Solar Energy in Powering Agriculture

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Overview

On our planet Earth, there are three sources for renewable energy: solar radiation, heat from the Earth’s core (geothermal energy) and gravitational force resulting from planetary movements (tidal power). Energy resulting from solar radiation accounts for about 99.9% of all energy available on Earth.

By definition solar energy is "Solar energy is the conversion of sunlight into usable energy forms"[1]. The main solar technologies are photovoltaics (PV), solar thermal electricity and solar heating and cooling. For agricultural production and processing solar energy is a crucial energy source, in particular for irrigation, cooling and drying.


Solar Powered Irrigation

Solar energy presents a huge potential for agricultural irrigation. Experience from past projects has proven photovoltaic pumping systems to be technically mature and suitable for utilization in rural areas of developing countries.

  • For more information on PV pumping systems for irrigation see here
  • For more information on PV pumping systems in general please see here
  • For a case study from Egypt on solar powered irrigation systems please see here




Solar Drying

Up to 70 per cent of agricultural products spoil during the traditional process of open-air drying, especially in tropical and subtropical regions.[2][3] Thus, in many developing countries large quantities of fruits and vegetables spoil. Common reasons areinadequate infrastructure, insufficient processing capacities, and growing marketing difficulties caused by intensifying competition and protectionism in global agricultural markets. Often, drying is carried out at farm level right after harvest, especially with highly perishable crops, at peak harvest time when local markets are saturated. Drying agricultural produce such as vegetables, fruits and meat with thermal energy enables longer storage times and easier transportation - thereby contributing to improving the population's income and supply situation[2]

There are different types of solar dryers, such as direct drying (solar box dryer), indirect drying (solar cabinet dryer), mixed mode drying (solar tunnel dryer) or hybrid drying (hybrid solar/biomass cabinet dryer). Small-scale solar box and cabinet dryers are based on natural air convection, while solar tunnel dryer is based on forced convection (air circulation fan necessary).

For more information please see here.

Solar Cooling

While solar cooling remains a niche market, the market has grown considerably in recent years[1].

Cooling and refrigeration is essential in agricultural production and processing, e.g. for preserving food products. It generally is a very energy-intensive process. Solar powered cooling presents an important clean energy opportunity, particularly in rural areas without access to the national grid, but also for other processors. For more information please see here.

System Example: SunChill Agricultural Product Refrigeration

SunChill™ is a novel, off-grid refrigeration solution enabling increased agricultural productivity by: (i) removing field heat from crops immediately following harvest (ii) providing continued product cooling at local markets and/or central processing facilities. This clean energy solution transforms 50°C solar thermal energy into 10°C refrigeration using solid refrigerants and local, non-precision components. These characteristics enable production of a low cost, low-maintenance technology that reduces spoilage and benefits the livelihoods of smallholder farmers. For more inforation please see here.


Solar Photovoltaic in Agriculture

PV can be applied for pumping for a wide range of processes, most importantly for irrigation, refrigeration of agricultural products, aeration for aquacultures, but also for electric fencing, poultry lighting and pest control. Application of small PV systems though is limited to the provision of power for activities that require little power input. For energy intensive activities e.g. in rice mills and other agricultural processing PV systems are not an option[4].


Business Models for PV in Agriculture

The study "Enabling PV in the MENA Region - The emerging PV market in Tunisia" analyses four cases, showing that any photovoltaic system installed in Tunisia is amortised during their 20-year project duration, and this no matter what market segment is concerned. Two of those business models apply to the agricultural sector. Find this study here.

The initiative "RaSeed" in Egpyt prsents another case study, promoting the use of Photovoltaic (PV) systems in drip irrigation farming in order to support cost-effective and sustainable agriculture. Therefore, the aim is to introduce high capacity solar operated water pumps - of up to a pump size of 100kW - to the Egyptian agricultural sector. RaSeed targets farm specific optimization of drip irrigation systems that enable maximum fuel savings and water efficiency by taking into account soil compositions and environmental conditions. The initiative has published several infomaterials, including analyses of costs and benefits of solar pumps, please see here.


Specific Publications

  • Solar PV-diesel hybrid business planning: This publication by GIZ provides a systematic approach to asses and develop solar PV-diesel hybrid applications - in general, but also within the agricultural and food industry. The document contains a checklist for the major parameters related to the development of technically feasible and economically viable SPV-hybrid business cases for power generation in off-grid areas. For each of these parameters, this checklist presents general specifications and critical issues/recommendations, which should be taken into consideration. Please see Table 2 “Business planning checklist” on page 8 of the document.
  • Enabling PV in the MENA Region - Tunisia


Further Information


References

  1. 1.0 1.1 International Energy Agency, 2015. Solar. http://www.iea.org/topics/renewables/subtopics/solar/ Cite error: Invalid <ref> tag; name "IEA" defined multiple times with different content
  2. 2.0 2.1 INNOTECH – Ingenieuresgesellschaft mbH. Retrieved from: http://innotech-ing.com/en/
  3. Solar Drying. Retrieved from: https://energypedia.info/wiki/Solar_Drying
  4. Van Campen, B.; D. Guidi & G. Best (FAO), 2000. Solar Photovoltaics for Sustainable Agriculture and Rural Development.http://www.fao.org/uploads/media/Solar%20photovoltaic%20for%20SARD.pdf


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