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International Journal of Energy and Environmental Engineering

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01-01-2021 | Original Research

Spatio-temporal assessment and economic analysis of a grid-connected island province toward a 35% or greater domestic renewable energy portfolio: a case in Bohol, Philippines

Authors: Dave J. Pojadas, Michael Lochinvar Sim Abundo

Published in: International Journal of Energy and Environmental Engineering | Issue 2/2021

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Abstract

The year 2020 marks the start of the implementation of the Renewable Portfolio Standards in the Philippines. To raise the country’s renewable energy (RE) share to 35% by 2030 (aspirational target), an annual minimum incremental RE of 1% has been imposed to all mandated participants. This local-level policy implementation has allowed the assessment of RE resource adequacy to be carried out on a smaller geographical scale (i.e., province level). The case for grid-connected island provinces, such as our study area, can be more interesting because of the opportunity to self-sustainable energy production. In this paper, we assess the adequacy of domestic RE resources of Bohol province to reach this target by estimating the technical potential of solar, wind, biomass, and hydropower using spatio-temporal datasets. Then, for every identified potential RE project, we calculate the busbar levelized cost. We also evaluate the province's base RE share to assess the extent to which the technical potential can improve its RE penetration in four distinct domestic and imported energy generation scenarios. With 20 different scenarios of additional RE capacity, we generate RE portfolios for the minimum target RE share (35%), as well as the 50% and maximum. The results revealed that, when the country’s RE penetration continues, Bohol’s hydropower potential is not enough to meet the 35% target. Seasonal renewables are also insufficient for a 50% target. In several scenarios, the province’s energy self-sustainability can be possible at reasonable costs when variable RE technologies are included in the portfolio.

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Department of Energy: Providing rules and guidelines governing the establishment of the Renewable Portfolio Standard (RPS). Taguig City, Philippines, (2017)

Department of Energy, “2019 Power Statistics,” 2020. [Online]. https://www.doe.gov.ph/sites/default/files/pdf/energy_statistics/2019_power_statistic_03_gross_generation_per_plant_Type_per_grid.pdf. Accessed 30 Jun 2020

BEDAG-TWG: “Bohol Island Power Development Plan 2016–2045,” Bohol Provincial Planning and Development Office, Tagbilaran City, Philippines (2018)

Department of Energy, “2019 Power Statistics,” 2020. [Online]. https://www.doe.gov.ph/sites/default/files/pdf/energy_statistics/2019_power_statistic_09_monthly_system_peak_demand_per_visayas_sub_grid.pdf. Accessed 30 Jun 2020

Van Dael, M., Van Passel, S., Pelkmans, L., Guisson, R., Swinnen, G., Schreurs, E.: Determining potential locations for biomass valorization using a macro screening approach. Biomass Bioenergy 45, 175–186 (2012)

Baseer, M.A., Rehman, S., Meyer, J.P., Alam, M.M.: GIS-based site suitability analysis for wind farm development in Saudi Arabia. Energy 141, 1166–1176 (2017)

Jangid, J., et al.: Potential zones identification for harvesting wind energy resources in desert region of India—A multi criteria evaluation approach using remote sensing and GIS. Renew. Sustain. Energy Rev. 65, 1–10 (2016)

Höfer, T., Sunak, Y., Siddique, H., Madlener, R.: Wind farm siting using a spatial Analytic Hierarchy Process approach: a case study of the Städteregion Aachen. Appl. Energy 163, 222–243 (2016)

Tegou, L.I., Polatidis, H., Haralambopoulos, D.A.: Environmental management framework for wind farm siting: Methodology and case study. J. Environ. Manage 91, 2134–2147 (2010)

10.

Uyan, M.: GIS-based solar farms site selection using analytic hierarchy process (AHP) in Karapinar region, Konya/Turkey. Renew. Sustain. Energy Rev. 28, 11–17 (2013)

11.

Ali, S., Taweekun, J., Techato, K., Waewsak, J., Gyawali, S.: GIS based site suitability assessment for wind and solar farms in Songkhla, Thailand. Renew. Energy 132, 1360–1372 (2019)

12.

Watson, J.J.W., Hudson, M.D.: Landscape and Urban Planning Regional Scale wind farm and solar farm suitability assessment using GIS-assisted multi-criteria evaluation. Landsc. Urban Plan. 138, 20–31 (2015)

13.

Vasileiou, M., Loukogeorgaki, E., Vagiona, D.G.: GIS-based multi-criteria decision analysis for site selection of hybrid offshore wind and wave energy systems in Greece. Renew. Sustain. Energy Rev. 73, 745–757 (2017)

14.

Konstantinos, I., Georgios, T., Garyfalos, A.: A Decision Support System methodology for selecting wind farm installation locations using AHP and TOPSIS: Case study in Eastern Macedonia and Thrace region, Greece. Energy Policy 132, 232–246 (2019)

15.

Atici, K.B., Simsek, A.B., Ulucan, A., Tosun, M.U.: A GIS-based Multiple Criteria Decision Analysis approach for wind power plant site selection. Util. Policy 37, 86–96 (2015)

16.

M. Tavana, F. J. SantosArteaga, S. Mohammadi, and M. Alimohammadi, “A fuzzy multi-criteria spatial decision support system for solar farm location planning,” Energy Strateg. Rev., vol. 18, pp. 93–105, 2017.

17.

Shorabeh, S.N., Firozjaei, M.K., Nematollahi, O., Firozjaei, H.K., Jelokhani-Niaraki, M.: A risk-based multi-criteria spatial decision analysis for solar power plant site selection in different climates: A case study in Iran. Renew. Energy 143, 958–973 (2019)

18.

Noorollahi, Y., Yousefi, H., Mohammadi, M.: Multi-criteria decision support system for wind farm site selection using GIS. Sustain. Energy Technol. Assess. 13, 38–50 (2016)

19.

Ayodele, T.R., Ogunjuyigbe, A.S.O., Odigie, O., Munda, J.L.: A multi-criteria GIS based model for wind farm site selection using interval type-2 fuzzy analytic hierarchy process: The case study of Nigeria. Appl. Energy 228, 1853–1869 (2018)

20.

Sánchez-lozano, J.M., García-cascales, M.S., Lamata, M.T.: GIS-based onshore wind farm site selection using Fuzzy Multi-Criteria Decision Making methods. Evaluating the case of Southeastern Spain. Appl. Energy 171, 86–102 (2016)

21.

Villacreses, G., Gaona, G., Martínez-Gómez, J., Jijón, D.J.: Wind farms suitability location using geographical information system (GIS), based on multi-criteria decision making (MCDM) methods: The case of continental Ecuador. Renew. Energy 109, 275–286 (2017)

22.

Vafaeipour, M., Zolfani, S.H., Varzandeh, M.H.M., Derakhti, A., Eshkalag, M.K.: Assessment of regions priority for implementation of solar projects in Iran: New application of a hybrid multi-criteria decision making approach. Energy Convers. Manag. 86, 653–663 (2014)

23.

Perpiña Castillo, C., Batista e silva, F., Lavalle, C.: “An assessment of the regional potential for solar power generation in EU-28. Energy Policy 88, 86–99 (2016)

24.

Mahdy, M., Bahaj, A.B.S.: Multi criteria decision analysis for offshore wind energy potential in Egypt. Renew. Energy 118, 278–289 (2018)

25.

Mensour, O.N., El Ghazzani, B., Hlimi, B., Ihlal, A.: A geographical information system-based multi-criteria method for the evaluation of solar farms locations: a case study in Souss-Massa area, southern Morocco. Energy 182, 900–919 (2019)

26.

Gavériaux, L., Laverrière, G., Wang, T., Maslov, N., Claramunt, C.: Annals of GIS GIS-based multi-criteria analysis for offshore wind turbine deployment in Hong Kong. Ann. GIS 25(3), 207–218 (2019)

27.

Ghasemi, G., Noorollahi, Y., Alavi, H., Marzband, M., Shahbazi, M.: Theoretical and technical potential evaluation of solar power generation in Iran. Renew. Energy 138, 1250–1261 (2019)

28.

Dhunny, A.Z., Doorga, J.R.S., Allam, Z., Lollchund, M.R., Boojhawon, R.: Identification of optimal wind, solar and hybrid wind-solar farming sites using fuzzy logic modelling. Energy 188, 116056 (2019)

29.

Doorga, J.R.S., Rughooputh, S.D.D.V., Boojhawon, R.: Multi-criteria GIS-based modelling technique for identifying potential solar farm sites: a case study in Mauritius. Renew. Energy 133, 1201–1219 (2019)

30.

Asakereh, A., Soleymani, M., Sheikhdavoodi, M.J.: A GIS-based Fuzzy-AHP method for the evaluation of solar farms locations: case study in Khuzestan province, Iran. Sol. Energy 155, 342–353 (2017)

31.

Farthing, A., Carbajales-Dale, M., Mason, S., Carbajales-Dale, P., Matta, P.: Utility-Scale Solar PV in South Carolina: Analysis of Suitable Lands and Geographical Potential. Biophys. Econ. Resour. Qual. 1(2), 1–15 (2016)

32.

Deshmukh, R., Wu, G.C., Callaway, D.S., Phadke, A.: Geospatial and techno-economic analysis of wind and solar resources in India. Renew. Energy 134, 947–960 (2019)

33.

Pantusa, D., Tomasicchio, G.R.: Large-scale offshore wind production in the Mediterranean Sea. Cogent Eng. 6(1), 1–20 (2019)

34.

Schallenberg-Rodríguez, J., Montesdeoca, N.G.: Spatial planning to estimate the offshore wind energy potential in coastal regions and islands. Practical case: The Canary Islands. Energy 143, 91–103 (2018)

35.

Kim, T., Park, J., Maeng, J.: Offshore wind farm site selection study around Jeju Island, South Korea. Renew. Energy 94, 619–628 (2016)

36.

Anwarzai, M.A., Nagasaka, K.: Utility-scale implementable potential of wind and solar energies for Afghanistan using GIS multi-criteria decision analysis. Renew. Sustain. Energy Rev. 71, 150–160 (2017)

37.

Kim, C., Jang, S., Kim, T.Y.: Site selection for offshore wind farms in the southwest coast of South Korea. Renew. Energy 120, 151–162 (2018)

38.

Polo, J., Bernardos, A., Navarro, A.A., Fernandez-peruchena, C.M., Ramírez, L., Guisado, M.V.: Solar resources and power potential mapping in Vietnam using satellite-derived and GIS-based information. Energy Convers. Manag. 98, 348–358 (2015)

39.

Mentis, D., Siyal, S.H., Korkovelos, A., Howells, M.: A geospatial assessment of the techno-economic wind power potential in India using geographical restrictions. Renew. Energy 97, 77–88 (2016)

40.

Manomaiphiboon, K., Paton, C.P., Prabamroong, T., Rajpreeja, N., Assareh, N., Siriwan, M.: Wind energy potential analysis for Thailand: Uncertainty from wind maps and sensitivity to turbine technology. Int. J. Green Energy 14(6), 528–539 (2017)

41.

Wong, M.S., et al.: Estimation of Hong Kong’s solar energy potential using GIS and remote sensing technologies. Renew. Energy 99, 325–335 (2016)

42.

Kusre, B.C., Baruah, D.C., Bordoloi, P.K., Patra, S.C.: Assessment of hydropower potential using GIS and hydrological modeling technique in Kopili River basin in Assam (India). Appl. Energy 87, 298–309 (2010)

43.

Bódis, K., Monforti, F., Szabó, S.: Could Europe have more mini hydro sites? A suitability analysis based on continentally harmonized geographical and hydrological data. Renew. Sustain. Energy Rev. 37, 794–808 (2014)

44.

Pandey, A., Lalrempuia, D., Jain, S.K.: Assessment of hydropower potential using spatial technology and SWAT modelling in the Mat River, southern Mizoram, India. Hydrol. Sci. J. 60(10), 1651–1665 (2015)

45.

Tarife, R.P., Tahud, A.P., Gulben, E.J.G., Macalisang, H.A.R.C.P., Ignacio, M.T.T.: Application of geographic information system (GIS) in hydropower resource assessment: a case study in Misamis Occidental, Philippines. Int. J. Environ. Sci. Dev. 8(7), 507–511 (2017)

46.

Garegnani, G., Sacchelli, S., Balest, J., Zambelli, P.: GIS-based approach for assessing the energy potential and the financial feasibility of run-off-river hydropower in Alpine valleys. Appl. Energy 216, 709–723 (2018)

47.

Beccali, M., Columba, P., Alberti, V.D., Franzitta, V.: Assessment of bioenergy potential in Sicily: A GIS-based support methodology. Biomass Bioenerg. 33, 79–87 (2009)

48.

Grilli, G., Garegnani, G., Geri, F., Ciolli, M.: Cost-benefit analysis with GIS: an open source module for the forest bioenergy sector. Energy Procedia 107, 175–179 (2017)

49.

Teixeira, T.R., et al.: Forest biomass power plant installation scenarios. Biomass Bioenerg. 108, 35–47 (2018)

50.

Lopez, A., Roberts, B., Heimiller, D., Blair, N., Porro, G.: U.S. renewable energy technical potentials: a GIS-based analysis. National Renewable Energy Laboratory (2012). Available: https://www.nrel.gov/docs/fy12osti/51946.pdf. Accessed 2 Dec 2020

51.

Deng, Y.Y., et al.: Quantifying a realistic, worldwide wind and solar electricity supply. Glob. Environ. Chang. 31, 239–252 (2015)

52.

Nagababu, G., Kachhwaha, S.S., Savsani, V.: Estimation of technical and economic potential of offshore wind along the coast of India. Energy 138, 79–91 (2017)

53.

Hong, L., Möller, B.: Offshore wind energy potential in China: Under technical, spatial and economic constraints. Energy 36, 4482–4491 (2020)

54.

Soulouknga, M.H., Oyedepo, S.O., Doka, S.Y., Kofane, T.C.: Evaluation of the cost of producing wind-generated electricity in Chad. Int. J. Energy Environ. Eng. 11(2), 275–287 (2020)

55.

Ohunakin, O.S., Oyewola, O.M., Adaramola, M.S.: Economic analysis of wind energy conversion systems using levelized cost of electricity and present value cost methods in Nigeria. Int. J. Energy Environ. Eng. 4(2), 2–9 (2013)

56.

Ram, M., Child, M., Aghahosseini, A., Bogdanov, D., Lohrmann, A., Breyer, C.: A comparative analysis of electricity generation costs from renewable, fossil fuel and nuclear sources in G20 countries for the period 2015–2030. J. Clean. Prod. 199, 687–704 (2018)

57.

Maclaurin, G., et al.: The Renewable Energy Potential (reV) model: a geospatial platform for technical potential and supply curve modeling. National Renewable Energy Laboratory (2019). Available: https://www.nrel.gov/docs/fy19osti/73067.pdf. Accessed 2 Dec 2020

58.

Wu, G.C., Deshmukh, R., Ndhlukula, K., Radojicic, T., Reilly, J.: Renewable energy zones for the Africa clean energy corridor. International Renewable Energy Agency and Lawrence Berkeley National Laboratory, LBNL report number 187271 (2015). Available: https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2015/IRENA-LBNL_Africa-RE-_CEC_2015.pdf. Accessed 2 Dec 2020

59.

The World Bank: “Solar resource data: Solargis. (2019)

60.

Ramachandra, T.V., Krishna, S.V., Shruthi, B.V.: Decision support system to assess regional biomass energy Potential. Int. J. Green Energy 1(4), 407–428 (2005)

61.

Manzano-Agugliaro, F., Taher, M., Zapata-Sierra, A., Juaidi, A., Montoya, F.G.: An overview of research and energy evolution for small hydropower in Europe. Renew. Sustain. Energy Rev. 75, 476–489 (2017)

62.

IRENA: Renewable Power Generation Costs in 2017. International Renewable Energy Agency (2018)

63.

New England States Committee on Electricity: Renewable Resource Supply Curve Report (2012)

64.

NREL: 2019 Annual Technology Baseline (ATB) (2019)

65.

Mills, A., Phadke, A., Wiser, R.: Exploration of resource and transmission expansion decisions in the Western Renewable Energy Zone initiative. Energy Policy 39(3), 1732–1745 (2011)

66.

Department of Energy, “2019 Power Statistics,” 2020. [Online]. Available: https://www.doe.gov.ph/sites/default/files/pdf/energy_statistics/2019_power_statistic_04_gross_generation_per_plant_Type_per_visayas_sub_grid.pdf. Accessed: 2 Jul 2020.

67.

Department of Energy: Power Development Plan 2016–2040. Taguig City, Philippines (2017)

68.

Pojadas, D.J., Abundo, M.L.S.: Datasets for spatial analysis of potential inland renewable portfolio for Bohol, Philippines. Mendeley Data (2020). https://doi.org/10.17632/92xb8tnr9x.2CrossRef

69.

Intergovernmental Panel on Climate Change: Renewable energy sources and climate change mitigation (2012)

70.

AL Badwawi, R., Abusara, M., Mallick, T.: A review of hybrid solar PV and wind energy system. Smart Sci. 3(3), 127–138 (2015)

71.

USAID and the Department of Energy:“Greening the grid: Solar and Wind Grid Integration Study for the Luzon-Visayas System of the Philippines (2018)

72.

Notton, G., et al.: Intermittent and stochastic character of renewable energy sources: Consequences, cost of intermittence and benefit of forecasting. Renew. Sustain. Energy Rev. 87, 96–105 (2018)

73.

Jurasz, J., Canales, F.A., Kies, A., Guezgouz, M., Beluco, A.: A review on the complementarity of renewable energy sources: concept, metrics, application and future research directions. Sol. Energy 195, 703–724 (2020)

Title: Spatio-temporal assessment and economic analysis of a grid-connected island province toward a 35% or greater domestic renewable energy portfolio: a case in Bohol, Philippines
Authors: Dave J. Pojadas
Michael Lochinvar Sim Abundo
Publication date: 01-01-2021
Publisher: Springer Berlin Heidelberg
Published in: International Journal of Energy and Environmental Engineering / Issue 2/2021
Print ISSN: 2008-9163
Electronic ISSN: 2251-6832
DOI: https://doi.org/10.1007/s40095-020-00369-7

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