Estimating the Energy Demand and Growth in Off-Grid Villages: Case Studies from Myanmar, Indonesia, and Laos
Abstract
:1. Introduction
1.1. Literature Review
1.2. Aims and Scope
2. Materials and Method
2.1. Case study Villages
2.1.1. Thae Kone Village (Myanmar)
2.1.2. Karya Jadi Village (Indonesia)
2.1.3. Houaykhing and Houayha Villages (Laos)
2.2. Survey Procedures
2.3. Energy Demand Estimation Methodology
2.4. Projection of Energy Demand Future Growth
3. The Case Study Country Energy Profile
3.1. Myanmar
3.2. Indonesia
3.3. Laos
4. The Respondents’ Energy Related Basic Needs and Social Activities
4.1. Lighting
4.2. Water for Drinking, Washing, and Bathing
4.3. Food Storage and Cooking
5. Estimation of Electricity Demand
5.1. Data from the Questionnaire as Estimation Parameters
5.2. Energy Demand and Load Pattern
6. Projection of Energy Demand Future Growth
6.1. Constructed Scenarios
6.2. Projection Results
7. Discussions and Conclusions
7.1. Findings
- The solar panel is among the earliest adopted renewable energy for lighting in rural households.
- Lighting appliance, television, and cellphones are the earliest adopted electric appliances in the case studies.
- The possession of food preservation appliance such as the refrigerator is less prioritized as food can be obtained on a daily basis from the vicinity.
- The village location that was closer and with better access to the city created a more diverse job for the residents resulting in a more diverse activities and time variation of the use of energy at home.
- In the colder climate village, there is less need of air conditioning.
- In the steep topography or the mountainous case study village, there is less need of energy for pumping because water can be distributed by gravity.
- Peak energy demand could be found early in the morning and late in the afternoon.
7.2. Limitations and Challenges
7.3. Future Perspectives and Venues for Further Studies
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Myanmar | Indonesia | Laos | |
---|---|---|---|
Number of Participants | 100 | 60 | 60 |
Total Number of Households | 300 | 60 | 305 |
Job diversity | Medium | Low | Low |
Location of Survey | Assembly Hall | Village Manager’s House | Individual Home visits |
Percentage of male participant (%) | 50 | 70 | 50 |
Percentage of female participant (%) | 50 | 30 | 50 |
Age average | 40 | 41 | 43 |
Percentage of last education level | |||
Never went to school (%) | 24 | 15 | 0 |
Elementary school (%) | 9 | 63 | 77 |
Junior High School (%) | 30 | 13 | 17 |
High School (%) | 20 | 7 | 4 |
University or Vocational School (%) | 16 | 2 | 2 |
Parts | Content Excerpts |
---|---|
1. The respondent’s necessary demographic information | Household size, migration activities, and education levels. |
2. Energy-use for basic needs related information | Lighting sources, how the respondents secure clean water for bathing, washing, and drinking purposes, means of food storage, and source of cooking fuel. |
3. Household income and expenditure | Monthly income, monthly expenditure on food, clean water, fuels, education, health, transportation, communication, and clothing. |
4. Time-use questionnaire | Activities throughout the day, their duration, and time in the day. |
Activities | Myanmar | Indonesia | Laos | |||
---|---|---|---|---|---|---|
Main Time | Duration (Hours) | Main Time | Duration (Hours) | Main Time | Duration (Hours) | |
Washing/Bathing | 6:00–8:00 18:00–18:45 | 0.5–1 | 6:30–7:00 17:00–17:15 | 0.25–0.5 | 17:00–18:30 | 0.25–0.5 |
Commuting (1 way) | 6:00–9:00 16:00–19:00 | 0.5–1.5 | 7:30–8:00 16:30–17:15 | 0.25–0.5 | 7:30–10:00 16:00–18:00 | 0.75–1 |
Work | 8:00–18:00 | 7–10 | 8:00–12:00 13:00–17:00 | 8 | 9:00–16:30 | 5.5–7.5 |
Studying/Homework | 8:00–16:00 18:00–20:00 | 6–9 | 5:00–7:00 | 2 | 20:00–20:30 | 0.5 |
Family care/housework | 6:00–7:00 18:00–20:00 | 1–5 | 7:00–12:00 | 1–5 | 4:30–7:00 18:00–20:00 | 1.5–3 |
Cooking | 5:00–7:00 | 0.5–2 | 4:00–6:00 19:00–21:00 | 1–2 | 4:30–7:00 17:30–19:00 | 2–2.5 |
Resting/Entertainment | 18:00–22:00 | 0.5–5 | 18:00–21:00 | 1.5–4 | 13:00–15:00 19:00–22:00 | 2–4 |
Shopping/others | 6:00–9:00 | 0.5–1 | 15:00–16:00 | 0.5–1 | 5:00–8:00 | 3 |
Eating | 5:30–8:30 12:00–13:00 17:30–19:30 | 1–1.5 | 6:00–7:45 12:00–14:00 17:00–20:30 | 0.5–1 | 7:00–8:30 12:00–13:00 19:00–20:00 | 0.5–1 |
Myanmar | Indonesia | Laos | |
---|---|---|---|
Lighting appliance | 95.1% | 54.7% | 100% |
Electric fan | 74.1% | 1.9% | 17% |
Air Conditioner | 49.4% | 1.9% | 0 |
Television | 86.4% | 30.2% | 60% |
Cellphone | 95.1% | 41.5% | 90% |
Refrigerator | 16.0% | 0 | 20% |
Water pump | 79.0% | 3.8% | 0 |
Radio | 34.6% | 32.1% | 33% |
Rice cooker | 22.2% | 0 | 40% |
Washing machine | 3.7% | 0% | 0% |
Myanmar | Indonesia | Laos | |
---|---|---|---|
Average floor area (m2) | 50 | 30.7 | 50 |
Lighting appliance | 74.6 W Fluorescent lamp | 46.3 W Fluorescent lamp | 74.6 W Fluorescent lamp |
Lighting appliances simultaneous operating rate | 0.7 | 0.7 | 0.7 |
Air Conditioner operation period * | 9.6 weeks from 22nd March to 28th May Weekday 2 h/d (18:00–20:00), Weekend 8 h/d (12:00–20:00) | 64 days From 18th February to 23rd April, 3 h/d | Currently not in use and assumed to be not required based on the all year long mild temperature |
Air conditioner (W) | 800 | 800 | 800 |
Electric fan operation period * | 8 months from March to November, Average of 5 h/d, | 64 days from 18 February to 23 April, Average of 5 h/d | 73 days from 4 March to 19 May, Average of 5 h/d |
Electric fan (W) | 100 | 100 | 100 |
Television (W) | 70 | 70 | 70 |
Refrigerator (W) | 200 | 200 | 200 |
Water pump (W) | 320 | Not used (Using hand handled water pump) | Not used (Water is distributed by gravity) |
Radio (W) | 2.4 | 2.4 | 2.4 |
Rice cooker | Not used | Not used | 72 W |
Washing machine | 400 | 400 | 400 |
Cellphone charging | Charging time: 2.25 h/d Charging wattage: 5 | Charging time: 2.25 h/d Charging wattage: 5 | Charging time: 2.25 h/d Charging wattage: 5 |
Scenarios | Description of Scenarios |
---|---|
CASE1 | Demand for lighting only: Household ownership rate of lighting equipment is 100% and other electrical equipment is 0% |
CASE2 | Current demand: Estimated based on the current ownership rate of electrical equipment (lighting appliance, television, cellphone, radio, air conditioner, electric fan, refrigerator, rice cooker, washing machine, and water pump) |
CASE3 | Predicted demand in a few years after electrification: For Myanmar, lighting equipment and cellphone ownership rate is 100%, television and water pump are increased to 88%, and other electrical equipment is increased by 20% from the present scenario (Myanmar’s television and water pump ownership rates are already above 75% in the present scenario). For Indonesia, lighting equipment and cellphone ownership rate is 100%, television is increased by 50%, and other electric equipment is increased by 20% from the present scenario. For Laos, lighting equipment and cellphone ownership rate is 100%, and other electric equipment is increased by 20% from the present scenario except for water pump and air conditioner that remains 0 because temperature is considered mild all year long and fresh water is already delivered by gravity from the spring. |
CASE4 | Predicted demand after mass adoption of electric appliances: The ownership rate of lighting equipment and cellphone are 100%, refrigerator 40%, and other electrical equipment is increased to 90% in all of the case study villages except for water pump and air conditioner in Laos that remains 0 because the temperature is considered mild all year long and fresh water is already delivered by gravity from the spring. |
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Share and Cite
Pandyaswargo, A.H.; Ruan, M.; Htwe, E.; Hiratsuka, M.; Wibowo, A.D.; Nagai, Y.; Onoda, H. Estimating the Energy Demand and Growth in Off-Grid Villages: Case Studies from Myanmar, Indonesia, and Laos. Energies 2020, 13, 5313. https://doi.org/10.3390/en13205313
Pandyaswargo AH, Ruan M, Htwe E, Hiratsuka M, Wibowo AD, Nagai Y, Onoda H. Estimating the Energy Demand and Growth in Off-Grid Villages: Case Studies from Myanmar, Indonesia, and Laos. Energies. 2020; 13(20):5313. https://doi.org/10.3390/en13205313
Chicago/Turabian StylePandyaswargo, Andante Hadi, Mengyi Ruan, Eiei Htwe, Motoshi Hiratsuka, Alan Dwi Wibowo, Yuji Nagai, and Hiroshi Onoda. 2020. "Estimating the Energy Demand and Growth in Off-Grid Villages: Case Studies from Myanmar, Indonesia, and Laos" Energies 13, no. 20: 5313. https://doi.org/10.3390/en13205313
APA StylePandyaswargo, A. H., Ruan, M., Htwe, E., Hiratsuka, M., Wibowo, A. D., Nagai, Y., & Onoda, H. (2020). Estimating the Energy Demand and Growth in Off-Grid Villages: Case Studies from Myanmar, Indonesia, and Laos. Energies, 13(20), 5313. https://doi.org/10.3390/en13205313