Combining food and energy production: Design of an agrivoltaic system applied in arable and vegetable farming in Germany

• Published in: Renewable & sustainable energy reviews Vol. 140; p. 110694
• Main Authors: Trommsdorff, Max, Kang, Jinsuk, Reise, Christian, Schindele, Stephan, Bopp, Georg, Ehmann, Andrea, Weselek, Axel, Högy, Petra, Obergfell, Tabea
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.04.2021
• Subjects: Agrivoltaics; Agrophotovoltaics; Integrated food-energy system; Land productivity; Land use efficiency; Solar sharing; Agrivoltaics; Integrated food-energy system; Land productivity; Solar sharing; Land use efficiency; Agrophotovoltaics
• ISSN: 1364-0321; 1879-0690
• DOI: 10.1016/j.rser.2020.110694

Combining agriculture and photovoltaics on the same land area gains in attention and political support in a growing number of countries accompanied by notable research activities in France, USA and Korea, amongst others. This study assesses the technical feasibility of agrivoltaic (APV), while it gives insights on how to design an APV system. Furthermore, it analyses the electrical yield and the behavior and productivity of four crops grown in Germany's largest agrivoltaic research facility installed in 2016 near Lake Constance within the research project APV-RESOLA by Fraunhofer Institute for Solar Energy Systems ISE. The German design differs from most other agrivoltaic approaches by allowing for a wide range of machine employment, facilitated by a vertical clearance of 5 m and a width clearance of up to 19 m. Crops cultivated under the APV system and on the reference field under a crop rotation scheme include potato, celeriac, clover grass and winter wheat. The land use efficiency measured by the Land Equivalent Ratio (LER) indicated a rise between 56% and 70% in 2017 while the dry and hot summer in 2018 demonstrated that the agrivoltaic system could increase land productivity by nearly 90%. Radiation simulations showed that deviating from full south by around 30° resulted in equal distribution of radiation on ground level, representing the basis for the agrivoltaic design. Considering climate change and increasing land scarcity, our overall results suggest a high potential of agrivoltaics as a viable and efficient technology to address major challenges of the 21rst century. •Light distribution under the APV system simulated by Radiance software tool.•Assessment of different system orientations on the light availability.•The effect of different row distance on the biomass and electrical yield.•The technical feasibility and the design of APV in arable farming.•Promising results of Land Equivalent Ratios for the first two operational years.