What is a Cooling Tower in HVAC and How Does It Work?
Posted on Friday Jun 19, 2020 at 08:15AM
This Cooling Tower blog is the third in a series of blogs that will explore how Veris Industries products can be used to monitor and regulate heating, ventilation, and air conditioning (HVAC) applications.
In a commercial chiller, water is used to extract heat from the refrigerant on the condenser side of the chiller before the refrigerant is recirculated to cool water on the air handler side of the chiller. If the heat extracted from the refrigerant cannot be used in other building processes, it remains in the water. This heated water is pumped to a cooling tower.
What is a Cooling Tower?
A cooling tower is a heat rejection device that extracts waste heat to the atmosphere by cooling a stream of hot water in the tower. Cooling towers remove heat through evaporation from water to lower the water’s temperature.
Because the cooling tower utilizes an evaporative process, it must be placed outside of the building. Cooling towers can be found on the roofs of large buildings or on a cement pad or risers.
How Do Cooling Towers Work
The type of heat rejection that cooling towers use is termed "evaporative" because it allows a small portion of the water being cooled to evaporate into a moving air stream. This heat removal then provides significant cooling to the rest of the water stream. The heat that is transferred from the water stream to the air stream raises the air's temperature and its relative humidity to 100%, and this air is discharged to the atmosphere. The remaining cooled water is pumped back to the condenser side of the chiller. Additional water is added to the cooled water stream to compensate for volume losses due to evaporation.
Cooling Tower Diagram
Types of Cooling Towers
Cooling towers are defined by various factors. There are two types of cooling towers: Natural Draft Cooling Towers and Mechanical Draft Cooling Towers. Cooling towers can further be defined by how the air and water interact with each other. These two types are counter flow and crossflow.
Natural Draft Cooling Towers
What is a Natural Draft Cooling Tower?
A Natural Draft Cooling Tower does not use fans or mechanics to create air flow. They use convective flow to provide air circulation, causing hot air to rise within the tower. This can be called the stack effect. Hot water from the system is cooled via direct contact with fresh air.
How does a Natural Draft Cooling Tower Work?
The differences in density between the entering air and internal air within the tower causes air movement. The warm air (more dense) will naturally rise through the tower while cool air (less dense) from the outside will fall. This creates a constant cycle of airflow.
Natural Draft Cooling Tower Applications
Natural Draft Cooling Towers are used for applications that there is a high demand for constant cooling over many years. Examples of these types of applications are: thermal power plants, power plants new load centers, oil refineries, petrochemical plants, natural gas plants
Natural Draft Advantages and Disadvantages
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Mechanical Draft Cooling Towers
What is a Mechanical Draft Cooling Tower and how does a Mechanical Draft Cooling Tower work?
Unlike a Natural Draft Cooling tower, Mechanical Draft Cooling towers use a single fan or multiple fans to create air flow through the tower. Typical fans that are used are propeller fans and centrifugal fans. There are two types of Mechanical Draft Cooling towers: induced draft cooling towers and forced draft cooling towers.
Mechanical Draft Cooling Tower Applications
They are commonly used in petroleum, chemical metallurgical and other industries.
Mechanical Draft Advantages and Disadvantages
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Types of Mechanical Draft cooling towers
Induced Draft Cooling Tower
The fan is installed after the heat exchanger (located at the top) and draws air from up through the tower against a strong downward flow of water. Coldest water is at the bottom and comes in contact with dry air while the warmest water is at the top of the tower coming in contact with the moist air. This causes a quick and efficient heat transfer. These are widely used in industrial plants that need stable performance. Some advantages for the induced draft cooling tower: Low absorbed capacity, requires little space for installation. Disadvantages are that it is more noisy than a forced draft cooling tower.
Forced Draft Cooling Tower:
The fans are located before the heat exchanger in the air intake at the sides or the base of the tower. Air is pushed directly into the tower taking air in at a high velocity but discharging it at a lower velocity. Forced Draft Cooling Towers are best used for Indoor applications where high static pressure is a concern. Advantages are: handles high pressure well, Easy to maintain, low noise, low absorbed capacity. Some disadvantages are: more susceptible to undesirable air recirculation due to lower velocity output, costly design due to requiring more power to operate, more susceptible to freezing.
What is a cross flow cooling tower?
With a cross Flow cooling tower air flows horizontally across the downward flow of water. They use splash fills to allow incominig air to flow horizontally while gravity sends the hot water down from the distribution basins from the top of the tower. This eliminates the need for a pressurized spray system.
Advantages:
- Easy to maintain: distribution system can be sectionalized and serviced separately, access to nozzles available anytime
- Cost effective: uses smaller pumps due to use of gravity, no need for pressurized water system
- More variable water flow due to spray being non pressurized
Disadvantages:
- More prone to freezing
- More inefficient
- More likely to become clogged with dirt or debris
- Distribution basin prone to biological fouling
What is a counterflow cooling tower?
The air and water enter from opposite ends of the tower, air moves upward while water moves downward. These towers have a pressurized spray distribution system and it is not possible to use gravity flow basins.
Advantages:
- Greater efficiency and saves energy due to being more compact size
- Smaller area than Cross flow
- More resistance to freezing due to spray distribution
- Heat transfer more efficient due to spray distribution improving water droplet size
Disadvantages:
- Higher energy and operational costs due to large pumps required
- Less variable water flow
- More noisy
How Cooling Tower Systems Work with Veris Products
| Product Family | Why it is used on a Cooling Tower |
| Flow Meters | Monitors flow of the supply and return heating loop. The water utility will charge the end user based on the amount of water supplied. The end user is also charged for the amount of water dispelled into the sewer system. In some climates, evaporation can be as much as 50% = 60%. Utilizing a flow meter on both the supply and the sewer drain will save the end user money by capturing the actual amount of water sent down the drain. The difference between the amount of water supplied and the amount of water sent down the drain is the volume of water lost due to evaporation. With this data from the supply and the drain flow meters in hand, the end user will receive a credit for the evaporation losses. |
| Temperature | Immersion temp in the cooling tower is a control input for fat rotation. The cooling tower fan removes a large amount of the heat to prepare the water for conditioning (via coolant) in the chiller. |
| Current Sensors | Monitors run status of pumps and fans to ensure that they are working when needed. Proof of functionality. No need to manually check each fan or pump. (If current is flowing, the fan or pump is working.) |
Read the entire HVAC series:
Part 1: What are Air Handling Units (AHU)?
Part 2: What is a Water Chiller?
Part 3: What are Cooling Towers?