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6.7 Evaporation loss of water in cooling tower: 

Blowdown: During the cooling process of hot water in cooling tower, around 2% water evaporates [1-3]. In the long run, it increases the solid content in the circulating water. Some dust particles also come from the environment and mix with circulating water. But the solid content of the cooled water must be kept under a certain limit to avoid scaling or fouling on the heat exchange equipment. A part of the circulating water is drained from the bottom of the cooling tower to discard the deposited solids from the cooling tower. This is called blowdown. The losses due to blowdown, evaporation, drift and leakage are compensated by adding make-up water.

Water balance in cooling tower 
M=B+D+E                                                   (6.38)
where, M is make-up water rate; B is blowdown rate; D is drift leakage loss rate; E is evaporation loss.
Solid balance
M×C1=(B+D) ×C2+E×0                                      (6.39)
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering                                         (6.40)
where, r=C2/C1; C1 is dissolved solid concentration in the make-up water; C2 is dissolved solid concentration in the circulating water.

Evaporation loss is estimated by a thumb rule as: 
E=water flow rate (L)×range(ºF)×0.00085 gallon/min

The other design characteristics are pump horsepower, fan horsepower, source of make-up water and drift eliminators.

Nomenclature 
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering      Contact area/tower volume, m2/m3
L           Water flow rate, kg/m2s
cwL       Heat capacity of liquid (water), kJ/kg.K
V           active cooling volume/plan area, m3/m2
Gs          Air rate, kg dry air/m2s
Y/           Humidity, kg moisture/kg dry air
hG           Heat transfer coefficient of air film, kJ/m2.s.K
Y/w        Saturation humidity, kg moisture/kg dry air
hL          Heat transfer coefficient of liquid (water), kJ/m2.s.K
z          Cooling tower height, m
kG          Mass transfer co-efficient of moisture transport, kg/m2.s (ΔpA)
λw          Latent heat of vaporization of water, kJ/kg
K/Y          Overall mass transfer co-efficient, kg/m3.s
VH          Humid volume, m3/kg dry air 

HUMIDIFICATION PROBLEM 
Example Problem 6.1: 
A cooling tower is to be designed to cool water from 450C to 300C by countercurrent contact with air of dry bulb temperature 300C and wet bulb temperature of 250C. The water rate is 5500 kg/m2.h and the air rate is 1.25 times the minimum. Determine the tower height if the individual gas-phase mass transfer coefficient ( Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering ) is 5743.5
kg/m3 h (ΔY). The volumetric water side heat transfer coefficient is given by hLā=0.059L0.51Gs, in Kcal/m3hK, where L and Gs are mass flow rates of water and air (dry basis). Antoine Equation: ln PVA (bar)=11.96481-3984.923/(T-39.724).

Solution 6.1: 
TG1=30ºC
Tw=Tas=25ºC
Y/1 =0.019 [From psychrometric chart]
H/1= {(1.005 1.88 0.019) 30 2500 0.019}kJ/kg
=78.7 kJ/kg
TL1=30ºC
Locate point Q(TL1, H/1 ) (Lower terminal of operating line) at Q(30, 78.7) on TL-Hplane.

Generation of Equilibrium curve 
(i) Calculate pv from Antoine Equation: ln PVA (bar)=11.96481-3984.923/(T39.724).
(ii) Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
(iii) Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical EngineeringHere, reference temperature, T0 is 0ºC.   

Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering

Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering



Draw a tangent to the equilibrium line through Q. Slope of the tangent is 8.78.
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
=2623 kg/h.m2
Actual air rate =Gs,min×1.25
=2623×1.25 kg/h.m2
= 3279 kg/h.m2
Slope of the operating line
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
5500 x 4.187(45 - 30) = 3279(H/2 - 78.7) 
H/2 = 184kJ/kg
Now, locate point P (TL2, H/2 ) (Upper terminal of the operating line) at P (45, 184) on TL-Hplane.

We have,
hLā=0.059L0.51Gs
=0.059(5500)0.51(3279) kcal/m3h.K
=15637.9 kcal/m3hK=15637.9 ×4.187 kJ/m3h.K
=65,475.9 kJ/m3hK
Slope of tie line= Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
A set of tie lines of this slope is drawn from several points on the operating line. These tie lines meet the equilibrium line at (TLi, H/i ). Hence, the points (H/ , H/i ) are obtained. The values of   Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering  are plotted against TL and the integral Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering  is evaluated graphically.
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering
NtG=Area under the curve= (184-78.7)×0.088=9.27
Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering =(3279/5743.5)m=0.56 m
Tower height= 9.27×0.56 m=5.19 m (Ans.)

The document Evaporation Loss Of Water In Cooling Tower | Mass Transfer - Chemical Engineering is a part of the Chemical Engineering Course Mass Transfer.
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FAQs on Evaporation Loss Of Water In Cooling Tower - Mass Transfer - Chemical Engineering

1. What is evaporation loss in a cooling tower?
Evaporation loss in a cooling tower refers to the amount of water that is lost due to evaporation during the cooling process. As hot water is sprayed into the cooling tower and comes into contact with air, a portion of it evaporates, resulting in the loss of water from the system.
2. How does evaporation loss affect the performance of a cooling tower?
Evaporation loss can significantly impact the performance of a cooling tower. As water evaporates, the concentration of dissolved solids in the remaining water increases. This can lead to scaling and fouling of heat transfer surfaces, reducing the efficiency of the cooling tower and increasing energy consumption.
3. What factors influence the rate of evaporation loss in a cooling tower?
Several factors can influence the rate of evaporation loss in a cooling tower. These include the temperature and humidity of the air, the flow rate and temperature of the water, the design and operation of the cooling tower, and the presence of any additional chemicals or contaminants in the water.
4. How can evaporation loss be minimized in a cooling tower?
There are several strategies to minimize evaporation loss in a cooling tower. These include optimizing the cooling tower design for efficient heat transfer, reducing the water temperature before it enters the tower, using drift eliminators to capture water droplets and prevent their escape, and implementing water treatment programs to control dissolved solids and prevent scaling.
5. Are there any potential drawbacks to reducing evaporation loss in a cooling tower?
While reducing evaporation loss is generally beneficial, it can also have some drawbacks. For example, implementing measures to minimize evaporation loss, such as using drift eliminators, may increase the pressure drop across the cooling tower, resulting in higher energy consumption. Additionally, controlling dissolved solids through water treatment may require the use of chemicals, which can have environmental and cost implications. Therefore, it is important to carefully consider the trade-offs and select the most appropriate strategies for each specific cooling tower application.
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