Implementation of a Data Logging System for a Small Scale Hydrokinetic Turbine
A suitable data logger is needed for data collection to demonstrate the practicality of Hydrokinetic Turbine (HKT) in a rural area of Sarawak application. HKT is a technology that extracts kinetic energy from river currents of almost zero elevation. Currently, commercial data loggers are embedded wi...
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A suitable data logger is needed for data collection to demonstrate the practicality of Hydrokinetic Turbine (HKT) in a rural area of Sarawak application. HKT is a technology that extracts kinetic energy from river currents of almost zero elevation. Currently, commercial data loggers are embedded with features that may not be usable for specific applications of the system. Additionally, they use excessive amounts of energy and are incompatible with certain transducers. Conventionally, Turbem software has been used for the HKT’s numerical simulations. However, estimations of electrical power are usually higher than the experimental values obtained, which causes some difficulty in determining the right range of transducers. In this study, to cater to the problem, a prediction graph was produced by the combination of the BEM theory and laboratory experiments. The data logger was implemented with an automatic data-file creation capability, the energy consumption of which would be very low, and it would be easily customizable. Transducers such as a voltage divider showed 0.7% of error, and a current transducer performed at 5%. Whereas a propeller type current meter and rotational speed meter performed at 1% of inaccuracy. The data logger demonstrated an acceptable accuracy and behavior of the logging performance test. The real time operation of the data logger was also verified in a field test. The results showed that the terminal voltage suffered ±2% of error, while the output current, rotational speed of generator, river velocity and output power showed about ±4%, ±21%, ±16% and ±5% of error, respectively. Therefore, the ranges of the data logger’s transducers are considered within the HKT system nominal and operational values, except the range of the current transducer. These readings demonstrated that the data logger could fulfill its function. |
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Diana, Ringgau |
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Diana, Ringgau |
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Diana, Ringgau |
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Implementation of a Data Logging System for a Small Scale Hydrokinetic Turbine |
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Implementation of a Data Logging System for a Small Scale Hydrokinetic Turbine |
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Implementation of a Data Logging System for a Small Scale Hydrokinetic Turbine |
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Implementation of a Data Logging System for a Small Scale Hydrokinetic Turbine |
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Implementation of a Data Logging System for a Small Scale Hydrokinetic Turbine |
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implementation of a data logging system for a small scale hydrokinetic turbine |
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Universiti Malaysia Sarawak (UNIMAS) |
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Faculty of Engineering |
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2020 |
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http://ir.unimas.my/id/eprint/34634/1/Implementation%20of%20a%20Data%20Logging%20System%20for%20a%20Small%20Scale%20hydrokinetic%20Turbine%20-%2024%20pgs.pdf http://ir.unimas.my/id/eprint/34634/4/Diana%20Anak%20Ringgau%20ft.pdf |
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my-unimas-ir.346342023-05-11T01:29:27Z Implementation of a Data Logging System for a Small Scale Hydrokinetic Turbine 2020-07-27 Diana, Ringgau T Technology (General) TA Engineering (General). Civil engineering (General) A suitable data logger is needed for data collection to demonstrate the practicality of Hydrokinetic Turbine (HKT) in a rural area of Sarawak application. HKT is a technology that extracts kinetic energy from river currents of almost zero elevation. Currently, commercial data loggers are embedded with features that may not be usable for specific applications of the system. Additionally, they use excessive amounts of energy and are incompatible with certain transducers. Conventionally, Turbem software has been used for the HKT’s numerical simulations. However, estimations of electrical power are usually higher than the experimental values obtained, which causes some difficulty in determining the right range of transducers. In this study, to cater to the problem, a prediction graph was produced by the combination of the BEM theory and laboratory experiments. The data logger was implemented with an automatic data-file creation capability, the energy consumption of which would be very low, and it would be easily customizable. Transducers such as a voltage divider showed 0.7% of error, and a current transducer performed at 5%. Whereas a propeller type current meter and rotational speed meter performed at 1% of inaccuracy. The data logger demonstrated an acceptable accuracy and behavior of the logging performance test. The real time operation of the data logger was also verified in a field test. The results showed that the terminal voltage suffered ±2% of error, while the output current, rotational speed of generator, river velocity and output power showed about ±4%, ±21%, ±16% and ±5% of error, respectively. Therefore, the ranges of the data logger’s transducers are considered within the HKT system nominal and operational values, except the range of the current transducer. These readings demonstrated that the data logger could fulfill its function. Universiti Malaysia Sarawak, (UNIMAS) 2020-07 Thesis http://ir.unimas.my/id/eprint/34634/ http://ir.unimas.my/id/eprint/34634/1/Implementation%20of%20a%20Data%20Logging%20System%20for%20a%20Small%20Scale%20hydrokinetic%20Turbine%20-%2024%20pgs.pdf text en public http://ir.unimas.my/id/eprint/34634/4/Diana%20Anak%20Ringgau%20ft.pdf text en validuser https://www.akademisains.gov.my/asmsj/ masters Universiti Malaysia Sarawak (UNIMAS) Faculty of Engineering Alegria, F. C. and Travassos, F. A. M. (2008) ‘Implementation Details of an Automatic Monitoring System Used on a Vodafone Radiocommunication Base Station’, Engineering Letters, 16(4), p. 529. Aling, L. A. et al. 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E.A Azrulhisham (2018) ‘Potential Evaluation of Vertical Axis Hydrokinetic Turbine Implementation in Equatorial River Potential Evaluation of Vertical Axis Hydrokinetic Turbine Implementation in Equatorial River’, Journal of Physics: Conference Series, 1072(1), pp. 1–6. Fuentes, M. et al. (2014) ‘Design of an accurate, low-cost autonomous data logger for PV system monitoring using ArduinoTM that complies with IEC standards’, Solar Energy Materials and Solar Cells. Elsevier, 130, pp. 529– 543. ‘HOBO U12 4-Channel External Data Logger - U12-006’ (2015) onset HOBO Data Loggers. United State of America. Available at: http://www.onsetcomp.com/products/data-loggers/u12- 006. Ling, T. Y. et al. (2017) ‘Assessment of water quality of Batang Rajang at Pelagus area, Sarawak, Malaysia’, Sains Malaysiana, 46(3), pp. 401–411. Mahzan, N. N. et al. (2013) ‘Design of data logger with multiple SD cards’, CEAT 2013 - 2013 IEEE Conference on Clean Energy and Technology, pp. 175–180. Melo, E. S., Rosa, P. C. and Ribeiro, E. R. (2013) ‘Electronic load controller of a micro-hydro generator for stand-alone operation’, 2013 Brazilian Power Electronics Conference, COBEP 2013 - Proceedings, pp. 718–723. Pattanaik, B. et al. (2017) ‘Design and development of subsea power and instrumentation system for new ocean current turbine power module’, 2016 IEEE Annual India Conference, INDICON 2016. Riglin, J. D. (2016) Design , Modeling , and Prototyping of a Hydrokinetic Turbine Unit for River Application, PhD thesis, Lehigh University, USA. Saupi, A. F. et al. (2018) ‘An illustrated guide to estimation of water velocity in unregulated river for hydrokinetic performance analysis studies in East Malaysia’, Water (Switzerland), 10(10). Siew, Z. W. et al. (2012) ‘Design and development of a tablet based real time wireless data logger’, 2012 IEEE Global High Tech Congress on Electronics, pp. 111–116. Sondkar, S. Y., Dudhane, S. and Abhyankar, H. K. (2012) ‘Frequency measurement methods by signal processing techniques’, Procedia Engineering, 38, pp. 2590–2594. Thomas, K. et al. (2012) ‘A Permanent Magnet Generator for Energy Conversion from Marine Currents: No Load and Load Experiments’, ISRN Renewable Energy, 2012, pp. 1– 7. |