The installed power plant capacity in Indonesia until 2018 was 56.509.53 MW. This capacity was supplied by PLN of 40.486.60 MW by private sector of 13.350.79 MW, and by rental power plants of 2.672.14 MW. Most of the sources of electricity generation in Indonesia are coal energy of 49%, PLTG/PLTGU/PLTMG of 27% from PLTD of 12%, PLTA/PLTM of 11%, PLTP of 3%, and the rest comes from RE. The capacity of this power plant continues to increase every year from 48.739 MW in 2014 [23,24].
Petroleum production in Indonesia in 2018 decreased to 283 million/barrels (778 thousand b/d) compared to 2009 of 346 million/barrels (949 thousand b/d) [2,25,26]. The decline in oil production was caused by several factors such as production wells that were no longer feasible. While the development of new wells for production was still very limited. However, until now, Indonesia has a dependency on petroleum. The available petroleum cannot meet the needs of the existing refineries, so the government of Indonesian continues to import from other countries such as the Middle East. The number of Indonesia’s oil imports from 2009-2018 reached more than 35% as shown in Fig. 2. (a).
In general, energy demand in 2018 reached 465.07 million barrels/year including biodiesel fuel. Total domestic oil production is 278.01 barrels, while the total amount of oil imported by the government of Indonesian from oil-producing countries is 165.04 barrels/year. The comparison of total oil production and import each year can be seen in Fig. 2 (b). In 2017, Indonesia was ranked the third-largest country in terms of crude oil imports after Singapore and Thailand at US$21.04 and US$ 20.1 billion, respectively. The total of Indonesia’s oil imports was US$8.1, Malaysia was US$3.9, the Philippines was US$3.5, Brunei Darussalam was US$1.6, and Vietnam of US$93.2 million [27].
Natural gas consumption in Indonesia in 2018 was 1.7 million MMSCF for the industrial sector of feedstock/energy, electricity generation, city gas (household and commercial), and gas lift [2]. In addition, this natural gas is also an export commodity with an annual average of 1.2 million MMSCF in the form of LNG and gas. LPG consumption in 2018 was 7.5 million/tons, supplied from import of 74% (5.5 million/tons) and domestic production of 26% (2 million/tons). In 2018, the total percentage of LNG exports to natural gas decreased to 40% compared to 2009 by 50% as shown in Fig. 3.
Conversion of kerosene to LPG by the government has increased the LPG consumption in the community. Meanwhile, the availability of LPG produced domestically is still very limited. Consumption of 3 kg LPG continues to increase due to subsidies from the government. Therefore, the government must anticipate this increase since in the implementation, it is considered mistarget.
3.1 Potential and Implementation RE in Indonesia
The availability of renewable energy which is quite a lot can replace the dependence of fossil energy. This can be done if the existing renewable energy can be utilized optimally. Thus, the global government’s commitment to reduce greenhouse gas emissions can be achieved. As a result, it has encouraged the Government to increase the role of RE sustainably as part of maintaining domestic energy security and independence. Following the Government Regulation No. 79 of 2014 on the National Energy Policy, the target of RE in 2025 is at least 23% and 31% in 2050. Indonesia has very abundant potential of RE to achieve the primary energy mix target.
The total RE potential in Indonesia reached 441.7 GW in 2019 with an installed power of 9.07 GW or only 2% of the total that can be utilized. Total RE of 441.7 GW is sourced from tidal/wave energy potential of 17.9 GW, geothermal of (potential resources 11.0 GW, reserve 17.7 GW and realization of PLTP 1.808 GW), bioenergy of (potential 32.6 GW, BBN 200 Bph and Realization of PLTBio 1.840 GW), wind power potential of 60.6 GW and realization of PLTB 1.1 MW, and solar power potential of 207.08 GW and realization of PLTS 0.090 GWp show in Fig. 1. While the implementation of RE sources only reached 2% from geothermal of 1.949 GW, bioenergy of 1.858 GW, wind of 147.01 M, hydro of 5.417 GW, and solar power of 0.135 GW as shown in Fig. 1 [28,29].
The highest geothermal energy potential is found in Sumatera Utara at 970 MW and followed by West Java at 790 MW. While Aceh Province is ranked third with 590 MW, East Java of 405 MW, Lampung of 395 MW, Maluku of 290 MW, West Sumatera of 270 MW, Bengkulu and Central Java of 245 MW. Meanwhile, the other provinces show geothermal energy potential is below 200 MW as shown in Fig. 4.(a). The total geothermal energy in Indonesia are 5.395 MW spread in 21 provinces [28,29].
Total hydroelectric energy potential (PLTA) in Indonesia is 12.281 MW spread in 17 provinces. The highest potentials of hydropower energy are spread in South Sumatera, East Java and West Java, respectively, 2.368 MW, 2.168 MW, and 2.138 MW. Meanwhile the Province of Aceh has a hydropower energy potential of 1.595 MW, Central Sulawesi of 670 MW, Jambi of 374 MW, Central Java of 360 MW, West Kalimantan of 198 MW, East Kalimantan of 168 MW, and Maluku of 156 MW. Meanwhile, the provinces with a hydropower energy potential below 100 MW are shown in Fig. 4 (b) [28,29].
One of the RE sources in Indonesia that cannot be utilized properly is solar energy. The potential of solar energy can be found almost in all provinces in Indonesia. However, the utilization of this energy has not been optimal, even though solar energy can be used as electrical energy, heating, cooling, etc. The highest potential of solar energy is found in the province of West Kalimantan of 20.113 MW. Furthermore, the potentials of solar energy can be found the provinces of South Sumatra, East Kalimantan, and North Sumatera, respectively, 17.233 MW, 13.479 MW, and 11.51 MW. Meanwhile, the least solar energy potentials are found in Jakarta and Bangka Belitung, respectively, 225 MW and 281 MW as shown in Fig. 5. The total utilization of solar energy in Indonesia in 2018 was 0.05% of the total potential. However, the government’s target for the solar energy utilization in 2025 is 1.047 MWp compared to 94.42 MWp in 2018 [30].
The total potential of RE in Indonesia such as geothermal, solar, bioenergy, wind, hydro, mini-micro hydro, and tidal/wave reaches 239.970 MW. Meanwhile, the RE installed capacity in 2019 is only 8.215.5 MW. The total of new RE that can be utilized until 2019 reached 17.452%. It is assumed to be very small compared to the existing potential as shown in Table 1.
Table 1. RE potential, installed and utilization in Indonesia [31,32]
Energy Type
|
Geothermal (MW)
|
Solar (MW)
|
Bioenergy (MW)
|
Wind (MW)
|
Hydro (MW)
|
Mini-micro Hydro (MW)
|
Tidal wave (MW)
|
Potential
|
29.544
|
4.80 kWh/m2/h
|
32.654
|
60.647
|
75.091
|
19.385
|
17.989
|
Installed capacity
|
1.438.5
|
78.5
|
1.671.0
|
3.1
|
4.826.7
|
197.4
|
0.3
|
Utilization
|
4.9%
|
0.04%
|
5.1%
|
0.01%
|
6.4%
|
1.0%
|
0.002%
|
The total target of RE development during the period 2019-2028 shows that the use of RE is more dominant. This is because conventional energy reserves (fossil) are running low so the government has to import substantial oil. With the development of RE, the government can reduce oil imports that have continued to soar in recent decades. Development for hydropower energy power plants is the highest compared to other energy. Meanwhile PLTP, PLT Bio-Fuel, PLTMH and PLTS were ranked second, third, fourth, and five respectively, during the period 2019-2028 as shown in Fig. 6 [2]. Meanwhile, in the sixth, seventh and eighth place, respectively PLT Bayu, PLT Biomass and PLT Wave.
RE development in Indonesia is generally spread in five islands including Sumatra, Kalimantan, Java-Bali, Sulawesi, and Maluku and Papua as shown in Table 2. The highest total capacity target for RE is in Sumatra Island with a total capacity of 8.852 MW. While the highest potential for RE that has not been utilized during the 2017-2026 period is found in Sulawesi Island at 4.155 MW. The type of RE for the highest installed capacity is hydropower energy of 12.342 MW. While the potential of hydropower energy that has not been utilized is 6.869 MW. The total installed capacity of hydropower energy in Java-Bali is higher than Sumatra Island and other islands. However, the potential of hydropower energy during the period 2017-2026 does not exist. Meanwhile, the highest potential of hydropower energy that has not been utilized is in Sulawesi Island of 3.852 MW. The total installed capacity of RE in Indonesia until 2026 reaches 21.549 MW and the potential for RE that has not been utilized in the same period is 9.3889 MW [29,33,34].
Overall, energy sourced from biomass found in 27 provinces in Indonesia is 23.335.07 MW. The most biomass energy sources are in Riau province of 4.169.6 MW and followed by the provinces of North Sumatra and South Sulawesi of 2.796.01 MW and 2.061.04 MW, respectively. Meanwhile, the smallest biomass energy source is in Jakarta of 0.5 MW as shown in Fig. 7 (a). The small potential of biomass in Jakarta is caused by the area of mapping and has been met by housing residents. Whereas for forest areas, it is almost certain that there are no more in Jakarta. Meanwhile, if compared to the forest area in Riau and Sumatra Utara provinces, it is far more than Jakarta. Furthermore, the potential source of biogas energy in Indonesia is also very adequate when used for energy, especially for electricity generation. The first most potential sources of biogas energy are in Jakarta, Banten, and North Sumatera with 126.01 MW, 118.06 MW and 115.05 MW, respectively, as shown in Fig. 7 (b) [35,36]. The potential for biogas energy in Indonesia in 2016 reached 2.603 MW. The potential of biogas is much smaller than the potential of biomass reaching 30.051 MW. However, it is predicted that the potential of biogas will continue to increase along with the increase in other renewable energy sources, mainly from agricultural products. The high biogas in these three provinces can be due to the high number of the population so that the potential for biogas produced is more than the other provinces.
Table 2. RE capacity and potential in Indonesia 2017-2026
Regions
|
Sumatera
|
Kalimantan
|
Jawa-Bali
|
Sulawesi
|
Maluku & Papua
|
Indonesia Total
|
Generator RE
|
Capacity (MW)
|
Potential
|
Capacity (MW)
|
Potential
|
Capacity (MW)
|
Potential
|
Capacity (MW)
|
Potential
|
Capacity (MW)
|
Potential
|
Capacity (MW)
|
Potential
|
PLTP
|
3.305
|
N/A
|
N/A
|
N/A
|
2.510
|
N/A
|
400
|
N/A
|
75
|
N/A
|
6.290
|
N/A
|
PLTA
|
4.284
|
1.193
|
1.056
|
1.804
|
4.562
|
N/A
|
2.323
|
3.852
|
118
|
20
|
12.342
|
6.869
|
PLTMH
|
938
|
752
|
10
|
N/A
|
437
|
N/A
|
221
|
N/A
|
43
|
N/A
|
1.694
|
752
|
PLT Solar
|
5
|
59
|
N/A
|
12
|
N/A
|
200
|
52
|
38
|
N/A
|
6
|
57
|
315
|
PLT Bayu
|
N/A
|
200
|
150
|
N/A
|
250
|
823
|
170
|
5
|
N/A
|
N/A
|
570
|
1.028
|
PLT Biomass
|
274
|
135
|
41
|
30
|
206
|
N/A
|
21
|
10
|
55
|
N/A
|
597
|
175
|
PLT Wave
|
N/A
|
N/A
|
N/A
|
N/A
|
N/A
|
N/A
|
N/A
|
250
|
N/A
|
N/A
|
N/A
|
250
|
PLT Bio-Fuel
|
411
|
N/A
|
830
|
N/A
|
439
|
N/A
|
4.423
|
N/A
|
469
|
N/A
|
6.572
|
N/A
|
Total
|
8.851
|
2.339
|
1.257
|
1.846
|
7.965
|
1.023
|
3.186
|
4.155
|
290
|
26
|
21.549
|
9.389
|
3.2 Target RE
At present, the development of RE refers to Presidential Regulation No. 5 of 2006 on National Energy Policy. It is stated that the contribution of RE in the national primary energy mix in 2025 is 17% with the composition of Biofuel of 5%, Geothermal of 5%, Biomasses, Nuclear, Water, Solar, and Wind 5%, and coal liquefied of 2%. For this reason, the steps to be taken by the Government are to increase the installed capacity of the Micro Hydro Power Plant to 2.846 MW in 2025, the installed capacity of 180 MW Biomass in 2020, the installed wind capacity (PLT Bayu) of 0.97 GW in 2025, solar 0.87 GW in 2024, and nuclear 4.2 GW in 2024. The total investment absorbed by RE development until 2025 is projected at USD 13.197 million.
Utilization of solar energy as electricity generation aims to increase national energy security, reduce dependence on the use of fossil fuels, and increase economic investment. In addition, it can make domestic industries are more efficient, reduce greenhouse gas emissions, and meet the government’s target of RE use by 23% by 2025. The Government of Indonesia has set targets for the use of installed solar energy in 2025 by 1.008.4 MW [2,37]. The use of the energy mix in 2025 is targeted by the government for coal of 54.6%, natural gas/LNG of 22%, RE of 23% and fossil energy of 0.4%. The target for energy use in 2025 is adjusted to government policies in utilizing RE and gas, so that dependence on fossil energy can be reduced. The development of RE can be increased until 2028 by seeking to be able to increase the capacity of PV roofs of 3.200 MW for 1.6 million customers. Electricity energy production in 2028 is targeted at 500.691 GWh, mostly produced from coal energy of 272.354 GWh, gas of 110.150 GWh, hydro of 54.736 GWh, Geothermal of 48.217 GWh, RE and fossil energy of 13.205 GWh and 2.019 GWh, respectively, as shown in Fig. 8.(a). Based on the composition of electricity production by type of fuel, the government’s target to reduce the use of fossil fuels and reduce imports can be achieved. However, to achieve this target, a strong government policy and adequate resources are needed. Meanwhile, Fig. 8 (b) shows the composition of the energy mix for electricity generation. Based on the composition of the power plant using the energy mix, the government’s target to reduce greenhouse gas emissions in 2028 can be achieved. Therefore, air pollution caused by industrial fuels and vehicles can be realized. The composition of production and generation with a mixture of energy during the period 2019-2028 is shown in Fig. 8 (a) and 8 (b). To be able to support this energy production target, sufficient fuel is needed with adequate availability. If the availability of this fuel is lacking, it is highly unlikely that targets for energy production and emission reductions can be achieved.
The government’s RE targets in 2025 and 2050 are 23% and 31%, respectively, as shown in Fig. 9 (a) and 9 (b). It can be seen that the RE target becomes greater than the other energy mix. Meanwhile, the petroleum energy mix will decrease to 20% by 2050. The increasing population has driven the increasing demand for energy, especially for transportation and electricity. Meanwhile, fossil energy production (non-renewable) will continue to decline, forcing the government to import petroleum to meet domestic needs. To overcome fossil fuels that continue to experience depletion, the government has made several policies to support the use of RE nationally. The government’s target is to meet national energy by building several electricity generators such as geothermal energy, solar energy, and bioenergy, hydropower, and wind power. Besides, the government made policy on the use of biofuels (B20), namely mixing diesel engine fuel with palm oil to reduce the use of fossil energy [26,28,37].
3.3 Energy Demand
National energy demand in 2050 is targeted at 548.8 MTOE (5.0%) sourced from the energy mix (EM), sustainable development (SD) of 481.1 MTOE (4.7%), and low carbon (LC) of 424.2 MTOE (4.3%). The SD to EM scenario can save final energy reaching 12% by 2050. Meanwhile, the final energy demand from the LC scenario to EM can save 23% by 2050 as shown in Fig. 10. The total amount of energy demand in 2050 is predicted to be still dominated by the transportation and industrial sector. This is due to industrial growth and the increase in the volume of motor vehicles accompanied by an increase in population which increases every year. Final energy demand by type of energy in 2050 shows that electricity demand will dominate by 35% (EM), 34% (SD) and 33% (LC), respectively [2,37]. The high demand for electricity can be influenced by the increasing use of electronic devices, especially in the household sector. In addition, the substitution of the use of generators in the industrial and commercial sectors with fuel oil to using electricity on the grid.
Energy demand for the industrial sector in 2050 is estimated to reach 230.9 MTOE sourced from EM, SD of 194.03 MTOE and LC of 157.07 MTOE. The use of energy in this industry is divided into six parts including the cement industry, fertilizer, paper, ceramics, metals, and the food/beverage industry. The total amount of energy demand in the industrial sector reaches87%. For the transportation sector, energy demand is still dominated by fuels such as diesel, gasoline, biodiesel, bioethanol, gas, avgas, and aviation fuel. The transportation sector consumed 96% of fuel in 2018 and the rest was supplied by natural gas and biodiesel. The biggest energy demand for transportation in 2018 was dominated by motorcycles, i.e. 41%. Energy demand for air transportation in 2018 also increased and in 2050 demand for aviation fuel is predicted to reach 27.06 MTOE. Energy demand for the trucking sector in 2050 is projected at 43%. For passenger car transportation, although there is an upward trend in energy demand, its growth has been able to be tempered by the use of more efficient technology. Therefore, energy demand in 2050 is projected to increase from 6.07 MTOE in 2018 to 23.07 MTOE in the EM scenario and 21.01 MTOE in the SD scenario and 20.9 MTOE in the LC scenario.
Energy demand in the household sector is affected by the increasing number of households predicted to reach 70.6 million in 2025 and around 80 million in 2050. In addition, the level of urbanization drives future energy demand increases. Based on BPS projections, in 2035, the urbanization rate can reach 67% compared to 2010 which was only 49.8%. Energy demand in 2050 for the household sector reaches 120 MTOE (EM), 109 MTOE (SD) and 94.7 MTOE (LC). The dominant use of energy for the household sector in 2050 is electricity. Thus, the share of electricity demand in 2050 is projected to increase by 90% compared to 2018 which was only 60%. Energy demand for the commercial sector such as offices, hotels, restaurants, hospitals, and other services. The use of energy in the commercial sector such as electricity, LPG, solar, gas, biodiesel, and DME use electricity around 60%-70%. Total final commercial energy demand in 2050 is estimated at 47.7 MTOE (EM), 40.5 MTOE (SD), and 36.2 MTOE (LC). In the agriculture, mining, and construction sectors, energy demand is generally sourced from coal, diesel, biodiesel, and electricity. Coal is used in the mining sub-sector, while diesel and biodiesel are used as generators as electricity supply reserves. In 2018, energy demand for the three mining sectors declined by 43%, while in 2050, it is projected to decrease to 27%. However, the construction sector is projected to increase from 26% in 2018 to 42% in 2050. This was greatly influenced by increased economic growth as the population increases [2,38].
Energy demand in the industrial sector in 2050 is estimated to reach 230.9 MTOE (EM), 194.3 MTOE (SD), and 157.7 MTOE (LC) as shown in Fig. 11 (a). Meanwhile, energy demand for transportation in the EM scenario and the sustainable development scenario (SD) shows the share of conventional oil demand until 2050 is still high. However, in the low carbon (LC) scenario, the share of conventional (fossil) oil demand in 2050 is estimated to decrease due to the application of mixing biodiesel by 100% (green diesel) and bioethanol by 85%. Thus, the share of oil demand in the LC scenario in 2050 becomes 37% and the RE demand share increases to 62% as shown in Fig. 11 (b). Energy demand for the household sector in 2050 is estimated to reach 323.7 MTOE sourced from 120 MTOE (EM), 109 MTOE (SD), and 94.7 MTOE (LC). The share of electricity demand is estimated to increase from 60% in 2018 to 90% in 2050. The increasing electricity demand is driven by the increasing use of electronic equipment such as air conditioners, refrigerators, water pumping machines, and induction electric stoves. Meanwhile, the demand for LPG in the EM, SD, and LC scenarios in 2050 reached 4.8 MTOE, 4.3 MTOE and 3.4 MTOE as shown in Fig. 12 (a). In the commercial sector such as offices, hotels, restaurants, hospitals and other services, the demand for energy is dominated by electricity, LPG, diesel, gas, biodiesel, and DME, reaching 60%-70%. Electricity consumption is used for air conditioning (AC), water pumping machines, and lighting (lamps). Total final energy demand for the commercial sector in 2050 is estimated to reach 124.4 MTOE sourced from 47.7 MTOE (EM), 40.5 MTOE (SD), and 36.2 MTOE (LC) as shown in Fig. 12 (b).
3.4 Energy Supply
In 2050, the primary energy supply is targeted to reach 943 MTOE compared to 2025 at 314 MTOE. The supply of primary energy for power plants is included in the modelling based on the assumption of generating capacity according to the electricity supply business plan (ESBP) which generates the primary energy requirements for each power plant [2,33,39,40]. In this case, 298 MTOE (32%) is sourced from coal energy. It is expected that the use of coal can increase added value to the process of coal gasification and coal liquefaction. Energy demand sourced from gas pipelines, LNG, and LPG in 2050 is predicted to be 222 MTOE (24%) of the total primary energy supply. Meanwhile, the supply of RE is around 29% (275 MTOE) in 2050. The increase in the supply of RE is influenced by the optimization for the utilization of solar cell energy, geothermal energy, biomass, and water that is intended for electricity generation and fuel subsidies in the transportation sector. In the SD scenario, the primary energy supply is smaller than the energy mix (EM) scenario of 828 MTOE in 2050. However, in the SD scenario, the RE energy is greater than the EM scenario, which is 23% in 2025 and 32% in 2050. This figure is following the targets listed in the KEN and RUEN. In the special LC scenario, RE increases significantly by 58% in 2050 compared to 2025 by 36%. The comparison of the primary energy mix with SD and LC 2025-2050 scenarios is shown in Fig. 13 (a) and 13 (b).
3.5 Economic Growth
Indonesia’s economic growth in 2017 and 2018 were 5.07% and 5.17%, respectively, as reported in the data from the Central Statistics Agency (CSA) [41]. In 2019, it increased to 5.3% and in 2045 it is targeted at 5.6%. ESBP stated that Indonesia’s economic growth uses BAPPENAS scenario in 2028 of 6.45% [29]. This is one of the factors to consider in making scenarios of long-term domestic energy demand. Economic growth statistics are accompanied by energy demand in general.
Energy demand is closely related to economic activity, so the assumption of economic growth will be very sensitive to energy demand from the three scenarios developed as shown in Table 3. Indonesia’s economic growth during the 2013-2018 period tended to decrease from 5.6% to 5.17% as a result of the global economic downturn due to financial market uncertainty and declining trade volume at the world level. The assumption of economic growth is adjusted to the “Vision of Indonesia 2045” published by BAPPENAS [42,43]. The Indonesia’s economic growth in the next few years is supported by rising domestic needs, including consumption and investment, as well as better export growth including in the manufacturing sector which is a major energy consumer in the industrial sector.
Table 3. Assumptions and RE scenarios
Assumption
|
Energy Mix (EM)
|
Sustainable Development (SD)
|
Low Carbon (LC)
|
Economic growth
|
|
Population growth
|
0.7% (2045)
|
Biodiesel target
|
20% (2025)
|
30% (2025)
|
30% (2025)
|
30% (2050)
|
30% (2050)
|
100% (2050)
|
Bioethanol target
|
5% (2025)
|
20% (2025)
|
20% (2025)
|
50% (2050)
|
85% (2050)
|
Jargas growth
|
4.7 SR (2025)
|
1 juta SR/years
|
>1 juta SR/years
|
LPG substitution with Electric Induction Cooker
|
0.5% (2025)
|
1% (2025)
|
2% (2025)
|
2% (2050)
|
5% (2050)
|
LPG substitution with DME
|
20% (2025)
|
20% (2025)
|
20% (2025)
|
Electric Car Target (% of total population) vehicle)
|
0.01% (2025)
|
0.01% (2025)
|
0.5% (2025)
|
0.07% (2050)
|
0.24% (2050)
|
1.18% (2050)
|
Electric Motor Target (% of total population) vehicle)
|
1.38% (2025)
|
1.44% (2025)
|
1.18% (2025)
|
Power plants
|
1.5% (2050)
|
1.7% (2050)
|
3% (2050)
|
Electricity supply business plan (ESBP)
|
RUEN
|
Emission Reduction> RUEN
|
10% Switching Capacity PLTU to PLT Biomass
|
30% Switching Capacity PLTU to PLT Biomass
|
25% of Luxury Homes use Solar Rooftop
|
30% of Luxury Homes use Solar Rooftop
|
3.6 RE Policy
To accelerate the development of RE, the Government of Indonesia has established several regulations or policies which are considered to be very supportive:
- The Government of Indonesian issued two policies in 2014 and 2017 concerning national energy and national energy general plans through Presidential Regulation numbers 79/2014 and 22/2017, respectively [33].
- Presidential Regulation No. 4 of 2016 (Article 14) on the Acceleration of Electricity Infrastructure. The government mandates to be able to implement and accelerate the development of electricity infrastructure by prioritizing the use of RE [44].
- Central and Local Governments can provide support in the form of fiscal incentives, licensing, and non-licensing facilities. Besides determining the purchase price of electricity from each type of RE source, the establishment of a separate business entity in the context of supplying electricity to be sold to PT. PLN (Persero), and/or providing subsidies.
- Presidential Regulation No. 66 of 2018 on the Second Amendment to Presidential Regulation No. 61 of 2015 on Collecting and Using Palm Oil Plantation Funds, which require the use of biodiesel for PSO and non-PSO following article 18 paragraph (1b) [45].
- Minister of Finance Regulation No. 177/PMK.011/2007 on Exemption of Import Duties on Imported Goods for Upstream Oil and Gas and Geothermal Business Activities [46].
- Minister of Finance Regulation No. 03/PMK.011/2012 on Procedures for Management and Accountability of Geothermal Fund Facilities [46].
- Minister of Energy and Mineral Resources Regulation No. 49 of 2017 is an improvement to the Minister of Energy and Mineral Resources Regulation No. 10 of 2017 on Principles of Electricity Sales and Purchase Agreement [47].
- Minister of Energy and Mineral Resources Regulation No. 50 of 2017 is a revision of the Minister of Energy and Mineral Resources Regulation No. 12 of 2017 on Utilization of RE Sources for Electricity Supply, which is issued to create a better business climate while still encouraging efficiency practices and realizing reasonable and affordable electricity prices.
- Minister of Energy and Mineral Resources Regulation No. 49 of 2018 on the Use of Roof Solar Power Generation Systems by Consumers of PT. Perusahaan Listrik Negara (PLN).
KEN mandates for RE mix target in the primary energy mix of at least 23% by 2025 and minimizes the use of petroleum less than 25% by 2025. In addition, energy efficiency is also targeted to decrease by 1% per year to encourage savings in energy use in all sector. Some targets in the KEN which are also considered in the projected energy demand include optimization of the use of natural gas for domestic use and priority use of fossil energy for national industrial raw materials. This policy is implemented to maximize the use of RE, minimize the use of petroleum, optimize the use of natural gas and RE, use coal as a mainstay of national energy supply, and use nuclear as a last resort. With the regulations set by the government, it is expected that the developers (investors) can work better and the targets set can be achieved.
3.7 Risks & Challenges RE
In the construction of RE project, investors sometimes need to evaluate the risks that may arise when construction or operations begin. Each RE project has different types of risks and obstacles [48]. A study conducted by the United Nations Environment Program (UNEP) elaborates some of the risks that are generally inherent in the development of RE projects as shown in Table 4 [49,50].
Table 4. Risks and Challenges in RE Projects
Type RE
|
Risk Issues
|
Risk Management Consideration
|
Biomass
|
- Availability/variability of fuel supply.
- Variability in resource prices.
- Environmental obligations are related to fuel handling and storage.
|
- Long-term contracts can solve resource problems.
- Fuel handling costs.
- Emission control.
|
Biogas
|
- Resource risks (eg reduction in quantity and quality of gas due to changes in organic raw materials).
- Opposition planning is related to the smell problem.
|
- Strict safety procedures are needed such as loss control such as firefighting equipment and services.
- High level of wear.
|
Wind
|
- Long waiting times and upfront costs (e.g. permit planning and construction costs).
- Failure of important components (eg gear train/box, bearings, blades etc.).
- Variability of wind resources
- Offshore cabling.
|
- Turbine makes and models.
- Manufacturing guarantees from component suppliers.
- Good wind source data.
- Loss control e.g. Firefighting can be difficult if the location is off the coast or altitude.
- Development of procedures that are generally used
|
Tidal/Wave
|
- Survival in a harsh marine environment.
- Various designs and concepts but without a clear winner.
- Prototype/technology risk.
- Small scale and long waiting time
|
- Most of the prototypes and technology demonstration projects.
- Good resource measurement data.
|
Geothermal
|
- Drilling costs and risks that arise (blow out).
- Exploration risk (Unexpected temperature).
- Important components that are damaged, such as pumps.
- Long waiting time (Permission).
|
- Limited operator experience and different aspects of technology at different locations.
- Limited sources of measurement data.
- Agreement on planning can be difficult
- 'Technology stimulation' is still unproven but can reduce the risk of exploration.
|
Solar Thermal
|
- Prototype/technology risks as project size increases and is combined with others.
- RETs, for example, solar towers
|
- Good operating history (already since 1984).
- Maintenance can be neglected (especially in developing countries).
|
Small Hydro
|
- Flood.
- Seasonal/annual source variability.
|
- Prolonged damage due to off-site monitoring (long response time) and lack of spare parts.
|
PV
|
- Component damage (e.g. Short-circuit current).
- Weather damage
- Theft/vandalism
|
- Performance guarantees are available (for example up to 25 years).
- Standard components, with easy substitution.
- Maintenance can be neglected (especially in developing countries).
|
3.8 The electricity selling price
The price of electricity sales to customers from renewable energy is cheaper compared to conventional energy as shown in Table 5. Meanwhile, the cost of conventional energy production is cheaper than RE, except for the production of wind power plants. However, renewable energy has more advantages than conventional energy. The benefits of include environment friendly, more lace emission, reusable, sustainable, and lower operational costs. Meanwhile, conventional energy has higher operational costs compared to RE despite lower production costs. In addition, conventional energy produces higher emissions than RE.
Table 5. Comparison of selling prices of RE and conventional energy [40,51]
Type of fuels
|
Production price (USD/MW)
|
Selling price (USD/kWh)
|
Solar power generation
|
1.9 million
|
0.081-0.06
|
Mini-hydro/micro-hydro power plant
|
2 million
|
0.044-0.04
|
Wind power plant
|
638 thousand
|
0.06
|
Biomass power plant
|
|
0.07
|
Biomass Palm Oil
|
1 million
|
0.053
|
Biogas power plant
|
2.1 million
|
0.086-0.05
|
Coal-fired power plant
|
1.5 million
|
0.045
|
Energy conventional (Diesel)
|
750 thousand
|
0.13
|