Difference between revisions of "Transition to Renewable Energies Through Mini-grids"
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= Overview = | = Overview = | ||
| − | The following article details the proceedings of the [ | + | The following article details the proceedings of the [[Micro_Perspectives_for_Decentralized_Energy_Supply_-_Conference_2013|Micro Perspectives for Decentralized Energy Supply Conference - 2013]]. The experiences from projects in India, Nepal and Tanzania using mini-grids to extend access to electricity for local communities are detailed.<br/> |
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| − | = Providing Access to Clean, Reliable and Affordable Power to the Poor in <span data- | + | = Providing Access to Clean, Reliable and Affordable Power to the Poor in <span data-scayt_word="Bihar" data-scaytid="3">Bihar</span> (India) Through Solar Micro Grid Networks = |
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== Abstract == | == Abstract == | ||
| − | <span data- | + | <span data-scayt_word="Bihar" data-scaytid="5">Bihar</span> is <span data-scayt_word="3rd" data-scaytid="7">3<sup>rd</sup></span> largest state in terms of population of the 27 states in India, having 9% of population, and in terms of area it is the <span data-scayt_word="12th" data-scaytid="8">12<sup>th</sup></span> largest and has less than 3% of the total national area. Per capita energy consumption is 95 units, which is 8 times less than the national average. The reasons for this are attributed to Insufficient supply and high transmission & distribution losses (51%). Bihar clearly is the state with the highest population density, wherein most of the other states have no access to electricity which causes a huge demand-supply gap. These factors among others have led to strong market opportunitys for off-grid energy solutions. The government in Bihar has made some changes in its laws which have led to the emergence of enterprises in various sectors as well as the improvement of infrastructure. |
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== Objectives == | == Objectives == | ||
| − | To create a sustainable solar micro grid project in order to address the electricity shortage problems that <span data- | + | To create a sustainable solar micro grid project in order to address the electricity shortage problems that <span data-scayt_word="Bihar" data-scaytid="14">Bihar</span> is facing. |
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== Approach == | == Approach == | ||
| − | To begin the installation, a room is constructed where solar panels of 5.5kW are set up to generate power during the day and store it in the energy bank. At night this energy is converted from '''direct current (DC)''' to '''alternating current (AC) '''using a '''solar power conditioning unit (<span data- | + | To begin the installation, a room is constructed where solar panels of 5.5kW are set up to generate power during the day and store it in the energy bank. At night this energy is converted from '''direct current (DC)''' to '''alternating current (AC) '''using a '''solar power conditioning unit (<span data-scayt_word="PCU" data-scaytid="18">PCU</span>)''' and is then transmitted to various clusters of 10 houses each. Each cluster has a distribution box which supplies power to 10 '''households (<span data-scayt_word="HHs" data-scaytid="19">HHs</span>) '''separately. In order to limit the supply, a load checker is kept for <span data-scayt_word="HHs" data-scaytid="20">HHs</span> to keep a cap on maximum allotted usage. Due to problems with theft of the components, the transmission system was subsequently built underground.<br/> |
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== Lessons Learned == | == Lessons Learned == | ||
| − | <u>After careful observation of the operations in the first plant, some issues identified and resolved were:</u | + | <u>After careful observation of the operations in the first plant, some issues identified and resolved were:</u> |
| − | <br/> | + | '''<span dir="LTR"></span>1. Abuse of system'''<br/>Reduced by constructing underground transmission and load checkers<br/> |
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*Equipment and hardware were secured by storing them in locked cabinets and rooms | *Equipment and hardware were secured by storing them in locked cabinets and rooms | ||
| − | <br/> | + | '''2. System Maintenance '''<br/> |
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*Train people locally to do the basic maintenance | *Train people locally to do the basic maintenance | ||
*Regular visits by technical supervisors | *Regular visits by technical supervisors | ||
| − | < | + | '''<span dir="LTR"></span>3. Monitoring''' |
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*Give incentives to the local NGOs versus remote monitoring | *Give incentives to the local NGOs versus remote monitoring | ||
| − | < | + | '''<span dir="LTR"></span>4. Regular Payment collection''' |
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*Currently being addressed by giving incentives to operators | *Currently being addressed by giving incentives to operators | ||
*Prepaid meters (for buying credits by making advanced payment) were not installed because of weather issues leading to insufficient charge in batteries | *Prepaid meters (for buying credits by making advanced payment) were not installed because of weather issues leading to insufficient charge in batteries | ||
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| − | = <span style="font-size: 19px; line-height: 23px | + | = <span style="font-size: 19px; line-height: 23px">Interconnected Mini-grids for Rural Energy Transition - A Case Study of Nepal</span> = |
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| − | == <span style="font-size: 17px | + | == <span style="font-size: 17px">Abstract</span> == |
| − | More than 2 billion people worldwide have no access to electricity, with 99 % of these people residing in developing countries. About 80% of them live in rural areas. In Nepal 56% of the population has access to electricity (49% in the rural areas), but with up to 16 hours of load-shedding in the national grid. This study has been done to show whether the use of individual renewable energy technologies have socio-economic benefits. | + | More than 2 billion people worldwide have no access to electricity, with 99 % of these people residing in developing countries. About 80% of them live in rural areas. In Nepal 56% of the population has access to electricity (49% in the rural areas), but with up to 16 hours of load-shedding in the national grid. This study has been done to show whether the use of individual renewable energy technologies have socio-economic benefits. |
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The approach that has been considered is the Next Generation of Renewable Based Mini-Grids. This approach has many advantages including: | The approach that has been considered is the Next Generation of Renewable Based Mini-Grids. This approach has many advantages including: | ||
| + | |||
*Grid stabilization | *Grid stabilization | ||
*Reliable energy supply | *Reliable energy supply | ||
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== Abstract == | == Abstract == | ||
| − | Tanzania has a population of around 47 million people who live in an area of approximately 950,000<span data- | + | Tanzania has a population of around 47 million people who live in an area of approximately 950,000<span data-scayt_word="km2" data-scaytid="31">km<sup>2</sup></span>. The installed capacity of electricity power generation is more than '''950 megawatts (MW)''', where 60.5% of it is renewable energies (mainly hydropower). Many mini-grid diesel generators are installed. These have high power generation costs due to the price of diesel, transport costs and low efficiency. At the same time, these generators are air pollutants causing '''carbon dioxide (CO'''<sub>2</sub>''')''' emissions. Therefore there is a need to upgrade these diesel mini-grids with renewable energies. |
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The main idea was to upgrade diesel mini-grids with renewable energies. This upgrade has many advantages such as: | The main idea was to upgrade diesel mini-grids with renewable energies. This upgrade has many advantages such as: | ||
| + | |||
*Lower power generation costs | *Lower power generation costs | ||
*Lower fuel dependency | *Lower fuel dependency | ||
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**Using the information on power plant inventory and locations from world power plant database. | **Using the information on power plant inventory and locations from world power plant database. | ||
**Spatial extension of transmission grid | **Spatial extension of transmission grid | ||
| − | **Extraction of <span data- | + | **Extraction of <span data-scayt_word="25km" data-scaytid="36">25km</span> buffer zone |
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**Loss of 0.42 USD per generated kWh in diesel mini-grids | **Loss of 0.42 USD per generated kWh in diesel mini-grids | ||
**An average deficit of 85 million USD between 2003 - 2009 | **An average deficit of 85 million USD between 2003 - 2009 | ||
| − | **Subsidies are necessary for enabling electricity access, but investments in <span data- | + | **Subsidies are necessary for enabling electricity access, but investments in <span data-scayt_word="renerwable" data-scaytid="37">renerwable</span> energies cannot be covered with low tariffs |
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| − | + | = Further Research = | |
*Community operated diesel mini-grids<br/> | *Community operated diesel mini-grids<br/> | ||
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| − | = <span style="font-size: | + | = <span style="font-size: 22px; line-height: 30px">Further Information</span> = |
| − | More information can be found at [ | + | Read more in the [[Transition to Renewable Energies Through Mini-grids - Discussion|Discussion and Answer Session]]. |
| + | |||
| + | More information can be found at [[Micro_Perspectives_for_Decentralized_Energy_Supply_-_Conference_2013|Micro Perspectives for Decentralized Energy Supply Conference - 2013]]. | ||
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[[Category:Conference_Documentation]] | [[Category:Conference_Documentation]] | ||
| + | [[Category:Energy_Transition]] | ||
[[Category:Microenergy_Systems]] | [[Category:Microenergy_Systems]] | ||
[[Category:PV_Mini-grid]] | [[Category:PV_Mini-grid]] | ||
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[[Category:Tanzania]] | [[Category:Tanzania]] | ||
[[Category:Nepal]] | [[Category:Nepal]] | ||
| + | [[Category:Lessons_Learned]] | ||
[[Category:Solar]] | [[Category:Solar]] | ||
Latest revision as of 14:25, 30 October 2019
Overview
The following article details the proceedings of the Micro Perspectives for Decentralized Energy Supply Conference - 2013. The experiences from projects in India, Nepal and Tanzania using mini-grids to extend access to electricity for local communities are detailed.
Providing Access to Clean, Reliable and Affordable Power to the Poor in Bihar (India) Through Solar Micro Grid Networks
Abstract
Bihar is 3rd largest state in terms of population of the 27 states in India, having 9% of population, and in terms of area it is the 12th largest and has less than 3% of the total national area. Per capita energy consumption is 95 units, which is 8 times less than the national average. The reasons for this are attributed to Insufficient supply and high transmission & distribution losses (51%). Bihar clearly is the state with the highest population density, wherein most of the other states have no access to electricity which causes a huge demand-supply gap. These factors among others have led to strong market opportunitys for off-grid energy solutions. The government in Bihar has made some changes in its laws which have led to the emergence of enterprises in various sectors as well as the improvement of infrastructure.
Objectives
To create a sustainable solar micro grid project in order to address the electricity shortage problems that Bihar is facing.
Approach
To begin the installation, a room is constructed where solar panels of 5.5kW are set up to generate power during the day and store it in the energy bank. At night this energy is converted from direct current (DC) to alternating current (AC) using a solar power conditioning unit (PCU) and is then transmitted to various clusters of 10 houses each. Each cluster has a distribution box which supplies power to 10 households (HHs) separately. In order to limit the supply, a load checker is kept for HHs to keep a cap on maximum allotted usage. Due to problems with theft of the components, the transmission system was subsequently built underground.
Lessons Learned
After careful observation of the operations in the first plant, some issues identified and resolved were:
1. Abuse of system
Reduced by constructing underground transmission and load checkers
- Equipment and hardware were secured by storing them in locked cabinets and rooms
2. System Maintenance
- Train people locally to do the basic maintenance
- Regular visits by technical supervisors
3. Monitoring
- Give incentives to the local NGOs versus remote monitoring
4. Regular Payment collection
- Currently being addressed by giving incentives to operators
- Prepaid meters (for buying credits by making advanced payment) were not installed because of weather issues leading to insufficient charge in batteries
- A Diesel Generator Hybrid system with a battery management system (BMS) is to be introduced
Interconnected Mini-grids for Rural Energy Transition - A Case Study of Nepal
Abstract
More than 2 billion people worldwide have no access to electricity, with 99 % of these people residing in developing countries. About 80% of them live in rural areas. In Nepal 56% of the population has access to electricity (49% in the rural areas), but with up to 16 hours of load-shedding in the national grid. This study has been done to show whether the use of individual renewable energy technologies have socio-economic benefits.
Objectives
To show the socio-economic benefits that individual renewable energy technologies have in Nepal.
Approach
The approach that has been considered is the Next Generation of Renewable Based Mini-Grids. This approach has many advantages including:
- Grid stabilization
- Reliable energy supply
- Avoids end-user maintenance
- Periodic maintenance
- Simple integration of different energy sources (PV, wind, hydro, etc.)
- Least-cost option
- Increasing quality of energy services
- Supports local infrastructure and economic development
- Alternative solution to the national electricity grid
Geographic Analysis of Isolated Diesel Mini-grids for the Implementation of Renewable Energies – A Case Study of Tanzania
Abstract
Tanzania has a population of around 47 million people who live in an area of approximately 950,000km2. The installed capacity of electricity power generation is more than 950 megawatts (MW), where 60.5% of it is renewable energies (mainly hydropower). Many mini-grid diesel generators are installed. These have high power generation costs due to the price of diesel, transport costs and low efficiency. At the same time, these generators are air pollutants causing carbon dioxide (CO2) emissions. Therefore there is a need to upgrade these diesel mini-grids with renewable energies.
Objectives
The main goal is to show the effects of using diesel mini-grids with renewable energies.
Approach
The main idea was to upgrade diesel mini-grids with renewable energies. This upgrade has many advantages such as:
- Lower power generation costs
- Lower fuel dependency
- Fewer CO2 emissions and fewer detrimental environmental effects
- Existing diesel generators serve as back-up power sources
- Different methods are used in the localization of diesel main-grids and deciding whether the power plant operates off-grid or on-grid such as:
- Using the global spatial information
- Using the information on power plant inventory and locations from world power plant database.
- Spatial extension of transmission grid
- Extraction of 25km buffer zone
Results
- State owned village mini-grids have to be targeted for a broader implementation of renewable energies in decentralized power generation.
- Problem: Tariff structure
- Loss of 0.42 USD per generated kWh in diesel mini-grids
- An average deficit of 85 million USD between 2003 - 2009
- Subsidies are necessary for enabling electricity access, but investments in renerwable energies cannot be covered with low tariffs
Recommendations
- It's necessary to break the negative feed-back loop
- Fuel imports–Debt–Lack of capital–Fuel imports
- External funding necessary for upgrading with renewable energies
- Improved and more reliable power supply through hybrid mini-grids can increase electricity access (National target: 30% of population in 2015)
Further Research
- Community operated diesel mini-grids
- Individually operated diesel generators
Further Information
Read more in the Discussion and Answer Session.
More information can be found at Micro Perspectives for Decentralized Energy Supply Conference - 2013.
