This document discusses recirculation aquaculture systems (RAS) for fish and shrimp farming with integrated hydroponics (aquaponics). It provides details on candidate species for RAS, system design considerations, and examples of RAS for various species including sea bass, turbot, Arctic charr, European perch, and shrimp. It also discusses factors to consider like temperature, salinity, growth rates, feed conversion ratios, and production densities for different species in RAS.
Whiteleg shrimp (Litopenaeus vannamei, formerly Penaeus vannamei), also known as Pacific white shrimp or King prawn, is a variety of prawn of the eastern Pacific Ocean commonly caught or farmed for food.L. vannamei is a decapod crustacean which is native to the Eastern Pacific Coast of Central and
South America from Tumbes, Peru in the south to Mexico in the north. It has been introduced widely around the world since the 1970s, but especially since 2000, as it has become the principle
cultured shrimp species in Asia. The species itself is not considered a major threat to biodiversity, does not appear to have formed breeding populations, and has generally resulted in positive economic impacts in non-indigenous areas. An examination of current lists of invasive species
published by the International Union for Conservation of Nature’s Invasive Species Specialist Group (IUCN, 2004) revealed no listings for L. vannamei. As mentioned, L. vannamei has been anthropogenically introduced as an aquaculture species to several areas of the world to which it is
not native.
,
Nazmul Haque Syekat
Biosecurity measures in shrimp farming:-
- Biosecurity measures at the time of stocking
- Biosecurity measures at the initial time of culture period
- Biosecurity measures during mid culture period
- Biosecurity measures at the end of culture period
Recirculating aquaculture systems (RAS) operate by filtering water from the fish (or shellfish) tanks so it can be reused within the tank. This dramatically reduces the amount of water and space required to intensively produce seafood products.
Whiteleg shrimp (Litopenaeus vannamei, formerly Penaeus vannamei), also known as Pacific white shrimp or King prawn, is a variety of prawn of the eastern Pacific Ocean commonly caught or farmed for food.L. vannamei is a decapod crustacean which is native to the Eastern Pacific Coast of Central and
South America from Tumbes, Peru in the south to Mexico in the north. It has been introduced widely around the world since the 1970s, but especially since 2000, as it has become the principle
cultured shrimp species in Asia. The species itself is not considered a major threat to biodiversity, does not appear to have formed breeding populations, and has generally resulted in positive economic impacts in non-indigenous areas. An examination of current lists of invasive species
published by the International Union for Conservation of Nature’s Invasive Species Specialist Group (IUCN, 2004) revealed no listings for L. vannamei. As mentioned, L. vannamei has been anthropogenically introduced as an aquaculture species to several areas of the world to which it is
not native.
,
Nazmul Haque Syekat
Biosecurity measures in shrimp farming:-
- Biosecurity measures at the time of stocking
- Biosecurity measures at the initial time of culture period
- Biosecurity measures during mid culture period
- Biosecurity measures at the end of culture period
Recirculating aquaculture systems (RAS) operate by filtering water from the fish (or shellfish) tanks so it can be reused within the tank. This dramatically reduces the amount of water and space required to intensively produce seafood products.
A Minimal Water Exchange Aquaculture System, also known as a Recirculating Aquaculture System (RAS), is a modern and sustainable approach to fish farming that minimizes water usage by continuously recycling and treating the water within a closed system. In this system, water is reused and treated to maintain optimal water quality for fish while reducing the environmental impact associated with traditional aquaculture methods.
The key components of a minimal water exchange aquaculture system include:
1. Fish Tanks: These are the primary units where fish are raised. The tanks are designed to provide suitable conditions for fish growth, such as appropriate water depth, temperature, and oxygen levels.
2. Filtration System: RAS incorporates various filtration components to remove solid waste, excess nutrients, and harmful substances from the water. Mechanical filters remove large particles, while biological filters foster beneficial bacteria that convert toxic ammonia into less harmful substances.
3. Water Treatment: Water treatment technologies, such as UV sterilization or ozonation, are used to control pathogens and maintain water quality within acceptable parameters. These methods help to ensure a healthy environment for the fish.
4. Oxygenation: Adequate oxygen levels are critical for fish health. RAS employs techniques such as aerators, oxygen injectors, or oxygen cones to maintain dissolved oxygen levels throughout the system.
5. Monitoring and Control: RAS relies on advanced monitoring and control systems to continuously measure and regulate parameters such as temperature, pH, oxygen levels, and water flow. This ensures optimal conditions for fish growth and allows for timely adjustments if any deviations occur.
The benefits of a Minimal Water Exchange Aquaculture System (RAS) include:
1. Water Conservation: RAS significantly reduces water consumption by recycling and reusing water within the system. It helps conserve this valuable resource and minimizes the environmental impact associated with traditional aquaculture, which often requires large amounts of freshwater usage.
2. Improved Water Quality: The water in a RAS undergoes thorough filtration and treatment, resulting in high-quality water conditions for the fish. By removing waste and controlling water parameters, RAS helps minimize the risk of disease outbreaks and promotes optimal fish health.
3. Reduced Environmental Impact: The closed-loop nature of RAS prevents the release of excess nutrients and waste into the surrounding environment, minimizing the impact on natural ecosystems and reducing the risk of pollution.
4. Increased Production Density: RAS allows for higher stocking densities compared to traditional aquaculture systems. The controlled environment and efficient waste management of RAS enable farmers to maximize production within a smaller footprint.
5. Disease Control: The controlled and isolated environment of RAS helps minimize the risk of disease transmission
This presentation help you to get the information about the integrated multi trophic aquaculture system. IMTA is best technology for environment sustainability, economic sustainability and social sustainability.
Bottom clean Aquaculture system and It’s Engineering PrincipleDegonto Islam
Bottom clean Aquaculture method is considered an updated version of bio-floc.
The most important tasks here are scientifically removing the waste from the bottom of the reservoir and the rotation of oxygen and food supply to the fishes
In this type of culture system, as the amount of oxygen is higher, it is able to culture fishes 10- 20 times more.
Nursery Pond Management
Objectives:
To obtain required amount of desirable species at desired time at desired price all the year round.
After completing these stages of management the nursery pond is prepared for rearing fry and fingerlings.
The next stage is to select culturable species for stocking in the prepared pond and other management.
If we prepare a good nursery pond we will get a good production .
A Minimal Water Exchange Aquaculture System, also known as a Recirculating Aquaculture System (RAS), is a modern and sustainable approach to fish farming that minimizes water usage by continuously recycling and treating the water within a closed system. In this system, water is reused and treated to maintain optimal water quality for fish while reducing the environmental impact associated with traditional aquaculture methods.
The key components of a minimal water exchange aquaculture system include:
1. Fish Tanks: These are the primary units where fish are raised. The tanks are designed to provide suitable conditions for fish growth, such as appropriate water depth, temperature, and oxygen levels.
2. Filtration System: RAS incorporates various filtration components to remove solid waste, excess nutrients, and harmful substances from the water. Mechanical filters remove large particles, while biological filters foster beneficial bacteria that convert toxic ammonia into less harmful substances.
3. Water Treatment: Water treatment technologies, such as UV sterilization or ozonation, are used to control pathogens and maintain water quality within acceptable parameters. These methods help to ensure a healthy environment for the fish.
4. Oxygenation: Adequate oxygen levels are critical for fish health. RAS employs techniques such as aerators, oxygen injectors, or oxygen cones to maintain dissolved oxygen levels throughout the system.
5. Monitoring and Control: RAS relies on advanced monitoring and control systems to continuously measure and regulate parameters such as temperature, pH, oxygen levels, and water flow. This ensures optimal conditions for fish growth and allows for timely adjustments if any deviations occur.
The benefits of a Minimal Water Exchange Aquaculture System (RAS) include:
1. Water Conservation: RAS significantly reduces water consumption by recycling and reusing water within the system. It helps conserve this valuable resource and minimizes the environmental impact associated with traditional aquaculture, which often requires large amounts of freshwater usage.
2. Improved Water Quality: The water in a RAS undergoes thorough filtration and treatment, resulting in high-quality water conditions for the fish. By removing waste and controlling water parameters, RAS helps minimize the risk of disease outbreaks and promotes optimal fish health.
3. Reduced Environmental Impact: The closed-loop nature of RAS prevents the release of excess nutrients and waste into the surrounding environment, minimizing the impact on natural ecosystems and reducing the risk of pollution.
4. Increased Production Density: RAS allows for higher stocking densities compared to traditional aquaculture systems. The controlled environment and efficient waste management of RAS enable farmers to maximize production within a smaller footprint.
5. Disease Control: The controlled and isolated environment of RAS helps minimize the risk of disease transmission
This presentation help you to get the information about the integrated multi trophic aquaculture system. IMTA is best technology for environment sustainability, economic sustainability and social sustainability.
Bottom clean Aquaculture system and It’s Engineering PrincipleDegonto Islam
Bottom clean Aquaculture method is considered an updated version of bio-floc.
The most important tasks here are scientifically removing the waste from the bottom of the reservoir and the rotation of oxygen and food supply to the fishes
In this type of culture system, as the amount of oxygen is higher, it is able to culture fishes 10- 20 times more.
Nursery Pond Management
Objectives:
To obtain required amount of desirable species at desired time at desired price all the year round.
After completing these stages of management the nursery pond is prepared for rearing fry and fingerlings.
The next stage is to select culturable species for stocking in the prepared pond and other management.
If we prepare a good nursery pond we will get a good production .
Following on from a successful presentation to the Reciculation council members earlier in 2004, I was asked to make this presentation which should be titled why abalone farmers should grow seaweeds.
role of women and girls in various terror groupssadiakorobi2
Women have three distinct types of involvement: direct involvement in terrorist acts; enabling of others to commit such acts; and facilitating the disengagement of others from violent or extremist groups.
In a May 9, 2024 paper, Juri Opitz from the University of Zurich, along with Shira Wein and Nathan Schneider form Georgetown University, discussed the importance of linguistic expertise in natural language processing (NLP) in an era dominated by large language models (LLMs).
The authors explained that while machine translation (MT) previously relied heavily on linguists, the landscape has shifted. “Linguistics is no longer front and center in the way we build NLP systems,” they said. With the emergence of LLMs, which can generate fluent text without the need for specialized modules to handle grammar or semantic coherence, the need for linguistic expertise in NLP is being questioned.
हम आग्रह करते हैं कि जो भी सत्ता में आए, वह संविधान का पालन करे, उसकी रक्षा करे और उसे बनाए रखे।" प्रस्ताव में कुल तीन प्रमुख हस्तक्षेप और उनके तंत्र भी प्रस्तुत किए गए। पहला हस्तक्षेप स्वतंत्र मीडिया को प्रोत्साहित करके, वास्तविकता पर आधारित काउंटर नैरेटिव का निर्माण करके और सत्तारूढ़ सरकार द्वारा नियोजित मनोवैज्ञानिक हेरफेर की रणनीति का मुकाबला करके लोगों द्वारा निर्धारित कथा को बनाए रखना और उस पर कार्यकरना था।
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‘वोटर्स विल मस्ट प्रीवेल’ (मतदाताओं को जीतना होगा) अभियान द्वारा जारी हेल्पलाइन नंबर, 4 जून को सुबह 7 बजे से दोपहर 12 बजे तक मतगणना प्रक्रिया में कहीं भी किसी भी तरह के उल्लंघन की रिपोर्ट करने के लिए खुला रहेगा।
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Recirculation systems for fish and shrimp with integrated hydroponics
1. Recirculation Systems for fish and
shrimp with integrated hydroponics
(Aquaponics)
Recirculating Aquaculture Systems - RAS
• Candidate Species
• System Design and function
• Snippets of economics (dangerous without looking at all
details of each situation)
• Possibilities to integrate with hydroponics
• Aquaponics – Fish farming with a bit of veg’ on the side
2. Llyn Aquaculture Ltd
Established Summer 1999 at Afonwen
Farm, Pwllheli, Gwynedd, N. Wales
Marine and Freshwater Recirculation
Systems
Demonstration Farm
Design and Consultancy
Supply and installation
R & D projects
3. Recirculation Systems – Llyn Aqua
Marine systems
Brackish water Turbot pilot system - Marine
Fresh water
5. Design and supply Intensive Fish Production
systems – research, pilot and commercial.
High Value species
Turbot
Sole
Shrimp
Sea Bass
Eels
Fresh water Perch
Arctic Charr
•Low Value (high
volume)
•Barramundi (Asian Sea Bass)
•Tilapia
6. General Design Considerations
Choice of Species
Temperature Production capaci
Location Water Issues
Availability / discharge
Biosecurity
Design
Financial Issues
Salinity Grants
Investement
Sales stratedgy Selling price
Production costs
Construction costs
Land cost
Borrowing cost
7. Reasons to Recirculate
Limited Water
Temperature Control
Salinity Control (specialised)
Disease control
Increase production per unit area / volume
To boldly grow fish where no fish has been grown
before
8. Recirculation System Complexity vs % daily
exchange
% of tank volume exchanged per day
2,400% 1,000 % 500% 100% 50% 20% 10% 5%
Mechanical Filtration
Flow Through Re - Use Biological Filtration
Oxygen + Aeration Fine Filtration (< 50 micron)
UV
Simple Solids Separation Degassing and pH control
Sedimentation
Foam Fractionation
Denitrification
Ozone
9. Design. Each situation is unique and
must have custom design based on tried
and tested technology.
Water Exchange (new water)
Mechanical Filtration – Coarse and fine particle removal
Biological Filtration
UV and Ozone
Gas Exchange / Oxygen / CO2 /pH
Salinity
Water Movement – pumping and pipes
Protein skimming / foam fractionation
10. Reduced water exchange to < 50%
vol per day
Fine particle filtration (< 50 micron) – side
stream
UV ‘sterilisation’ – side stream
Foam fractionation (Protein skimming)
Ozonation – requires strict control – only to
be used on very ‘closed’ intensive systems.
pH Buffering
11. Pros and Cons - Recirculation
Total Control
Cons
Water Quality
High Cost!?
Temperature
Oxygen More Pros
Flow rates •Enables aquaculture to
Disease Control take place where otherwise
not possible
High Productivity
•Low food miles
Low Labour •Freshness
Effluent Control
12. E.g. Recirc’ vs Flow Through with 5
m3/hr water (120 m3/day)
Flow through – 10 m3 tank vol – 1 tpa
production
Recirculation 10 % volume exchanged per
day – 1,200m3 tank vol – 120 to 200 tpa
production depending on species.
13. Minimal Water intake
e.g. 20 tonnes Sea Bass pa
Fine Filtration – 5 micron
High UV dose - Filter and
UV rated 4m3/hr – used at –
10 m3 per day.
Pathogen Free
Pumping once per month
from sea to storage tank.
Easy temperature control
14. Species – with system examples
Marine (or Fresh Water (or Brackish)
Brackish)
Arctic Charr
Turbot
Sea Bass Perch
Sole
Shrimp
Barramundi
Barramundi Tilapia
Sea Trout
Halibut (cold) Sturgeon
15. 2000 – 2002, 1st sea bass RAS in UK, 20
tonnes per annum (300m2 building)
Purging tank (clean
water)
Total water volume of 160 m3 = 125 Kg / m3 / yr
Water Exchange average 10% / day = < 300 l/ kg fish
16. Sea Bass
•Temperature (opt) 18-25
•Salinity 10-40
•Growth to 400g <1 yr
•Growth to 800g Av’ 1.5 yr
•FCR 1.3 to 1.5
•Density - up to 100 Kg/m3
Pros Cons
•Temperature •Delicate
• Well known •Aggressive
• Sales volume •Competition
•Fry •Low price
•£4.50 / Kg
•Large volume
17. Ongrowing System. Sea Bass 160 Cubic metres.-
Llyn Aqua Pilot - 20 tonnes per year = 125 Kg / m3
per year!
Price Drop
00-02 - £5.5 to £6.5/ kg ex farm
03 < £4.50 delivered UK from Greece
2009 – Euro 3.00 per Kg (Greece, Turkey)
Now need to sell at £4.00 to £4.70 per Kg ex
farm UK
21. Turbot. 1.5 - 2.0 Kg in 18 - 24 months
from egg. 12 – 18 moths from 5-10g fry
Pros
•Temperature (opt) to 500g 22 to17
•Temperature*
•Temp’ (opt) 0.5 – 2Kg 17 to14
• Luxury Niche
•Salinity 10-37
•High Value
•Growth to 1 kg 1 to 1.5 yr
£6.0 - £7 per
•Growth to 1.5 Kg 18 – 24 mths Kg
•FCR 0.9 to 1.1 •Higher if sell
direct
•Density - up to 40 Kg/m2
•At 30 to 40 cm deep = 100-120kg/m3
23. Turbot in Shallow raceway recirculation system. 20
Kg per m2 (7 cm deep) = 285 Kg / m3
Approx’ 600 kg / m3 / year production !
At 10% exchange per day
= 60 litres per Kg
produced.
(Sea bass = 300 l/kg)
24. Solids Removal
Prevents overloading of bio-filter and build up of
anoxic sludge.
Removal down to 50 microns.
Sedimentation – Simple / low flow / load
Moving screens – Drum or Conveyor belt
Removal below 50 microns
Fixed bed – Pressurised sand or beads
Fixed bed – slow up-flow / submerged media
Both require periodic backwashing.
25. Example 50 tonne perch farm – Ireland, 2 modules of 25
tonnes per annum
47.500m
Upflow
Upflow
1.800m
1.800m
4.000m
2.950m 0.400m 2.950m
4.000m
3.600m
3.600m
RSJ
RSJ
0.800m 0.800m
2.250m 2.250m
3.850m 3.850m
Fluid Bed
Fluid Bed
2.800m
2.800m
1.850m 1.850m
12.000m
Concrete drain sumps
6.000m
1.900m
1.900m
0.800m 0.800m
6.000m 6.021m
6.021m 0.150m 0.150m 8.500m
2.000m 2.000m
1.936m 1.936m 200mm 85
m
1.500m
UV
1.500m
UV
0.5
m
Water filtration area
2.650m 2.650m
m
00
35
.5
0.3 85
0.2
m
0.3
0.2
00
4.000m
m
35
m
3.850m 3.850m
4.000m
2.760m
Pink pipes above ground until this point 160mm pipe under tanks Waste pipe between the two 400 mm pipes here
Green pipe shows waste water out from sumps
26. Solids removal – Moving mesh with
backwash spray - Conveyor or Drum filter.
27. Drum Filter – High flow / low head
Only 2 – to 5 cm head loss
28. Mechanical Drum Filter with vortex
separator Biological Filtration
1.800m
4.000m
2.950m
3.600m
0.800m
2.250m
3.850m
2.800m
1.850m
6.000m
1.900m
0.800m
6.021m
0.150m
2.000m
8.500m
1.936m m
85
UV
1.500m
0.5
2.650m
m
35
0.2
0.3
00
m
3.850m
4.000m
2.760m
Low Head Pumps
Biological Filtration
29. 30 tonne per annum system (European Perch) Low Head Llyn
Aqua pumps- 6 of 100 m3/ hr @ 1m head. 0.75 KW each.
31. (pre 2000 technology) 8 + 2
temp monitoring.
£9,000 in 1999
Llyn Aqua Sensor Monitor (LASM)
e.g 8 oxygen - £4,000 Today
32. Monitoring and control -
4 x LASM units on
network – with phone
dialer
•2 x 25 tonne systems -
•24 Oxygen
•2 Temp
•6 float switch level alarm
•2 pressure switch – Oxygen
•Power failure
•WWW – viewed and
controlled from anywhere on
net
33. Dover Sole – The Holy Grail? Very High Value
Very difficult broodstock
Slow Growth – 300 –
400g in 1 year (30% of
stock)
Feed related – Do not
thrive on fish based diet
35. • Temperature (opt)
12-17
Arctic Charr • Salinity 0 - 37
• Growth to 1Kg <1 yr
Fresh water – brackish - marine • Growth to 1.5Kg 17 mth
• FCR <1.0
• Density - up to 100
Kg/m3
Down Side
Price drop
2006 £5.30
2009 Euro £4.50
Production cost of
£3.5 / Kg.
£3.0 / Kg at over
200 tonnes.
36. Relevant Example - 60 tpa Arctic
Charr farm - Ireland.
Bore hole water - 12 Deg. C
50 % exchange per day (300m3)
Circulation up to 2.5 x per hour through
tanks = 60 times per day
New water = 0.8 % per cycle
Rate of recycling = 99.2%
37. 60 Tonne per annum Charr.
Nursery system – 8 of 15 m3
Grow Out System – 4 of 100
m3
Fish More relaxed at high density
– up to 80 Kg/m3 in Nursery and
100 Kg / m3 in Grow out tanks –
10 tonnes per tank!
38. Large tanks – more economical from Concrete. < 10 m3,
GRP or HDPE.
45. Tropical Shrimp (white)
L. Vannamei
•Temperature (opt) 26 - 30
•Salinity 3 - 40
•Growth to 20g 4.5 mths
•£8 (20g) to £12 (25 – 30g) / Kg
•FCR 1.0 to 1.3
•Density - 7 to 10 Kg/m2
•Niche market – top quality,
never frozen, super fresh,
live, no preservatives,
harvest and deliver same day.
•Not to compete with bulk
frozen imported
47. ‘ICE’ Shrimp – Indoor
Controlled Environment
PROS
•Fast turnover
•2.5 cycles per year
•25 Kg / m2 tank per year
•High price - £8 + /kg ex farm
CONS
•High space required
•High Temp
•Cheap competition
High space means high
construction cost – 100
tonnes - £1.25 million
48. Tilapia – The Chicken
of the ‘sea’
PROS
•Fast turnover (<10 mths)
•>200 Kg / m3 / year
•Salinity 0- 5ppt
•Some strains – full Sea water
•Low protein plant based feed –
35%
•Production cost ca. £4.0/Kg
400 tpa farm – ca £1.45m
CONS
•High Temp 26 - 30
•Cheap competition
50. Aquaponics -Plenty of freshwater
examples on the internet
Silver Carp +
Rice
‘Backyard’
aquaponics
51. Llyn Aqua Integrated System – 2001, EU
funded R & D programme - GENESIS
Lly Aquaculture - C C
old limate Integrated System
F R
ish earing Systems Surplus water
W W
aste ater+ Sinking
Sludge Secondary Settler
Primary S ettler
Floating
Solids separation
Septic tank
Discharge
C 5 m3 per day
a.
Phytoplankton / A ??
rtemia T N
o atural Wetland
or recycled back to fish
New 10.000m
3.000m
Sedimentation, worms?
300m3 40 m3 300m3
12.000m
P eriodic pumping 2m deep 0.3m deep 2m deep
Spread on Land R = 4 days
T
10.000m
Aerated Lagoon
Retention time
30 days
Phytoplankton Salicornia + Clams ?
3.032m
N A
ew rea
S G ??
and ravel w simulated tide
ith