The Effects of Dissolved Carbon Dioxide on the Formation of Vaterite in Aquacultured Rainbow Trout Oncorhynchus Mykiss

Adams, Casondra A.

19 December 2022

No description available.

Aquaculture

Physiology

Biology

Aquatic Sciences

recirculating aquaculture system (RAS)

carbon dioxide

aragonite

vaterite

The Presence of Pathogenic Bacteria in Recirculating Aquaculture System Biofilms and their Response to Various Sanitizers

King, Robin K.

26 April 2001

Recirculating aquaculture offers a prospect for successful fish farming, but this form of aquaculture presents a great potential for pathogenic microorganisms to become established in the system through the formation of biofilms. Biofilms are capable of forming on all aquaculture system components, incorporating the various microflora present in the water. Pathogenic microorganisms released from the biofilms are capable of causing recurring exposure to disease in both fish and humans. With the increased consumption of raw and rare fish, the presence of these bacteria in or on the fish could lead to ingestion of pathogens. There is also the possibility of cross-contamination during processing. The objectives of this study were to increase the understanding of pathogen incorporation into biofilms in recirculating aquaculture systems and to determine the effectiveness of various sanitizers in eliminating biofilms. Seven freshwater and two saltwater facilities were sampled, with eight different types of materials tested. Pathogenic bacteria were identified using Bacteriological Analytical Manual methods and rapid commercial test kits. Most of the pathogenic bacteria identified were opportunistic organisms ubiquitous in an aquatic environment. The most significant human pathogens were Bacillus cereus, the Shigella species and the Vibrio species. The major piscine pathogens of concern were Photobacterium damsela, the Vibrio species, and Aeromonas hydrophila. The most significant variation in biofilm pathogens was observed between facilities and not construction material. Buna-N rubber, polyvinyl chloride (PVC), chlorinated PVC, glass, fiberglass and stainless steel disks were suspended in 79.2 liter (20 gallon) aquariums stocked with Nile tilapia (Oreochromus niloticus). The tanks were inoculated with a known amount of green fluorescent protein (GFP) modified Escherichia coli and samples were removed on days 1,3, 7 and 15. The modified E. coli were isolated on Luria Broth Agar and plate counts were performed under ultraviolet light. There was no significant difference in the growth of the surrogate pathogen on the different materials. The GFP E. coli was isolated in the largest numbers 24 hours after inoculation of the tanks, with an approximate 1-log decrease after day 1. Days 3, 7, and 15 showed equivalent growth of the target organism. Two sets of disks were suspended in another six 79.2 liter (20 gallon) aquariums. The tanks were inoculated with a known amount of the surrogate pathogen, GFP E. coli, and after 24 hours one set of disks was removed from each tank. The second set of disks was removed and treated by spraying with water, alkaline cleanser, sodium hypochlorite, quaternary ammonium compound, or peracetic acid. Ozone was bubbled directly into one tank to treat another set of disks. The modified E. coli were isolated and counted. Total aerobic plate counts and Enterobacteriaceae counts were performed. Statistical analysis indicated that the type of material had no significant affect on the effectiveness of the sanitizers. It was determined that sodium hypochlorite (99.4591 overall reduction) and peracetic acid (98.8461 % overall reduction) were the most effective sanitizers overall, and ozone (32.9332 % overall reduction) was the least effective. / Ph. D.

sodium hypochlorite

peracetic acid

ozone

quaternary ammonium compounds

recirculating aquaculture

green fluorescent protein

Biofilms

Evaluation of ozone treatment, pilot-scale wastewater treatment plant, and nitrogen budget for Blue Ridge Aquaculture

Sandu, Simonel Ioan

12 October 2004

Sustainable tilapia production at Blue Ridge Aquaculture (BRA) is constrained by availability of high quality replacement water. I developed a pilot-scale wastewater treatment system to treat and reuse effluent presently discharged. An initial study was conducted to determine the response of the BRA waste stream to ozone application. Dosages of 6.9, 4.8 and 2.4 g O3 were applied for 30 minutes to 35 L of settled effluent. Optimum ozone dosage and reaction time, ozone transfer efficiency, ozone yield coefficient, degree of pollutant removal, and other ozone and water quality parameters were determined. Most results suggested that the maximum process feasibility limit for ozone contact time was approximately 9 minutes at an applied ozone concentration of 23g/m3 (6.9 g O3 dose). Formation of foam increased solids and COD removal up to three times. Poor removal or accumulation of DOC and TAN was observed, indicating the need for biological treatment following ozonation. Next, I evaluated a pilot station treatment train including sedimentation, microscreen filtration, fluidized bed denitrification, ozonation, aerobic biological oxidation in a trickling filter, and jar-test chemical flocculation. Significant improvements were found regarding solids, COD, cBOD5, NO3--N, TKN, and turbidity. Removal of foam after ozonation improved ozonation efficacy and pollutant removal. A nitrogen budget for the BRA facility was derived, indicating that 35% of the nitrogen applied in feed was assimilated in fish. I evaluated the possible impact of residual inorganic nitrogen forms from treated effluent upon fish in the recirculating systems. I found that less than 1% of the TAN produced would return the recovered stream, and that the existing biological contactors can remove it. Evaluation of TAN fate indicated that 84% was oxidized in biofilters, 14% was oxidized by passive nitrification, and 1% was removed by water exchange. For NO3-N, I determined that 56% was removed by passive denitrification and 44% by daily water exchange. The pilot station design was effective for removing organics and nutrients, and can serve as the basis for scale-up for treating and reusing the entire BRA effluent stream. / Ph. D.

aquaculture

recirculating aquaculture systems

wastewater treatment

pilot plant

ozone

nitrogen budget

Establishment and Utilization of Tools for Enhancing Foodfish Health

Galagarza, Oscar Andres

29 January 2018

Aquacultured products assist the human demands for seafood so that foodfish supplies can remain sustainable and consistent. Although the fish-farming industry has seen dramatic growth and intensification in recent years, the latter has led to an increase in bacterial diseases and fish health management problems, resulting in major economic losses around the world. In addition to the lack of understanding of fish physiology, these complications are exacerbated by the inappropriate and controversial use of antibiotics. This work addressed these issues in striped catfish (Pangasius hypophthalmus) and Nile tilapia (Oreochromis niloticus), two economically important foodfish, by investigating alternative, more cost-effective options to promote fish health. The first two studies established reference intervals for immunology, hematology and plasma chemistry analytes in striped catfish in a recirculating aquaculture system (RAS). In a third study, the immunomodulatory effects after directly feeding probiotic strains of Bacillus subtilis NZ86 and O14VRQ in Nile tilapia were ascertained. This last study revealed that supplementation with both of the probiotic strains for 51 days stimulated several local and systemic innate immune responses of tilapia. When these transient probiotic bacteria were present in the gut, a pro-inflammatory environment was developed as evidenced by the localized higher expression of the cytokines tumor necrosis factor (TNF) – α and interleukin (IL) – 1β. Significant increases (p < 0.05) were noted differentially by both probiotic strains throughout the trial in plasma lysozyme content, alternative complement activity, and in the peripheral blood leukocyte profiles. Additionally, there were trends for increased levels of phagocytosis and respiratory burst in leukocytes of the anterior kidney and spleen at the end of the trial, suggesting the potential use of these probiotic strains for improved immune-competence. These findings help to understand and clarify the potential mechanism of action associated with the increased disease resistance recorded in preliminary studies with the same probiotic strains. Implementation of the tools established and validated in this work could be useful in evaluating fish welfare situations involving striped catfish grown in RAS conditions, and also show promise for a healthier foodfish supply where antibiotic applications practices could be minimized. / Ph. D.

tilapia

striped catfish

Bacillus subtilis

probiotics

reference intervals

hematology

immunity

recirculating aquaculture systems

Nitrogen Removal from Closed Aquaculture System by Bio-electrochemical System

Guan, Lu

22 January 2018

Removal of nitrogen elements in culture water is one of the major concerns in recirculating aquaculture system (RAS). Maintaining a low concentration of nitrogen compounds is essential for a good quality of aquaculture production. Due to fish is very sensitive to the toxic ammonium/ammonia, nitrification biofiltration tank is often an integrate part of filtration in RAS to remove ammonium via nitrification. However, nitrate accumulation via nitrification in RAS is often observed during the operation, which is usually solved by replacing with the fresh water into the system. With the concern of water consumption, bio-electrochemical system (BES) is introduced in this study to realize simultaneous nitrate removal for the system while generating the electricity through electron transferring. A microbial fuel cell (MFC) with an anion exchange membrane (AEM) was constructed. The removal of nitrate from aquaculture water generated from RAS was achieved by nitrate migration across the AEM and heterotrophic denitrification in the anode chamber. To further investigate the potential application of BES in RAS, the cathode chamber was incubated with biofilm to do the nitrification while the denitrification processing in the anode chamber. The study gave a total inorganic nitrogen removal efficiency of 38.72% ± 4.99, and a COD removal of 86.09% ± 9.83. The average daily electricity generation was 67.98 A m-3 ± 13.91, and nitrate-nitrogen concentration remained at 21.02 ± 2.62 mg L-1 throughout the experiment. These results of treating aquaculture water indicate that BES has a potential to install within RAS for enhanced nitrogen removal. / MS

Bio-electrochemical systems

Recirculating Aquaculture System (RAS)

Microbial Fuel Cells

Nitrification

Denitrification

Smakprofil av Tilapia (Niltilapia) : en jämförelse av vakuumförpackad Tilapia över tid. / Sensory profile of Tilapia (Nile tilapia) : A comparison of Tilapia in vacuum package over time

Bohman, Marcus, Magnusson, Per

January 2016

Fler svenskar vill konsumera mer inhemskt producerad fisk. Scandinavian Aquasystems odlar och försöker introducera fisken tilapia på svenska marknaden. Tilapia är en fisk som precis börjat göra intåg i Europa men är stor runtomkring resten av världen. En smakprofil som berättar hur länge produkten är sensoriskt tjänlig kan vara av hjälp. Denna undersökning syftade till att skapa en sensorisk smakprofil för fisken tilapia och till att se hur smakprofilen förändrades vid lagring i vakuumförpackning. För att skapa smakprofilen användes metoden QDA. Resultatet gav många egenskapsord var av vissa kunde klassificeras som färskhetsrelaterade och vissa som förskämningsrelaterade. Det kunde även konstateras att färsk, odlad tilapia har en antydan av saftigare och mer mjäll textur. Vid lagring finns en möjlighet att tilapia får en intensivare smak av dy och metall, samt en intensivare doft av dy. / A large amount of Swedes has a desire to consume more nationally produced fish. Scandinavian Aquasystems produces and tries to introduce tilapia into the Swedish market. As a fish, tilapia has just begun making ways into Europe but is already a big commodity around the rest of the world. In addition, a sensory profile which tells how long the product remains sensorially suitable could be of help. This study aimed to create a sensory profile and to study its inherent effects of vacuum packaging over time. In creating the sensory profile, a QDA method was used. The study resulted in a variance of different attributes which of some could be categorized as either fresh related or spoilage related. It was found that fresh, farmed tilapia carried an indication of having a juicier and more tender texture. With storage there is chance of tilapia getting a more intense flavor of mud and metal, as well as a more intense odor of mud.

Tilapia

Sensory

Recirculating aquaculture system

Sensory profile

Shelf-life

Fish

Geosmin

Tilapia

Sensorik

Recirkulerande vattenbruk

Smakprofil

Lagring

Fisk

Geosmin

Desempenho de um sistema de tratamento de efluentes de aquacultura : a recirculação como um alternativa sustentável

Porto, Cassiano Cauê Pôssas

January 2010

O intenso desenvolvimento da aquacultura tem sido acompanhado de um aumento nos impactos ambientais causados por esta atividade. As descargas de efluentes da aquacultura em ecossistemas aquáticos são uma fonte de deterioração da qualidade ambiental e podem causar eutrofização. O presente trabalho investigou e avaliou o desempenho de um sistema de tratamento e recirculação de efluentes de aquacultura em relação à sua eficiência em manter e restaurar os parâmetros de qualidade da água em níveis adequados ao ciclo produtivo, considerando as implicações desta técnica na conservação dos recursos hídricos. O experimento foi conduzido em dois sistemas funcionando paralelamente, simulando situações com e sem tratamento e recirculação de efluentes. Os sistemas aquícolas, em escala experimental, foram compostos pelos tanques e pelas unidades de tratamento e recirculação. Os tanques de cultivo foram povoados com juvenis de tilápia-do-Nilo (Oreochromis niloticus). Os sistemas sem recirculação e com recirculação receberam, respectivamente, 65 indivíduos (biomassa total inicial = 477g) e 64 indivíduos (biomassa total inicial = 491g). O sistema de tratamento e recirculação de efluentes foi composto por um filtro biológico de leito flutuante granular (floating beads biofilter) e duas colunas de aeração, com diferentes meios de preenchimento. Ao longo dos seis meses de experimento foram medidos os principais parâmetros de qualidade da água para a aquacultura e para a estimativa do funcionamento e desempenho do sistema de tratamento e recirculação de efluentes. O desempenho zootécnico obtido nos tanques foi também avaliado e comparado. Análise de variância (ANOVA) foi utilizada para comparar os dados. Na comparação entre a água de cultivo dos tanques, os seguintes parâmetros apresentaram um valor mais elevado (p<0,05) para o sistema com recirculação: nitrato, carbono orgânico total, fosfato, cloreto, sulfato e condutividade. A água de cultivo do tanque sem recirculação apresentou maiores valores de nitrogênio amoniacal, sólidos suspensos e turbidez (p<0,05). As duas colunas de aeração usadas no experimento não apresentaram diferenças significativa entre si (p>0,05), apresentando uma eficiência de aeração de 67%. O sistema com recirculação foi caracterizado por um uso semanal de água significativamente menor (p<0,05), utilizando apenas 36% do volume de água que foi necessário para o tanque sem recirculação. Indícios de nitrificação foram identificados em ambos os sistemas, porém este processo apresentou uma importância maior sobre a qualidade da água no sistema com recirculação e filtro biológico. O sistema com recirculação produziu efluentes (através da retrolavagem do filtro) mais concentrados (p<0,05) em relação a nitrato, alcalinidade, carbono orgânico total, fosfato, sólidos suspensos e dissolvidos, cloreto, sulfato, condutividade. Em relação à carga de resíduos lançada ao ambiente, o sistema sem recirculação obteve valores maiores (p<0,05) de nitrogênio amoniacal, nitrato, carbono orgânico total, fosfato, sólidos suspensos, sólidos dissolvidos, fluoreto, cloreto e sulfato. Para os demais parâmetros, não houve diferenças significativas quanto à carga de resíduo do efluente produzido (p>0,05). Não houve diferenças significativas entre os dois sistemas comparados (p>0,05) quanto ao ganho de peso das tilápias durante o período de avaliação do desempenho zootécnico. A partir da biomassa total de peixes produzida nos dois tanques durante todo o período experimental calculou-se que o sistema sem recirculação fez uso de 4053 litros de água para cada kg (L/kg) de peixe produzido e o sistema com recirculação usou 1129 L/kg. O sistema de aquacultura com recirculação estudado, construído a partir de materiais nacionais e de baixo custo, obteve êxito como forma de criação de peixes, oferecendo uma significativa redução no volume de água usado e na carga de alguns resíduos em seus efluentes, quando comparado a técnicas convencionais de aquacultura. Apesar de haver significativas necessidades de aprimoramento do protótipo usado e de estudos complementares em relação ao assunto tendo em vista a realidade brasileira, principalmente contemplando a sua viabilidade econômica em diferentes cenários, o experimento conduzido oferece subsídios para o desenvolvimento da tecnologia de aquacultura com recirculação em âmbito nacional. / The active aquaculture growth that has been observed over the last few decades has been accompanied by important environmental impacts. One main concern is the discharge of aquaculture effluents in aquatic systems. Since these effluents contain nutrients, their discharge can contribute to the eutrophication of the receiving water bodies. The present work describes an investigation in which the aquaculture effluent was treated and recycled back to the system. The treatment process was evaluated with respect to its capability to remove contaminants and restore water quality to levels that were adequate to the fishing productive cycle. Such a system can contribute to the conservation of water resources by saving water and discarding fewer pollutants. The experiment was conducted in two pilot systems working in parallel, simulating fish culture processes with and without effluent treatment and recycling. The culture tanks were populated with Nile tilapia (Oreochromis niloticus). The systems with and without recirculation were populated with 65 (initial total biomass = 477g) and 64 (initial total biomass = 491g) individuals, respectively. The effluent treatment and recirculation system were composed by a floating bead biofilter and two natural aeration columns, each filled with different media. The experiment was conducted along six months, during which the systems were monitored for water quality parameters and zootechnical performance. Analysis of variance (ANOVA) was used to compare data collected in the culture tanks. The following parameters presented a higher value (p<0.05) in the recirculation system: nitrate, total organic carbon, phosphate, chloride, sulfate and conductivity. Culture water without recirculation presented higher values for total ammonia nitrogen, suspended solids and turbidity (p<0.05). The two aeration columns used in the experiment had about 67% aeration efficiency. Water use in the recirculation system was significantly lower (p<0.05) than the system without recycling, using just 36% of the water needed by the latter. Nitrification occurred in both systems, but had greater importance in the process with recycling and biological filtration. Filter backwashing from the recirculating system produced effluent that was more concentrated (p<0.05) than the system without recycling with respect to nitrate, alkalinity, total organic carbon, phosphate, suspended and dissolved solids, chloride, sulfate and conductivity. On the contrary, the residue loads discharged from the system without recirculation were higher (p<0.05) for total ammonia nitrogen, nitrate, total organic carbon, phosphate, suspended and dissolved solids, fluoride, chloride and sulfate. For the remaining parameters, no significant difference in the residue loads of the two systems was observed (p>0.05). One important observation was that no significant difference occurred between the two systems (p>0.05) regarding tilapia weight gains in the experimental period. Based on the fish biomass growth and water use measured on both systems, it was calculated that the system without recirculation used 4053 liters of water per each kg of produced fish. On the other hand, the system with recirculation used 1129 liters per kg. Considering the outlined results, it was concluded that the recirculating aquaculture system, built with simple and low cost national material, was successful with respect to fish cultivation, water use reduction, and effluent residue load discharges when compared with the conventional aquaculture technique. Despite the required refinements of the tested prototype, especially regarding scale and economic viability in different scenarios, it offers subsidies to the advance of the recirculating aquaculture technology at the national level.

Tratamento de efluentes

Aqüicultura

Filtro biologico

Tilapia do nilo

Recirculating aquaculture

Biological filter

Aquaculture wastewater treatment

Tilapias intensive production

Vliv nasycení vody kyslíkem na příjem krmiva a růst síha peledě (Coregonus peled) v intenzivním chovu / Influence of oxygen saturation on feed intake and growth of peled whitefish (Coregonus Peled) in intensive farming

SEICHERSTEIN, Adam

January 2014

The results of an experimental rearing of peled under different oxygen regimes are presented in this work. Four variants were tested in three repetitions (hypoxia 55-65 %, normoxia 85-95 %, permanent hyperoxia 145-155 % and alternate hyperoxia 145-155 % during the day and 85-95 % overnight). Also the oxygen consumption of fish with weight from 4.5 to 20 g at temperatures of 15, 19 and 23 °C was measured.

Desempenho de um sistema de tratamento de efluentes de aquacultura : a recirculação como um alternativa sustentável

Porto, Cassiano Cauê Pôssas

January 2010

O intenso desenvolvimento da aquacultura tem sido acompanhado de um aumento nos impactos ambientais causados por esta atividade. As descargas de efluentes da aquacultura em ecossistemas aquáticos são uma fonte de deterioração da qualidade ambiental e podem causar eutrofização. O presente trabalho investigou e avaliou o desempenho de um sistema de tratamento e recirculação de efluentes de aquacultura em relação à sua eficiência em manter e restaurar os parâmetros de qualidade da água em níveis adequados ao ciclo produtivo, considerando as implicações desta técnica na conservação dos recursos hídricos. O experimento foi conduzido em dois sistemas funcionando paralelamente, simulando situações com e sem tratamento e recirculação de efluentes. Os sistemas aquícolas, em escala experimental, foram compostos pelos tanques e pelas unidades de tratamento e recirculação. Os tanques de cultivo foram povoados com juvenis de tilápia-do-Nilo (Oreochromis niloticus). Os sistemas sem recirculação e com recirculação receberam, respectivamente, 65 indivíduos (biomassa total inicial = 477g) e 64 indivíduos (biomassa total inicial = 491g). O sistema de tratamento e recirculação de efluentes foi composto por um filtro biológico de leito flutuante granular (floating beads biofilter) e duas colunas de aeração, com diferentes meios de preenchimento. Ao longo dos seis meses de experimento foram medidos os principais parâmetros de qualidade da água para a aquacultura e para a estimativa do funcionamento e desempenho do sistema de tratamento e recirculação de efluentes. O desempenho zootécnico obtido nos tanques foi também avaliado e comparado. Análise de variância (ANOVA) foi utilizada para comparar os dados. Na comparação entre a água de cultivo dos tanques, os seguintes parâmetros apresentaram um valor mais elevado (p<0,05) para o sistema com recirculação: nitrato, carbono orgânico total, fosfato, cloreto, sulfato e condutividade. A água de cultivo do tanque sem recirculação apresentou maiores valores de nitrogênio amoniacal, sólidos suspensos e turbidez (p<0,05). As duas colunas de aeração usadas no experimento não apresentaram diferenças significativa entre si (p>0,05), apresentando uma eficiência de aeração de 67%. O sistema com recirculação foi caracterizado por um uso semanal de água significativamente menor (p<0,05), utilizando apenas 36% do volume de água que foi necessário para o tanque sem recirculação. Indícios de nitrificação foram identificados em ambos os sistemas, porém este processo apresentou uma importância maior sobre a qualidade da água no sistema com recirculação e filtro biológico. O sistema com recirculação produziu efluentes (através da retrolavagem do filtro) mais concentrados (p<0,05) em relação a nitrato, alcalinidade, carbono orgânico total, fosfato, sólidos suspensos e dissolvidos, cloreto, sulfato, condutividade. Em relação à carga de resíduos lançada ao ambiente, o sistema sem recirculação obteve valores maiores (p<0,05) de nitrogênio amoniacal, nitrato, carbono orgânico total, fosfato, sólidos suspensos, sólidos dissolvidos, fluoreto, cloreto e sulfato. Para os demais parâmetros, não houve diferenças significativas quanto à carga de resíduo do efluente produzido (p>0,05). Não houve diferenças significativas entre os dois sistemas comparados (p>0,05) quanto ao ganho de peso das tilápias durante o período de avaliação do desempenho zootécnico. A partir da biomassa total de peixes produzida nos dois tanques durante todo o período experimental calculou-se que o sistema sem recirculação fez uso de 4053 litros de água para cada kg (L/kg) de peixe produzido e o sistema com recirculação usou 1129 L/kg. O sistema de aquacultura com recirculação estudado, construído a partir de materiais nacionais e de baixo custo, obteve êxito como forma de criação de peixes, oferecendo uma significativa redução no volume de água usado e na carga de alguns resíduos em seus efluentes, quando comparado a técnicas convencionais de aquacultura. Apesar de haver significativas necessidades de aprimoramento do protótipo usado e de estudos complementares em relação ao assunto tendo em vista a realidade brasileira, principalmente contemplando a sua viabilidade econômica em diferentes cenários, o experimento conduzido oferece subsídios para o desenvolvimento da tecnologia de aquacultura com recirculação em âmbito nacional. / The active aquaculture growth that has been observed over the last few decades has been accompanied by important environmental impacts. One main concern is the discharge of aquaculture effluents in aquatic systems. Since these effluents contain nutrients, their discharge can contribute to the eutrophication of the receiving water bodies. The present work describes an investigation in which the aquaculture effluent was treated and recycled back to the system. The treatment process was evaluated with respect to its capability to remove contaminants and restore water quality to levels that were adequate to the fishing productive cycle. Such a system can contribute to the conservation of water resources by saving water and discarding fewer pollutants. The experiment was conducted in two pilot systems working in parallel, simulating fish culture processes with and without effluent treatment and recycling. The culture tanks were populated with Nile tilapia (Oreochromis niloticus). The systems with and without recirculation were populated with 65 (initial total biomass = 477g) and 64 (initial total biomass = 491g) individuals, respectively. The effluent treatment and recirculation system were composed by a floating bead biofilter and two natural aeration columns, each filled with different media. The experiment was conducted along six months, during which the systems were monitored for water quality parameters and zootechnical performance. Analysis of variance (ANOVA) was used to compare data collected in the culture tanks. The following parameters presented a higher value (p<0.05) in the recirculation system: nitrate, total organic carbon, phosphate, chloride, sulfate and conductivity. Culture water without recirculation presented higher values for total ammonia nitrogen, suspended solids and turbidity (p<0.05). The two aeration columns used in the experiment had about 67% aeration efficiency. Water use in the recirculation system was significantly lower (p<0.05) than the system without recycling, using just 36% of the water needed by the latter. Nitrification occurred in both systems, but had greater importance in the process with recycling and biological filtration. Filter backwashing from the recirculating system produced effluent that was more concentrated (p<0.05) than the system without recycling with respect to nitrate, alkalinity, total organic carbon, phosphate, suspended and dissolved solids, chloride, sulfate and conductivity. On the contrary, the residue loads discharged from the system without recirculation were higher (p<0.05) for total ammonia nitrogen, nitrate, total organic carbon, phosphate, suspended and dissolved solids, fluoride, chloride and sulfate. For the remaining parameters, no significant difference in the residue loads of the two systems was observed (p>0.05). One important observation was that no significant difference occurred between the two systems (p>0.05) regarding tilapia weight gains in the experimental period. Based on the fish biomass growth and water use measured on both systems, it was calculated that the system without recirculation used 4053 liters of water per each kg of produced fish. On the other hand, the system with recirculation used 1129 liters per kg. Considering the outlined results, it was concluded that the recirculating aquaculture system, built with simple and low cost national material, was successful with respect to fish cultivation, water use reduction, and effluent residue load discharges when compared with the conventional aquaculture technique. Despite the required refinements of the tested prototype, especially regarding scale and economic viability in different scenarios, it offers subsidies to the advance of the recirculating aquaculture technology at the national level.

Tratamento de efluentes

Aqüicultura

Filtro biologico

Tilapia do nilo

Recirculating aquaculture

Biological filter

Aquaculture wastewater treatment

Tilapias intensive production

Utilização de reator aeróbio de leito fluidizado com circulação em tubos concêntricos no tratamento de águas residuarias da produção intensiva de tilapia com recirculação da água tratada

Maigual Enriquez, Yemall Alexander [UNESP]

22 August 2011

Made available in DSpace on 2014-06-11T19:30:23Z (GMT). No. of bitstreams: 0 Previous issue date: 2011-08-22Bitstream added on 2014-06-13T20:20:51Z : No. of bitstreams: 1 maigualenriquez_ya_me_ilha.pdf: 1515184 bytes, checksum: 854b45266358b64c6017c5058af88c81 (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Sistemas de Recirculação para Aquicultura (SRA) possibilitam um meio alternativo de produção de peixes para áreas com limitada disponibilidade de água. Estes sistemas de cultivo intensivo de peixes oferecem potencial de produção em pequena escala assim como em grande escala, devido a recuperação de efluentes e a reutilização da água, produzindo volumes relativamente pequenos de resíduos líquidos e sólidos. O objetivo deste estudo foi determinar a eficácia do tratamento de águas residuárias em relação à remoção de Nitrogênio Amoniacal Total (NAT), Sólidos Totais (ST), Sólidos Suspensos Totais (SST), Demanda Química de Oxigênio (DQO) e Demanda Bioquímica de Oxigênio (DBO5), Nitrogênio total (NT) e Fósforo Total (FT). Para tanto, foram introduzidos Tilápia do Nilo (Oreochromis niloticus), com 0,323kg de peso médio inicial e 17 kg m-3 de densidade de armazenamento inicial no SRA experimental. O SRA era composto de 03 tanques de plástico com capacidade de 0,20 m3, Decantador de Coluna (DC), o reator de leito fluidizado aeróbio com circulação em tubos concêntricos (BAS-CT), tendo como meio de suporte a areia de diâmetro efetivo (D10) = 0,29 mm e na sequência reator de transferência de oxigênio e remoção de CO2. A eficiência na remoção do NAT no reator BAS-CT no período de aclimatação e de estabilização foi 31,0% e 35,2%, respectivamente. A remoção de ST e SST foi de 44,44% e 71,71%, respectivamente. A eficiência alcançada de remoção no SRA da DQO foi de 64,90% e de 48,01% para DBO5. Os valores médios de remoção do NT e FT no SRA foram de 25,02% e 41,05%, respectivamente. Estes resultados indicaram que o tratamento de águas residuárias de aquicultura proposto neste estudo através do BAS-CT associado ao DC tem evitado elevadas concentrações e acumulação de poluentes dentro do SRA / Recirculating aquaculture systems (RAS) offer an alternative means of fish production for areas that to have limited water and land availability. RAS are a highly intensive fish culture systems and offer potential production units for small and large scale operations. For effluent recovery and treated water reuse, RAS produce relatively small volumes of liquid and solids wastes. The objective of this study were to determine the efficiency of the wastewater treatment with recommended to removal of Total Ammonia Nitrogen (TAN), Total Solids (TS), Total Suspended Solids (TSS), Chemical Oxygen Demand (COD) and Biochemical Oxygen Demand (BOD5), Total Nitrogen (TN) and Total Phosphorus (TP). In this study was cultivating the Nile Tilapia (Oreochromis niloticus) with 0.323kg initial average weight and 17 kg m-3 initial storage density, cultivated in RAS. The RAS was composed with 03 plastic tanks with capacity of 0.20 m3 in each, column settler (CS), aerobic fluidized bed reactor with concentric tubes circulation (BAS-CT) with sand bed support of effective diameter (D10) of 0.29 mm and oxygen transfer-CO2 removal reactor. NAT removal efficiency was in acclimation and stabilized periods in BAS-CT reactor were 31.0% and 35.2% respectively. TS and TSS removal was 44.44% and 71.71% respectively. In this RAS, the COD removal efficiency reached was 64.90% and 48.01% for BOD5. The average removal in the NT and FT in the RAS were 25.02% and 41.05% respectively. These results indicate that aquaculture wastewater treatment proposed in this study by BAS-CT associated to CS prevents high concentrations and accumulating of pollutants within the SRA

Águas residuais - Purificação

Agua - Reutilização

Decantador de coluna

Reator aeróbio

Efluente - Recuperação

Recirculating aquaculture system

Effluent recover

Water reuse