Role of Cooling Tower Air Inlet Louvers
Role of Cooling Tower Air Inlet Louvers
Cooling Towers
Role of Cooling Tower Air Inlet Louvers
Cooling Towers
| April 14,
Cooling Tower Air Inlet Louvers disallows the illumination of the sun from entering the cooling tower bowl. Introducing air delta louvers helps control the development of algae and green bacteria. Controlling the light and restricting algae growth implies bringing down substance costs. The Cooling Tower Air Inlet Louvers additionally assist with bringing down how much splash-out from the cooling tower. This lessens how much water and compound are expected to run the cooling tower louvres proficiently. Additionally, you will encounter more straightforward basin access and evacuation.
Without appropriate consideration and upkeep, the air intake/air inlet louvres in cooling towers with counterflow can once in a while become scaled. Assuming this happens, it decreases the effectiveness of industrial cooling towers. The louvres that are scaled decrease the wind stream to the unit, which leads to reducing proficiency.
A cooling tower louvre is a part of a proficient cooling tower framework. It guarantees that water is of great quality and amount. In a cooling tower, water and air are united. Essentially, certain circumstances are probably going to occur. For example, algae can develop, water and compound quality may be diminished or water might sprinkle out from the tower, which calls for cooling tower maintenance services to fix the issue.
These circumstances might lessen the viability of the cooling tower and in the end the general limit of the factory, treatment facility, or anything that tasks with cooling towers you are keeping up with. The louvers and boards will assist with keeping these cases from happening to guarantee the ideal execution of the cooling tower.
There are various types of cooling tower louvers. You can have an air channel louvers cooling tower or a louver cell board. Each likewise has a different design and compound.
What is the function of cooling tower air inlet louversinlet louvers?
The louvers are an essential component of the cooling tower. They equalize the flow of air in the fill and maintain the level of water. Cross-flow towers usually have air inlet louvers while counterflow tower designs have no need for any louvers.
- Prevent daylight from infiltrating into the towers fill. An openness to daylight clears the way for the development of algae and, surprisingly, a few bacterial types.
- Impedes water splashing out, and that implies water is held inside the assortment tank.
- Evades enormous materials or garbage from entering the tower.
- Difficult to hinder from water line to shower spout make a decent temperature cooling.
- Limits expenses of keeping up with the tower, like costs to kill algae growth.
Features of cooling tower louvers
Adaptable to various cooling towers
Cooling tower louvers are planned such that they can fit into various sorts of cooling towers. It is adequately adaptable to adjust to various constructions. The cooling tower louver can likewise be fitted to a recently constructed cooling tower. It can likewise be retrofitted to existing cooling towers, saving you from being required to roll out huge improvements.
Utilitarian design
The cooling tower louver configuration isnt just to give a feel to the cooling tower. The cooling tower louvers have a plan that capacities as a hindrance for daylight section, entering of enormous flotsam and jetsam and work on the wind stream in the pinnacle. It is useful when to get an algae-free tower, water sprinkles out avoidance, and the general ability of the pinnacle to work.
Smooth and reflexive surface
One of the issues of cooling tower louvre cleaning and upkeep is the development of scales. To forestall this, cooling tower louvers have a smooth and polished surface that aids in forestalling scaling. In this manner, it can limit your costs and exertion for upkeep exercises.
UV obstruction
We have louvres that are additionally UV-safe. The Ultra Violet obstruction is useful in two ways. In the first place, it helps in forestalling the development of the algae somewhat. Second, it additionally assists with the strength of the louver. Accordingly, it broadens the existence of the item.
Regardless of how little a component it is, a cooling tower louver can characterize the adequacy and maintainability of your cooling towers. It has a bigger purpose to fill. Along these lines, picking the right louvres and their legitimate establishment is fundamental to guarantee that it performs in view of assumptions.
How Louvers Work
A louver is a ventilation product that allows air to pass through it while keeping out unwanted elements such as water, dirt, and debris. A number of fixed or operable blades mounted in a frame can provide this functionality. The basic considerations for selecting louvers are Louver Free Area, Water Penetration, and Resistance to Airflow (Pressure Loss). Once these concepts are understood, they can be used to properly apply a louver.
Louvers are required when buildings need to balance airflow and protection from external elements based on their specific functions and requirements. Different structures may demand louvers to control ventilation and prevent water ingress, such as in parking ramps where air circulation is essential but maximum rain protection is not necessary. Conversely, spaces housing sensitive equipment like generators or electrical components may necessitate louvers that offer robust defense against extreme weather conditions like storms and hurricanes, while also meeting stringent airflow specifications. In essence, the necessity for louvers arises from the distinct operational needs and environmental considerations of each building or facility.
Louver Free Area
Free area is derived by taking the total open area of a louver (after subtracting all obstructions - blades and frame) and dividing by the overall wall opening. This gives a comparison of a louvered opening to an unobstructed opening. Common louver free areas range from 35% to 60% of the wall opening (65% to 40% obstructed). A high percentage free area is beneficial because more air can enter into a smaller wall opening, reducing the cost of the wall opening and louver.
Obviously some obstruction is required in order to keep undesirable water out. A fully obstructed opening would allow no water in, while a totally unobstructed opening would allow water to enter unimpeded. A properly designed louver will maximize free area while allowing a minimal amount of water to enter.
For more information about free area, please visit the linked page Louver Free Area.
Louver Water Performance
First Point of Water Penetration is the point at which a louver allows the passage of water through the louver. It is a threshold measurement of air intake velocity at which the louver will begin leaking (in feet per minute or fpm).
Traditional Louvers:
The typical method of testing for water penetration is to intake air through the louver while applying a measured water content into the airstream. The velocity of airflow through the louver free area is increased until the louver allows water to enter. The result of this test is the first point of water penetration - ranging from 300 fpm (a very poor resistor to water entrainment) to fpm (a very good resistor to water entrainment).
Wind Driven Rain Louvers:
Testing is done similar to traditional louvers, but with wind simultaneously applied to the face of the louver. The wind is applied at a fixed rate, while the air intake velocity is increased from 0 feet per minute to a predetermined value. Instead of a "first point of water penetration" value, efficiency of the louver is measured instead. Basically, "how good is the louver at stopping the water?" The efficiency is rated as a percentage, determined from the amount of water that passes through the louver divided by the total water applied during the test. A very efficient louver will have a value from 99-100%. Inefficient louvers will have values below 85%, meaning they allow over 15% of the water applied to pass through the louver.
Testing procedures have fixed values for water volume and the wind speeds applied. Two tests are common - 3" per hour rainfall combined with 29 mph wind speeds, and 8" per hour rainfall combined with 50 mph wind speeds. As described earlier, the air intake velocity is the only variable.
Obviously this testing is more stringent and requires a special louver design to perform well in this environment. Several designs are available throughout the market, but few have surpassed the capabilities of our E2WV, E4WH, and E6WH louver models.
back to top
Louver Resistance to Airflow
Every obstruction in the airstream creates resistance - louvers, ductwork, filters, coils, building structure, etc. The resistance of the louver can be measured by running air through the louver and measuring the pressure differential at various free area velocities (measured in water gauge or wg). Every louver will create resistance based on the frame and blade shapes. Lower blade angles or more aerodynamic shapes create less resistance. We must know the free area velocity through the louver in order to properly evaluate the overall resistance to airflow. For a majority of applications, we can calculate the pressure loss of the louver at the required free area velocity and determine if it is acceptable. The resistance created can be detrimental to the application of fans and other air movement equipment, so we should attempt to minimize it.
Applying the Principles
To properly evaluate a louver's capability, we must have a method to include both the Free Area and the First Point of Water Penetration in a meaningful way. Since the overall objective is to get as much air as possible through the louver, we want to evaluate the allowable volume of air through the louver (cubic feet per minute or cfm). Test methods for these principles are covered in AMCA Standard 500-L Laboratory Methods of Testing Air Louvers for Rating. The following example compares two louvers for a wall opening size of 48" wide x 48" high with different performance characteristics:
Louver
Free Area (percentage)
Free Area for 48" x 48" (square feet)
First Point Water (fpm)
1
45%
7.2
2
53%
8.5
750
Since our objective is to get more air through the louver, we might assume that Louver 2 is better than Louver 1, since it has a higher free area. However, more evaluation is required. The real question is, "How much total air can I get through the louver without entraining water?"
Louver
Free Area (percentage)
Free Area for 48" x 48" (square feet)
First Point Water (fpm)
Design Velocity (fpm)
Volume of Air (cfm)
1
45%
7.2
893
2
53%
8.5
750
563
View performance of Architectural Louvers
Louver 1 has a free area of 45% for a size 48" wide x 48" high wall opening. The total square feet of free area is 7.2 ( = 45% x 16 sq ft of wall opening). The tested First Point of Water Penetration for this louver is feet per minute free area velocity. We should build in a safety factor for some variation in our airflow through the louver - we have chosen 25% safety factor. The design velocity including the safety factor would be 25% less than fpm, or 893 fpm ( x .75). We can now determine how much air can safely be run through the louver by multiplying the louver free area by the design velocity ( 7.2 sq ft x 893 fpm). The resulting Volume of Air for Louver 1 is cfm.
If we go through the same calculations for Louver 2, the result (with a 25% safety factor) is only cfm. This is 25% less air through the same opening size. Louver 1 is a better choice - IF we can live with the pressure drop from the higher airflow rates! back to top
Most Manufacturers publish air flow resistance for their louvers. Each louver will have slightly different resistance based on the blade and frame shapes and angles. These characteristic can be expressed by a formula and graphed, such as:
Louver 1
Louver 2
Simplifying things a bit - most louvers do not fluctuate dramatically from these graphs (about 15% in this example), unless the louver is designed for very high air velocities, like wind driven rain louvers. However, if you have the data, use it! Here we can calculate the resistance at the design velocities for each louver and determine that:
Louver 1 - at 893 fpm free area velocity, will create 0.090 inches w.g. of static pressure
Louver 2 - at 563 fpm free area velocity, will create 0.055 inches w.g. of static pressure
Both of these values should be acceptable for HVAC system design, and would mean that our Louver 1 is the better choice, even though the free area is lower. A good rule of thumb is to stay below 0.2 inches w.g. static pressure for most applications. If your values exceed this rule, we recommend you increase the opening size or select a louver model with higher free area, higher first point of water penetration, lower pressure drop, or a combination of these factors.
The following table represents the performance capability of louvers by Architectural Louvers. Table is based on a test size of 48" wide x 48" high for comparison purposes:
Product Model Free Area First Point of Water Penetration (free area velocity) Overall Performance (C.F.M.) Pressure Loss at this velocity (inches water gauge) E6JN 69.1% 915 fpm cfm 0.12 E4DP 59.3% 930 fpm cfm 0.12 E4JP 58.4% 960 fpm cfm 0.13 E6DP 57.7% fpm cfm 0.13 E6JP 57.3% fpm cfm 0.18 E4DS 56.0% 930 fpm cfm 0.13 E4WS 56.0% 346 fpm cfm 0.02 E6JF 54.4% fpm cfm 0.18 E2WV 53.8% 889 fpm cfm 0.34 E6WH 51.4% > fpm cfm 0.48 E6WF 51.1% fpm cfm 0.46 E4WH 50.6% > fpm cfm 0.54 E4JS 50.4% 888 fpm cfm 0.15 E2DS 49.4% 889 fpm cfm 0.12 E2JS 48.7% 725 fpm cfm 0.08
Go to list of industry links
| April 14,
Cooling Tower Air Inlet Louvers disallows the illumination of the sun from entering the cooling tower bowl. Introducing air delta louvers helps control the development of algae and green bacteria. Controlling the light and restricting algae growth implies bringing down substance costs. The Cooling Tower Air Inlet Louvers additionally assist with bringing down how much splash-out from the cooling tower. This lessens how much water and compound are expected to run the cooling tower louvres proficiently. Additionally, you will encounter more straightforward basin access and evacuation.
Without appropriate consideration and upkeep, the air intake/air inlet louvres in cooling towers with counterflow can once in a while become scaled. Assuming this happens, it decreases the effectiveness of industrial cooling towers. The louvres that are scaled decrease the wind stream to the unit, which leads to reducing proficiency.
A cooling tower louvre is a part of a proficient cooling tower framework. It guarantees that water is of great quality and amount. In a cooling tower, water and air are united. Essentially, certain circumstances are probably going to occur. For example, algae can develop, water and compound quality may be diminished or water might sprinkle out from the tower, which calls for cooling tower maintenance services to fix the issue.
These circumstances might lessen the viability of the cooling tower and in the end the general limit of the factory, treatment facility, or anything that tasks with cooling towers you are keeping up with. The louvers and boards will assist with keeping these cases from happening to guarantee the ideal execution of the cooling tower.
There are various types of cooling tower louvers. You can have an air channel louvers cooling tower or a louver cell board. Each likewise has a different design and compound.
What is the function of cooling tower air inlet louvers?
The louvers are an essential component of the cooling tower. They equalize the flow of air in the fill and maintain the level of water. Cross-flow towers usually have air inlet louvers while counterflow tower designs have no need for any louvers.
- Prevent daylight from infiltrating into the towers fill. An openness to daylight clears the way for the development of algae and, surprisingly, a few bacterial types.
- Impedes water splashing out, and that implies water is held inside the assortment tank.
- Evades enormous materials or garbage from entering the tower.
- Difficult to hinder from water line to shower spout make a decent temperature cooling.
- Limits expenses of keeping up with the tower, like costs to kill algae growth.
Features of cooling tower louvers
Adaptable to various cooling towers
Cooling tower louvers are planned such that they can fit into various sorts of cooling towers. It is adequately adaptable to adjust to various constructions. The cooling tower louver can likewise be fitted to a recently constructed cooling tower. It can likewise be retrofitted to existing cooling towers, saving you from being required to roll out huge improvements.
Utilitarian design
The cooling tower louver configuration isnt just to give a feel to the cooling tower. The cooling tower louvers have a plan that capacities as a hindrance for daylight section, entering of enormous flotsam and jetsam and work on the wind stream in the pinnacle. It is useful when to get an algae-free tower, water sprinkles out avoidance, and the general ability of the pinnacle to work.
Smooth and reflexive surface
One of the issues of cooling tower louvre cleaning and upkeep is the development of scales. To forestall this, cooling tower louvers have a smooth and polished surface that aids in forestalling scaling. In this manner, it can limit your costs and exertion for upkeep exercises.
UV obstruction
We have louvres that are additionally UV-safe. The Ultra Violet obstruction is useful in two ways. In the first place, it helps in forestalling the development of the algae somewhat. Second, it additionally assists with the strength of the louver. Accordingly, it broadens the existence of the item.
Regardless of how little a component it is, a cooling tower louver can characterize the adequacy and maintainability of your cooling towers. It has a bigger purpose to fill. Along these lines, picking the right louvres and their legitimate establishment is fundamental to guarantee that it performs in view of assumptions.
How Louvers Work
A louver is a ventilation product that allows air to pass through it while keeping out unwanted elements such as water, dirt, and debris. A number of fixed or operable blades mounted in a frame can provide this functionality. The basic considerations for selecting louvers are Louver Free Area, Water Penetration, and Resistance to Airflow (Pressure Loss). Once these concepts are understood, they can be used to properly apply a louver.
Louvers are required when buildings need to balance airflow and protection from external elements based on their specific functions and requirements. Different structures may demand louvers to control ventilation and prevent water ingress, such as in parking ramps where air circulation is essential but maximum rain protection is not necessary. Conversely, spaces housing sensitive equipment like generators or electrical components may necessitate louvers that offer robust defense against extreme weather conditions like storms and hurricanes, while also meeting stringent airflow specifications. In essence, the necessity for louvers arises from the distinct operational needs and environmental considerations of each building or facility.
Louver Free Area
Free area is derived by taking the total open area of a louver (after subtracting all obstructions - blades and frame) and dividing by the overall wall opening. This gives a comparison of a louvered opening to an unobstructed opening. Common louver free areas range from 35% to 60% of the wall opening (65% to 40% obstructed). A high percentage free area is beneficial because more air can enter into a smaller wall opening, reducing the cost of the wall opening and louver.
Obviously some obstruction is required in order to keep undesirable water out. A fully obstructed opening would allow no water in, while a totally unobstructed opening would allow water to enter unimpeded. A properly designed louver will maximize free area while allowing a minimal amount of water to enter.
For more information about free area, please visit the linked page Louver Free Area.
Louver Water Performance
First Point of Water Penetration is the point at which a louver allows the passage of water through the louver. It is a threshold measurement of air intake velocity at which the louver will begin leaking (in feet per minute or fpm).
Traditional Louvers:
The typical method of testing for water penetration is to intake air through the louver while applying a measured water content into the airstream. The velocity of airflow through the louver free area is increased until the louver allows water to enter. The result of this test is the first point of water penetration - ranging from 300 fpm (a very poor resistor to water entrainment) to fpm (a very good resistor to water entrainment).
Wind Driven Rain Louvers:
Testing is done similar to traditional louvers, but with wind simultaneously applied to the face of the louver. The wind is applied at a fixed rate, while the air intake velocity is increased from 0 feet per minute to a predetermined value. Instead of a "first point of water penetration" value, efficiency of the louver is measured instead. Basically, "how good is the louver at stopping the water?" The efficiency is rated as a percentage, determined from the amount of water that passes through the louver divided by the total water applied during the test. A very efficient louver will have a value from 99-100%. Inefficient louvers will have values below 85%, meaning they allow over 15% of the water applied to pass through the louver.
Testing procedures have fixed values for water volume and the wind speeds applied. Two tests are common - 3" per hour rainfall combined with 29 mph wind speeds, and 8" per hour rainfall combined with 50 mph wind speeds. As described earlier, the air intake velocity is the only variable.
Obviously this testing is more stringent and requires a special louver design to perform well in this environment. Several designs are available throughout the market, but few have surpassed the capabilities of our E2WV, E4WH, and E6WH louver models.
back to top
Louver Resistance to Airflow
Every obstruction in the airstream creates resistance - louvers, ductwork, filters, coils, building structure, etc. The resistance of the louver can be measured by running air through the louver and measuring the pressure differential at various free area velocities (measured in water gauge or wg). Every louver will create resistance based on the frame and blade shapes. Lower blade angles or more aerodynamic shapes create less resistance. We must know the free area velocity through the louver in order to properly evaluate the overall resistance to airflow. For a majority of applications, we can calculate the pressure loss of the louver at the required free area velocity and determine if it is acceptable. The resistance created can be detrimental to the application of fans and other air movement equipment, so we should attempt to minimize it.
Applying the Principles
To properly evaluate a louver's capability, we must have a method to include both the Free Area and the First Point of Water Penetration in a meaningful way. Since the overall objective is to get as much air as possible through the louver, we want to evaluate the allowable volume of air through the louver (cubic feet per minute or cfm). Test methods for these principles are covered in AMCA Standard 500-L Laboratory Methods of Testing Air Louvers for Rating. The following example compares two louvers for a wall opening size of 48" wide x 48" high with different performance characteristics:
Louver
Free Area (percentage)
Free Area for 48" x 48" (square feet)
First Point Water (fpm)
1
45%
7.2
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2
53%
8.5
750
Since our objective is to get more air through the louver, we might assume that Louver 2 is better than Louver 1, since it has a higher free area. However, more evaluation is required. The real question is, "How much total air can I get through the louver without entraining water?"
Louver
Free Area (percentage)
Free Area for 48" x 48" (square feet)
First Point Water (fpm)
Design Velocity (fpm)
Volume of Air (cfm)
1
45%
7.2
893
2
53%
8.5
750
563
View performance of Architectural Louvers
Louver 1 has a free area of 45% for a size 48" wide x 48" high wall opening. The total square feet of free area is 7.2 ( = 45% x 16 sq ft of wall opening). The tested First Point of Water Penetration for this louver is feet per minute free area velocity. We should build in a safety factor for some variation in our airflow through the louver - we have chosen 25% safety factor. The design velocity including the safety factor would be 25% less than fpm, or 893 fpm ( x .75). We can now determine how much air can safely be run through the louver by multiplying the louver free area by the design velocity ( 7.2 sq ft x 893 fpm). The resulting Volume of Air for Louver 1 is cfm.
If we go through the same calculations for Louver 2, the result (with a 25% safety factor) is only cfm. This is 25% less air through the same opening size. Louver 1 is a better choice - IF we can live with the pressure drop from the higher airflow rates! back to top
Most Manufacturers publish air flow resistance for their louvers. Each louver will have slightly different resistance based on the blade and frame shapes and angles. These characteristic can be expressed by a formula and graphed, such as:
Louver 1
Louver 2
Simplifying things a bit - most louvers do not fluctuate dramatically from these graphs (about 15% in this example), unless the louver is designed for very high air velocities, like wind driven rain louvers. However, if you have the data, use it! Here we can calculate the resistance at the design velocities for each louver and determine that:
Louver 1 - at 893 fpm free area velocity, will create 0.090 inches w.g. of static pressure
Louver 2 - at 563 fpm free area velocity, will create 0.055 inches w.g. of static pressure
Both of these values should be acceptable for HVAC system design, and would mean that our Louver 1 is the better choice, even though the free area is lower. A good rule of thumb is to stay below 0.2 inches w.g. static pressure for most applications. If your values exceed this rule, we recommend you increase the opening size or select a louver model with higher free area, higher first point of water penetration, lower pressure drop, or a combination of these factors.
The following table represents the performance capability of louvers by Architectural Louvers. Table is based on a test size of 48" wide x 48" high for comparison purposes:
Product Model Free Area First Point of Water Penetration (free area velocity) Overall Performance (C.F.M.) Pressure Loss at this velocity (inches water gauge) E6JN 69.1% 915 fpm cfm 0.12 E4DP 59.3% 930 fpm cfm 0.12 E4JP 58.4% 960 fpm cfm 0.13 E6DP 57.7% fpm cfm 0.13 E6JP 57.3% fpm cfm 0.18 E4DS 56.0% 930 fpm cfm 0.13 E4WS 56.0% 346 fpm cfm 0.02 E6JF 54.4% fpm cfm 0.18 E2WV 53.8% 889 fpm cfm 0.34 E6WH 51.4% > fpm cfm 0.48 E6WF 51.1% fpm cfm 0.46 E4WH 50.6% > fpm cfm 0.54 E4JS 50.4% 888 fpm cfm 0.15 E2DS 49.4% 889 fpm cfm 0.12 E2JS 48.7% 725 fpm cfm 0.08
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