To main content

RASORGMAT

RASORGMAT

The project addresses important challenges in land-based, closed containment aquaculture facilities using water recirculation treatment technology (RAS).

We will examine how water hydraulics in circular and rectangular tanks and water treatment strategy, influence the content of organic matter, microbial communities and the quality of product. In addition, we on developing a new type of sensor for carbon dioxide in RAS systems.

The project is funded by ERANET, COFASAP and is a research collaboration between SINTEF OCEAN AS, University of Copenhagen and CIIMAR, Portugal. In addition students (Masters ad PhD) from NTNU participate in parts of the program. The experiment are carried out at NTNU Sealabs new RAS facility.

WordPackages:

WP1 : Tank Hydraulics
WP2 : Removal of Organic matter in RAS
WP3 : Effects on microbial communities
WP4 : Effect on Off-flavour
WP5 : Effects on Dissolved Carbon Dioxide

Objectives:

  1. To characterize the consequence of different levels of organic matter removal (high, low) in LBCC-RAS on: (1) conventional water quality parameters, (2) heterotrophic microbial carrying capacity, bacterial stability and nitrification efficiency, (3) the biological processes that cause off-flavour production, and (4) dissolved CO2.
  2. To demonstrate the water flow pattern in circular and plug-flow rearing in LBCC-RAS to obtain improved self-cleaning and high water quality conditions for fish.
  3. To develop an overall tank design for water flow in fish tanks/raceways in LBCC-RAS that facilitates early removal of particles.
  4. To demonstrate the usefulness of a dissolved CO2 sensing platform for approximation of RAS organic load.

Accomplishments:

  • Workshop with all partners (R&D and Industry) in Velje Denmark
  • Workshop with all partners involved in experiment in the mini RAS system at NTNU Trondheim
  • Established the experimental RAS set up at NTNU, Sealab in Trondheim Norway
  • Developed a new treatment setup for removal of organic matter in the experimental setup
  • Done first experiment testing how turbulence from fishes influences the movement of particles in a circular tank system.
  • Started the development and initial test of the new CO2 sensor
  • Different taxonomic groups of off-flavour producing microorganisms were identified in biofilter of a recirculated system in Denmark

[{¤src¤:¤/globalassets/sintef-ocean/prosjekter/rasorgmat/figure1.png¤,¤alt¤:¤Figure 1. Configuration of the new dissolved CO2 sensor to be tested in RAS-ORGMAT project. This sensor uses multimode optical fibers combined with polymer membranes capable to change its own color\nin the presence of Co2. Photo: Niels O. G. Jørgensen (University of Copenhagen).¤},{¤src¤:¤/globalassets/sintef-ocean/prosjekter/rasorgmat/figure2.png¤,¤alt¤:¤Figure 2. The organic matter supply is determining for the carrying capacity of heterotrophic bacteria in the recirculating aquaculture systems. High supply gives room for more bacteria, and sudden increases in the supply\nof organic matter will promote growth of bacteria to the new carrying c apacity. Opportunistic bacteria are favoured during this regrowth. Photo: SINTEF¤},{¤src¤:¤/globalassets/sintef-ocean/prosjekter/rasorgmat/figure3.png¤,¤alt¤:¤Figure 3. Off flavour producing bacterias. Filamentous cyanobacteria (top left), Streptomyces (right), Myxobacteria (bottom left). The intense fish density and water reuse\nin RAS have in many cases led to an unwanted growth of off-flavour-producing microorganisms.\nCoelho, L (INESC/CIIMAR-University of Porto, Portugal)¤}]

Expected impact of project for policy/industry/other stakeholder and future perspectives:

The project will pave the way for further innovation of Landbased Closed Containment (LBCC)-RAS systems. The deliverables provides necessary knowledge important for successful development of both inland aquaculture and smolt / post-smolt farms. By helping decreasing waste effluents and bio-deposit impacts, and these measures will allow for an increased and improved aquaculture production, even in environmental sensitive areas. The project aim to improve strategies and technology for optimum control of the production environment, but will also help in safeguarding fish quality and animal welfare. We believe that the project will:

  1. Provide ideas for simpler, lower capital expenditure, more compact, efficient and well performing RAS systems
  2. Develop new and integrated knowledge on production and mitigation on off-flavour compounds in RAS
  3. Deliver new directions for optimum control of the water body inside the a fish tank. The results are particular important for Portugal, since the country wants to develop inland aquaculture, and LBCC- RAS is signalised as the preferred technology by the authorities.

Results from the project are also expected to be of major importance for improving the water quality in LBCC-RAS in Denmark and Norway, where a significant production fish already occurs. Denmark has their "model dambrug" and nitrogen quotas, whilst Norway have opened up for further expansion of salmon production to harvest size LBCC-RAS systems. The challenges they will meet in water and product quality will be addressed in this project and strategies and water treatment solutions will be published so they are available as scientific background for the industry and authorities.

Fish
Underwater picture form first experiment, testing the effects of fish on turbulence and particle removal in circular tanks. Photo: SINTEF
Published 14 August 2017
Senior Research Scientist

Project duration

2016 - 2018

Funding:

Total: €765 213
Denmark: €238.223
Norway: €400.000
Portugal: €126.990