Simpler mantainance results due to their relative
simplicity as compared to water cooled chillers. Air cooled chillers will occupy
less space, but will mostly reside outside a facility. Thus,
the outdoor elements will compromise their functional lifespan.
The all-inclusive nature of air-cooled chillers reduces maintenance
costs. Their relative simplicity coupled with reduced space requirements
produces great advantages in many types of installations.
 |
Ø
Actions to Increase Efficiency of Chiller Systems:
Chiller costs consume a substantial
part of your building’s utility bills. What measures should one take to obtain energy savings
through maximal efficiency of the chiller system?
Let’s examine some possibilities.
v Ongoing Maintenance
Chiller systems will operate more efficiently through proper ongoing
maintenance. Most organizations recognize this value and have taken steps as
part of their day-to- day facility management best practices. Some common best
practices for chiller systems include:
·
Inspect and clean condenser coils. Heat transfer has a
large effect on chiller systems and remains fundamental to producing
efficient chiller operation. Routine maintenance should inspect condenser coils
for clogging and free air passage.
·
Maintain refrigerant charge. A
chiller’s cooling quotient depends on proper refrigerant levels in the system.
Maintaining proper refrigerant charge can greatly impact energy efficiency by reducing cooling
costs by nearly
5-10%.
· Maintain
condenser water: Condenser water loops used with cooling towers must maintain
proper water flow as designed. Any debris like sand, erosive solids and
contamination materials can affect the condenser water loop. Fouling or scaling
can inhibit water flow and greatly impact the chiller operating efficiency.
v Predictive Maintenance
·
Artificial Intelligence (AI)
continues to advance in everyday practical applications. Machinery such as
chiller systems will benefit from AI algorithms that can detect potential
failures before they occur. Predictive maintenance leverages the collection and
analysis of chiller system operational data to determine when maintenance
actions should be taken prior to catastrophic failure. As chillers systems
represent the heart of most modern HVAC systems, the prevention of catastrophic
failures that produce significant “downtime” will save on emergency repair
costs as well as reputation. The critical role
played by a chiller system warrants the increased scrutiny. Big Data and AI will minimize
downtime and maximize productivity.
·
The Internet of Things (IoT)
provides the data collection tool that can enable AI applications such as
predictive maintenance. In fact, the future of HVAC is AI and IoT. IoT enables the collection of real-time data from a chiller to enable
continual analysis of its operation. The granular IoT data collected from a
chiller will go far beyond that obtained by visual inspection. IoT connects
building engineers to real-time visibility of critical HVAC assets, thereby
enabling informed monitoring of actual operating conditions.
Ø
Optimization
:
·
Chillers operate as part of a
complex HVAC system. Water-cooled chillers have greater complexity due to the
connection to a cooling tower system. Evaluating overall chiller plant
performance will therefore involve an analysis of total power consumption of
the compressor, pumps, cooling tower fans, etc. to evaluate
comprehensive efficiency measures
such as kW/ ton.
·
Optimization of the overall chiller
plant must be performed holistically. Various adjustments focusing on optimal
chilled water set points, chiller sequencing and load balancing, peak demand
management, cooling tower water management, etc. can only be performed with
operational data. IoT can provide the tools for such optimization by providing
real-time monitoring of power consumption from each part of the chiller plant,
supply/return temperatures from the chiller and cooling tower, water flow rates from the condenser water loop,
etc. IoT has found practical application in HVAC to facilitate true optimization.
Ø Conclusion:
·
Chiller operational efficiency will greatly impact your building
operating costs. Ongoing routine maintenance represents the minimum from
the perspective of facility management. Predictive maintenance and optimization
of the chiller system requires real-time operational data. IoT has opened the door to new forms of chiller
efficiencies.
§
References -
senseware.co
https://blog.senseware.co/2017/11/16/ultimate-guide-chiller-systems
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