Feasibility studies and system performance of 2 MW solar PV plant at UTeM

Feasibility studies and system performance of 2 MW solar PV plant at UTeM

Photovoltaic (PV) is becoming increasingly important as one of the most promising source of renewable energy to tackle climate change challenge. Four PV systems were installed in UTeM, namely polycrystalline, thin film, HIT, and monocrystalline with total capacity of 23.88 kW. In this regard, this r...

Full description

Saved in:
Bibliographic Details
Main Author: Abunima, Hamza Z. M.
Format: Thesis
Language:English
English
Published: 2015
Subjects:
TK Electrical engineering
Electronics Nuclear engineering
Online Access:http://eprints.utem.edu.my/id/eprint/16926/1/Feasibility%20Studies%20And%20System%20Performance%20Of%202%20MW%20Solar%20PV%20Plant%20At%20UTeM%2024%20Pages.pdf
http://eprints.utem.edu.my/id/eprint/16926/2/Feasibility%20studies%20and%20system%20performance%20of%202%20MW%20solar%20PV%20plant%20at%20UTeM.pdf
Tags: Add Tag
No Tags, Be the first to tag this record!
id my-utem-ep.16926
record_format uketd_dc
institution Universiti Teknikal Malaysia Melaka
collection UTeM Repository
language English
English
advisor Gan, Chin Kim
topic TK Electrical engineering
Electronics Nuclear engineering
spellingShingle TK Electrical engineering
Electronics Nuclear engineering
Abunima, Hamza Z. M.
Feasibility studies and system performance of 2 MW solar PV plant at UTeM
description Photovoltaic (PV) is becoming increasingly important as one of the most promising source of renewable energy to tackle climate change challenge. Four PV systems were installed in UTeM, namely polycrystalline, thin film, HIT, and monocrystalline with total capacity of 23.88 kW. In this regard, this research aims to evaluate the complete electrical design of a 2 MW grid-connected solar PV plant located in UTeM, Melaka. To achieve this, a site survey was carried out to inspect the installation site condition as well as the distance to the possible interconnection point. In addition, meteorological parameters were obtained from Meteonorm software. The existing PV systems in UTeM were used to export actual meteorological data at the proposed site. Subsequently, the PV modules orientation, array sizing, and cable sizing were determined based on the data obtained. Inverters and transformers for this PV plant were proposed and studied. The research highlights the key factors that affect the performance of solar PV power systems. Furthermore, the performance ratio and specific yield of the proposed plant were calculated to verify the plant design validity. Economic viability was also analyzed based on the system performance. It take into account the Feed-in Tariff (FiT) scheme. Financial models of the project were assessed and expressed as levelized cost of energy, simple pay back, internal rate of return, and present value of the net profit. The key findings suggest that the project has economic and environmental value which is socially beneficial to the community in Melaka state. The proposed solar PV plant is expected to generate an annual energy of approximately 2,395 MWh, with return on investment of 13.7%. Therefore, the proposed 2 MW solar PV power plant is technically and economically feasible.
format Thesis
qualification_name Master of Philosophy (M.Phil.)
qualification_level Master's degree
author Abunima, Hamza Z. M.
author_facet Abunima, Hamza Z. M.
author_sort Abunima, Hamza Z. M.
title Feasibility studies and system performance of 2 MW solar PV plant at UTeM
title_short Feasibility studies and system performance of 2 MW solar PV plant at UTeM
title_full Feasibility studies and system performance of 2 MW solar PV plant at UTeM
title_fullStr Feasibility studies and system performance of 2 MW solar PV plant at UTeM
title_full_unstemmed Feasibility studies and system performance of 2 MW solar PV plant at UTeM
title_sort feasibility studies and system performance of 2 mw solar pv plant at utem
granting_institution Universiti Teknikal Malaysia Melaka
granting_department Faculty Of Electrical Engineering
publishDate 2015
url http://eprints.utem.edu.my/id/eprint/16926/1/Feasibility%20Studies%20And%20System%20Performance%20Of%202%20MW%20Solar%20PV%20Plant%20At%20UTeM%2024%20Pages.pdf
http://eprints.utem.edu.my/id/eprint/16926/2/Feasibility%20studies%20and%20system%20performance%20of%202%20MW%20solar%20PV%20plant%20at%20UTeM.pdf
_version_ 1747833910148988928
spelling my-utem-ep.169262022-06-07T13:51:58Z Feasibility studies and system performance of 2 MW solar PV plant at UTeM 2015 Abunima, Hamza Z. M. TK Electrical engineering. Electronics Nuclear engineering Photovoltaic (PV) is becoming increasingly important as one of the most promising source of renewable energy to tackle climate change challenge. Four PV systems were installed in UTeM, namely polycrystalline, thin film, HIT, and monocrystalline with total capacity of 23.88 kW. In this regard, this research aims to evaluate the complete electrical design of a 2 MW grid-connected solar PV plant located in UTeM, Melaka. To achieve this, a site survey was carried out to inspect the installation site condition as well as the distance to the possible interconnection point. In addition, meteorological parameters were obtained from Meteonorm software. The existing PV systems in UTeM were used to export actual meteorological data at the proposed site. Subsequently, the PV modules orientation, array sizing, and cable sizing were determined based on the data obtained. Inverters and transformers for this PV plant were proposed and studied. The research highlights the key factors that affect the performance of solar PV power systems. Furthermore, the performance ratio and specific yield of the proposed plant were calculated to verify the plant design validity. Economic viability was also analyzed based on the system performance. It take into account the Feed-in Tariff (FiT) scheme. Financial models of the project were assessed and expressed as levelized cost of energy, simple pay back, internal rate of return, and present value of the net profit. The key findings suggest that the project has economic and environmental value which is socially beneficial to the community in Melaka state. The proposed solar PV plant is expected to generate an annual energy of approximately 2,395 MWh, with return on investment of 13.7%. Therefore, the proposed 2 MW solar PV power plant is technically and economically feasible. 2015 Thesis http://eprints.utem.edu.my/id/eprint/16926/ http://eprints.utem.edu.my/id/eprint/16926/1/Feasibility%20Studies%20And%20System%20Performance%20Of%202%20MW%20Solar%20PV%20Plant%20At%20UTeM%2024%20Pages.pdf text en public http://eprints.utem.edu.my/id/eprint/16926/2/Feasibility%20studies%20and%20system%20performance%20of%202%20MW%20solar%20PV%20plant%20at%20UTeM.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=96656&query_desc=kw%2Cwrdl%3A%20Feasibility%20Studies%20And%20System%20Performance%20Of%202%20MW%20Solar%20PV%20Plant%20At%20UTeM mphil masters Universiti Teknikal Malaysia Melaka Faculty Of Electrical Engineering Gan, Chin Kim 1. AlBarqouni, S., 2010. Re-Evaluation and Re-Design Stand-Alone PV Solar Lighting Projects in Gaza Strip, Palestine. Gaza: Islamic University of Gaza. 2. Ali, A., 2013. Smart Grids: Opportunities, Developments, and Trends. London: Springer Science and Business Media. 3. Appen, J., Braun, M., Stetz, T., and Diwold, K., 2013. Time in the Sun: The Challenge of High PV Penetration in the German Electric Grid. Power and Energy Magazine, IEEE 11 (2), pp.55 – 64. 4. Arlett, C., Bridges, B., et al., 1992. Solar and Ultraviolet Radiation. IARC Monographs on The Evaluation of Carcinogenic Risks to Humans, 5, Lyon, 11-18 February 1992, International Agency For Research On Cancer. 5. Balfour, J. and Shaw, M., 2011. Introduction to Photovoltaic System Design. Burlington: Jones and Bartlett Publishers. 6. Benghanem, M., 2011, Optimization of Tilt Angle for Solar Panel: Case Study for Madinah, Saudi Arabia. Applied Energy, 88, pp.1427–1433. 7. Berdner, J., 2009. Array to Inverter Matching. SolarPro Magazine, (2.1). 8. Bhattacharyya, S., 2014. Mini-Grids for Rural Electrification of Developing Countries: Analysis and Case Studies from South Asia. London: Springer Science and Business Media. 9. Brenndorfer, B. and Kennedy L., 1985. Solar Dryers: Their Role in Post-harvest Processing. London: Commonwealth Secretariat. 10. Chang, T., 2008. Study on the Optimal Tilt Angle of Solar Collector According to Different Radiation Types. International Journal of Applied Science and Engineering, 6 (2), pp.151–161. 11. Chen, S., Li, P., Brady, D. and Lehman, B., 2011. Optimum Inverter Sizing in Consideration of Irradiance Pattern and PV Incentives. Applied Power Electronics Conference and Exposition (APEC), 2011 Twenty-Sixth Annual IEEE. pp.982–988. 12. Chen, W., & Kai, Z., 2012. A Survey of Nuclear and Solar Energy. Advanced Materials Research, 535-537, pp.2116-2122. 13. Chuanchaiyakul, N. and Chaitusaney, S., 2013. Calculation of Shading Effect in PV Module by Graphical Method with Experimental Validation. Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON), 2013 10th International Conference. Krabi, 15-17 May 2013, IEEE. 14. Chubb, D., 2007. Fundamentals of Thermophotovoltaic Energy Conversion. Oxford: Elsevier. 15. Cox, J., Nair, N. and Ford, J., 2012. Evaluation of Solar and Meteorological Data Relevant to Solar Energy Technology Performance in Malaysia. Journal of Sustainable Energy and Environment, 3(3), pp.115-124. 16. Dahlan, N., El Azizi Mohammed, M., Abdullah, W. and Zain, Z., 2013. Economic feasibility study of a 16 kWp grid connected PV system at Green Energy Research Centre (GERC), UiTM Shah Alam. Business Engineering and Industrial Applications Colloquium (BEIAC), 2013 IEEE, pp.125-130, Langkawi, 7-9 April 2013, IEEE. 17. Deline, C., 2009. Partially Shaded Operation of A Grid-Tied PV System. National Renewable Energy Laboratory, 34th IEEE Photovoltaic Specialists Conference, Philadelphia, 7–12 June 2009. 18. Department of Standards Malaysia, 2010. MS 1837:2010, Installation of Grid- Connected Photovoltaic (PV) System. Cyberjaya: Department of Standards Malaysia. 19. Dhere, N., 2005. Reliability of PV Modules and Balance-of-System Components. Photovoltaic Specialists Conference, 2005. Conference Record of the Thirty-first, pp.1570–1576, 3-7 Jan. 2005, IEEE. 20. Doshi, T., D’Souza, N., Nguyen, L., Guan, T. and Zahur, N., 2013. The Economics of Solar PV in Singapore. International Journal of Engineering Technology (JET), 2 (1). 21. Duffie,A. and Beckman, W., 2013. Solar Engineering of Thermal Processes, 4th ed. New Jersey: John Wiley and Sons. 22. El-Sebaii, A., Al-Hazmi, F., Al-Ghamdi, A. and Yaghmour, S., 2010. Global, Direct and Diffuse Solar Radiation on Horizontal and Tilted Surfaces. Applied Energy, 87 (2), pp.568–576. 23. El-Shobokshy, M. and Hussein, F., 1993. Effect of the Dust with Different Physical Properties on the Performance of Photovoltaic Cells. Solar Energy, 51(6), pp.505–11. 24. Eltawil, M. and Zhao, Z., 2010. Grid-Connected Photovoltaic Power Systems: Technical and Potential Problems—A Review. Renewable and Sustainable Energy Reviews, 14, pp.112–129. 25. Enerdata, 2014. Electricity domestic consumption. [Online] Available at: https://yearbook.enerdata.net/electricity-domestic-consumption-data-by-region.html 26. [Accessed on 8 March 2014]. 27. Fraas, L. and Partain, L., 2010. Solar Cells and Their Applications. New Jersey: John Wiley and Sons. 28. GAISMA, 2014. Sun Path Diagram, Melaka, Malaysia. [Online] Available at: http://www.gaisma.com/en/location/melaka.html [Accessed on 25 April 2014]. 29. Gan, C. K., Tan, P. and Khalid, S., 2014. System Performance Comparison between Crystalline and Thin-Film Technologies under Different Installation Conditions. Clean Energy and Technology (CEAT), 2013 IEEE Conference, pp.362-367, Lankgkawi, 18- 20 Nov. 2013, IEEE. 30. Gavaskar, A., and cumming, L., 2001. Cost Evaluation Strategies for Technologies Tested Under the Environmental Technology Verification Program. Darby: DIANE Publishing. 31. Georgilakis, P., 2009. Spotlight on Modern Transformer Design. London: Springer Science and Business Media. 32. Gopalakrishnan, K., Khaitan, S. and Kalogirou, S, 2011. Soft Computing in Green and Renewable Energy Systems. Berlin: Springer Science and Business Media. 33. Häberlin, H., 2012. Photovoltaics System Design and Practice. Chichester: John Wiley and Sons. 34. Hren, S. and Hren ,R., 2010. A Solar Buyer's Guide for the Home and Office: Navigating the Maze of Solar Options, Incentives, and Installers. White River Junction: Chelsea Green Publishing. 35. Hussin, M., Hamid, M., Zain, M. and Rahman, R., 2010. An Evaluation Data of Solar Irradiation and Dry Bulb Temperature at Subang under Malaysian Climate. Control and System Graduate Research Colloquium (ICSGRC). 2010 IEEE (June), pp.55–60. 36. Hussin, Z., Omar, A., Zain, Z., and Shaari, S., 2012. Sizing Ratio of Inverter and PV Array for a-Si FS GCPV System in Malaysia’s Perspectives, 2012. Control and System Graduate Research Colloquium (ICSGRC), Shah Alam, 16-17 July 2012, IEEE. 37. Jones, P., 1991. Cloud-Cover Distributions and Correlations. Journal of Applied Meteorology, 31, pp.732-741. 38. JPPPET, 2008. National Renewable Energy Policy and Action Plan. Jawatankuasa Perancangan Pelaksanaan Pembekalan Elektrik Dan Tarif. 39. Kacira, M., Simsek, M., Babur, Y. and Demirkol, S., 2003. Determining Optimum Tilt Angles and Orientations of Photovoltaic Panels in Sanliurfa, Turkey. Renewable Energy, 29 (8), pp.1265–1275. 40. Kaltschmitt, M., Streicher, W. and Wiese, A., 2007. Renewable Energy: Technology, Economics and Environment. Berlin: Springer Science and Business Media 41. Virtuani, A., Pavanello D., and Friesen, G., 2010. Overview of Temperature Coefficients of Different Thin Film Photovoltaic Technologies. 25th European Photovoltaic Solar Energy Conference and Exhibition / 5th World Conference on Photovoltaic Energy Conversion, 6-10 September 2010, Valencia, pp. 4248- 4252 42. Kaushikaa, N., and Rai, A., 2007. An Investigation of Mismatch Losses in Solar Photovoltaic Cell Networks. Energy, 32 (5), pp.755–759. 43. Khatib, T.,Mohamed A. and Sopian, K., 2012. On The Monthly Optimum Tilt Angle of Solar Panel for Five Sites in Malaysia. Power Engineering and Optimization Conference (PEDCO) Melaka, Malaysia, 2012 IEEE International, pp.7–10. 44. King, D., Kratochvil, J. and Boyson, W., 1997. Temperature Coefficients for PV Modules and Arrays: Measurement Methods, Difficulties, and Results. Photovoltaic Specialists Conference, 1997, Conference Record of the Twenty-Sixth IEEE, pp.1183– 1186. 45. Kinney, M. and Raiborn, C., 2008. Cost Accounting: Foundations and Evolutions. Boston: Cengage Learning. 46. Kroposki, B., Emery, K., Myers, D. and Mrig, L., 1994. A Comparison of Photovoltaic Module Performance Evaluation Methodologies for Energy Ratings. Photovoltaic Energy Conversion, 1994. Conference Record of the Twenty Fourth. IEEE Photovoltaic Specialists Conference - 1994, 1994 IEEE First World Conference, 1, pp.858-862, Waikoloa, 5-9 December 1994, IEEE. 47. Kumi, H., and Hammond, A., 2013. Design and Analysis of a 1 MW Grid-Connected Solar PV System in Ghana. African Technology Policy Studies Network, ATPS 2013 No. 78. 48. Kurokawa, K., 2006. Energy from the Desert: Practical Proposals for Very Large Scale Photovoltaic Systems. London: Earthscan. 49. Lafferty, M., 2008. Module Power Tolerance Matters. SolarPro Magazine, (1.1). 50. Lau, C., Gan, C. K. and Tan, T., 2014. Evaluation of Solar Photovoltaic Levelized Cost of Energy for PV Grid Parity Analysis in Malaysia. International Journal of Renewable Energy Resources, pp.28-34. 51. Luque, A. and Hegedus, S., 2011. Handbook of Photovoltaic Science and Engineering. Chichester: John Wiley and Sons. 52. Macdonald, D., Cuevas, A., Kerr, M., Samundsett, C., Ruby, D., Winderbaum, S. and Leo, A., 2001. Texturing Industrial Multicrystalline Silicon Solar Cells. Solar Energy, 76 (1–3), pp.277–283. 53. Magee, S., 2010. Solar Photovoltaic Resource for Residential, Commercial and Utility Systems, CreateSpace Independent Publishing Platform. 54. Masters, G., 2013. Renewable and Efficient Electric Power Systems. New Jersey: John Wiley and Sons. 55. Masters, G., 2013. Renewable and Efficient Electric Power Systems. New Jersey: John Wiley and Sons. 56. Mayfield, R., 2011. Choosing a Grid-Tied Inverter. Home Power Magazine, (141). 57. McVeigh, J. and Mordue, J., 2003. Energy Demand and Planning. New York: Routledge. 58. Meteorological Malaysia department, 2014. General Climate of Malaysia. [Online] 59. Miller, A., and Lumby, B., 2012. Utility Scale Solar Power Plants, New Delhi: International Finance Corporation (IFC). 60. Mondola, J., Yohanisa, Y. and Nortonb, B., 2007. The Impact of Array Inclination and Orientation on The Performance of A Grid-Connected Photovoltaic System. Renewable Energy, 32 (1), pp.118–140. 61. Morris, N., 2006. Solar Power, North Mankato: Smart Apple Media. 62. Nguyen, D. and Lehman, B., 2006. Modeling and Simulation of Solar PV Arrays under Changing Illumination Conditions. Computers in Power Electronics, 2006. COMPEL '06. IEEE Workshops, pp.295–299, Troy, 16-19 July 2006, IEEE. 63. Patel, H. and Agarwal, V., 2008. MATLAB-Based Modeling to Study the Effects of Partial Shading on PV Array Characteristics. Energy Conversion, IEEE Transactions, 23 (1), pp.302–310. 64. Paulescu, M., Paulescu, E., Gravila, P. and Badescu, V., 2012. Weather Modeling and Forecasting of PV Systems Operation. London: Springer Science and Business Media. 65. Pearsall, N., 2011. PV research and development in Europe - A view from the Technology Platform. Photovoltaic Specialists Conference (PVSC), 2011 37th IEEE, pp.200 – 205. 66. Pidwirny, M., 2010. Understanding Physical Geography. Kelowna: Our Planet Earth Publishing. 67. Pizam, A., 2010. International Encyclopedia of Hospitality Management. Butterworth- Heinemann. 68. Rahman, M.and Zakaria, M., 2005. Modified Angstrom coefficients for the sunshine- irradiation correlation. Indian Journal of Radio and Space Physics, 34, pp.33-41. 69. Rajput, R., 2005. Basic Electrical Engineering. Bhopal: Firewall Media. 70. Ramabadran, R. and Mathur, B., 2009. Effect of Shading on Series and Parallel Connected Solar PV Modules. Modern Applied Science, 3 (10). 71. Rao, G., 2008. Agricultural Meteorology. New Delhi: Phi Learning Private Limited. 72. Remund, J. et al, 2014. Meteonorm Global Meteorological Database. Bern: METEOTEST. 73. Revankar, S. and Majumdar, P., 2014. Fuel Cells: Principles, Design, and Analysis. Boca Raton: CRC Press. 74. Rosa, A., 2008. Fundamental of renewable energy process, 2nd ed., California: Elsevier’s Science and Technology Rights Department. 75. SEDA, 2012. Annual Report 2012. Sustainable Energy Development Authority, Malaysia. 76. SEDA, 2014. FiT Rates for Solar PV. [Online] Available at: http://seda.gov.my/ 77. [Accessed on 8 November 2010]. 78. Sera, D., Teodorescu, R. and Rodriguez, P., 2007. PV Panel Model Based on Datasheet Values. Industrial Electronics, 2007. ISIE 2007. IEEE International Symposium, pp.2392–2396. 79. Shaari, S., Omar, A., Haris, A., and Sulaiman, S., 2010. Solar Photovoltaic power: designing Grid-Connected systems, 1st Edition, Ministry of Energy, Green Technology and Water, Malaysia /MBIPV, Malaysia. 80. SHARP, 2012. ND-RxxxA5 (60 cells) Datasheet. SHARP. 81. SHARP, 2012. NS-F130G5 Datasheet. SHARP. 82. Shayani, R. and Oliveira, A., 2011. A New Index for Absolute Comparison of Standalone Photovoltaic Systems Installed at Different Locations. IEEE Transactions on Sustainable Energy, 2 (4). 83. Solanki, C., 2009. Solar Photovoltaics: Fundamentals Technologies and Applications. 84. New Delhi: PHI Learning Private Limited. 85. Solanki, C., 2013. Solar Photovoltaic Technology and Systems: A Manual for Technicians, Trainers and Engineers. Delhi: PHI Learning Private Limited. 86. Sonnenenergie, D., 2013. Planning and Installing Photovoltaic Systems a Guide for Installers, Architects and Engineers, 3rd ed. New York: Routledge. 87. Squatrito, R., Sgroi, F., Tudisca, S., Trapani, A. and Testa, R., 2014. Post Feed-in Scheme Photovoltaic System Feasibility Evaluation in Italy: Sicilian Case Studies. Energies, 7(11), pp.7147-7165. 88. Stapleton, G. and Neill, S., 2012. Grid-Connected Solar Electric Systems: The Earthscan Expert Handbook for Planning, Design and Installation. New York: Routledge. 89. Sulaiman, S, Rahman, T., Musirin, I. and Shaari, S., 2011. Sizing Grid-Connected Photovoltaic System Using Genetic Algorithm. Industrial Electronics and Applications (ISIEA), 2011 IEEE Symposium, pp.505-509, Langkawi, 25-28 September 2011, IEEE. 90. Tam, A., 2013. Feed-In Tariff and Renewable Energy Fund. Parliamentary Research Officer, Malaysia. 91. Testa, A., Caro, S., and Scimone, T., 2013. Sizing of Step-Up Transformers for PV Plants through a Probabilistic Approach. WSEAS Transactions on Power Systems, 8 (3), p 114. 92. Tiwari, G. and Dubey, S., 2010. Fundamentals of Photovoltaic Modules and Their Applications. Cambridge: Royal Society of Chemistry. 93. TNB, 2013. TNB Annual Report. 94. Trupke, T., Green, M. and Würfel, P., 2002. Improving Solar Cell Efficiencies by Up- Conversion of Sub-Band-Gap Light. Journal of Applied Physics, 92 (7), pp 4117–4122. 95. Tsai, H., Ci-Siang, T., Yi-Jie S., 2008. Development of generalized photovoltaic model using MATLAB/Simulink. Proceedings of the World Congress on Engineering and Computer Science, October 22 - 24, San Francisco. 96. Twidell, J. and Weir, A., 2006. Renewable Energy Resources. Philadephia: Taylor and Francis. 97. Valentini, M., Raducu, A., Sera, D. and Teodorescu, R., 2008. PV Inverter Test Setup for European efficiency, Static and Dynamic MPPT Efficiency Evaluation. Optimization of Electrical and Electronic Equipment, 2008. OPTIM 2008. 11th International Conference, pp.433-438, Brasov, 22-24 May 2008, IEEE. 98. Wang, Y., Zhang, P., Li, W. and Kan'an, N., 2012. Comparative Analysis of the Reliability of Grid-Connected Photovoltaic Power Systems. Power and Energy Society General Meeting, 2012 IEEE, pp.1–8. 99. Webster, J. and Eren, H., 2014. Measurement, Instrumentation, and Sensors Handbook, 2nd ed., Boca Raton: CRC Press. 100. Wenham, S., Green, M., Watt, M., Corkish, R. and Sproul, A., 2013. Applied Photovoltaics. New York: Routledge. 101. Yeh, K. and Kwan, K., 1978. A Comparison of Numerical Integrating Algorithms by Trapezoidal, Lagrange, and Spline Approximation. Journal of Pharmacokinetics and Biopharmaceutics, 6 (1), pp.79-98. 102. Yuan, X. and Zhang, Y., 2012. Status and Opportunities of Photovoltaic Inverters in Grid-Tied and Micro-Grid Systems. Power Electronics and Motion Control Conference, 2006. IPEMC 2006. CES/IEEE 5th International, 1, pp.1-4. Shanghai, 14-16 August 2006, IEEE. 103. Zheng, D., 2013. International Conference on Frontiers of Environment, Energy and Bioscience. Lancaster: DEStech Publications. 104. Zorrilla, J., Piliougine, M., Carretero, J., Bernaola, P., Carpena, P., Mora, L., and Sidrach, M., 2011, Asnalysis of Dust Losses in Photovoltaic Modules. World Renewable Energy Congress, pp. 2985-2992, Linkoping, 8-13 May 2011,

Similar Items