THE SIMULATION OF WAVE ENERGY CONVERSION BY FLOATING POINT ABSORBER BUOY IN INDONESIAN SEA WAVES
The sea wave has the potential to be used as a source of alternative energy. The energy density of sea wave farms is 2-3 kW/m2, higher than solar parks (0.1-0.2 kW/m2) and wind farms (0.4-0.6 kW/m2). Besides, sea wave energy is available 90% of the time, whereas solar and wind power availability...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/61833 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The sea wave has the potential to be used as a source of alternative energy. The
energy density of sea wave farms is 2-3 kW/m2, higher than solar parks (0.1-0.2
kW/m2) and wind farms (0.4-0.6 kW/m2). Besides, sea wave energy is available 90%
of the time, whereas solar and wind power availability is hardly 20-30% times.
Therefore, sea wave energy is considered a renewable and sustainable energy
source, especially in Indonesia, based on the fact that its sea area (about 7.9x106
km2, including an Exclusive Economic Zone) constitutes about 81% of the country's
total area.
This study presents the simulation of ocean wave energy conversion of Indonesian
sea waves, specifically along the west coast of Sumatra, the southern coasts of Java,
and Bali waters using Wave Energy Converter Simulator (WEC-Sim). WEC-Sim is
an open-source code for modelling wave energy converters. The code is written in
MATLAB/Simulink and uses the multi-body dynamics solver. This simulator uses
the Cummins equation in the 6 degrees of freedom (DOF) modelling process. The
floating-point absorber buoy RM3 model simulated five hot spots with the high
potential wave energy. These five hotspots are South Pagai Island II (101.25oE-
4.25oS), Enggano (102.25oE-5.5oS), Cilacap (109.06oE-7.94oS), Jember (113.68oE-
8.56oS), and Bali (115oE-8.75oS). RM3 consists of a float and a spar/plate coupled
to a central column, and it converts energy from the axial motion between these
components induced by ocean waves. Modification of mass and moment of inertia
on float and spare/plate was carried out to determine its effect on the output
electrical power.
In this simulation, the Pierson-Moskowitz (PM) spectrum was used to model
irregular waves. The WEC's power take-off (PTO) mechanism was simulated as a
hydraulic system. It consists of a hydraulic cylinder, a check valve, a hydraulic
motor, hydraulic accumulators, and hoses to connect the various components.
Besides, hydraulic PTO forces were affected by the total force of WEC bodies (float
and spar/plate). Based on the simulation, Hydraulic PTO yields the PTO force
interval between -0.2 and 0.2 MN in the five selected locations. The simulation ran
for 400 seconds of time simulation and 0.01 seconds of time step with the predefined
parameters, such as significant wave height and wave period.
The average absorbed power by the WEC device is in the range of 21.13 to 26.18
kW. Meanwhile, the range of average mechanical power is from 17.02 to 21.53 kW,
and the range of average electrical power is from 14.10 to 18.13 kW. The average
value of electrical powers generated during the simulation were 15,84; 15,53;
18.13; 14,10; 15,69 kilowatts (kW) or 129.34; 126.71; 147.96; 115.09; 128.02
megawatts hours (MWh) per year for South Pagai Island II, Enggano Island,
Cilacap, Jember, and Bali. Based on Indonesia National Energy Council (DEN)
report, electricity demand per capita in 2018 was 964 kW. It means a unit of RM3
buoy is sufficient to provide electricity from between 116 to 148 individuals. The
addition of mass and moment of inertia by 25% on the float and a reduction of
0.75% on the spar/plate can increase the electric power by an average of 11.65% -
12.48%. This modification is proven to be able to increase output electrical energy
per year to 129.46 MWh - 165.19 MWh or equivalent to electricity needs for 134 to
171 individuals.
The WEC device location that generated the highest average electrical power is
Cilacap, with the highest significant wave height value. On the contrary, Jember,
which has the lowest significant wave height value, generated the lowest average
electrical power. It means that the significant wave height is a crucial parameter
to determine the output power of the wave energy. In conclusion, Indonesian sea
waves are great potential and promising locations to implement WEC devices in
the future.
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