Generating electricity from wave is predicted to be a new source of renewable energy conversion gaining more attention and is considered in various countries as promising renewable resource. Being surrounded by sea, Malaysia has the advantage of tapping energy from the nearest sea wave. However, Malaysia has low wave climate compared to other regions. On top of that, the technologies available for extracting this energy are still in infancy stage. This study explored the potential of generating electricity from low height wave energy. The recorded average electricity can be generated from the lab scale device which is 0.224 V, 0.175 A and 0.039 W. The data collected from Mukah Beach show that the maximum voltage recorded is 1.021 V, maximum current of 0.86 A and highest power of 0.878 W. By comparing results from both locations, the difference is almost 10-fold which validates the wave maker built in laboratory with 1:10 ratio. The standard deviation of all the outputs is small which indicates that the output generation from low height wave would be consistent. Although the output is small, it could be paired together to make a larger system to generate higher output. This study concludes that the developed lab scale model is useful for harnessing electrical energy from sea wave. The future direction of research would be to optimize the current method to maximize energy capture from sea wave. Another direction for future study is to make a system comprised of a large number of such devices to generate higher output.
Wave energy power is abundant, has lower enviromental impacts and is more reliable than other renewable resources such as solar and wind energy due to the power density of 2 - 3 kW/m2 (wind 0.4 - 0.6 kW/m2; solar 0.1 - 0.2 kW/m2) [
Ocean waves are created by endless development of water under the influence of gravitational powers of sun, moon, and blowing winds. At the point when wind is sweeping across the surface of ocean, surface applies the weight on the base layer of the wind [
generally estimated in numbers every second (Hertz) and is the same as 1 T . The
rate of propagation, c, is the speed at which the wave profile travels such as the speed at which the peak and trough of the wave progresses. It is normally referred to as wave speed or phase speed. The steepness of a wave is the ratio of the
height to the length H λ .
Kinetic and potential energy of a wave per meter of crest and unit of surface can be derived by the velocity potential which can be obtained through linear wave theory. The sum of these two energies can be analysed as shown in Equation 1 below. Hence, the wave height, H is equal to 2A. The wave period is the
measurement of time taken for the wave cycle to complete, T = λ f , where λ is
wavelength and f is the frequency.
E = ρ g A 2 2 (1)
where:
ρ = water density;
g = acceleration due to gravity;
A = wave amplitude.
Many concepts are available to convert wave motion to electrical energy. The concepts are illustrated in
Wave activated bodies concept is where the motion of the wave is translated to the motion a device. A noteworthy sub class of wave activated bodies are point absorbers. The main characteristic of point absorbers is that they are small in the horizontal dimensions compared to the length of the waves from which they aim to capture energy. In other words, they take up a relatively small area of the ocean surface. This concept is the combination of the idea of Faraday’s law and Newton’s laws of movement together, and the considerably more settled rule of Archimedes with relative late progress in materials advancement. The magnetism of this concept is governing by Faraday’s Law; with rotor wavering the connected magnetic flux ψ with the copper coil will actuate in it, an electro motive force (emf) given by
e ( t ) = − d ψ d t
generating alternating current and voltage at coil ends, which can be connected to an electric load [
voltage generated = N × B A t
where,
N = turns of the copper wire;
B = magnetic field;
A = cross section area;
t = time.
Overtopping devices subsist of a ramp that drives the water of approaching waves to rise and overflow into a pool. Since the water surface of the pool is higher as compared to the ocean surface, therefore energy of the waves has been converted into potential energy. In this aspect, this concept resembles hydro power plant with the water being lead back into the sea through a turbine to extract the energy [
This study begins with literature review for collecting latest research findings related to wave energy convertors and their findings. The conceptual model was built in the second stage of this study. Designing and developing the wave energy convertor was the third stage of this study. Final stage was conducting experiments to validate the developed lab scale model. To test the conceptual model, a lab scale model is being built. The developed lab scale model is then tested in laboratory. The methodology of this study is shown in
The layout and machinery setup to test the model is shown in
Wave maker is used to produce longitudinal wave to simulate low height sea wave. The wave generated by this wave maker has ratio 1:10 compared to average wave data of Sarawak, Malaysia as reported by [
The wave energy convertor utilized the float to trap the oscillating force of wave and convert it to alternating current through emf induced by stator and rotor movements. The float moves in six degrees of freedom when interacting with the body and sea wave: pitch, roll, yaw, heave, surge and sway. The movement is illustrated in
The generated output from lab scale model has been continuously recorded. The significant findings are recorded in
generated is recorded to be 0.33 W with voltage of 0.412 V. The interesting part of this finding is that the standard deviation of all the collected data is relatively small. This signifies that even with small wave height, extracting energy from wave is possible and the output would be relatively consistent. Power takeoff
Parameter | Value | ||
---|---|---|---|
Min | Max | Average | |
Amplitude (A) | 3.2 cm | 5.2 cm | 3.86 cm |
Wave height (2A) | 6.4 cm | 10.4 cm | 7.72 cm |
Wavelength (λ) | 9 cm | 14 cm | 11.3 cm |
Frequency (f) | 0.025 Hz | 0.026 Hz | 0.026 Hz |
Parameter | Value |
---|---|
Density of seawater, ρ | 1025 kg/m3 |
Standard acceleration due to gravity, g | 9.81 m/s2 |
Water depth in tank | 28 cm |
Floating ball | |
Mass of buoy, Mb | 0.1 kg |
Inner radius of buoy | 14.0 cm |
Outer radius of buoy | 14.5 cm |
Height of buoy | 14.5 cm |
Generator | |
Length of copper wire | 427.5 m |
Turn of copper wire | 4050 turns |
Copper wire thickness | 0.5 mm |
Roll of layer | 15 layer |
Outputs | Value | Std. deviation | ||
---|---|---|---|---|
Min | Max | Average | ||
Voltage (V) | 0.036 | 0.412 | 0.224 | 0.092 |
Current (A) | 0.050 | 0.800 | 0.175 | 0.107 |
Power (W) | 0.002 | 0.330 | 0.039 | 0.026 |
system is needed to improve energy generation performance of such system. The example system that could be implemented with such system is shown in
or near the ocean surface away from the shoreline and may occupy a variety of ocean depths ranging from shallow to very deep water depending on the design and the mooring system.
The aim of this study is to produce wave energy convertor to be able to generate electricity from wave. The models are tested in laboratory and beach in Mukah, Sarawak. The results generated from both locations were consistent. However, by comparing results from both locations, the difference is more than 10-fold which validated the wave maker built in laboratory with 1:10 ratio. The advantage of using this type of wave energy convertor is that the area needed is small and there is no significant negative impact towards marine ecosystem within the extraction area. However, the limitation of this study is that it did not pair it with power takeoff system to store the electricity generated. On the other hand, energy generation from wave is presently too costly to be even considered as renewable energy. The costings of energy generation from wave are classified into: production, installation, maintenance, and power takeoff system. Due to the nature of variation in costings between different modes of extraction, it is not easy to determine the cost of production for wave energy conversion system. As an example, the cost of connecting electrical grid from shoreline is definitely lower compared to offshore convertors because less electrical cable to be installed and maintained. In addition, installation and maintenance costs are much higher for offshore conversion systems than shoreline since the offshore ones are more difficult to access. However, for future study, the focus is likely to reduce cost to a significant level to make it sustainable. Continuation of current study will most possibly generate more cheap and efficient devices that will bring down total production costs. Similarly, current studies in the field of ocean engineering focus on producing devices in limited quantity for research purposes. If produce large enough, the economy of scale will contribute to lowering the overall production cost and making this technology sustainable in the long run.
Wave energy is an alternative source of renewable energy that would contribute to tackling world energy crisis. Wave energy would be useful for countries that are surrounded by sea, particularly Malaysia. However, extracting wave energy has been one of the most challenging parts as most technologies for extracting this energy are still in infancy stage. This study explored the potential of generating electricity from low height wave energy. The recorded average electricity can be generated from the lab scale device which is 0.224 V, 0.175 A and 0.039 W. The data collected from Mukah Beach show that the maximum voltage recorded is 1.021 V, maximum current of 0.86 A and highest power of 0.878 W. By comparing results from both locations, the difference is almost 10-fold which validates the wave maker built in laboratory with 1:10 ratio. The standard deviation of all the outputs is small which indicates that the output generation from low height wave would be consistent. Although the output is small, it could be paired together to make a larger system to generate higher output. This study concludes that the developed lab scale model is useful for harnessing electrical energy from sea wave. The future direction of research would be to optimize the current method to maximize energy capture from sea wave. Another direction for future study is to make a system comprised of a large number of such devices to generate higher output.
The authors acknowledge the financial support received from University College of Technology Sarawak, Malaysia under university internal grant scheme (UCTS/research/4/2017/2). Authors are also pleased to offer special thanks to staffs of School of Engineering for their support.
The authors declare no conflicts of interest regarding the publication of this paper.
Lee, M.D., Ngu, H.J. and Shin, D.T.Y. (2019) Energy Extraction from Low Height Sea Wave in Sarawak near Shore Region. Open Journal of Optimization, 8, 47-58. https://doi.org/10.4236/ojop.2019.81005