Difference between revisions of "Energy Needs in Smallholder Agriculture"
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[http://pubs.iied.org/pdfs/16562IIED.pdf Best, S., (2014). Growing Power: Exploring energy needs in smallholder agriculture. IIED, London.] | [http://pubs.iied.org/pdfs/16562IIED.pdf Best, S., (2014). Growing Power: Exploring energy needs in smallholder agriculture. IIED, London.] | ||
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= Productive use of energy = | = Productive use of energy = | ||
| − | While other approaches define productive uses of energy in a rathe broad way, this paper defines productive uses of energy as uses that "''directly increase incomes or add value to goods and services such as power for milling machine''" (p.10). Nontheless, it acknowledges the importance of energy for other uses such as education or health services. Please also see the article "<span dir="auto">[[ | + | While other approaches define productive uses of energy in a rathe broad way, this paper defines productive uses of energy as uses that "''directly increase incomes or add value to goods and services such as power for milling machine''" (p.10). Nontheless, it acknowledges the importance of energy for other uses such as education or health services. Please also see the article "<span dir="auto">[[Productive Use of Electricity|Productive Use of Electricity]]</span>" for more information on different definitions of productive use, as well as other articles on the "[https://energypedia.info/wiki/Portal:Productive_Use Productive Use Portal]". |
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= Smallholder energy needs = | = Smallholder energy needs = | ||
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Energy needs of smallholders and rural enterprises can be categorized into two main types: 1) energy for transport, and 2) energy for production, processing and commercialisation of goods. The paper - as well as most of the available literature - focsues on the latter. Other energy inputs such as indirect energy inputs (e.g. fertilisers) and household energy (e.g. for cooking) are not covered by the paper. | Energy needs of smallholders and rural enterprises can be categorized into two main types: 1) energy for transport, and 2) energy for production, processing and commercialisation of goods. The paper - as well as most of the available literature - focsues on the latter. Other energy inputs such as indirect energy inputs (e.g. fertilisers) and household energy (e.g. for cooking) are not covered by the paper. | ||
| − | The main energy needs are | + | The main energy needs are<br/> |
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== Land preparation == | == Land preparation == | ||
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Most land is tilled, ploughed and weeded by aninmal and human power in Sub-Saharan Africa (65% human effort, 25% animals, 10% engines). | Most land is tilled, ploughed and weeded by aninmal and human power in Sub-Saharan Africa (65% human effort, 25% animals, 10% engines). | ||
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Weeding in particular is time consuming and physically demanding. At the same time, weeding is critical as more than 30% of crops are averagely lost due to weed infestation. | Weeding in particular is time consuming and physically demanding. At the same time, weeding is critical as more than 30% of crops are averagely lost due to weed infestation. | ||
| − | The use of machines could increase yields substantially i.e. while a farm family using human power can cultivate 1.5 hectares per year, the use of animal power would increase that to 4 hectares and the use of tractor power even to 8. | + | The use of machines could increase yields substantially i.e. while a farm family using human power can cultivate 1.5 hectares per year, the use of animal power would increase that to 4 hectares and the use of tractor power even to 8. |
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== Irrigation == | == Irrigation == | ||
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In Sub-Saharan Africa only 4% of land is irrigated. Irrigation would allo farmers to grow one or more crops throughout the year, decreasing farmers' vulnerability. | In Sub-Saharan Africa only 4% of land is irrigated. Irrigation would allo farmers to grow one or more crops throughout the year, decreasing farmers' vulnerability. | ||
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== Processing == | == Processing == | ||
| + | Key processing activities are drying, milling and pressing. Using machinery saves manual labour and increases efficiency. Drying and cooling of ruit and meat is crucial for preserving food and to meet quality standards. There is potential for applying thermal energy technologies such as [[Solar Drying|solar dryers]]. | ||
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== Storage == | == Storage == | ||
| + | Improved storage is crucial for reducing post-harvest food losses. This includes refrigeration and requires energy inputs.[[Solar Cooling|refrigeration]]<br/> | ||
| − | + | See also the article "<span dir="auto">[[Energy within Food and Agricultural Value Chains|Energy within Food and Agricultural Value Chains]]".</span> | |
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| − | See also the article "<span dir="auto">[[ | ||
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Depending on the level of power needed and the resources availbale locally different energy technologies are required: | Depending on the level of power needed and the resources availbale locally different energy technologies are required: | ||
*Electrical energy: suitable for powering water pumps, milling machines, fridges | *Electrical energy: suitable for powering water pumps, milling machines, fridges | ||
| − | *[[ | + | *[[Mechanical Energy|Mechanical energy]]: suitable for production and processing e.g. for harvesters or tractors |
| − | *[[ | + | *[[Productive Use of Thermal Energy|Thermal energy]]: suitable for different value-adding processes e.g. cooking, drying, cooling |
The report points out that mechanical and thermal energy are not sufficiently targeted by policymakers and donors. | The report points out that mechanical and thermal energy are not sufficiently targeted by policymakers and donors. | ||
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= See also = | = See also = | ||
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*[[Portal:Productive Use|Portal "Productive Use"]] | *[[Portal:Productive Use|Portal "Productive Use"]] | ||
| + | [[Category:Water-Energy-Food_Nexus]] | ||
| + | [[Category:Productive_Use]] | ||
[[Category:Powering_Agriculture]] | [[Category:Powering_Agriculture]] | ||
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Revision as of 15:25, 1 October 2014
Summary
Access to modern energy services and equipment for smallholder farmers could have significant positive impacts on food security, gender empowerment and rural poverty. The publication "Growing Power: Exploring energy needs in smallholder agriculture" by Sarah Best, International Institute for Environment and Development (IIED), analyses the ‘productive uses’ of energy. In detail, the author discusses energy needs and impacts in smallholder food systems, as well as potential approaches to meeting those demands.
Best, S., (2014). Growing Power: Exploring energy needs in smallholder agriculture. IIED, London.
Productive use of energy
While other approaches define productive uses of energy in a rathe broad way, this paper defines productive uses of energy as uses that "directly increase incomes or add value to goods and services such as power for milling machine" (p.10). Nontheless, it acknowledges the importance of energy for other uses such as education or health services. Please also see the article "Productive Use of Electricity" for more information on different definitions of productive use, as well as other articles on the "Productive Use Portal".
Smallholder energy needs
Energy needs of smallholders and rural enterprises can be categorized into two main types: 1) energy for transport, and 2) energy for production, processing and commercialisation of goods. The paper - as well as most of the available literature - focsues on the latter. Other energy inputs such as indirect energy inputs (e.g. fertilisers) and household energy (e.g. for cooking) are not covered by the paper.
The main energy needs are
Land preparation
Most land is tilled, ploughed and weeded by aninmal and human power in Sub-Saharan Africa (65% human effort, 25% animals, 10% engines).
Weeding in particular is time consuming and physically demanding. At the same time, weeding is critical as more than 30% of crops are averagely lost due to weed infestation.
The use of machines could increase yields substantially i.e. while a farm family using human power can cultivate 1.5 hectares per year, the use of animal power would increase that to 4 hectares and the use of tractor power even to 8.
Irrigation
In Sub-Saharan Africa only 4% of land is irrigated. Irrigation would allo farmers to grow one or more crops throughout the year, decreasing farmers' vulnerability.
There are different technical options for irrigation, for more information see e.g. an article on irrgation methods on Agriwaterpedia.
Processing
Key processing activities are drying, milling and pressing. Using machinery saves manual labour and increases efficiency. Drying and cooling of ruit and meat is crucial for preserving food and to meet quality standards. There is potential for applying thermal energy technologies such as solar dryers.
Storage
Improved storage is crucial for reducing post-harvest food losses. This includes refrigeration and requires energy inputs.refrigeration
See also the article "Energy within Food and Agricultural Value Chains".
Energy technologies and sources
Depending on the level of power needed and the resources availbale locally different energy technologies are required:
- Electrical energy: suitable for powering water pumps, milling machines, fridges
- Mechanical energy: suitable for production and processing e.g. for harvesters or tractors
- Thermal energy: suitable for different value-adding processes e.g. cooking, drying, cooling
The report points out that mechanical and thermal energy are not sufficiently targeted by policymakers and donors.
