Stephanie Roblin explores how solar power can be used in farming and explains why it could be an ideal solution for the irrigation purpose in developing countries.
Farmers have always played a very significant role in our society as they provide the world’s population with food.
However, one may also forget that, not only farmers help to provide the world’s population with food but also provide energy, which nowadays, is of paramount importance, especially as in light of renewable energies.
Indeed, farmers can produce energy from the wind, the sun or the biomass and they can use it for their own farm, or, if they have a surplus, resell it to companies.
Solar energy might be one of the easiest ways for farmers to produce energy.
Indeed, farmers usually have several large buildings whose roofs are directly under the sun, without being hindered by the shadows of the trees, turning them into an ideal place to settle a photovoltaic system.
Therefore, the use of solar energy in agriculture is becoming increasingly popular and the energy produced from these renewable energy sources can be used either on the farm or in the local power grid, providing the farmer with an additional income.
One of the areas in agriculture that benefits the most from solar energy is irrigation, especially in arid regions.
The main reason is that using the sun for irrigation represents a virtuous circle: when the sun shines, it feeds the irrigation system, well, we know that crops needs more water when the sun shines a lot.
Therefore, a large quantity of energy is available when it is actually needed.
How Does a Solar Irrigation System Work?
The pumps used for the transport of the water are equipped with solar cells.
The solar energy absorbed by the cells is then converted into electrical energy via a generator which then feeds an electric motor driving the pump.
Most of the traditional pump systems mainly work with a diesel engine or with the local power grid. However, these two modes of operations present disadvantages compared to solar pumps.
In many rural areas, especially in developing and emerging countries, the access to the electricity grid is not always guaranteed. In this case, farmers cannot rely on the traditional irrigation system.
Thus, using an independent and alternative energy system can be a solution for the farmer to secure a safe power source and for the public grid to avoid saturation.
Diesel pumps are slightly more efficient than AC powered pumps as they allow greater flexibility.
However, one of the main constraints is that this system relies on the fuel availability, added to a greater impact on the environment.
Diesel-driven pumps are cheaper than solar-powered pumps but the operating costs are quite high and depend heavily on the diesel price.
In solar-powered systems, it works the other way round, that is, although this system is relatively expensive, the source of energy is free, therefore, after the amortization period, there are no longer operating costs (only the maintenance costs must be considered).
Therefore, solar pumps turn out to be a viable long term investment.
As several studies, such as Water for wealth and food security by AgWater Solutions Project, have shown, the access to water for agricultural purposes remains critical in some areas such as in arid regions of Africa and Southern Asia.
Many Indian and African farmers fetch the water directly from the well or the rivers and irrigate their fields using buckets. If farmers of those regions could have access to a motorized pump, they would increase their yield by 300%.
Therefore, nowadays, R&D tends to focus on creating solar pumps that are affordable in arid regions. The company IBC SOLAR has developed with Siemens, a solution to replace diesel engine by solar-powered engine.
These are alternative solar technology to install solar panels.
That helps irrigation and generate electricity without panel installation.
In this case, the whole irrigation system including the pump can remain as it is; only the diesel engine is replaced by a photovoltaic system and the so-called “IBC pump drive controller”.
A prototype of this system was tested in 2015 in a farm in Namibia and according to the manufacturer, turned out to be quite efficient.
The main advantage lies in the fact that there are low acquisition costs as the existing infrastructure is used.
Where is Solar Irrigation Happening?
The installation of solar pumps in arid regions such as in Africa, India and South America is also part of many development projects, aiming at increasing local farmers productivity and as a consequence, improving their living conditions.
One of the successful example of this is the initiative of a Physics teacher in a school in Blankenese (Germany) where students have developed two solar-powered pumping systems in cooperation with the company SET GmbH from Wedel.
They installed these systems in two farms in Nicaragua to pump underground water. This project could also be achieved with the collaboration of the UNAN University in León, which deals a lot with the exploitation of solar energy.
Indeed, the project has been running for over 10 years and 30 pumps are in operation now in Nicaragua.
It is supervised by the Nicaraguan company Enicalsa that helps farmers benefit from solar irrigation.
The use of solar pumps allows the latter to produce all year round, even in dry season and thus to increase their income and strengthen their position in the local market.
Aside from the regions previously mentioned, there is also an increasing interest in solar irrigation systems in Europe. Just a few months ago, a mobile solar drip irrigation system from Austria has reached the production stage.
The Austrian company Wien Energie carried out this project which pursues a dual objective: on the one hand, reduction of CO2 emissions owing to the use of solar energy, on the other hand, achievement of 30% water savings thanks to the drip irrigation method versus the traditional sprinkler irrigation.
The principle of the drip irrigation method is quite simple. With the use of various valves, hoses and pipes, water drips slowly and at regular intervals to the roots of the plants.
Therefore, there is no water waste as water goes directly where it should go, contrary to a sprinkler system in which water evaporates into the air or seeps into soils where no plants grow.
Therefore, drip irrigation method enables to grow more crops with less water, turning it into a highly efficient irrigation method.
In the Wien Energie solar irrigation system, a mobile solar energy system with photovoltaic modules (up to 3kW) is connected to a wheeled pump which can pump from wells or rivers.
Thanks to an app on your smartphone, you can determine the amount of energy produced by the system.
The solar-powered pump then distributes the water through the hoses, directly to the crops.
After a successful test on a 3.5-hectare organic cornfield in Guntramsdorf, Austria, this system is now ready for production.
Therefore, in countries which suffer from high temperatures and scarce water resources, the drip irrigation system could contribute to an efficient water management.
This is all the more important as farmers have to face three challenges: save water, money and energy.
Mobile solar drip irrigation systems shall turn out to be the perfect answer to face these challenges.
Although these systems are still quite expensive and complicated to settle, many R&D projects are working on the democratization of the use of solar power in agriculture, which, in the future (and even now), could play a vital part in the management of the food and energy crisis.
Solar Water Pump System Solutions!
Water and Irrigation Purposees Projects
In Pakistan, where agriculture is the base of the economy, till date many areas where lands is very fertile, but due to the unavailability of the Electric supply Irrigation is almost impossible or very costly.
Not just that even today there are many regions in Pakistan where due to non-availability of electricity pumping drinking water is also not possible.
To overcome these problems, there are solar water pumping system at a very affordable cost with high reliability.
These systems are best alternatives for areas where there is no electricity or scarcity of power supply.
These pumps operate by converting sunlight directly into electric energy through csp power plants, utility scale solar, concentrated solar power csp and photovoltaics pv.
This large scale solar photovoltaic will soon be around the world’ and the United States energy agency to provide residential solar energy as well assisting in agriculture and irrigation.
The specially designed modules of the system can withstand extreme weather conditions such as storm, rain and dust and are impact resistant.