- 1. Adlin Miranda Morales INTD 3355Prof. Liz Pagan
2. Agenda What is a compact heat exchanger? Types Advantages and
limitations Cost of heat exchangers Fouling Security and
Environmental aspect Design Conclusion 3. Basic Definitions Heat
exchanger: apparatus that has two streams of fluid that exchange
temperatures in order to heat or cool the system. Fouling: type of
contamination in the heat exchanger that can damage its purpose. 4.
Description Basically this presentation focuses on what are compact
heat exchangers, the various types, costs, advantages and
disadvantages and how fouling may affect. The main option for
research was internet and the library ( books, journals, thesis,
etc.) 5. What is a Compact Heat Exchanger? Area density greater
than 700 m2/m3 for gas or greaterthan 300 m2/m3 when operating in
liquid or two-phasestreams. Highly efficient Reduce volume, weight
and cost 6. Types of CHEs Plate and frame heat exchangers: (PHE) 7.
Plate and Frame Heat Exchanger Most common type of PHE Consists of
plates and gaskets Materials: stainless steel, titanium and
non-metallic Operation limits:- temperatures from -35C to 220C-
pressures up to 25 bar- flow rate up to 5000 m3/h 8. Brazed Plate
Heat Exchanger (PHE) 9. Brazed Plate Heat Exchanger Operates at
higher pressures than gasketed units Materials: stainless steel,
copper contained braze Operating limits:- From -195C to 200C-
Pressures up to 30 bar It is impossible to clean. The only way is
by applying chemicals. 10. Welded Plate Heat Exchanger (PHE) 11.
Welded Plate Heat Exchanger Plates welded together to increase
pressure and temperature limits Materials: stainless steal and
nickel based alloys. Can be made with copper , titanium or graphite
Operation Limits: - temperature limits depend on the material - can
tolerate pressures in excess of 60 bar 12. Spiral Heat Exchanger
(SHE) 13. Spiral Heat Exchanger (SHE) Two long strips of plate
wrapped to form concentric spirals Materials: carbon steel,
stainless steel and titanium Operation limits: - Temperatures up to
400C (depends on gasketed materials) - Pressures up to 25 bar 14.
Plate Fin Heat Exchanger (PFHE) 15. Plate Fin Heat Exchanger (PFHE)
High area density and handles several streams Materials: aluminum,
corrosion and heat resistant alloys, and stainless steel (available
in titanium) Operation limits: - Temperature limits depend on the
material- cryogenic temperature up to 100C (aluminum)- stainless
steel up to 650C - Pressures up to 100 bar for aluminum and 90 bar
for stainless steel 16. Printed-circuit heat exchangers (PCHE) 17.
Printed-circuit heat exchangers (PCHE) Flexibility of design and
high strength offered by techniques of construction Materials:
Stainless steel 316L, alloys, nickel and titanium. Operating
limits: - temperature ranges from -200C to 900C - pressures up to
400 bar 18. Compact Shell-and-Tube Heat ExchangerTo increase
surface area, this equipment has a largenumber of small diameter
tubes 19. Other Types of CHE Compact types retaining a shell APV
Paratube Heat Exchanger Fluidized Bed Heat Exchanger Twisted Tube
Heat Exchanger 20. Advantages and Limitations Improved energy
efficiency- Closer approach temperatures allows greater
energytransfer. Smaller volume and weight Higher efficiency Lower
cost Multi-stream and multi-pass configurations Tighter temperature
control Power savings Improved safety 21. Limitations Lack of
industrial awareness Companies remain aware of technology of CHE
Limited choice Particularly for high-pressure Conservatism in the
user industries Process industries are reluctant to adopt what they
may seen either as new technologies. Susceptibility to fouling
Perception that small passages are likely to foul. 22. Cost of
compact heat exchangers Compact heat exchanger tend to be cheaper
especiallywhen their total installed cost is considered. In some
cases the materials used to manufacture isexpensive, but when we
consider the cost of unit plusthe installation, the cost is less
than equivalent shelland tube. 23. Cost of compact heat exchangers
24. Fouling Crystallization or precipitationSolutes in the fluid is
precipitated and crystals are formed Particulate fouling or
siltingSolid particles are deposited on the heat transfer surface
Biological foulingDeposition and growth of organism on surfaces
Corrosion foulingCarrying of corrosion products from other part of
thesystem being left on the heat transfer area surface Chemical
reaction foulingArises from reactions between constituents in the
processfluids Freezing or solidification foulingOccurs when the
temperature of a fluid passing through a heat exchanger becomes too
low 25. Security Aspects Fouling:- Use of non-fouling fluids
wherever possible is ofcourse recommended, for example clean air
orgases, light carbons and refrigerants.- In open systems, check
the possible application ofself-cleaning strainers, and the
installation of systemsto dose with biocides, scale inhibitors,
etc., to controlfouling.- Use self-cleaning filter if possible-
Consider chemical cleaning. If this is undertaken, thesystem must
be designed to allow the introduction andcomplete removal of
cleaning fluids. 26. Corrosion: In some CHEs, the wall thicknesses
are less than in a shell-and-tube heat exchanger, so corrosion
rates and allowances need to be accessed carefully Although CHEs
are often made from more corrosion- resistant materials than the
shell-and-tube units, other corrosion mechanisms such as cracking
may occur, and the compatibility of the material with the fluids in
the CHE should be checked. 27. Design Analysis based on and Ntu
method Convection and friction coefficients have been determined by
Kays and London. Some data of design can be supplied by
manufacturers. Results for heat transfer and friction factors for
circular tube- circular fin and for circular tubes continuous fin.
28. VA frmm GV max A ffA ffA fr A ff rea mnimaflujo libre A fr rea
frontal 2 /3jHSt PrSth /Gcp GV maxReGD h / 29. 2 /3 jH St Pr VA
frmm GV max A ff A ffA fr St h /Gcp A ff rea mnima flujo libre G V
max A fr rea frontalRe GD h / 30. Environmental Aspects Energy
conservation and environmental considerations are the driving
forces behind changes aimed at reducing both chemical and thermal
waste. More efficient use of energy and raw materials Recovery of
heats of reaction High intensity mixing, enhancing process
selectivity Minimum risk of runaway reactions Smaller and cheaper
plant Ability to handle high-pressure reactions 31. Conclusion
Compact heat exchangers are available in a wide variety of
configurations to suit most processes heat transfer requirements.
The advantages of CHEs, and associated heat transfer enhancement
techniques, extend far beyond energy efficiency. Lower capital
cost, reduced plant size, and increased safety are typical of the
benefits arising from the use of CHEs. Compact heat exchangers can
replace some normal size heat exchangers bringing advantages and
performance. 32. Conclusion This research took a lot of time, since
the specific details of a theme like this take time to search. Even
though it took time, I really enjoyed making this presentation. 33.
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http://www.flatplate.com/?gclid=CNbbnaC1pZoCFRKIxwodJDnU8w Heat
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