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Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering PDF Download

6.3 Humidification and dehumidification operations and design calculations 
Humidification operations: In this operation, water transfers from liquid phase to gas phase. Hence, moisture content of air increases. Air with particular moisture content is useful for drying of a solid under controlled condition.
Dehumidification operations: It is the reverse phenomena of humidification. A portion of water vapor from moist warm air is condensed by contacting cold water in air conditioning.

6.4 Cooling tower principle and operation 
A cooling tower is a special type of heat exchanger in which the warm water and the air are brought in direct contact for ‘evaporative cooling’. It provides a very good contact of air and water in terms of the contact area and mass transfer coefficient of water vapor while keeping air pressure drop low. Enthalpy of air is lower than enthalpy of water. Sensible heat and latent heat transfer take place from water drop to surrounding air. Schematic of heat transfer from water drop to surrounding air is presented in Figure 6.3. 

Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering
Figure 6.3: Schematic of heat transfer from water drop to surrounding air.

Thus, cooling is accomplished by sensible heat transfer from water to air and evaporation of a small portion of water. A generalized cooling tower system is shown in Figure 6.4. The hot water which is coming from heat exchanger is sprayed at the top of the cooling tower. Air enters through the louvers at the two opposite walls of the cooling tower. During cooling process of water, around 2% water is evaporated. Make water is used to compensate the water loss due to evaporation. Blowdown is there to drain a part of water containing solid deposit. The exit cold water from the cooling tower is used in the heat exchanger or other unit operation.

Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering
Figure 6.4: Generalized cooling tower system.

Factors govern the operation of cooling tower 
i. The dry-bulb and wet-bulb temperatures of air
ii. Temperature of warm water
iii. The efficiency of contact between air and water in terms of volumetric mass transfer coefficient Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering
iv. Contact time between air and water
v. The uniformity of the distribution of the phases within the tower
vi. Air pressure drop
vii. Desired temperature of cooled water   

6.5 Types of equipment 
Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering

(A) Atmospheric Towers 
It is a big rectangular chamber with two opposite ‘louvered’ walls. Tower is packed with a suitable ‘tower fill’. Atmospheric air enters the tower through louvers driven by its own velocity. Direction and velocity of wind greatly influence its performance. Figure 6.5 shows the schematic of the atmospheric cooling tower.
Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering
Figure 6.5: Schematic of atmospheric cooling tower.

 

(B) Natural Draft Towers 
A natural draft cooling tower has a large reinforced concrete shell of hyperbolic shape (also called ‘hyperbolic tower’). Natural flow of air occurs through the tower; hence it is called natural draft (refer Figure 6.6).
Factors responsible for creating natural draft 
(a) A rise in temperature and humidity of air in the column reduces its density
(b) Wind velocity at the tower bottom
Fan is used to enhance the air flow rate in fan assisted natural draft tower. The typical diameter of tower is 150 m and capacity is 5,00,000 gallon/minute.
Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering
Figure 6.6: Schematic of natural draft tower.

Why hyperbolic shape? 
(i) More packing materials can be placed at the bottom
(ii) The entering air gets smoothly directed towards the centre
(iii) Greater structural strength and stability

The document Humidification And Dehumidification Operations And Design Calculations | Mass Transfer - Chemical Engineering is a part of the Chemical Engineering Course Mass Transfer.
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FAQs on Humidification And Dehumidification Operations And Design Calculations - Mass Transfer - Chemical Engineering

1. What is the purpose of humidification in chemical engineering?
Ans. Humidification is the process of increasing the moisture content in air or gas. In chemical engineering, humidification is often required for various reasons such as providing optimal conditions for certain chemical reactions, maintaining specific humidity levels in controlled environments, and improving the efficiency of certain industrial processes. This process is commonly used in industries such as pharmaceuticals, food processing, and HVAC systems.
2. How is dehumidification used in chemical engineering?
Ans. Dehumidification, on the other hand, involves the removal of moisture from air or gas. In chemical engineering, dehumidification is often necessary to prevent condensation, control humidity levels in sensitive processes, and ensure the quality of final products. Industrial applications of dehumidification include drying processes, storage of hygroscopic materials, and maintaining specific humidity conditions in manufacturing facilities.
3. What are some common design calculations involved in humidification and dehumidification processes?
Ans. Design calculations in humidification and dehumidification operations typically involve determining the required heat or mass transfer rates, sizing of heat exchangers or humidifiers, and estimating the energy consumption. Specific calculations may include determining the amount of water needed for humidification, heat transfer coefficients, and the impact of temperature and humidity on the process efficiency.
4. What factors should be considered when designing a humidification or dehumidification system?
Ans. When designing a humidification or dehumidification system, several factors need to be considered. These include the desired humidity levels, the temperature and flow rate of the air or gas, the available energy sources, the efficiency of the system, and the specific requirements of the process or application. It is also important to consider the control mechanisms, maintenance requirements, and potential environmental impacts of the system.
5. Are there any energy-saving strategies for humidification and dehumidification processes in chemical engineering?
Ans. Yes, there are several energy-saving strategies that can be implemented in humidification and dehumidification processes. These include the use of heat recovery systems to reuse waste heat, optimizing the design and operation of heat exchangers or humidifiers to minimize energy losses, and integrating the process with other energy-efficient systems. Additionally, advanced control systems and sensors can be utilized to ensure precise and efficient humidity control, reducing energy consumption in the long run.
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