Modern Building Services
MODERN BUILDING SERVICES JANUARY 2022 29 The LEED rating system rewards environmentally sustainable practices that conserve energy, material and water resources. An evaporative cooling tower system capable of achieving these goals has the potential to earn points toward energy optimization credit, including up to 20 in existing buildings and up to 18 in new buildings. A building looking to achieve credits for optimizing energy performance can get about halfway to certification by implementing HVAC-related strategies and equipment choices that contribute to increased efficiency. Remember, a building becomes LEED certified at a minimum of 40 points. First, to earn points toward certification, buildings must meet a few prerequisites. For new buildings, design teams can demonstrate the cooling tower’s contribution to indoor water reduction with makeup water meters, conductivity controllers and overflow alarms, and drift eliminators. New buildings can also pre-qualify for certification if owners commit to water metering and fundamental commissioning and verification. Fundamental commissioning and verification include implementation of a “facilities requirements and operations plan,” which may address equipment run-time schedules and HVAC set points that optimize energy use. Cooling towers evaporate an HVAC system’s recirculated water to remove heat. Only small amounts of water are required to be recirculated through the system. Water in the evaporative cooling tower mixes with air flow – typically produced by a fan (often using a variable frequency drive to save energy); evaporation of the hot water results, creating a cooling action. Cooling tower operation can be optimized in several ways to directly contribute to LEED certification: • Operating a cooling tower under variable flow conditions at off- peak times can achieve greater efficiency by reducing flow rate and fan energy, as long as proper water distribution is achieved. Examples: - Running half the fans at full speed for 50 percent cooling at half the energy usage. - Running all the fans at half speed for 50 percent cooling at one-eighth the energy usage. • Monitoring water consumption to identify ways to minimize use. As mentioned earlier, water metering can potentially help an existing building earn up to two points and a new building up to one point. TheWater Usage Calculator at spxcooling.comhelps building planners determine howmuch water they can save using evaporative cooling in their specific applications. • Incorporating water quality management, contaminant control and cycles of concentration as part of system water conservation. Achieving water conservation has the potential of earning an existing building up to three points and a new building up to two points. Maximizing “cycles of concentration” is a recommended water conservation practice. Cycles of concentration is defined as the resulting ratio of concentrated dissolved solids in the circulating “blowdown” water compared to that in the fresh makeup water. Increasing cycles of concentration can greatly reduce blowdown and make-up water simultaneously, creating a water chemistry equilibrium that conserves water and removes minerals that dissolved during the evaporative cooling process. At the same time, the quantity of dissolved solids must be carefully controlled. Implementing an effective water treatment program with tools to monitor water quality empower cooling tower operators to proactively address issues related to microorganisms, corrosion, scale and water conservation. How does relative humidity impact the evaporative cooling process, and why is that important in arid parts of the world? Cooling tower efficiency is largely driven by operation and maintenance standards, but climate also plays a role. When relative humidity is low, as it is in hot and dry regions like the Middle East, the more beneficial evaporative cooling is for building owners. Relative humidity measures the difference between moisture actually in the air and the amount of moisture the air could hold. That is the difference between wet bulb temperature, or the amount of moisture in the air, and dry bulb temperature, the outdoor temperature. At 100 percent relative humidity, wet and dry bulb temperatures are the same. In evaporative cooling systems, heat is transferred based on wet bulb, while dry systems rely on dry bulb. Evaporative systems are capable of producing cold-water temperatures near wet bulb levels that often fall below outdoor dry bulb temperatures, which results in energy savings in arid areas. Dry systems, on the other hand, have to work against high dry bulb temperatures year-round in areas like the Middle East. In arid climates with limited or no water resources, hybrid cooling towers may help limit water consumption. The hybrid combination of wet and dry components maximizes cooling efficiency under high heat load conditions while achieving water savings at reduced load. Innovative hybrid products using both wet and dry technologies – like the Marley NCWD Cooling Tower – first cool water through a dry section at the top of the tower, offering additional water savings and another way to potentially earn points toward the innovation credit. The NCWD tower can reduce annual water consumption by up to 20 percent, depending on climate and the facility’s heat load profile. Are there benefits of using water- versus air-cooled cooling systems? Yes, and the simple explanation is that air-cooled HVAC systems requiring higher fan power to reduce temperatures are less energy efficient. Air-cooled equipment use fans to chill a fluid moving through a coil by blowing air across the coil surface, and electricity powers those fans. Depending on the location’s climate, the energy savings realized from water-cooled systems are significant. According to the Hydronics Industry Alliance, a building can save five to 30 percent or more on HVAC energy consumption when using a water- cooled system compared to air- cooled or variable refrigerant flow (VRF) systems. Are there any cooling tower components or accessories that building operators might consider to see additional energy savings? The use of variable frequency drives (VFDs) with fans is recommended. With two-speed fan motors, any time you need greater than 50 percent cooling capacity, fan power needs to be increased to 100 percent to reach it. VFD systems are designed to combine absolute temperature control with ideal energy management. The cooling tower user selects a cold-water temperature and the drive system will vary the fan speed to maintain that temperature. Using VFDs can significantly reduce annual energy consumption in most climates, making them essential for projects focused on energy efficiency and LEED concepts. When used with a VFD, the use of a permanent magnet motor may be as energy efficient as a gear drive, but the initial cost can be significantly higher. In addition to these two factors, building managers should consider ease of maintenance, reliability and service life, balanced against installation costs, operational complexity and environmental impact. How does the size of a cooling tower affect energy savings? Physically larger cooling towers are more efficient because they typically have more heat transfer media (fill) volume, allowing them to use less air flow and lower fan power for increased energy savings. Numerous combinations of physical tower size and fan power can meet certain temperature requirements for a specific water flow. Because maximizing power savings generally requires using a larger, and potentially more costly cooling tower, system designers should consult with cooling tower manufacturers for help weighing the costs compared with power consumption benefits to find a solution that best meets their requirements. In sum, green building concepts have evolved from being the innovative exception to becoming the accepted standard for many communities. Today, building designers, engineers and managers expect manufacturers of HVAC systems to dedicate R&D resources to commercialize environmentally responsible cooling systems that offer exceptional performance and value while meeting global ASHRAE, LEED and other sustainability standards. FEATURE WORKING BUILDINGS
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