Types, Operations and Functions of Open Loop & Closed Loop Cooling Towers

Chapter 1: OHow do pen loop and closed loop cooling tower operating principles work?

This section will explore the functioning of both Open Loop and Closed Loop Cooling Towers.

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An open loop cooling tower is a system where the water being cooled comes into direct contact with the surrounding air to dissipate heat.

An open loop cooling tower utilizes direct interaction with the air to lower the temperature of the water. Functioning as a type of heat exchanger, it facilitates partial heat transfer through the exchange between air and water. Additionally, cooling is achieved through the evaporation of a small portion of water, enabling the system to reach temperatures below the surrounding ambient conditions.

How Open Loop Cooling Towers Operate

In the cooling tower, the water that needs to be cooled is introduced at the top. It is dispersed over the tower's packing through nozzles, creating a thin, uniform film across the packing material. This design increases the contact area significantly, enhancing the heat exchange process.

The fan either blows or pulls ambient air through the packing, depending on its design. This air cools the water through two main mechanisms: convection, where the heat is transferred from the warm water to the cooler air, and evaporation, which primarily reduces the water temperature. The moist air is then expelled from the top of the cooling tower. Meanwhile, the cooled water collects in a basin below for reuse in industrial processes. Drop eliminators positioned above the nozzles ensure that water droplets do not escape the cooling tower.

Closed Loop Cooling Towers

Closed Loop Cooling Towers are heat dissipation systems where the water being cooled never directly interacts with the air inside the cooling tower. Instead, the system operates in a closed loop, keeping the water separate from the air.

Closed loop cooling towers use an extra heat exchanger to manage heat transfer, unlike open loop systems where the water and air come into direct contact. Additionally, some cooling towers incorporate piping and plate heat exchangers to facilitate this process.

How Closed Loop Cooling Towers Operate

Closed loop cooling towers are similar and yet differ from open loop cooling towers. When there can’t be direct contact between the water that needs to be cooled down and the air (e.g. in food industries), it is necessary to employ a heat exchanger. The heat exchanger separates the processed water to be cooled down from the cooling tower’s evaporation water. This prevents the processed water from getting into contact with the air. In closed loop cooling towers, it might be necessary to use antifreeze, whereas in open loop cooling towers antifreeze is unnecessary.

Closed Loop Cooling Tower Process Side

The water needing cooling passes through a heat exchanger, which is constructed from stainless-steel plates and located in a separate room adjacent to the cooling tower. Within this heat exchanger, heat is transferred from the process water to the cooling water. As a result, the process water is cooled and can be reused, creating a closed-loop system where cooling water circulates between the heat exchanger and various users like condensers and production equipment.

Closed Loop Cooling Tower Side

Once the reheated water exits the plate heat exchanger, it is channeled via piping to the top of the cooling tower. The water is then spread over the tower packing by nozzles. As it descends through the packing, it cools and collects in a basin. From there, it is pumped back to the heat exchanger for reuse. In the heat exchanger, the water is cooled by air that flows in countercurrent through the tower. This air absorbs heat and becomes saturated before being expelled through the tower’s top. Drop eliminators above the nozzles prevent water droplets from escaping the cooling tower.

Factors Affecting Open Loop and Closed Loop Cooling Tower Performance

The efficiency of open loop and closed loop cooling towers can be influenced by several factors, such as:

Temperature Range

The range refers to the temperature difference between the incoming hot water and the outgoing cold water at the cooling tower. For example, if hot water enters at 100°C and needs to be cooled to 80°C, the range is 20°C. Increasing the range can help lower both the initial investment and operating costs of the cooling tower.

Heat Load

The heat load of a cooling tower is influenced by the specific process it supports. The required level of cooling is dictated by the target operating temperature. Generally, a lower operating temperature is preferred to enhance process efficiency or improve the quality and quantity of the product. Conversely, higher temperatures may be beneficial for certain applications, such as in internal combustion engines. An increased heat load necessitates a larger and more expensive cooling tower. While process heat loads can be challenging to measure accurately due to their variability, heat loads in refrigeration and air conditioning are typically easier to quantify with precision.

Wet-bulb Temperature (WBT)

The wet-bulb temperature indicates the local temperature conditions by using a thermometer with its bulb wrapped in a moist cloth. This reading is compared to the 'dry bulb' temperature (DBT), which is taken from a thermometer with a dry bulb. By comparing these two readings, and referring to a psychrometric chart or air properties table, the relative humidity can be calculated. Typically, the wet-bulb temperature is lower than the dry-bulb temperature, except when the air is fully saturated with water, known as 100% relative humidity. In such cases, the wet-bulb and dry-bulb temperatures are the same.

A cooling tower cannot reduce the temperature of the hot process water below the wet-bulb temperature of the incoming air, which also represents the dew point of the air. It is not feasible to design a cooling tower that cools water to a temperature equal to or lower than the ambient wet-bulb temperature. Each cooling tower must be tailored to the specific wet-bulb temperatures experienced in its location during summer. High-efficiency mechanical draft towers can typically lower water temperatures to within 5 to 6°F of the wet-bulb temperature, while natural draft towers usually achieve temperatures within 10 to 12°F of the wet-bulb temperature.

Typically, it is assumed that the wet-bulb temperature of the ambient air reflects the temperature of the air entering the cooling tower. However, this assumption holds true only if the cooling tower is positioned away from any heat sources that might elevate the local temperature. Ideally, the ambient wet-bulb temperature should be measured from 50 to 100 feet upwind of the tower, at a height of 5 feet above the base of the tower, without any interference from nearby heat sources. In practice, very few cooling tower setups meet this precise criterion.

Temperature Approach

The term "approach" refers to the difference between the temperature of the water exiting the cooling tower and the wet-bulb temperature of the incoming air. To determine the approach, subtract the wet-bulb temperature of the ambient air from the temperature of the water leaving the tower. For example, if a cooling tower produces water at 86°F while the wet-bulb temperature is 79°F, the approach is 7°F.

Approach is a key performance indicator for a cooling tower, as it sets a limit on how low the temperature of the outgoing cold water can be, independent of the tower's size, heat load, or range. The temperature of the water cannot fall below the wet-bulb temperature of the surrounding air. When the wet-bulb temperature drops, the temperature of the water leaving the cooling tower will also decrease proportionally, provided that the flow and range remain constant. Typically, the approach temperature ranges from 5 to 20°F, meaning that the outgoing cold water temperature will always be 5 to 20°F higher than the ambient wet-bulb temperature, regardless of the cooling tower's capacity or heat load.

Reducing the approach temperature requires a significantly larger cooling tower, with the size increasing exponentially as the approach decreases. Cooling towers with an approach below 5°F are generally not cost-effective, and manufacturers typically do not guarantee performance for approaches lower than this threshold.

Calculations Involved in Cooling Towers

Approach is calculated using the formula: Approach = CWT - WBT, where CWT represents the temperature of the cold water and WBT denotes the wet-bulb temperature.

Range is determined by the formula: Range = HWT - CWT, where HWT stands for the temperature of the hot water and CWT represents the cold water temperature.

To calculate cooling tower efficiency, use the formula: Efficiency = (Range / (Range + Approach)) * 100.

Chapter 2: What are the components of open loop and closed loop cooling towers, and what functions do they serve?

This section will cover the various components of both open loop and closed loop cooling towers and explain their respective functions.

Cooling Tower Instrumentation

Most open loop and closed loop cooling towers consist of the following instrumentation systems: blow down rate; flow meters for cooling tower makeup water; water level switches for hot and cold water basins; vibration switches; high and low level switches; thermocouples for the measurement of the temperature of hot and cold water; and high and low oil level switches.

Cooling Tower Fan Motor

In refinery and petrochemical cooling tower applications, explosion-proof fan motors are essential because of the risk of leaks from heat exchangers. Additionally, these motors need to be equipped with protective systems, including overload relays and earth fault relays, to ensure safety and reliability.

Cooling Tower Nozzles

Cooling tower nozzles are typically crafted from various plastics, such as polypropylene, ABS, PVC, and glass-filled nylon. These nozzles are designed to evenly distribute hot water throughout the cooling tower's cell.

Distribution Valves

These valves control the flow of hot water to ensure it is distributed evenly within the cells. They are designed to withstand harsh, corrosive conditions.

Drive Shafts

They deliver power from the motor’s output shaft to the input shaft of the gear reduction unit.

Gear Box

They reduce the magnitude of the speed depending on the requirements of the cooling tower. The gear reducer, motor and driveshaft are permanently alighted by the torque tube.

Cooling Tower Louvers

Cooling tower louvers, typically constructed from asbestos sheets, serve two main purposes: (i) to prevent the loss of circulating water within the tower, and (ii) to evenly distribute the airflow into the fill media.

Fan Cylinder and Fan Deck

This serves as a support structure for the fan cylinders and offers easy access to both the fan and the water distribution system.

Water Distribution Piping

It must either be buried underground or properly supported on the ground to avoid thrust loading on the cooling tower. This thrust loading is due to the pressure exerted by the water in the pipe and the weight of the pipe itself.

Cooling Tower Fans

Cooling tower fans are crucial components in both open loop and closed loop systems. Common materials used for these fans include fiberglass, hot-dipped galvanized steel, fiber-reinforced plastic (FRP), and aluminum. Fiber-reinforced plastic is often preferred due to its lightweight nature, which helps to reduce the energy consumption of the fan. The blade angles of cooling tower fans are adjusted based on the season. For example, during the summer, when air density is lower, the blade angle is increased to enhance fan capacity.

Cooling Tower Structure Materials

Most open loop and closed loop cooling tower structures are constructed from chemically treated wood. However, depending on the specific application, some cooling towers are now built using fiber-reinforced plastic (FRP) or reinforced cement concrete.

Cold Water Basin

Cold water basins, typically constructed from reinforced cement concrete (RCC), serve two primary functions. First, they act as reservoirs for collecting and storing water from the cooling tower. Second, they provide the foundational support for the cooling tower structure. These basins are generally positioned either below ground level or on the surface of the soil. The height of the cooling tower, whether open loop or closed loop, is determined by measuring the distance from the top of the water basin to the fan assembly.

Drift Eliminators

Drift eliminators are designed to minimize the amount of water carried away by the exhaust air in a cooling tower. By directing the air flow in multiple paths, these devices reduce water loss. Typically made from PVC, drift eliminators work by increasing the number of air passes through them, which lowers drift loss but also raises pressure drop, thereby increasing fan power consumption. In large-scale industrial settings, more robust drift eliminators are employed to handle the demands.

Cooling Tower Fill Media

In open loop and closed loop cooling towers, the fill media facilitates the contact between air and the water surface. This media helps the water spread into thin, flowing layers, maximizing the surface area exposed to the air flow. Fill media is typically made from materials such as polypropylene, wood, or PVC. There are three primary types of fill media: vertical offset fill, cross-corrugated fill, and vertical fill.

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Chapter 3: What are the different types of open loop and closed loop cooling towers?

This section will explore the different types of both closed loop and open loop cooling towers.

Types of Closed Loop Cooling Towers

Closed loop cooling towers can be categorized into the following types:

Adiabatic Cooling Towers

These closed loop cooling towers operate similarly to dry cooling systems, but they also incorporate pre-cooling pads. As water passes over the porous media, air is drawn through the pads to enhance cooling efficiency.

Dry Cooling Towers

These closed loop cooling towers are ideal for applications where water conservation and minimal maintenance are crucial. They do not require water treatment as they operate without using water.

Eco/Hybrid Cooling Towers

These closed loop cooling towers enhance efficiency by integrating both dry and evaporative cooling methods, which helps to minimize water usage.

Evaporative Cooling Towers

This variety of closed loop cooling tower removes the necessity for a heat exchanger between the heat rejection system and the process loop. By relying primarily on evaporation for cooling, these towers offer energy-efficient performance within a smaller footprint compared to dry coolers.

Closed loop systems enhance water conservation compared to open loop systems by significantly reducing the need for blowdown of basin water.

In dry mode, these units handle heat rejection up to their dry capacity. Once the load surpasses this threshold, the system transitions to evaporative mode, thereby boosting its cooling capability.

By reducing the temperature of the incoming air measured by the dry bulb, greater heat rejection is achieved. Consequently, adiabatic systems are ideal for hot, dry climates and are more water-efficient.

Types of Open Loop Cooling Towers

Open loop cooling towers can be categorized into the following types:

Cross Flow Cooling Tower

This cooling tower type is ideal for industrial uses. It features a design where air moves horizontally through the fill media, while water descends vertically.

Fan-less, Fill-less Cooling Towers

As the name suggests, the fan-less, fill-less cooling tower operates without a fan or fill media for cooling wastewater. Instead, it relies on ambient wind to pass through its cooling structure.

This type of open loop cooling tower features wooden louvers that act as sidewalls to prevent water from spilling. It is considered the most cost-effective option and demands minimal maintenance compared to other cooling tower types.

This type of cooling tower is typically employed in environments with dirty water, such as in oil refineries and chemical processing. It is designed to handle water contaminated with substances like ammonia compounds, fats, oils, and other pollutants.

Field Erected Cooling Tower

The field erected cooling tower is available for those industries or manufacturing plants that cannot find the right standardized design of cooling towers for their specific needs. This type of open loop cooling tower is custom made. It is constructed using pultruded fiberglass and it uses steel as fasteners, fiberglass reinforced polyester sheets for cladding, pultruded FRP sections.

Round/Bottle Cooling Towers

The round or bottle cooling tower is renowned for its advanced technology and highly efficient compact design. Available in various sizes, its circular shape promotes uniform airflow, ensuring optimal heat transfer across its surface area and unit volume.

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This type of open loop cooling tower employs counter flow induced draft technology and features cross-corrugated PVC film for its fill media. Constructed from fiberglass-reinforced plastics, it is typically pre-fabricated at the manufacturer's facility and assembled at the installation site.

Square or Rectangular Cooling Tower

This cooling tower is one of the most well-known models. It also utilizes counter flow-induced draft technology, similar to the round cooling tower. It features heat transfer media composed of cross-corrugated PVC film fills.

The rectangular cooling tower is constructed from fiberglass-reinforced plastics, with architectural elements made of mild steel or hot-dipped galvanized steel. It comes in both single-cell and multi-cell configurations.

This type of cooling tower is suitable for both new and existing projects. Fiberglass-reinforced plastic (FRP) provides several benefits over traditional construction materials such as wood, concrete, and steel.

Chapter 4: AWhat are the primary applications of open loop cooling towers?

This section will explore the various uses, advantages, and enhancements in efficiency associated with both open loop and closed loop cooling towers. It will also cover important factors to consider when selecting between these types of cooling towers.

Applications of Open Loop and Closed Loop Cooling Towers

Open loop and closed loop cooling towers can be applied in various scenarios, including:

• Power plants
• Petrochemical plants
• Petroleum refineries
• Natural gas processing plants
• Food processing plants
• Semiconductor plants
• Water cooled air compressors
• Die casting machines
• Refrigeration
• Plastic injection and blow molding machine
• Distilleries

Benefits of Open Loop Cooling Towers

Advantages of using open loop cooling towers are as follows:

• A lower approach can be easily achieved
• Lower initial cost due to the absence of the intermediate heat exchanger
• Easier expansion

Benefits of Closed Loop Cooling Towers

Advantages offered by closed loop cooling towers include:

• Contaminant-free cooling loop
• Dry operation in winter
• Ease of maintenance
• Lower overall system costs
• Reduced water loss through evaporation
• Reduced need for chemical treatment
• Protection of the process fluid’s quality
• Operational flexibility at a slightly higher cost at first
• They can provide totally dry sensible heat rejection which can extremely lower the overall consumption of water at a project
• Based on the switchover temperatures of a dry bulb, they can be sized for partial load or full design.

Improving Efficiency of Open Loop and Closed Loop Towers

To enhance the performance of both open loop and closed loop cooling towers, consider the following:

Installing New Water Piping

Adding a new pipe in necessary locations can boost energy efficiency, even if only a single section of new piping is required.

Ensuring that the System is Recycling Water Properly

A cooling tower should recycle at least 98% of the water. If it fails to achieve this, maintenance is necessary. Efficient water recycling enhances both water and energy usage.

Increase Cooling Cycles

It's important to monitor the number of cooling cycles your tower operates. Increasing the cycles from three to six can notably improve efficiency and conserve water.

Chapter 5: What factors should be considered when selecting an open loop or closed loop cooling tower?

Key factors to keep in mind when choosing between open loop and closed loop cooling towers include:

Heat Transfer Efficiency

In closed loop cooling towers, the heat transfer efficiency between the cooling water and the process can be optimized under peak design conditions. This is because closed loop systems use clean water, leading to an improved coefficient of heat transfer. Additionally, some closed loop towers may incorporate a separate intermediate heat exchanger. This setup simplifies maintenance and reduces overall capital expenses. Should any fouling occur, it will be confined to the intermediate heat exchanger involved in the heat rejection process, making it easier to address.

Lower Cooling Tower Approach

Open loop cooling towers can achieve a lower approach temperature with relative ease. It's important to consider that in these systems, there are two types of approaches to account for: one at the cooling tower and another at the heat exchanger. When aiming for a lower approach, open loop cooling towers are often advantageous.

Power Saving Operation

Return head can be used effectively since there is no exposure of cooling water to the atmosphere in closed loop cooling towers. The head that is needed for the circulation of the cooling water shall only be the resistance of the heat exchanger and the frictional head. The static head needed by the pump can be totally eliminated. Since the cooling water used for heat transfer is not exposed to the atmosphere, corrosion and scaling problems can be eliminated.

Volume of Water Treatment

Closed loop cooling towers feature two separate circuits, which results in a lower water volume for treatment purposes. This design allows for more efficient management of the water treatment process.

Corrosion and Other Water Related Problems

Closed loop cooling towers prevent corrosion in process heat exchangers by keeping the cooling water isolated from direct atmospheric contact. This isolation protects the water from contamination by airborne particles, thereby safeguarding the heat exchangers from corrosion and other issues associated with water exposure.

Maintenance Requirements

Although a standalone open loop cooling tower typically requires minimal maintenance, the overall upkeep of the complete cooling system, including pipes and heat exchangers, tends to be significantly higher compared to the maintenance needs of closed loop cooling towers.

Water Requirement

Both open and closed loop cooling towers rely on the process of water evaporation to function. For a given heat load, both types of towers require a similar volume of water. However, closed loop cooling towers can provide an advantage in terms of reducing water consumption, thanks to their design that incorporates air/dry cooling features.

Capital Investment

Open loop cooling towers generally involve lower initial costs because they do not include an intermediate heat exchanger.

Operational Cost

Operating closed loop cooling towers is cost-effective thanks to their enhanced operational stability, reduced pumping power requirements, and overall efficiency improvements.

Expansion Flexibility

While open loop cooling towers are simple to scale up, closed loop systems demand advanced design expertise due to the incorporation of an intermediate heat exchanger.

Conclusion

Each class of cooling tower, either open loop or closed loop, has different types of designs with different capabilities and advantages. Therefore when picking an open loop or closed loop cooling tower for a specific application, one must consider the design specifications that meet the application requirements.

This section explains how the components of a cooling tower work together.

Water Distribution

Hot water from the chilled-water system is delivered to the top of the cooling tower by the condenser pump through distribution piping. In an open tower, the hot water is sprayed through nozzles onto the heat transfer medium (fill) inside the cooling tower. Some towers feed the nozzles through pressurized piping; others use a water-distribution basin and feed the nozzles by gravity. In a closed-loop tower, the water from the condenser loop runs through tubes in the tower and is not exposed to the outside air. Water for cooling the tubes circulates only in the tower.

In the open tower, a cold-water collection basin at the base of the tower gathers cool water after it has passed through the heat transfer medium. The cool water is pumped back to the condenser to complete the cooling-water loop. In the closed tower, the condenser water cools as it moves through the piping in the tower and returns to the chiller plant.

Heat Transfer Medium (Fill)

Cooling towers use evaporation to release waste heat from an HVAC system. In an open tower, hot water from the condenser is slowed down and spread out over the fill. Some of the hot water is evaporated in the fill area, or over the closed-circuit tubes, which cools the water. Cooling tower fill is typically arranged in packs of thin corrugated plastic sheets or as splash bars supported in a grid pattern.

Air Flow

Large volumes of air flowing through the heat-transfer medium help increase the rate of evaporation and the cooling capacity of the tower. The cooling-tower fans generate this airflow. The size of the cooling-tower fan and airflow rate are selected to achieve the desired cooling at design conditions of condenser-water temperatures, water flow rate, and wet-bulb temperature.

Cooling towers may have propeller fans or squirrel-cage blowers. Small fans may be connected directly to the driving motor, but most designs require an intermediate speed reduction provided by a power belt or reduction gears. The fan and drive system operate in conjunction with the control system to control start/stop and speed. Variable-speed drives (VSDs), when added to the fan motors, control fan speed and more precisely regulate the temperature of the water as it leaves the tower.

Drift Eliminator

As air moves through the fill, small droplets of cooling water become entrained and can exit the cooling tower as carry-over or drift. Devices called drift eliminators remove carry-over water droplets. Cooling-tower drift becomes annoying when the droplets fall on people and surfaces downwind from the cooling tower. Efficient drift eliminators virtually eliminate drift from the air stream.

Water Treatment

Cooling-tower water must be regularly treated, generally with chemicals, to prevent the growth of harmful bacteria, minimize corrosion, and inhibit the buildup of scale (mineral deposits) on the fill.

Maintenance Personnel

Cooling towers are often placed in precarious locations, and inspection ports can be located in awkward or exposed locations. This can create a hazardous working environment. Be sure to implement adequate fall-prevention measures and procedures. In addition, always follow lock-out and tag-out safety procedures.

Best Practices for Efficient Operation

Always consult the manufacturer’s manual for the cooling-tower. Another excellent source of information and standards for cooling towers is the Cooling Technology Institute. Here are some recommendations for operating any cooling tower more efficiently:

Implement a preventive-maintenance program: This includes regular water treatment and maintenance of the mechanical and electrical systems. See the Maintenance Schedule for Cooling Towers, below for more information.

Reduce the temperature of water leaving the tower: The temperature of water leaving the cooling tower should be as cold as the chiller manufacturer will allow for entering condenser water. Newer chillers usually tolerate colder temperatures for water returning from the cooling tower. Check with your chiller manufacturer’s representative or manual and set the entering condenser-water temperature (same as the leaving cooling tower temperature) as low as possible.

Operate cooling towers simultaneously: Direct water through all towers regardless of the number of chillers operating. Tower fans should be staged on as required. Operating the towers simultaneously will use less energy in most situations than staging towers individually. This strategy is particularly effective with VSDs on the fans. When a fan VSD reaches 40% speed (adjustable), the next fan stages on and operates in parallel, both now running at a minimum speed of 20%.

Balance water distribution between multiple towers (or cells within a single tower enclosure) and within each tower or cell. Water often flows down only one side of the tower, or one tower may have more flow than an adjacent tower. This increases the temperature of the water returning to the chiller and reduces the efficiency of the tower.

Consider a condenser water reset strategy: The temperature set point of the water leaving the cooling tower should be at least 5°F (adjustable according to the design) higher than the ambient wet-bulb temperature. If the Direct Digital Control (DDC) system has a wet-bulb temperature sensor, this can be done automatically. Otherwise the operator should consider manually adjusting the set point seasonally.

Close the bypass valve before starting the cooling-tower fans: Make sure the DDC control sequence prevents the tower fans from starting before the cooling-tower bypass valve is fully closed. If the bypass valve isn’t fully closed, hot water leaving the chiller short circuits into the water returning to the chiller, adding unnecessary load to the compressor.

Trend log the temperature of the water leaving the tower: Use the trend logging capability of the DDC to track the temperature of the water leaving the tower. Higher than normal temperatures may indicate that the tower in not operating properly.

Best Practices for Maintenance

Inside an operating cooling tower is much like a hurricane. This harsh environment must be regularly inspected and maintained for best system performance.

Effective water treatment: Effective water treatment eliminates harmful bacteria and bio-film and controls scale, solids, and corrosion. Bleed or blowdown-the continuous flow of a small portion of the recirculating water to a drain to eliminate dissolved solids-is insufficient by itself to control scale and corrosion and is always ineffective in controlling biological contamination. A regular chemical-treatment program is always recommended for controlling biological organisms, scale, and corrosion.

Prevent scale deposits: When water evaporates from the cooling tower, the minerals that were dissolved in it are left behind as scale deposits on the surface of the fill. Scale build-up inhibits heat transfer from the water to the air, which reduces the fill’s effectiveness. Excessive scale build-up is a sign of inadequate water treatment.

Prevent or clean clogged spray nozzles: Algae and sediment that collect in the water basin as well as excessive solids that get into the cooling water can clog the spray nozzles. This causes uneven water distribution over the fill and uneven airflow through the fill, which reduces evaporation. These problems indicate improper water treatment and clogged strainers. Kits are available to replace older, smaller distribution nozzles or troughs with large-orifice, clog-free designs.

Ensure Adequate Airflow: Poor airflow through the tower reduces the transfer of heat from the water to the air. Poor airflow can be caused by debris at the inlets or outlets of the tower or in the fill, loose fan and motor mountings, poor motor and fan alignment, poor gearbox maintenance, improper fan pitch, damage to fan blades, or excessive vibration. Reduced airflow due to poor fan performance can ultimately lead to motor or fan failure.

Ensure Adequate Pump Performance: A closed-loop cooling tower uses a pump to transport water over the tubes for evaporative cooling. Proper water flow is important to achieve optimum heat transfer. Loose connections, failing bearings, cavitation, clogged strainers, excessive vibration, and operating outside of design conditions result in reduced water flow, reduced efficiency, and premature equipment failure.

The table below provides a schedule for maintenance tasks.

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Maintenance Schedule for Cooling Towers

Description Comments Maintenance Frequency Cooling tower use/ sequencing Turn on/sequence unnecessary cooling towers Daily Overall visual inspection Complete overall visual inspection to be sure all equipment is operating and safety systems are in place Daily Fan motor condition Check the condition of the fan motor through temperature or vibration analysis and compare to baseline values Weekly Clean suction screen Physically clean screen of all debris Weekly Operate make-up water float switch Operate switch manually to ensure proper operation Weekly Vibration Check for excessive vibration in motors, fans, and pumps Weekly Check tower structure Check for loose fill, connections, leaks, etc. Weekly Check belts and pulleys Adjust all belts and pulleys Weekly Test water samples Test for proper concentrations of dissolved solids, and chemistry. Adjust blowdown and chemicals as necessary. Perform weekly for open towers and monthly for closed systems.

Weekly (Open)

Monthly (Closed)

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Check lubrication Assure that all bearings are lubricated per the manufacture’s recommendation Monthly Check motor supports and fan blades Check for excessive wear and secure fastening Monthly Motor alignment Aligning the motor coupling allows for efficient torque transfer Monthly Check drift eliminators, louvers, and fill Look for proper positioning and scale build up Monthly Inspect nozzles for clogging Make sure water is flowing through nozzles in the hot well Annually Clean tower Remove all dust, scale, and algae from tower basin, fill, and spray nozzles Annually Check bearings Inspect bearings and drive belts for wear. Adjust, repair, or replace as necessary. Annually Motor condition Checking the condition of the motor through temperature or vibration analysis assures long life Annually