skip to main content

Potential Effect and Analysis of High Residential Solar Photovoltaic (PV) Systems Penetration to an Electric Distribution Utility (DU)

Caraga State University, Philippines

Published: 4 Nov 2016.
Editor(s): H Hadiyanto

Citation Format:
Abstract

The Renewable Energy Act of 2008 in the Philippines provided an impetus for residential owners to explore solar PV installations at their own rooftops through the Net-Metering policy. The Net-Metering implementation through the law however presented some concerns with inexperienced electric DU on the potential effect of high residential solar PV system installations. It was not known how a high degree of solar integration to the grid can possibly affect the operations of the electric DU in terms of energy load management. The primary objective of this study was to help the local electric DU in the analysis of the potential effect of high residential solar PV system penetration to the supply and demand load profile in an electric distribution utility (DU) grid in the province of Agusan del Norte, Philippines. The energy consumption profiles in the year 2015 were obtained from the electric DU operating in the area. An average daily energy demand load profile was obtained from 0-hr to the 24th hour of the day based from the figures provided by the electric DU. The assessment part of the potential effect of high solar PV system integration assumed four potential total capacities from 10 Mega Watts (MW) to 40 MW generated by all subscribers in the area under study at a 10 MW interval. The effect of these capacities were measured and analyzed with respect to the average daily load profile of the DU. Results of this study showed that a combined installations beyond 20 MWp coming from all subscribers is not viable for the local electric DU based on their current energy demand or load profile. Based from the results obtained, the electric DU can make better decisions in the management of high capacity penetration of solar PV systems in the future, including investment in storage systems when extra capacities are generated.

Article History: Received July 15th 2016; Received in revised form Sept 23rd 2016; Accepted Oct 1st 2016; Available online

How to Cite This Article: Dellosa, J. (2016) Potential Effect and Analysis of High Residential Solar Photovoltaic (PV) Systems Penetration to an Electric Distribution Utility (DU). Int. Journal of Renewable Energy Development, 5(3), 179-185.

http://dx.doi.org/10.14710/ijred.5.3.179-185

Fulltext View|Download
Keywords: residential solar PV system; solar photovoltaic (PV) system penetration; net-metering; energy demand; load profile
Funding: Agusan del Norte Electric Cooperative, Inc.

Article Metrics:

  1. Almendras, J. (2012) Towards a Sustainable and Competitive Power Sector. Department of Energy, Philippine Government
  2. Asian Development Bank (2009) The Economics of Climate Change in Southeast Asia: A Regional Review
  3. Byrne, R.H., Concepcion, R., Neely, J., Wilches-Bernal, F., Elliot, R., Lavrova, O.& Quiroz, J. (2016) Small Signal Stability of the Western North American Power Grid with High Penetrations of Renewable Generation. Proceedings of the Photovoltaic Specialists Conference. Oregon, USA
  4. Damiel, D. (2014) Discussions on net-metering. Agusan del Norte Electric Cooperative, Inc. (ANECO)
  5. Dellosa, J. T. (2015). Financial payback of solar PV systems and analysis of the potential impact of Net-Metering in Butuan City, Philippines. In Environment and Electrical Engineering (EEEIC), 2015 IEEE 15th International Conference on (pp. 1453-1458)
  6. Department of Energy (2008) Philippine Energy Situation. Energy Situationer
  7. Ducut, Z. (2013) Rules Enabling the Net-Metering for Renewable Energy. Energy Regulations Commission (ERC), Philippines
  8. Elliot, R., Byrne, R., Ellis, A. & Grant, L. (2014) Impact of increased photovoltaic generation on inter-area oscillations in the Western North American power system. Proceedings of the 2014 IEEE PES General Meeting. National Harbor, MD, USA
  9. Green Peace International (2005) The Environmental Impacts of Coal
  10. Green Peace International (2014). Greenpeace statement ahead of the State of the Nation address: PNoy’s legacy: more coal plants than those built by all his predecessors combined?
  11. Inter-government Panel on Climate Change (2013) Climate Change 2013: The Physical Science Basis
  12. Inter-government Panel on Climate Change (2014) Climate Change 2014 Synthesis Report, Summary for Policy Makers
  13. International Energy Agency (2013) South East Asia Energy Outlook, Special Report
  14. Jimenez, H., Calleja, H., Gonzales, R., Huacuz, J. & Lagunas, J. (2006) The impact of photovoltaic systems on distribution transformer: a case study. Journal of Energy Conversion and Management, 47, 311-321
  15. Katiraei, F., Mauch, K. & Dignard-Bailey, L. (2007) Integration of Photovoltaic Power Systems in High-Penetration Clusters for Distribution Networks and Mini-Grids. International Journal of Distributed Energy Resources, 3(3)
  16. Kolhe, M., Khot, P. (2015) Impact of the Coal Industry on Environment. International Journal of Advanced Research in Computer Science and Management Studies, 3(1), 66-73
  17. Köppinger, P. (2014) Climate Report 2014 Energy Security and Climate Change Worldwide
  18. Latour, M., Fontaine, B., Masson, G., Rekinger, M., Theologitis, I. & Papoutsi, M. (2013) Global market outlook for photovoltaics 2013-2017. EPIA, 5-6
  19. Legarda, L. (2008) Republic Act 9513: Renewable Energy Act of 2008
  20. Liss, B. (2013) Accompanying the Philippines on the road towards sustainable energy supply. Gesellschaft fur Internationale Zusammenarbeit (GIZ)
  21. Mather, B., Cheng, D., Seguin, R., Hambrick, J. & Broadwater, R. (2016) Photovoltaic (PV) Impact Assessment for Very High Penetration Levels. IEEE Journal of Photovoltaics, 295-300
  22. Munnik, V., Hochmann, G., Hlabane, M. & Law S. (2010) The Social and Environmental Consequences of Coal Mining in South Africa. Environmental Monitoring Group, Cape Town, South Africa and Both ENDs, Amsterdam, The Netherlands, January 2010, http://www.bothends.org/uploaded_files/uploadlibraryitem/1case_study_South_Africa_updated.pdf
  23. Panzer, C., Balabanov, T., Pabon, V., Ulreich, S., Krämer, L., Chaturvedi, P., Diodato, A., Khatib, H., Gulczynski, D., Miga-Papadopol, P., Day, B., Camacho, M., Auchariyamet, S., Eakponpisan, P., Shastri, A., Echinope, M. and Olson, S. (2016) Variable Renewables Integration in Electricity Systems: How to Get It Right, World Energy Perspectives, Renewables Integration, World Energy Council. https://www.worldenergy.org/wp-content/uploads/2016/09/Variable-Renewables-Integration-in-Electricity-Systems-2016-How-to-get-it-right-_-Full-Report-1.pdf
  24. Rabbee, F., Wadud, A.M.A, Zaman, M.T. and Rahman, M.R (2013) Renewable Energy: An Ideal Solution of Energy Crisis and Economic Development in Bangladesh. Global Journal of Researches in Engineering Electrical and Electronics Engineering, Volume 13(5), 19-27
  25. Thoma, M., Laukamp, H., Meyer, T. & Erge, T. (2004) Impact of a large capacity of distributed PV production on the low voltage grid. Proceedings of the 19th European Photovoltaic Solar Energy Conference. Paris, France
  26. Tselepis, S. & Neris, A. (2006) Impact of increasing penetration of PV and wind generation on the dynamic behaviour of the autonomous grid of the island of Kythnos, Greece. 3rd European Conference on PV Hybrids and Mini-grids, Aix en Provence
  27. United States Energy Information Administration (2013) International Energy Outlook 2013
  28. United States Environmental Protection Agency (2012) The Emissions & Generation Resource Integrated Database for 2012 (eGRID2012) Technical Support Document
  29. Zwickel, T., Edenhofer, O., Pichs-Madruga, R., Sokona, Y., Seyboth, K., Matschoss, P., Kadner, S., Eickemeier, P., Hansen, G., von Stechow & C., Schlömer, S. (2012) Special Report on Renewable Energy Sources and Climate Change Mitigation

Last update:

  1. Optimal sizing and assessment of a hybrid energy based AC microgrid

    S. Madhura, Venkatesh Boddapati. Materials Today: Proceedings, 49 , 2022. doi: 10.1016/j.matpr.2021.02.133
  2. GIS-based multi-criteria wind farm site selection methodology

    S. Rehman, M.A. Baseer, L.M. Alhems. FME Transactions, 48 (4), 2020. doi: 10.5937/fme2004855R
  3. A Heuristic Approach to Siting and Design Optimization of an Onshore Wind Farm Layout

    Shafiqur Rehman, Abdul Baseer Mohammed, Luai Alhems. Energies, 13 (22), 2020. doi: 10.3390/en13225946
  4. Numerical simulation of PV cooling by using single turn pulsating heat pipe

    Hossein Alizadeh, Roghayeh Ghasempour, Mohammad Behshad Shafii, Mohammad Hossein Ahmadi, Wei-Mon Yan, Mohammad Alhuyi Nazari. International Journal of Heat and Mass Transfer, 127 , 2018. doi: 10.1016/j.ijheatmasstransfer.2018.06.108
  5. Optimal Sizing and Analysis of Solar PV, Wind, and Energy Storage Hybrid System for Campus Microgrid

    Furkan Ahmad, Mohammad Saad Alam. Smart Science, 6 (2), 2018. doi: 10.1080/23080477.2017.1417005
  6. A study on traction control system for solar panel on vessels

    Xuan Phuong Nguyen, Van Huong Dong. INTERNATIONAL CONFERENCE ON EMERGING APPLICATIONS IN MATERIAL SCIENCE AND TECHNOLOGY: ICEAMST 2020, 2235 , 2020. doi: 10.1063/5.0007708
  7. Resource Assessment of a Floating Solar Photovoltaic (FSPV) System with Artificial Intelligence Applications in Lake Mainit, Philippines

    J. Dellosa, E. V. Palconit. Engineering, Technology & Applied Science Research, 12 (2), 2022. doi: 10.48084/etasr.4863

Last update: 2024-10-11 17:44:56

  1. Multi-criteria decision making (MCDM) approach for selecting solar plants site and technology: A review

    Ghasempour R.. International Journal of Renewable Energy Development, 8 (1), 2019. doi: 10.14710/ijred.8.1.15-25
  2. GIS-based multi-criteria wind farm site selection methodology

    S. Rehman, M.A. Baseer, L.M. Alhems. FME Transactions, 48 (4), 2020. doi: 10.5937/fme2004855R
  3. Numerical simulation of PV cooling by using single turn pulsating heat pipe

    Hossein Alizadeh, Roghayeh Ghasempour, Mohammad Behshad Shafii, Mohammad Hossein Ahmadi, Wei-Mon Yan, Mohammad Alhuyi Nazari. International Journal of Heat and Mass Transfer, 127 , 2018. doi: 10.1016/j.ijheatmasstransfer.2018.06.108
  4. Composition assessment of a power distribution system with optimal dispatching of distributed generation

    Afzal M.. International Journal of Renewable Energy Development, 9 (3), 2020. doi: 10.14710/ijred.2020.31428
  5. Optimal Sizing and Analysis of Solar PV, Wind, and Energy Storage Hybrid System for Campus Microgrid

    Furkan Ahmad, Mohammad Saad Alam. Smart Science, 6 (2), 2018. doi: 10.1080/23080477.2017.1417005