Plant and fish production performance, nutrient mass balances, energy and water use of the PAFF Box, a small-scale aquaponic system
Plant and fish production performance, nutrient mass balances, energy and water use of the PAFF Box, a small-scale aquaponic system
Aquaponics is an integrated farming concept that combines fish and hydroponic plant production in a recirculating water system. This food production system promises a reduced environmental footprint when compared to conventional farming systems. However, questions regarding its sustainability remain and there is a lack of data on its performance. A small-scale aquaponic system named PAFF Box (Plant And Fish Farming Box) consisting of a ship container topped by a greenhouse was studied. Plant yield in ebb-and-flow and deep water culture (DWC) hydroponic beds, lettuce, basil and tilapia production capacity and water and energy consumption were investigated. Additionally, all macro- and micronutrient mass balances were analyzed in order to give a better picture of their dynamics and recycling ability. Thanks to the daily inputs of tap water, and 42 g of feed per m2 of plant beds, DWC beds showed 3–10 fold higher plant yields than ebb and flow. The production of 1 kg of vegetable in DWC consumed 244 L of water and 84.5 kWh of electricity and 1 kg increase of tilapia consumed 278 L and 96.2 kWh. The system was very efficient in water use for fish production but alternative solutions for warming the water and fine-tuned pumping setup are required to decrease energy needs. Key nutrients such as potassium, phosphorus, iron, copper, zinc, manganese and molybdenum, remained low in solution. Nitrate, calcium, boron and sodium concentrations increased quickly and only water exchange could control their accumulation meanwhile a low daily water exchange rate of 3.6% implicated a high nutrient loss in the environment. In the willingness to decrease aquaponics environmental footprint, this study indicates that improved designs could be explored such as decoupled aquaponic systems.
130-139
Delaide, Boris
ff8d6bc8-147e-41ab-b2ee-1375524086b7
Delhaye, Guillaume
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Dermience, Michael
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Gott, James
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Soyeurt, Hélène
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Jijakli, M. Haissam
38b8a762-36d9-47dc-8b15-9c2307e02ffb
1 August 2017
Delaide, Boris
ff8d6bc8-147e-41ab-b2ee-1375524086b7
Delhaye, Guillaume
c08a984c-3056-47bc-ac65-5f6d0edd2d49
Dermience, Michael
c10c69d0-82d8-432b-a73e-ab6667aefbc9
Gott, James
12937a59-3096-4980-8330-e82df5fb35d1
Soyeurt, Hélène
5d85a25b-97c4-44b8-a0ba-03f266a2bd34
Jijakli, M. Haissam
38b8a762-36d9-47dc-8b15-9c2307e02ffb
Delaide, Boris, Delhaye, Guillaume, Dermience, Michael, Gott, James, Soyeurt, Hélène and Jijakli, M. Haissam
(2017)
Plant and fish production performance, nutrient mass balances, energy and water use of the PAFF Box, a small-scale aquaponic system.
Aquacultural Engineering, 78 (B), .
(doi:10.1016/j.aquaeng.2017.06.002).
Abstract
Aquaponics is an integrated farming concept that combines fish and hydroponic plant production in a recirculating water system. This food production system promises a reduced environmental footprint when compared to conventional farming systems. However, questions regarding its sustainability remain and there is a lack of data on its performance. A small-scale aquaponic system named PAFF Box (Plant And Fish Farming Box) consisting of a ship container topped by a greenhouse was studied. Plant yield in ebb-and-flow and deep water culture (DWC) hydroponic beds, lettuce, basil and tilapia production capacity and water and energy consumption were investigated. Additionally, all macro- and micronutrient mass balances were analyzed in order to give a better picture of their dynamics and recycling ability. Thanks to the daily inputs of tap water, and 42 g of feed per m2 of plant beds, DWC beds showed 3–10 fold higher plant yields than ebb and flow. The production of 1 kg of vegetable in DWC consumed 244 L of water and 84.5 kWh of electricity and 1 kg increase of tilapia consumed 278 L and 96.2 kWh. The system was very efficient in water use for fish production but alternative solutions for warming the water and fine-tuned pumping setup are required to decrease energy needs. Key nutrients such as potassium, phosphorus, iron, copper, zinc, manganese and molybdenum, remained low in solution. Nitrate, calcium, boron and sodium concentrations increased quickly and only water exchange could control their accumulation meanwhile a low daily water exchange rate of 3.6% implicated a high nutrient loss in the environment. In the willingness to decrease aquaponics environmental footprint, this study indicates that improved designs could be explored such as decoupled aquaponic systems.
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More information
Accepted/In Press date: 6 June 2017
e-pub ahead of print date: 7 June 2017
Published date: 1 August 2017
Identifiers
Local EPrints ID: 437010
URI: http://eprints.soton.ac.uk/id/eprint/437010
ISSN: 0144-8609
PURE UUID: e0726f04-93f4-4194-96c7-3992d9a48d00
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Date deposited: 15 Jan 2020 17:30
Last modified: 16 Mar 2024 06:06
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Contributors
Author:
Boris Delaide
Author:
Guillaume Delhaye
Author:
Michael Dermience
Author:
James Gott
Author:
Hélène Soyeurt
Author:
M. Haissam Jijakli
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