2. OUTLINE
Introduction
What is steam
Types of steam
Heat exchanger
Steam in heat exchanger
Basic ways to improve heat transfer
Ways to improve steam efficiency
Problems in steam equipment
Conclusions
References
3. INTRODUCTION
The dramatic jump in petroleum prices over the recent
years has created much impetus to reduce operating costs
at chemical process plants.
The plant’s steam resource is often a primary provider of
heat to a process.
So using steam efficiently helps reducing operation cost
thereby generating savings.
4. STEAM
Steam is the gas formed when water passes from
the liquid to the gaseous state
Steam is one of the most common and effective
heat transfer mediums used in industry
They are mainly used in heat exchangers,
turbines, strippers, and chemical reaction vessels
5. TYPES OF STEAM
WET STEAM
Wet steam applies to steam when a portion of its water
molecules have given up their energy (latent heat) and
condense to form tiny water droplets
Also known as saturated steam
Mixture of water in the liquid state (tiny droplets) and
gaseous state (steam)
6. DRY STEAM
Dry steam applies to steam when all its water molecules
remain in the gaseous state
Known as superheated steam
It's a transparent gas
Superheated steam and liquid water cannot coexist
under thermodynamic equilibrium
7. WET STEAM VS. DRY STEAM
WET STEAM
Rapid, even heating through latent heat transfer
High heat transfer coefficient
Originates from water
Used for heating, cooking, drying or other procedures in
industries
DRY STEAM
Low heat transfer coefficient
Temperature may be extremely high
Sensible heat used to transfer heat
Exclusively used in turbines
8. HEAT EXCHANGER
Heat exchanger an equipment built for efficient heat transfer from
one medium to another
The media are separated by a solid wall so that they never mix
They are widely used in refrigeration, air conditioning, power plants,
chemical plants, petrochemical plants, petroleum refineries, and
natural gas processing
counter-current and co-current flow
9. STEAM IN HEAT EXCHANGER
Saturated steam is used in heat exchanger because it has high
heat transfer coefficient
Heat transfer with saturated steam utilizes the latent heat of
steam, releasing a large amount of energy as it condenses
Provision is made for condensate recovery
10. BASIC WAYS TO IMPROVE
HEAT TRANSFER
Temperature difference between the steam and process fluid
should be high
Using saturated steam instead of superheated steam
improves efficiency and minimizes operation cost
Higher the flow rate, higher will be the heat transfer
High conductivity of heat exchanger material helps in better
heat transfer
Larger the surface area of conducting interfaces, greater the
heat transfer rate
11. WAYS TO IMPROVE STEAM
EFFICIENCY
STEAM TRAPS
Steam traps are a type of automatic valve that filters out
condensate (condensed steam) and non-condensable gases
such as air without letting steam escape
They need to be monitored for leakage and other faults
Replacing faulty traps minimizes loss of steam and improves
efficiency
12. CONDENSATE RECOVERY
The condensate from traps can be returned to the boiler
This helps in reducing boiler fuel needs
Reducing boiler fuel needs through condensate recovery leads
to less air pollution by lowering CO2, NOx and SOx emissions
INSULATING STEAM SYSTEM
Despite high cost, insulation reduces heat loss
Helps save energy
MONITORING LEAKS
Checking the steam distribution lines and valves for leakage
and fixing them could save energy and enhance efficiency
STEAM METERING
Steam metering provides accurate steam usage statistics
It can be a useful troubleshooting tool
13. PROBLEMS IN STEAM
EQUIPMENT
WATER HAMMER (STEAM HAMMER)
Steam first supplied to steam distribution piping or steam-
using equipment, a metallic and repetitive 'bang, bang, bang',
or even sometimes a violent 'boom' accompanied by vibration
may be heard
Caused by high levels of accumulated condensate inside the
equipment
14. Water hammer causes a momentary abrupt pressure change
of over 10MPa inside the piping
Can severely damage piping and equipment
15. FIXING IT
Rapid discharge of condensate is critical from a preventative
maintenance standpoint
The speed of condensate discharge combined with how
smoothly the process occurs are two extremely important
factors in the fight against water hammer in steam-using
equipment
Proper design and orientation of the equipment
16. STALL
Occurs when the necessary pressure differential across a
drainage device such as a trap becomes negative
Condensate is no longer discharged from the drainage device
and instead pools inside the heat exchanger
Linked to the following problems - ruptured heaters, water
hammer, uneven heating temperatures
18. CONCLUSIONS
By proper use of steam, operational cost can be minimized
and high efficiency is achieved
Condensate recovery and recycling back to boiler helps
reducing boiler fuel needs thereby minimizing pollution
Damage to equipment can be averted by properly regulating
the steam
Using steam intelligently lowers carbon emission
19. REFERENCES
http://www.tlv.com/global/SG/steam-theory
James R. Risko, optimize the Entire Steam System, CEP June
2008, 31-32
James R. Risko, Understanding Steam Traps, CEP Feb 2011, 21-
26
James R. Risko, Handle Steam More Intelligently, CHEMICAL
ENGINEERING www.che.com Nov 2006, 44-48
