Power Plant Engineering


POWER PLANTS BASED ON OCEAN ENERGY


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Power-Plant-Engineering

2.21.1 POWER PLANTS BASED ON OCEAN ENERGY
Ocean thermal energy is used for many applications, including electricity generation. There are
three types of electricity conversion systems: closed-cycle, open-cycle, and hybrid.
Closed-cycle systems use the ocean’s warm surface water to vaporize a working fluid, which
has a low-boiling point, such as ammonia. The vapor expands and turns a turbine. The turbine then
activates a generator to produce electricity. Open-cycle systems actually boil the seawater by operating
at low pressures. This produces steam that passes through a turbine/generator. Hybrid systems combine
both closed-cycle and open-cycle systems.
Depending Upon these electricity conversion systems the Ocean power plant can be divided
mainly in to two groups.
The Open or Claude OTEC Cycle Power Plant. The Frenchman Georges Claude constructed
the first OTEC plant in 1929 on the Mantanzas Bay in Cuba.
The Claude plant used an open cycle in which seawater itself plays the multiple role of heat
source, working fluid, coolant, and heat sink.


NON-CONVENTIONAL ENERGY RESOURCES AND UTILISATION
99
Vacuum
pump
Dissolved
gases
Warm
surface
water
1
2
4
Warm-water
discharge
Evaporator
Direct
contact
condenser
Low-pressure steam
T
5
7
Cold-water
discharge
Cold deep
water
Pump
6
Powerplant
13° C
Surface water
27°C
Deep
water
11°C
Fig. 2.44. Flow diagram and schematic of a Claude (open-cycle) OTEC power plant.
In the cycle warm surface water at 27°C is admitted into an evaporator in which the pressure is
maintained at a value slightly below the saturation pressure corresponding to that water temperature.
Water entering the evaporator, there four, finds itself “superheated” at the new pressure.
This temporarily superheated water undergoes volume boiling causing that water to partially
flash to steam to an equilibrium two-phase condition at the new pressure and temperature. The low
pressure in the evaporator is maintained by a vacuum pump that also removes the dissolved
noncondensable gases from the evaporator.
The evaporator now contains a mixture of water and steam of very low quality at 2. The steam is
separated from the water as saturated vapor at 3. The remaining water is saturated at 4 and is discharged
as brine back to the ocean. The steam at 3 is, by conventional power plant standards, a very low-
pressure, very high specific-volume working fluid (0.0317 bar, 43.40 m
3
/kg, compared to about 160
bar, 0.021 m
3
/kg for modern fossil power plants). It expands in a specially designed turbine that can
handle such conditions to 5. Since the turbine exhaust system will be discharged back to the ocean in
the open cycle, a direct-contact condenser is used, in which the exhaust at 5 is mixed with cold water
from the deep cold-water pipe at 6, which results in a near-saturated water at 7. That water is now
discharged to the ocean.
The cooling water reaching the condenser at 13°C is obtained from deep water at 11°C (51.8°F).
This rise in temperature is caused by heat transfer between the pro-gressively warmer outside water and
the cooling water inside the pipe as it ascends the cold water pipe.
There are thus three temperature differences, all about 2°C: one between warm surface water
and working steam, one between exhaust steam and cooling water, and one between cooling water
reaching the condenser and deep water. 'These represent external irreversibility’s that reduce the over-
all temperature difference between heat source and sink from 27 – 11 = 16°C (28.8°F) to 25 – 15 =
10°C (18°F) as the temperature difference available for cycle work. It is obvious that because of the
very low temperature differences available to produce work, the external differences must be kept to
absolute minimum to realize as high efficiency as possible. Such a necessary approach, unfortunately,


100
POWER PLANT ENGINEERING
also results in very large warm and cold water flows and hence pumping power, as well as large heavy
cold water pipes.

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