Difference between revisions of "Features of PicoPV Systems"
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= Overview<br/> = | = Overview<br/> = | ||
[[Photovoltaic (PV)|Photovoltaic (PV)]] off-grid systems are mainly defined through power dimension and the number of users<ref>Mitja et al., 2003</ref>. | [[Photovoltaic (PV)|Photovoltaic (PV)]] off-grid systems are mainly defined through power dimension and the number of users<ref>Mitja et al., 2003</ref>. | ||
− | All systems include one or more solar modules of different sizes and various appliances. Frequently used categories are ''' | + | All systems include one or more solar modules of different sizes and various appliances. Frequently used categories are '''multi-user systems (MUSs) or PV mini-grids''', '''[[Solar Home Systems (SHS)|solar home systems (SHSs)]]''' and '''PicoPV systems'''. |
− | <u> | + | PicoPV systems are small independent plug-and-play appliances providing light and/or additional electrical services, like charging mobile phones and mp3 players as well as powering radios, small televisions, small fans etc. These systems in any case can replace candles and kerosene lamps. |
+ | |||
+ | The distinction between SHS and PicoPV is not an absolute one. Fundamentally, since the respective names refer to different aspects that don't exclude one another: very small systems (picoPV) just as well can serve a household. On the other hand since the range of products classically called "pico PV" (small capacity plug-and-play devices) is ever- expanding and now (2015) includes plug-and-play devices with capacities that historically were considered the lower end of SHS. | ||
+ | |||
+ | <br/><u>Rough Differentiation of PV systems by capacity</u><ref name="Difference">What difference can a PicoPV system make? Early findings on small Photovoltaic systems - an emerging low- cost energy technology for developing countries.</ref>: | ||
[[File:Graphik PicoPV.JPG|thumb|left|329px|Definition: MUS, SHS, PicoPV System]] | [[File:Graphik PicoPV.JPG|thumb|left|329px|Definition: MUS, SHS, PicoPV System]] | ||
− | + | . | |
<br/> | <br/> | ||
+ | <br/> | ||
= PicoPV System Components<br/> = | = PicoPV System Components<br/> = | ||
<u>A PicoPV system mainly consists of three components:</u> | <u>A PicoPV system mainly consists of three components:</u> | ||
− | *[[Solar Cells and Modules|Solar Panel:]] The PV panels for the lights are mostly made of polycrystalline | + | |
+ | *[[Solar Cells and Modules|Solar Panel:]] The PV panels for the lights are mostly made of polycrystalline or monocrystalline silicon. The peak power of the solar panel ranges from 0.3 Wp for a solar lantern with an integrated panel up to nowadays 80 Wp for the bigger plug-and play systems. | ||
<br/> | <br/> | ||
− | |||
− | + | *[[Batteries|Battery:]] While historically also a lot of lead-acid and NiMH batteries were used and still can be found on the market, nowadays nearly all picoPV devices have Li-Ion batteries, with lead-acid still incidentally used for bigger systems amongst the picoPV devices. <ref name="BOP">Lighting Africa. 2010. Solar Lighting for the Base of the Pyramid - Overview of an Emerging Market -</ref> Along with the batteries, a charge controller is important to protect the battery from damage caused by overcharging or deep-discharging. <ref>Solar Energy Foundation. 2010. Sun connect. Check list solar lamps</ref> | |
− | *[[ | ||
<br/> | <br/> | ||
− | + | *[[Lamps and Electric Appliances|Lamp:]] A PicoPV system can be equipped with various lighting technologies. Historically various picoPV devices used '''Compact Fluorescent Lighting (CFL) lamps. '''In recent years however, '''Light Emitting Diode (LED)''' technology has overtaken CFL in terms of both durability (lighting hours) as well lighting efficiency (lumen/watt). Consequently nowadays in nearly all picoPV devices LED is used as lightsource | |
− | |||
<br/> | <br/> | ||
− | Many models of PicoPV systems also allow for the operation of other small electric devices such as a ''small radio, small loudspeakers'', or a ''MP3-player''. In general, the size of the module and the storage capacity of the battery determine the range of electric appliances which can be connected to the system. If required even a ''small TV'' or a ''little fridge'' can be operated. One example is the seven inch solar LCD Colour TV of Free Energy Europe which consumes less than 10 W | + | Many models of PicoPV systems also allow for the operation of other small electric devices such as a ''small radio, small loudspeakers'', or a ''MP3-player''. In general, the size of the module and the storage capacity of the battery determine the range of electric appliances which can be connected to the system. If required even a ''small TV'' or a ''little fridge'' can be operated. One example is the seven inch solar LCD Colour TV of Free Energy Europe which consumes less than 10 W . In addition, various standard plugs USB-ports are also on the rise. They facilitate the operation of a huge range of small USB-devices like for example small fans. |
[[Features of PicoPV Systems#toc|►Go to Top]] | [[Features of PicoPV Systems#toc|►Go to Top]] | ||
+ | |||
+ | <br/> | ||
= Product Types = | = Product Types = | ||
− | New products are introduced to the market nearly daily. Even there is no common typology of lamps yet, a few | + | New products are introduced to the market nearly daily. Even though, there is no common typology of lamps yet, a few institutions refer to a [[PicoPV Types|typology of products]] in order to differentiate between the big range of PicoPV products. |
+ | |||
+ | <br/>[[Features of PicoPV Systems#toc|►Go to Top]] | ||
<br/> | <br/> | ||
− | + | ||
= Quality of PicoPV Systems<br/> = | = Quality of PicoPV Systems<br/> = | ||
− | + | In the recent years, a large number of differnt solar lamps has been introduced to the market. The number of new models increases almost daily. Therefore, it is difficult to find an adequate solar lamp regarding type and quality. In order to prevent customers from products of bad quality and destroy local markets, several [[Quality of PicoPV Systems|laboratory tests]] were accomplished to evaluate products. To complement this data, [[PicoPV Field Tests|field tests]] in various countries took place in order to test the products under real-life conditions.<br/> | |
− | Lighting | + | [https://www.lightingafrica.org/ Lighting Africa], a joint World Bank Group-International Finance Corporation program, developed a comprehensive '''quality test method (QTM)''' and established a minimum performance requirements for the Pico PV systems. [https://www.lightingglobal.org/products/?view=grid Here] you can find a list of the products that met the minimum quality standards.<ref name="Difference">GTZ. 2010. What difference can a PicoPV system make? Early findings on small Photovoltaic systems - an emerging low cost energy technology for developing countries</ref> <span lang="en">Lighting Africa aims to expand access to clean, affordable, quality-verified off-grid lighting to people currently living without electricity in sub-Saharan Africa.</span><br/> |
− | -> For more information on quality issues of Pico PV systems see | + | -> For more information on quality issues of Pico PV systems, please see '''[[Quality of PicoPV Systems|Quality of Pico PV Systems]]'''. |
<br/> | <br/> | ||
− | <u>PicoPV Lamps</u><ref>GTZ. 2009. Solar | + | <u>PicoPV Lamps</u><ref>GTZ. 2009. Solar Lanterns Test: Shades of Light.</ref>: |
+ | [[File:PicoPV Solarleuchten.JPG|thumb|left|288px|PicoPV Lamps]]<div style="clear: both;"></div> | ||
+ | [[Features of PicoPV Systems#toc|►Go to Top]] | ||
+ | |||
+ | <br/> | ||
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− | |||
− | |||
= Project Examples<br/> = | = Project Examples<br/> = | ||
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=== An Alternative for Home Lighting for Rural and Dispersed Populations === | === An Alternative for Home Lighting for Rural and Dispersed Populations === | ||
− | According to the National Rural Electrification Plan 2012-2021 from the Ministry of Energy and Mines, despite efforts to implement rural electrification projects, | + | [[File:Pico PV Yanacolpa Peru.JPG|thumb|right|300px|Pico PV in Yanacolpa, Huancavelica, at 4000 masl|alt=Pico PV Yanacolpa Peru.JPG]] |
+ | |||
+ | According to the National Rural Electrification Plan 2012-2021 from the Ministry of Energy and Mines, despite efforts to implement rural electrification projects, '''3 million people''' in Peru still lack access to electricity and are forced to use batteries, candles and lighters, spending about '''40 soles per month''' on low quality lighting.<br/> | ||
− | Given this reality, | + | Given this reality, PicoPV provide an alternative pre-electrification plan for remote and scattered rural communities throughout Peru. The PicoPV products are inexpensive, easy to transport (less than 2 kg), and involve simple installation, use and maintenance. They also have high energy efficiency, providing quality lighting that meets the daily needs of a family, while consuming less than 1 kWh per month. The systems can be used in a fixed or portable manner, and they can charge a radio or cell phone and in this way allow low income families to cut down on their daily spending. They provide greater security for the family and eliminate household pollution created by the use of diesel and other fuels used in rustic lighting. They are also a source of clean energy which decrease CO2 emissions in the environment. |
[[Features of PicoPV Systems#toc|►Go to Top]] | [[Features of PicoPV Systems#toc|►Go to Top]] | ||
+ | |||
+ | <br/> | ||
=== Smoke-free Lighting and Savings === | === Smoke-free Lighting and Savings === | ||
− | + | PicoPV products seek to improve the quality of life for families and communities that still lack permanent power sources. They do so by directly addressing the basic needs of the large segment of the population, in many countries, that live in remote, rural areas, far from the conventional electric network. And thanks to its small size, the systems can use high quality Lithium-ion batteries, the same as those used in cell phones and laptops, leaving behind lead-acid batteries, which pose an environmental and health risk. | |
− | |||
− | They do so by directly addressing the basic needs of the large segment of the population, in many countries, that live in remote, rural areas, far from the conventional electric network. And thanks to its small size, the systems can use high quality Lithium- | ||
Also, due to its small size, the system can, in good conditions and when fully charged, be used for up to 6 consecutive hours at the maximum intensity level (greater than 100 lumens) and up 50 hours at the minimum intensity level (greater than 20 lumens). Thus, given that these systems have different levels of intensity, the user can manage the stored energy as needed. | Also, due to its small size, the system can, in good conditions and when fully charged, be used for up to 6 consecutive hours at the maximum intensity level (greater than 100 lumens) and up 50 hours at the minimum intensity level (greater than 20 lumens). Thus, given that these systems have different levels of intensity, the user can manage the stored energy as needed. | ||
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Finally, for a product to be considered a Pico Photovoltaic System, it must have a maximum of 10 Wp panel, from which the light fixtures should be able to put out at least 100 lumens. | Finally, for a product to be considered a Pico Photovoltaic System, it must have a maximum of 10 Wp panel, from which the light fixtures should be able to put out at least 100 lumens. | ||
− | {| | + | {| style="width: 716px;" border="1" cellspacing="1" cellpadding="5" |
|- | |- | ||
− | | [[File:Clean Lighting in the Home.jpg|none| | + | | [[File:Clean Lighting in the Home.jpg|none|300px|Clean Lighting in the Home|alt=Clean Lighting in the Home.jpg]]<br/> |
− | | [[File:The Future of LED Lights.jpg|thumb|center| | + | | [[File:The Future of LED Lights.jpg|thumb|center|292px|The Future of LED Lights|alt=The Future of LED Lights.jpg]]<br/> |
|} | |} | ||
− | [[Features of PicoPV Systems#toc|►Go to Top]] | + | <br/>[[Features of PicoPV Systems#toc|►Go to Top]] |
+ | |||
+ | <br/> | ||
=== Opening the Doors to the Local Market === | === Opening the Doors to the Local Market === | ||
Line 114: | Line 127: | ||
[[Features of PicoPV Systems#toc|►Go to Top]] | [[Features of PicoPV Systems#toc|►Go to Top]] | ||
+ | |||
+ | <br/> | ||
== PicoPV Systems in Ethiopia == | == PicoPV Systems in Ethiopia == | ||
− | *To learn more about acceptance of PicoPV systems in Ethiopia, see [[:File:Rural Electrification, Acceptance of Pico Photovoltaic Systems in Ethiopia.pdf|Rural | + | *To learn more about acceptance of PicoPV systems in Ethiopia, see [[:File:Rural Electrification, Acceptance of Pico Photovoltaic Systems in Ethiopia.pdf|Rural electrification and acceptance of PicoPV Systems]] |
*For information about PicoPV market in Ethiopia, see [[PicoPV System Market Assessment in Ethiopia|Pico Solar PV System Market Assessment in Ethiopia]] | *For information about PicoPV market in Ethiopia, see [[PicoPV System Market Assessment in Ethiopia|Pico Solar PV System Market Assessment in Ethiopia]] | ||
+ | |||
+ | <br/> | ||
[[Features of PicoPV Systems#toc|►Go to Top]] | [[Features of PicoPV Systems#toc|►Go to Top]] | ||
+ | |||
+ | <br/> | ||
= Further Information = | = Further Information = | ||
Line 129: | Line 148: | ||
*[[Quality of PicoPV Systems|Quality of PicoPV Systems]]<br/> | *[[Quality of PicoPV Systems|Quality of PicoPV Systems]]<br/> | ||
*[[PicoPV Systems: Costs, Financing, Business and Operation Models|Financing Picopv]]<br/> | *[[PicoPV Systems: Costs, Financing, Business and Operation Models|Financing Picopv]]<br/> | ||
− | |||
*[[PicoPV Types|PicoPV Types]]<br/> | *[[PicoPV Types|PicoPV Types]]<br/> | ||
+ | *[[:file:Pico Solar PV Systems for Remote Homes - A New Generation of Small PV Systems for Lighting and Communication.pdf|Pico Solar PV Systems for Remote Homes - A New Generation of Small PV Systems for Lighting and Communication]] | ||
[[Features of PicoPV Systems#toc|►Go to Top]] | [[Features of PicoPV Systems#toc|►Go to Top]] | ||
+ | |||
= References = | = References = | ||
− | The article on PicoPV systems in Peru was originally published by EnDev Peru in the second issue of [ | + | The article on PicoPV systems in Peru was originally published by EnDev Peru in the second issue of [[Amaray Magazine - Energising Development Peru|Amaray Magazine]] published in November 2012. |
<references /><br/> | <references /><br/> |
Latest revision as of 12:19, 25 March 2022
Overview
Photovoltaic (PV) off-grid systems are mainly defined through power dimension and the number of users[1].
All systems include one or more solar modules of different sizes and various appliances. Frequently used categories are multi-user systems (MUSs) or PV mini-grids, solar home systems (SHSs) and PicoPV systems.
PicoPV systems are small independent plug-and-play appliances providing light and/or additional electrical services, like charging mobile phones and mp3 players as well as powering radios, small televisions, small fans etc. These systems in any case can replace candles and kerosene lamps.
The distinction between SHS and PicoPV is not an absolute one. Fundamentally, since the respective names refer to different aspects that don't exclude one another: very small systems (picoPV) just as well can serve a household. On the other hand since the range of products classically called "pico PV" (small capacity plug-and-play devices) is ever- expanding and now (2015) includes plug-and-play devices with capacities that historically were considered the lower end of SHS.
Rough Differentiation of PV systems by capacity[2]:
.
PicoPV System Components
A PicoPV system mainly consists of three components:
- Solar Panel: The PV panels for the lights are mostly made of polycrystalline or monocrystalline silicon. The peak power of the solar panel ranges from 0.3 Wp for a solar lantern with an integrated panel up to nowadays 80 Wp for the bigger plug-and play systems.
- Battery: While historically also a lot of lead-acid and NiMH batteries were used and still can be found on the market, nowadays nearly all picoPV devices have Li-Ion batteries, with lead-acid still incidentally used for bigger systems amongst the picoPV devices. [3] Along with the batteries, a charge controller is important to protect the battery from damage caused by overcharging or deep-discharging. [4]
- Lamp: A PicoPV system can be equipped with various lighting technologies. Historically various picoPV devices used Compact Fluorescent Lighting (CFL) lamps. In recent years however, Light Emitting Diode (LED) technology has overtaken CFL in terms of both durability (lighting hours) as well lighting efficiency (lumen/watt). Consequently nowadays in nearly all picoPV devices LED is used as lightsource
Many models of PicoPV systems also allow for the operation of other small electric devices such as a small radio, small loudspeakers, or a MP3-player. In general, the size of the module and the storage capacity of the battery determine the range of electric appliances which can be connected to the system. If required even a small TV or a little fridge can be operated. One example is the seven inch solar LCD Colour TV of Free Energy Europe which consumes less than 10 W . In addition, various standard plugs USB-ports are also on the rise. They facilitate the operation of a huge range of small USB-devices like for example small fans.
Product Types
New products are introduced to the market nearly daily. Even though, there is no common typology of lamps yet, a few institutions refer to a typology of products in order to differentiate between the big range of PicoPV products.
Quality of PicoPV Systems
In the recent years, a large number of differnt solar lamps has been introduced to the market. The number of new models increases almost daily. Therefore, it is difficult to find an adequate solar lamp regarding type and quality. In order to prevent customers from products of bad quality and destroy local markets, several laboratory tests were accomplished to evaluate products. To complement this data, field tests in various countries took place in order to test the products under real-life conditions.
Lighting Africa, a joint World Bank Group-International Finance Corporation program, developed a comprehensive quality test method (QTM) and established a minimum performance requirements for the Pico PV systems. Here you can find a list of the products that met the minimum quality standards.[2] Lighting Africa aims to expand access to clean, affordable, quality-verified off-grid lighting to people currently living without electricity in sub-Saharan Africa.
-> For more information on quality issues of Pico PV systems, please see Quality of Pico PV Systems.
PicoPV Lamps[5]:
Project Examples
PicoPV Systems in Peru
An Alternative for Home Lighting for Rural and Dispersed Populations
According to the National Rural Electrification Plan 2012-2021 from the Ministry of Energy and Mines, despite efforts to implement rural electrification projects, 3 million people in Peru still lack access to electricity and are forced to use batteries, candles and lighters, spending about 40 soles per month on low quality lighting.
Given this reality, PicoPV provide an alternative pre-electrification plan for remote and scattered rural communities throughout Peru. The PicoPV products are inexpensive, easy to transport (less than 2 kg), and involve simple installation, use and maintenance. They also have high energy efficiency, providing quality lighting that meets the daily needs of a family, while consuming less than 1 kWh per month. The systems can be used in a fixed or portable manner, and they can charge a radio or cell phone and in this way allow low income families to cut down on their daily spending. They provide greater security for the family and eliminate household pollution created by the use of diesel and other fuels used in rustic lighting. They are also a source of clean energy which decrease CO2 emissions in the environment.
Smoke-free Lighting and Savings
PicoPV products seek to improve the quality of life for families and communities that still lack permanent power sources. They do so by directly addressing the basic needs of the large segment of the population, in many countries, that live in remote, rural areas, far from the conventional electric network. And thanks to its small size, the systems can use high quality Lithium-ion batteries, the same as those used in cell phones and laptops, leaving behind lead-acid batteries, which pose an environmental and health risk.
Also, due to its small size, the system can, in good conditions and when fully charged, be used for up to 6 consecutive hours at the maximum intensity level (greater than 100 lumens) and up 50 hours at the minimum intensity level (greater than 20 lumens). Thus, given that these systems have different levels of intensity, the user can manage the stored energy as needed.
Financial gain is a powerful motive. A typical energy consumer spends about 30 or 40 soles in batteries, fuel or candles for lighting. Thus, a Pico PV system, the price of which varies between 50 and 100 dollars, depending on the model and brand, is equal to the cost of a half of a year of traditional lighting, with the advantage that it does not entail any future costs. Because of the savings and positive impacts provided in health, education and communication, Pico PV is a step towards a better quality of life.
Usually, the lights have an input jack where you insert the cable coming from the solar panel, which is installed on the roof of the house and which must stay connected during the day to recharge. Once charged, it is possible to use the accumulated electricity, not just for lighting, but also to recharge cell phones and radios, via an output cable, which is connected to the battery.
This is why Pico PV Systems are more than simple solar lights; they are integral domestic systems for lighting and basic communication. The purpose of Pico PV is not just to provide lighting at night, but also to open a window to communications technology, which is vital to the 21st century citizen.
It was necessary to create a lightweight and durable product that could be taken to remote areas without difficulties. In general, these systems are modular and are purchased as part of a kit, which includes a light with battery, a 3 Wp solar panel, phone charger, cables and accessories. A second light can also be acquired separately and charged by the same panel. In addition, a basic kit does not weigh more than 2 kg and can therefore be easily transported to remote areas.
Normally, solar panels are installed and remain stationary on the roof of the home, pointing north, so that it receives sun all day. One panel can charge up to two lights, which provides lighting for two rooms. In addition, most systems can be transported easily from room to room or carried as flashlights, because each light has its own battery, and certain models are even designed to be resistant to water, dust and impact.
Finally, for a product to be considered a Pico Photovoltaic System, it must have a maximum of 10 Wp panel, from which the light fixtures should be able to put out at least 100 lumens.
Opening the Doors to the Local Market
In Peru, the first products of this kind appeared in the capital in 2010. However, the market is still growing and therefore, they have mostly been utilized as part of projects that seek to promote human development through basic access to energy in the home, which is why the supply of these products has gone hand in hand with social initiatives from international cooperation organizations and the private sector.
These systems offer features suitable for remote locations, where installing other, more complex and powerful technologies, would be too costly or complicated for the locals. Also, this is an electrification alternative that comes with a guarantee from suppliers. Currently, they are working on providing a deal which includes a permanent service technicians in the San Martin region and replicating this model in Cusco and Cajamarca, according to the growth of the demand of the population. Generally the guarantee lasts one year. Moreover, these service centers are essential to the sustainability of the products, which may require maintenance, repairs or replacement batteries.
The GIZ’s Energising Development Project has been promoting the supply, demand and policy framework for these technologies in various regions of Peru, introducing products that have been tested for certain quality standards. Studies have been conducted in the laboratories of the National Engineering University (UNI) to ensure the capacity, efficiency and functionality of the systems.
The systems, tested in the field, have shown to be resistant to wear over time, and have generated positive social impact by replacing candles and diesel burners. There have been clear economic advantages, as the use of fuel for generators, which would light up one or two bulbs, has decreased sharply. This adds up to environmental conservation by contributing to the reduction of CO2 emissions.
The total replacement of batteries is still a work in progress, since some residents prefer having the equipment hanging in their rooms and not exposed to the elements, or they think equipment may be damaged by falling or getting wet and in some cases the residents have permanently installed the technology in their rooms and therefore continue to use regular flashlights for specific activities.
In addition, the use of batteries for radios is still common. However, there are now radios that work with USB music players and use cell phone batteries, which can be recharged via a Pico PV system.[6]
PicoPV Systems in Ethiopia
- To learn more about acceptance of PicoPV systems in Ethiopia, see Rural electrification and acceptance of PicoPV Systems
- For information about PicoPV market in Ethiopia, see Pico Solar PV System Market Assessment in Ethiopia
Further Information
- Solar portal on energypedia
- Market for PicoPV
- PicoPV Field Tests
- Quality of PicoPV Systems
- Financing Picopv
- PicoPV Types
- Pico Solar PV Systems for Remote Homes - A New Generation of Small PV Systems for Lighting and Communication
References
The article on PicoPV systems in Peru was originally published by EnDev Peru in the second issue of Amaray Magazine published in November 2012.
- ↑ Mitja et al., 2003
- ↑ 2.0 2.1 What difference can a PicoPV system make? Early findings on small Photovoltaic systems - an emerging low- cost energy technology for developing countries. Cite error: Invalid
<ref>
tag; name "Difference" defined multiple times with different content - ↑ Lighting Africa. 2010. Solar Lighting for the Base of the Pyramid - Overview of an Emerging Market -
- ↑ Solar Energy Foundation. 2010. Sun connect. Check list solar lamps
- ↑ GTZ. 2009. Solar Lanterns Test: Shades of Light.
- ↑ Peru: Amaray Magazine.