Conventional cooling systems do not exhibit significant reductions in energy use in relation to decreases in load demand. Air-cooled direct expansion (DX), water-cooled chillers, heat pumps, and even large fan air systems do not scale down well to light loading operation. Rather, the energy cost per ton of cooling increases dramatically as the output tonnage is reduced on conventional systems. This has been mitigated somewhat with the addition of fans, pumps, and chiller variable frequency drives (VFDs); however, their turn-down capabilities are still limited by such issues as minimum flow constraints for thermal heat transfer of air, water, and compressed refrigerant. For example, a 15% loaded air conditioning system requires significantly more than 15% power of its 100% rated power use. In most cases such a system requires as much as 40-50% of its 100% rated power use to provide 15% of cooling work.
Conventional commercial, residential, and industrial air conditioning cooling circuits require high electrical power draw when energizing the compressor circuits to perform the cooling work. Some compressor manufacturers have mitigated the power in rush and spikes by employing energy saving VFDs and other apparatuses for step loading control functions. However, the current systems employed to perform cooling functions are extreme power users.
Existing refrigerant systems do not operate well under partial or lightly loaded conditions, nor are they efficient at low temperature or “shoulder seasonal” operation in cooler climates. These existing refrigerant systems are generally required to be fitted with low ambient kits in cooler climates, and other energy robbing circuit devices, such as hot gas bypass in order to provide a stable environment for the refrigerant under these conditions.
Compressors on traditional cooling systems rely on tight control of the vapor evaporated in an evaporator coil. This is accomplished by using a metering device (or expansion valve) at the inlet of the evaporator which effectively meters the amount of liquid that is allowed into the evaporator. The expanded liquid absorbs the heat present in the evaporator coil and leaves the coil as a super-heated vapor. Tight metering control is required in order to ensure that all of the available liquid has been boiled off before leaving the evaporator coil. This can create several problems under low loading conditions, such as uneven heat distribution across a large refrigerant coil face or liquid slugging to the compressor. This latter scenario can damage or destroy a compressor.
To combat the inflexibility problems that exist on the low-end operation of refrigerant systems, manufacturers employ hot gas bypass and other low ambient measures to mitigate slugging and uneven heat distribution. These measures create a false load and cost energy to operate.
Conventional air-cooled air conditioning equipment are inefficient. The kw per ton (kilowatt electrical per ton of refrigeration or kilowatt electrical per 3.517 kilowatts of refrigeration) for the circuits are more than 1.0 kw per ton during operation in high dry bulb ambient conditions.
Evaporative assist condensing air conditioning units exhibit better kw/ton energy performance over air-cooled DX equipment. However, they still have limitations in practical operation in climates that are variable in temperature. They also require a great deal more in maintenance and chemical treatment costs.
Central plant chiller systems that temper, cool, and dehumidify large quantities of hot process intake air, such as intakes for turbine inlet air systems, large fresh air systems for hospitals, manufacturing, casinos, hotel, and building corridor supply systems are expensive to install, costly to operate, and are inefficient over the broad spectrum of operational conditions.
Existing compressor circuits have the ability to reduce power use under varying or reductions in system loading by either stepping down the compressors or reducing speed (e.g., using a VFD). There are limitations to the speed controls as well as the steps of reduction.
Gas turbine power production facilities rely on either expensive chiller plants and inlet air cooling systems, or high volume water spray systems as a means to temper the inlet combustion air. The turbines lose efficiency when the entering air is allowed to spike above 15° C. and possess a relative humidity (RH) of less than 60% RH. The alternative to the chiller plant assist is a high volume water inlet spray system. High volume water inlet spray systems are less costly to build and operate. However, such systems present heavy maintenance costs and risks to the gas turbines, as well as consume huge quantities of potable water.
Hospital intake air systems require 100% outside air. It is extremely costly to cool this air in high ambient and high latent atmospheres using the conventional chiller plant systems.
Casinos require high volumes of outside air for ventilation to casino floors. They are extremely costly to operate, and utilize a tremendous amount of water especially in arid environments, e.g., Las Vegas, Nev. in the United States.
Middle eastern and desert environments have a high impact on inlet air cooling systems due to the excessive work that a compressor is expected to perform as a ratio of the inlet condensing air or water versus the leaving chilled water discharge. The higher the delta, the more work the compressor has to perform with a resulting higher kw/ton electrical draw. As a result of the high ambient desert environment, a cooling plant will expend nearly double the amount of power to produce the same amount of cooling in a less arid environment.
High latent load environments, such as in Asia, India, Africa, and the southern hemispheres, require high cooling capacities to handle the effects of high moisture in the atmosphere. The air must be cooled and the moisture must be eliminated in order to provide comfort cooling for residential, commercial, and industrial outside air treatment applications. High latent heat loads cause compressors to work harder and require a higher demand to handle the increased work load.
Existing refrigeration process systems are normally designed and built in parallel. The parallel systems do not operate efficiently over the broad spectrum of environmental conditions. They also require extensive control operating algorithms to enable the various pieces of equipment on the system to operate as one efficiently. There are many efficiencies that are lost across the operating spectrum because the systems are piped, operated, and controlled in parallel.
There have not been many innovations in air conditioning systems and cooling equipment that address the inherent limitations of the various refrigerant cooling processes. Each conventional system exhibits losses in efficiency at high-end, shoulder, and low-end loading conditions. In addition to the non-linear power versus loading issues, environmental conditions have extreme impacts on the individual cooling processes. The conventional systems are too broadly utilized across a wide array of environmental conditions. The results are that most of the systems operate inefficiently for a vast majority of time. The reasons for the inefficiencies are based on operator misuse, misapplication for the environment, or losses in efficiency due to inherent limiting characteristics of the cooling equipment.
The present disclosure features a cooling system for data centers or for any other applications that have high heat rejection temperature and high sensible heat ratio compared to general air conditioning or refrigeration applications.
Some systems for data center cooling use two separate liquid refrigerant pump systems. Each pump system has its own water-cooled condenser, along with a chiller loop. The chiller loop includes a fluid cooler, a compressor, a trim condenser, and an air conditioning system (ACS) evaporator. When the outdoor ambient temperature is high, the chiller loop cools water from the outdoor fluid cooler. Further, if one of the two chiller loops fails to operate, the other is used as a backup. If both chiller loops are operable, the two of them can run in parallel for normal operation to obtain higher cooling capacity and energy efficiency.
The cooling systems and methods according to the present disclosure connect the water flow of the two chiller loop systems in a series, counter-flow arrangement. This design, together with optimal flow rate selection and control, significantly improves the system energy efficiency and reduces water flow rate and pipe size.
Some cooling systems use two circuits, each of which has a refrigerant pump loop and a water (or glycol) loop to condense the refrigerant. The water can be chilled (or “trimmed”) by a compressor/chiller loop when the outdoor wet bulb temperature is high. The two circuits have parallel water flow. In normal operation, the two circuits work simultaneously, and the evaporators for air cooling of the two circuits are in series, and air from the high temperature circuit enters the evaporator of the low temperature circuit to be cooled further.
If one of the two circuits fails to operate, the system operates in “failure mode” or “backup mode” with only one circuit in operation. The cooling system of the present disclosure employs two circuits, but the water (or glycol) flows through the two circuits in series and counter flow pattern, resulting in higher energy efficiency, lower water flow rate, and a broader operating range, e.g., it can run with a higher outdoor wet bulb temperature.
The two main pumped refrigerant fluid circuits are connected to evaporators at or near the heat source (e.g., mounted on the rear doors or tops of computer server cabinets or from the ceiling above the cabinets to cool the electronic equipment). Air and water flow of the two fluid circuits is in a counter flow arrangement: warm air (e.g., 40° C.) from electronic equipment is cooled in the first evaporator to a lower temperature (e.g., 32° C.), and then air leaving fluid circuit 2 enters the evaporator of fluid circuit 1 and is further cooled (e.g., to 25° C.). In other words, chilled water from the ACS evaporator is in thermal communication with the first and second fluid circuits, and the chilled water and the refrigerant flowing through the first and second fluid circuits are in thermal counter flow: the chilled water is first in thermal communication with the refrigerant with lower temperature (corresponding to lower air temperature in the evaporator) in fluid circuit 1 through the main condenser 1, with its temperature raised, and then is in thermal communication with the refrigerant with higher temperature (corresponding to higher air temperature in the evaporator) in fluid circuit 2 through the main condenser 2, with its temperature further raised. In embodiments, the evaporators may include microchannel evaporators.
The refrigerant saturation temperature of fluid circuit 1 is maintained lower than fluid circuit 2 (e.g., 24° C. for fluid circuit 1 versus 31° C. for fluid circuit 2); the water (or glycol) from the fluid cooler or ACS evaporator with lower temperature flows through main condenser 1 to condense refrigerant vapor in fluid circuit 1, with its temperature raised, and then flows through main condenser 2 to condense refrigerant vapor in fluid circuit 2, with its temperature further raised, then flows to the trim condenser. This flow arrangement plus optimal water (or glycol) flow rate control can increase system energy efficiency and significantly reduce water flow rate, pipe size and pumping power.
The two refrigerant fluid circuits 1 and 2 shown in
Although the illustrative embodiments of the present disclosure have been described herein with reference to the accompanying drawings, it is to be understood that the disclosure is not limited to those precise embodiments, and that various other changes and modification may be effected therein by one skilled in the art without departing from the scope or spirit of the disclosure.
In embodiments, the water flow through the trim condenser and the water flow through the ACS evaporator, the first main condenser, and the second main condenser, may be in a series or in a parallel arrangement.
Other applications for the cooling system of the present disclosure include turbine inlet air cooling, laboratory system cooling, and electronics cooling, among many others.
Number | Date | Country | |
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61900602 | Nov 2013 | US |