Types of Heat Exchangers and their Applications

Heat Exchanger

• A device that facilitate the exchange of heat between two fluids that are at different temperatures 

Applications of Heat Exchangers

• Chemical reactors (Jackets)
•  Preheating feeds
• Reboilers (Distillation column)
• Condensers (Distillation column)
• Air heaters for driers
• Crystallisers
• Heat transfer fluids 

Types of Heat Exchangers

Direct /Indirect Contact Heat Exchanger

Direct contact heat exchanger:

  o   Two fluids are not separated

• Gas bubbled through the liquid
• Liquid sprayed in the forms of droplets into the gas

Indirect contact heat exchanger:

  o   Two fluids are separated

  o   Heat transfer through the metal surface from one fluid to another 

Parallel /Counter/Cross Flow Heat Exchanger

Parallel Flow:

Both the hot & cold fluids enter the heat exchanger at the same end and move in the same direction

Counter Flow:

Hot and cold fluids enter the heat exchanger at opposite ends and flow in opposite directions

Cross Flow:

Hot and cold fluids usually move perpendicular to each other 

Double Pipe Heat Exchanger

One fluid flows through the smaller pipe

Other flows through the annular apace

Advantages:

  o   Simplest and Cheapest

  o   Used for high pressure applications

Disadvantages:

  o   Expensive for large duties

  o   Can’t be used in handling dirty fluids

  o   (Choking problem)(Used for only clean fluids)

Applications:

  o   Effluent cooling

  o   Pre heating

  o   Heat recovery 

Compact Heat Exchanger

• Thin plates or corrugated fins are attached closely spaced to walls separating two fluids

•  Commonly used in gas-gas and gas-liquid

Advantages:

    o   Large heat transfer surface area per unit volume

    o   Increase the H.T.C. of gas with increase surface area

    o   Lower cost

Disadvantages:

    o   Limited choice for high pressure

    o   Small passages likely to foul

Applications:

  o   Oil / water coolers

  o   Water / water coolers

     o   Condensers and evaporators 

Shell & Tube Heat Exchanger

Advantages:

o   Extremely flexible & robust design

o   Easy to maintain & repair

o   Dismantled for cleaning

Disadvantages:

o   Relatively large size & weight

o   Not suitable for automotive & aircraft

Applications:

o   Petrochemical: Processing & Refining

o   Food & Beverage

o   Metals and Mining

o   Pharmaceuticals 

Plate & Frame Heat Exchanger

• Hot & Cold fluids flow in alternate passages
• Suited for liquid-to-liquid heat exchange
• Hot & cold fluid streams at about same pressure

Advantages:

  o   Effective heat transfer (turbulence on both sides)

  o   Low cost because plates are thin

  o   Can easily be opened up for inspection and cleaning

  o   Less fouling

Disadvantages:

o   Gaskets may not be suitable for organic solvents

o   Usually not considered for refinery duties (Cannot withstand prolonged fire)

Applications:

o   Ethanol and Corn Processing

o   Industrial Energy

o   Power Plants

o   Food & Beverage 

Regenerative Heat Exchanger

Static type:

o    Hot & cold fluid flow through the mass alternatively

o    Heat transferred from hot fluid to the matrix

o    Heat transferred from matrix to the cold fluid

Dynamic type:

•  Rotating drum & continuous flow of hot & cold fluid
•  Periodic passing of drum through:

• Drum serves as medium to transport of heat

Advantages:

  o   Simple design

  o   Porous mass having large heat storage capacity

Disadvantages:

  o   Mixing of the fluid streams (separation problem)

  o   Constant heating and cooling puts a lot of stress cause cracking or breakdown of materials

Applications:

  o   Heat recovery from exhaust gases

  o   Air conditioning applications

  o   In food industry

  o   Temperature control of sewage sludge 

Spiral Heat Exchanger

Composed of two concentric spiral channels

Advantages:

  o   Applied where fouling and plugging are problems

  o   Ease of maintenance

Disadvantages:

  o   Higher initial cost

  o   Maximum design temperature is 400^oC (Special designs: operate up to 850^oC)

  o   Maximum design pressure is usually 15 bar (Special designs with pressures up to 30 bar

Applications:

  o   Food industry

  o   TiCl₄ cooling

  o   PVC slurry duties

  o   Oleum processing

  o   Temperature control of sewage sludge 

Fouling of Heat Exchanger

• Deposition of undesirable substance on the heat transfer surfaces.
• Increases the overall thermal resistance and lowers the overall heat transfer coefficient of heat exchangers.
• Impedes fluid flow, accelerates corrosion and increases pressure drop across the heat exchanger
• Strangely more heat exchangers are opened for cleaning due to excessive pressure drop than for an inability to meet the heat transfer requirement. 

References

1.         Cengel, Y. A. Heat Transfer: A  Practical Approach, 2nd Edition, McGraw-Hill.

2.         Bergman, T. L.; Lavine, A. S.; Incropera, F. P.; DeWitt, D. P. Fundamentals of Heat and Mass Transfer, Seventh Edition, Wiley.

3.         J. P. Holman, Heat Transfer. Sixth Edition, McGraw-Hill Book Company.

4.         McCabe W. L.; Smith, J. C.; Harriott, P. Unit Operations of Chemical Engineering. Fifth Edition, McGraw-Hill International Editions.

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