Advancement in the field of heat exchangers

1. Modern Technologies in Heat
Exchangers
Ahmed Ali Zafar L1F13BSME0066 MB-2

2. What are heat exchangers?
 A heat exchanger is a device used to transfer heat between one or more fluids. The fluids may be
separated by a solid wall to prevent mixing or they may be in direct contact.
 The classic example of a heat exchanger is found in an internal combustion engine in which a
circulating fluid known as engine coolant flows through radiator coils and air flows past the coils,
which cools the coolant and heats the incoming air.

3. Purpose:
They are widely used in
 power stations
 chemical plants
 petroleum refineries for
 space heating
 refrigeration
 air conditioning

4. Optimization( Level to be achieved)
There are three goals that are normally considered in the optimal design of heat exchangers are:
 Minimizing the pressure drop ,
 Maximizing the thermal performance and
 Minimizing the entropy generation (thermodynamic).

5. Stages of HE
Shell and Tube
Plate Heat
Exchangers
Spiral heat
exchanger
Plate and Shell
Heat Exchanger
Plate Fin Heat
Exchanger
Micro Channel
Heat Exchangers

6. Shell and tube
 Shell and tube heat exchangers consist of series of tubes. One set of these tubes contains the fluid
that must be either heated or cooled. The second fluid runs over the tubes that are being heated or
cooled so that it can either provide the heat or absorb the heat required

7. Advantages and Disadvantages
 It is used with pressures greater than 30 bar and temperatures greater than 260 °C.[
 Pressure drop across a tube cooler is less.
 Tube leaks are easily located due to easy application of pressure test.
 Heat transfer efficiency is less.
 Cleaning and maintenance is difficult.
 Capacity of tube cooler cannot be increased.
 Requires more space.

8. Plate Type HE
 Another type of heat exchanger is the plate heat exchanger. These exchangers are composed of
many thin, slightly separated plates that have very large surface areas and small fluid flow passages
for heat transfer.

9. Advantages and drawbacks:
 Serve low to medium pressure fluids,
 Countercurrent flow rather which allows lower approach temperature differences, high temperature
changes, and increased efficiencies.
 Simple and Compact in size.
 Capacity can be increased by introducing plates in pairs.
 Maintenance is simple. Can be easily cleaned.
 Initial cost is high since Titanium plates are expensive.
 Finding leakage is difficult since pressure test is not as ease as tube coolers.
 Bonding material between plates limits operating temperature of the cooler.
 Pressure drop caused by plate cooler is higher than tube cooler.

10. Spiral heat exchanger
 A modification to the perpendicular flow of the typical HCHE involves the replacement of shell with
another coiled tube, allowing the two fluids to flow parallel to one another,

11. Properties:
 lower all-around capital costs,
 Compact size
 Less pressure drop,
 Less pumping energy,
 Higher thermal efficiency, and
 Lower energy costs.

12. Plate and shell heat exchanger
 A heat exchanger have properties of both (shell and tube and plate heat exchanger)
 Plate and shell technology offers high heat transfer, high pressure, high operating temperature,
compact size, low fouling and close approach temperature.

13. Plate fin heat exchanger
 This type of heat exchanger uses "sandwiched" passages containing fins to increase the
effectiveness of the unit. The designs include cross flow and counter flow coupled with various fin
configurations

14. Characteristics:
Advantages of plate and fin heat exchangers are,
 High heat transfer efficiency especially in gas treatment
 Larger heat transfer area
 Approximately 5 times lighter in weight than that of shell and tube heat exchanger.
 Able to withstand high pressure
 Disadvantages of plate and fin heat exchangers:
 Might cause clogging as the pathways are very narrow
 Difficult to clean the pathways
 Aluminum alloys are susceptible to Mercury Liquid .

15. Criteria
 High/low pressure limits
 Thermal performance
 Temperature ranges
 Pressure drops across the exchanger
 Fluid flow capacity
 Cleanability, maintenance and repair
 Materials required for construction
 Ability and ease of future expansion
 Material selection, such as copper, aluminum, carbon steel, stainless steel, nickel
alloys, ceramic, and titanium.