CHILLED SYSTEM

CHILLED  SYSTEM

Water cooled chillers: With water cooled chillers, the refrigerant is cooled with a shell and tube condenser that is part of the chiller package. The condenser water heat is then rejected to the cooling tower located outdoors.

Glycol cooled chillers: Glycol-cooled chillers look identical to the water-cooled chillers. With glycol-cooled chillers, heat removed from the returning chilled water is rejected to a glycol loop for transport to the outside atmosphere. The glycol flows via pipes to an outdoor-mounted device called a dry cooler also known as a fluid cooler. Heat is rejected to the outside atmosphere as fans force outdoor air through the warm glycol-filled coil in the dry cooler.

 Air cooled chillers: With air-cooled chillers, the heat of refrigerant is rejected to an air-cooled condenser that is typically integrated with the chiller. This type of chiller is known as a packaged chiller and can also be integrated into a cooling facility module. Air-cooled chillers are typically located outdoors.

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HVAC COOLING SYSTEM DESIGN

HVAC COOLING SYSTEM DESIGN

 Cooling and heat dissipation techniques are extremely important topics when it comes to designing and operating a data center. In many instances, system designs fall short of clients’ expectations in terms of reliability and availability. Perhaps naively, often too much importance is placed on the power and network availability without the same being applied to the air conditioning systems.

 Remember, ‘a chain is only as strong as its weakest link’. Infrastructure designs often fail to meet expectations because the same level of reliability/redundancy in many instances is not applied to all other components of the supporting infrastructure. While many people understand that only a short interruption in power supply to computer equipment can mean loss of data, what is often not considered is that an interruption in cooling system can be just as devastating.

This section includes:

1. Heat gains

2. Temperature and humidity requirements

3. Ventilation rates

4. Air quality

5. Cooling loads

6. HVAC equipment

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Central Heating Systems

Central Heating Systems

Central heating systems have been considered a necessity in our homes and businesses for many years. When comparing available systems, consumers should carefully consider safety, installation cost, operating costs, maintenance costs, and comfort.

Types of Heating Systems

There are two basic types of systems - those that require a flame to operate (i.e., combustion based), and those that do not. Most central systems presently installed create heat by combustion, just as they did in the early part of the century. These systems use a furnace to burn a fossil fuel (such as oil, natural gas or propane) or, in some instances, wood. More advanced, non-combustion systems operate by transferring or moving heat from one location to another.

Combustion Based Systems

Until the last few years, combustion-based systems have been the preferred heating systems for home and business owners because of their moderate installation and operating costs, and wide availability in the market place. Unfortunately, there are a number of serious safety and related maintenance concerns with these systems.

Some combustion-based systems present an explosion hazard if the storage or delivery of their fuel is not carefully controlled. Explosions due to improperly installed or maintained gas pipes and delivery systems are often in the news. Since these systems require a flame to operate, failures or improper installation of system components (for example, heat exchanger, damper, chimney, or flue) can result in property loss to fire. Fortunately, smoke detectors have saved many lives that might have been lost to fires caused by combustion-based heating systems.

In addition to heat, combustion-based heating systems also create by-products such as carbon monoxide. Carbon monoxide is a result of the incomplete burning of fuel in combustion-based systems. Incorrectly installed systems, chimneys that are blocked by birds nests, or downdrafting can cause carbon monoxide to remain inside of buildings. This is especially dangerous in modern, well-sealed buildings, where it is difficult for outside combustion air to reach the furnace, and where carbon monoxide can be trapped and build up over time. Furnaces, water heaters, and other appliances must be properly vented outside.

Combustion-based systems that deliver heat through ducts present occasional "blasts" of hot air. This not only reduces comfort directly, but tends to dehumidify the air. The addition of a central humidifier (with its associated installation, operating, and maintenance costs) can correct this humidity problem.

Combustion based central heating systems are often coupled with low-efficiency central air conditioners. This raises installation and operating costs significantly, while adding an entirely separate unit to be maintained.

Heat Transfer Systems

Non-combustion or heat transfer systems include heat pumps and geoexchange systems. Heat pumps operate by capturing heat from outdoor air and transferring it inside of a home or business. geoexchange systems capture and transfer heat from the earth.

Nearly all heat transfer systems can be reversed, providing central cooling as well as heating. Some heat pumps and most geoexchange systems also provide domestic hot water at low operating costs.

Heat Pumps

Beginning in the 1970s, air-source heat pumps came into common use. They have the advantage of no combustion, and thus no possibility of indoor pollutants like carbon monoxide. Heat pumps provide central air conditioning as well as heating as a matter of course. And they are installation-cost competitive with a central combustion furnace/central air conditioner combination.

Heat pumps operate by moving or transferring heat, rather than creating it. During the summer, a heat pump captures heat from inside a home or business and transfers it to the outdoor air through a condensing unit. During the winter, the process is reversed. Heat is captured from outdoor air, compressed, and released inside.

Much less electricity is used to move heat rather than create it, making heat pumps more economical than resistance heating. However, in all but the most moderate climates, the heating ability of the heat pump is limited by freezing outdoor temperatures. So electric resistance heat is used to supplement outdoor-air-source heat pump during the coldest weather, preventing "cold blow."

Depending on climate, air-source heat pumps (including their supplementary resistance heat) are about 1.5 to 3 times more efficient than resistance heating alone. Operating efficiency has improved since the 70s, making their operating cost generally competitive with combustion-based systems, depending on local fuel prices. With their outdoor unit subject to weathering, some maintenance should be expected.

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Types of Cooling Systems

Types of Cooling Systems
Air conditioning, or cooling, is more complicated than heating. Instead of using energy to create heat, air conditioners use energy to take heat away. The most common air conditioning system uses a compressor cycle (similar to the one used by your refrigerator) to transfer heat from your house to the outdoors.
Picture your house as a refrigerator. There is a compressor on the outside filled with a special fluid called a refrigerant. This fluid can change back and forth between liquid and gas. As it changes, it absorbs or releases heat, so it is used to “carry” heat from one place to another, such as from the inside of the refrigerator to the outside.

 And the process gets quite a bit more complicated with all the controls and valves involved. But its effect is remarkable. An air conditioner takes heat from a cooler place and dumps it in a warmer place, seemingly working against the laws of physics. What drives the process, of course, is electricity — quite a lot of it, in fact.

Central Air Conditioners and Heat Pumps
Central air conditioners and heat pumps are designed to cool the entire house. In each system, a large compressor unit located outside drives the process; an indoor coil filled with refrigerant cools air that is then distributed throughout the house via ducts. Heat pumps are like central air conditioners, except that the cycle can be reversed and used for heating during the winter months. (Heat pumps are described in more detail in the heating section.) With a central air conditioner, the same duct system is used with a furnace for forced warm-air heating. In fact, the central air conditioner typically uses the furnace fan to distribute air to the ducts.

Air conditioners and heat pumps use the refrigerant cycle to transfer heat between an inside unit and an outside uint. Heat pumps differ from air conditioners only in the special valve that allows the cycle to reverse, providing either warm or cool air to the inside.

Room Air Conditioners
Room air conditioners are available for mounting in windows or through walls, but in each case they work the same way, with the compressor located outside. Room air conditioners are sized to cool just one room, so a number of them may be required for a whole house. Individual units cost less to buy than central systems.

Evaporative Coolers
Evaporative coolers, sometimes called swamp coolers, are less common than vapor compression (refrigerant) air conditioners, but they are a practical alternative in very dry areas, such as the Southwest. They work by pulling fresh outside air through moist pads where the air is cooled by evaporation. The cooler air is then circulated through a house. This process is very similar to the experience of feeling cold when you get out of a swimming pool in the breeze. An evaporative cooler can lower the temperature of outside air by as much as 30 degrees.
They can save as much as 75% on cooling costs during the summer because the only mechanical component that uses electricity is the fan. Plus, because the technology is simpler, it can also cost much less to purchase than a central air conditioner — often about half.
A direct evaporative cooler adds moisture to a house, which could be considered a benefit in very dry climates. An indirect evaporative cooler is a little different in that the evaporation of water takes place on one side of a heat exchanger. House air is forced across the other side of the heat exchanger where it cools off but does not pick up moisture. Both types begin to lose their effectiveness with increasing humidity, because humid air is less able to carry additional moisture.
For evaporative coolers to do their job, they must be the right size. The cooling capacity of an evaporative cooler is measured not in the amount of heat it can remove (Btu), but in the fan pressure required to circulate the cool air throughout the house, in cubic feet per minute (cfm). A good rule is to figure the cubic square footage of your house and divide by 2. For example, a 1,500-square-foot house with 8-foot-high ceilings would require a 6,000 cfm cooler.

Ductless Mini-Split Air Conditioners
Mini-split systems, very popular in other countries, can be an attractive retrofit option for room additions and for houses without ductwork, such as those using hydronic heat (see the heating section). Like conventional central air conditioners, mini-splits use an outside compressor/condenser and indoor air handling units. The difference is that each room or zone to be cooled has its own air handler. Each indoor unit is connected to the outdoor unit via a conduit carrying the power and refrigerant lines. Indoor units are typically mounted on the wall or ceiling.
The major advantage of a ductless mini-split is its flexibility in cooling individual rooms or zones. By providing dedicated units to each space, it is easier to meet the varying comfort needs of different rooms.
By avoiding the use of ductwork, ductless mini-splits also avoid energy losses associated with central forced-air systems.
The primary disadvantage of mini-splits is cost. They cost much more than a typical central air conditioner of the same size, where ductwork is already in place. But, when considering the cost and energy losses associated with installing new ductwork for a central air conditioner, buying a ductless mini-split may not be such a bad deal, especially considering the long-term energy savings. Talk with your contractor about what option would be most cost-effective for you.

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Selecting Heating and Cooling Systems

Selecting Heating and Cooling Systems

Heating and cooling system selection is very important to a home. Read on for some tips in selecting the right one for your needs.

 This is a very important decision with many variables. These systems are components to a building that will last for a long time and can be costly. They play a big part in a house's energy efficiency and comfort level. There is not a "one size fits all" answer; it will depend on the region of the country a home is built in, the homeowners' budget and individual preferences. Every heating and cooling system has pros and cons. Here are some things to think about:

- Forced Air Styles: The new technology utilized in forced air units is much more efficient than in the past. They can be run from a variety of energy sources such as gas, electric, oil and propane. A downside is that they may produce spotty heat and coolness. Those that are equipped with blowers may expose allergy sufferers to more dust.

- Heat Pumps: Heat pumps are quite efficient in terms of energy use. Both the AC and the warmth can be piped through the same ventilation pathways, cutting down on installation costs. Some of these units are split into inside/outside locations. Filters which trap debris from vents must be changed every month or a breakdown in the system could occur.

- Duct-free: Systems that are duct-free are those that either hang from the wall or set on the floor. A positive of this type of unit is that it costs less in terms of installation as there are no ducts to position. The duct-free devices are best used in small areas or temperate climates. If temperatures drop well into the freezing zones, these models won't provide enough warmth in the home.

- Radiators with Steam: These are also called boilers and can be comfortable because they emit moisture along with heat. Some downsides include that they can rattle, clank, make lots of noise and the warmth may be spotty through the home. This is kind of an old-fashioned method of warming up one's abode, but it may make a comeback.

- Solar Energy: Solar technology is great for energy efficiency because it harnesses warmth from the sun. Solar systems can be passive or active. Panels on the roof or thermal mass holders are options.

- Wind Energy: Harnessing the power of the wind may also be an ecologically sound method of using natural sources of energy.

- Radiant Heaters: These devices are installed beneath the flooring of one room or an entire house. Pipes with hot water warm surfaces. No ductwork is requiredPsychology Articles, so no allergens will blow around. Efficiency is quite high.

There are many options in heating and cooling systems. Each of their goals is to provide comfortable temperatures inside of a home with as low a utility consumption as possible.

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Condenser, Evaporator, and Compressor

Condenser, Evaporator, and Compressor

The condenser is one of three primary elements in your air conditioning system. The other two, the evaporator and compressor, are also important. To understand how the condenser works, it’s important to understand the other two as well.

• Evaporator: The system starts in home with inside air being blown over evaporator coils. These coils contain low-pressure refrigerant which absorbs the heat from the air and converts into a high-pressure gas.
• Compressor: The gas is transferred into the compressor, which is in the outside unit. Here, it’s compressed to help convert it back into a liquid so it can continue the cooling cycle. This produces extra heat.
• Condenser: The condenser is a set of coils, also located inside the outdoor unit. Here, a fan blows across the coils, dissipating the heat from the refrigerant inside them and allowing it to convert back into a liquid, at which point it’s sent back inside to start the process over again.

Without the condenser, the refrigerant would retain its heat and the process would not work. Therefore, it’s important to be able to tell if the condenser is malfunctioning or broken.


Diagnosing Condenser Problems

Often, the problem may not be with the condenser coils themselves, but with the fan or motor in the outdoor unit. The following signs can let you know if the condenser is broken:

• Air conditioner blows warm air inside.
• Outdoor condenser fan doesn’t run.
• Refrigerant leaks from outdoor unit.

Compressor Types

Compressor Types

Two types of compressor dominate HVAC systems in buildings: piston and scroll.
The piston type uses pistons attached to a motor-driven crankshaft to draw in and compress the refrigerant.

Scroll compressors use an orbiting scroll on an eccentric motor-driven crankshaft to suck in vaporized refrigerant and push it into a stationary scroll whose volume gradually decreases to compress the refrigerant. There are three forms of compressor construction. Hermetically sealed units have motor and compressor sealed within a welded steel casing. They can't leak, but they also can't be repaired. Semi-hermetic units put motor and compressor inside a steel shell whose halves are sealed with a gasket and bolts. These can be opened for repairs, but might leak refrigerant. Open compressors have motor and compressor as separate units linked by a coupling. This variety is found in very large HVAC systems.

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