AQUACULTURE SYSTEM

Field of the Invention

The present invention relates to a cleansing system configured to receive aqueous me- dium from at least one fish tank and to return a cleaned aqueous medium to the at least on fish tank.

Background of the Invention

Land based Recirculated Aquaculture Systems (RAS) are known and varieties exist and as an example, Moore discloses a fish growing tank and method in the patent lit- erature US 4,003,337.

Cleansing systems are also known and an integrated closed loop system for water pu- rification is known from the patent literature e.g. WO 03/065798 Al. Document US 3888210 A discloses a fish husbandry system having a fish rearing ver tically extending tank wherein the water flows in substantially laminar fashion from bottom to top.

Different parts or sub-systems have generally been interconnected and handled sepa- rately.

Object of the Invention

It is an object of the invention to improve the cleansing systems of aquaculture sys- tem. It is an object of the invention to improve a recirculation aquaculture system (RAS).

Although circular systems exist, further improvements are needed to save space. Description of the Invention

Initially the generic concept is described. Subsequently particular aspects are dis- closed.

An object is achieved by a cleansing system configured to receive aqueous medium from at least one fish tank and to return a cleaned aqueous medium to the at least one fish tank. The cleansing system comprising a cleansing system inlet arranged at a cleansing system inlet level to inlet the aqueous medium into a first volume. The first volume is substantially surrounded by an annulus section having at second volume. The first volume and the second volume are in communication via at least a first- second-overflow leveller arranged at first-second overflow leveller level and to radial - ly overflow the aqueous medium from the first volume to the second volume. There is a cleansing system outlet arranged in the annulus section configured to outletting the now cleaned aqueous medium from the annulus section. This particular configuration allows for an effective distribution of an aqueous medi- um such as water, say in an aquaculture system, through different volumes that can be configured according to specific purposes as will be described herein.

In an aspect, the annulus section is parted in arc-sections forming at least a further third volume in the annulus section, where first volume and the third volume are in communication via at least a first-third-overflow leveller arranged at a first-third over- flow leveller level and to radially overflow the aqueous medium from the first volume to the third volume.

This particular configuration allows for an effective distribution of the medium into at least three different process volumes. It further allows for the medium to be processed in parallel in the second and third volume. The arc-sections may be designed accord- ing to a certain ratio. The arc-sections may be adjustable.

A person skilled in the art will appreciate the generic concept and will be able to con- figure the described volumes, the first volume, the second, and the third volume ac- cording to circumstances. In the particular aspects, the first volume is configured with a specific purpose as first reactor, e.g. as a moving bed type of configuration, the sec- ond volume is configured with a specific purpose as a second reactor, e.g. as a fixed bed type of configuration, the third volume is configured with a specific purpose as a degassing section.

In an aspect, the second volume and the third volume are in communication via at least a second-third-overflow leveller arranged at second-third overflow leveller level and to tangentially overflow the aqueous medium from the third volume to the second volume.

This further allows for mixing the medium from third volume with the medium in the second volume. This configuration saves space and energy since the arc-sections may be designed or adjusted and the tangential flow may be controlled. Thereby, a three- stage process may be implemented and the medium may simply cascade through the volumes. The volumes may be configured to optimise the desired process. The actual flow rate and/or flow ratio may easily be controlled or adjusted to achieve the desired overall process, such as cleaning a contaminated aqueous medium.

In an aspect, the annulus section is parted in arc-sections forming at least a further fourth volume in the annulus section, where first volume and the fourth volume are in communication via at least a first-fourth-overflow leveller arranged at a first-fourth overflow leveller level and to radially overflow the aqueous medium from the first volume to the fourth volume. In an aspect, the third volume and the fourth volume are in communication via at least a third-fourth-overflow leveller arranged at third-fourth overflow leveller level and to tangentially overflow the aqueous medium from the fourth volume to the third vol ume. In an aspect, the fourth volume comprises return flow means for returning the aqueous medium from the fourth volume to the first volume as a return flow. The return flow means may be an arrangement with one or more pumps. The pumps may be config ured or controlled to ensure a certain level in the volume or a certain exchange to and from the volume.

There may be tangential flow means for exchanging the medium between the fourth and a third volume. The tangential flow means may be one or more arrangements of pumps. In an aspect, at least one first or second volume may be configured to biologically filtering of the aqueous medium. The other first or second volume may be configured to degassing the aqueous medium. In an aspect, the at least one first or second volume is configured with means for nitri fication of the aqueous medium. In an aspect, the annulus section comprises at least one volume for nitrification and another volume for de-nitrification.

In an aspect, the first volume is configured to biologically filtering of the aqueous medium by a moving bed system. The second volume is configured to degassing the aqueous medium. The third volume is configured to biologically filtering the aqueous medium by a fixed bed system

In an aspect of the previously disclosed, the one or more volumes may be configured as follows.

At least one first volume may be configured to for nitrification of the aqueous medi- um. At least one second volume may be configured for degassing the aqueous medi- um. At least one third volume may be configured for nitrification of the aqueous me- dium. At least one fourth volume is configured for de-nitrification of the aqueous me- dium.

This configuration may allow for de-nitrification. Whilst additional carbon provided for de-nitrification may degenerate the medium, if returned to a fish tank, and result in increased algae production, this particular configuration enables the aqueous medium to be returned to a volume configured for nitrification. The nitrification volume may be the first volume, the third volume or both. The additional carbon may then be con sumed by bacteria in one of the nitrification volumes. The first, centre, volume may be a moving bed type and consume carbon at a relatively high level. The third, annulus, volume may be a fixed bed type and consume carbon at a relatively low level. A per son skilled in the art will appreciate the option to balance the levels of carbon con sumption. In particular a person skilled in the art will appreciate the option and the ease to install pumps to adjust the levels or the flows between volumes configured for de-nitrification and volumes configured for nitrification.

In an aspect, the cleansing system may be configured so that the fourth volume is ar ranged adjacent to at least one third volume and wherein the least one third volume and the fourth volume are in communication via at least a third-fourth-overflow level ler arranged at third-fourth overflow leveller level and to tangentially overflow the aqueous medium from the fourth volume to the least one third volume.

In an aspect, the first volume may be configured as a moving bed type of reactor; the second volume may be configured for degassing the aqueous medium. The second volume may be sandwiched between two third volumes each configured as a fixed bed type of reactor. The fourth volume may be between the two third volumes and config ured for de-nitrification of the aqueous medium. This configuration will allow one third volume to be cleaned or maintained whilst the other third volume is in operation or use; and vice versa. In example, the third vol umes may be configured for nitrification. The configuration enables a“mirror-like” system and as seen and further disclosed in the detailed section, the suggested means allows for easy cleaning of the third volume.

Having only one degassing volume saves some piping. In an aspect, there may be pipes or outlets arranged at the two ends of degassing section, which outlets return the degassed aqueous medium to respective fish tanks. A person skilled in the art may want to make use of the configurations suggested. In an aspect the first volume, the centre volume, may be configured for de-nitrification. The fourth volume may then be configured for nitrification.

An object is achieved by a method for cleansing an aqueous medium from an aquacul- lure system in a cleansing system, the method comprising the following acts.

There is an act of providing the aqueous medium to a cleansing system inlet and into a first volume that is substantially surrounded by an annulus section having a second volume.

There is an act of overflowing the aqueous medium radially from the first volume to the second volume.

There is an act of outletting the now cleaned aqueous medium through an cleansing system outlet.

In an aspect, the overflowing of the aqueous medium from the first volume further comprises an act of parting the aqueous medium between the second volume and a further third volume in the annulus section second reactor.

In an aspect, there is an act tangentially overflowing the aqueous medium from the third volume to the second volume via at least a second-third-overflow leveller ar ranged at second-third overflow leveller level. An object is achieved by a recirculating aquaculture system, the system comprising a cleansing system as disclosed herein and comprising at the least one fish tank and ar ranged so that the water is recirculated between the at least one fish tank and the cleansing system. In an aspect, each of the least one fish tanks has a fish tank outlet in communication with the cleansing system inlet and where the cleansing system inlet level is at a gravi tational level that is lower than a fish tank outlet level of each of the least one fish tanks; and which cleansing system outlet is in communication with a flow-setter in each of the least one fish tanks; wherein there is a pump in the communication be- tween the cleansing system and the least one fish tanks.

An object of the invention is achieved by a method for cleansing an aqueous medium from an aquaculture system in a cleansing system. The method may comprise the fol lowing acts.

There may be an act of providing the aqueous medium to a cleansing system inlet in the cleansing system.

There may be a following act of mechanical filtering of the aqueous medium in a me- chanical screen filter. There may be a following act of biologically filtering the aqueous medium in a first reactor section

There may be a following act of parting the aqueous medium into a second reactor and a degassing section.

In the degassing section and the second reactor there may be acts performed in paral- lel. There may be an act of degassing the aqueous medium in the degassing section.

There may be an act overflowing of the aqueous medium from the second reactor into the degassing section. From the degassing section there may be an act of outletting the now cleaned aqueous medium through a cleansing system outlet.

There may be an act of pumping the aqueous medium. It is understood that a rector or section is a chamber or volume in which the aqueous medium or water can be and in which a reaction or process can take place. Each reac- tor or section may be a chamber or volume. Thus, the first rector may be a first vol- ume in which a first reaction may be performed. The second reactor may be a second volume in which a second reaction may be performed. In a very special embodiment a volume or a reactor may be used simply as storage or a buffer without any further purpose. It is understood that the aqueous medium from the fish tank is contaminated with at least carbon dioxide and nitrogenous products. The medium may also contain biologi- cal organic waste products, e.g. faeces, particulate matter, i.e. smaller or larger physi- cal objects. In general, the aqueous medium may be waste water from an aquaculture system, a fish farming system including fish farming of salmon or the like.

It is achieved that the contaminated aqueous medium is cleaned and degassed and sufficiently prepared for recirculation. The contaminated aqueous medium may be contaminated from an aquaculture tank and may have to be returned or recirculated into the aquaculture tank. The process performs this in a particular effective way that saves process steps and thus, resources to provide or enable the process steps. In par ticular the process provides an integrated process that results in e.g. sufficient clean ing, including mechanical cleaning, and biological cleaning, say nitrification, as well as de-gassing.

The process is further advantageous since the process allows for, either as per design or during operation, to adjust the partition of the medium between the second reactor process and the degassing process. In example the first reactor may perform nitrification and the overflow to the second reactor and degassing may be adjusted by changing the volume, either the diameter or the level of barriers between sections. The activity or recirculation in the moving bed character may also be adjusted. Thereby, the nitrification level may be controlled be fore overflowing the medium to the second reactor and the degassing section.

The first reactor or volume may be a moving bed type of reactor. The first reactor may be configured with aeriation means such as airlifts to generate mixing flows according to design or practice. The first reactor may be configured to sustain bio-elements or -carriers in the medium in the first reactor by being configured with means sealing off such bio-element from the first reactor from the annulus ring or arc-sections. There may be perforated walls, grids or other barriers restraining the bio-elements whilst allowing the aqueous medi- um to flow.

The second reactor may be used to filter or clean a certain part of the medium before overflowing into degassing. The second reactor may involve further nitrification, re- moval or containment of finer particles. The filtering may be biological or mechanical. In an aspect use of bio-elements suspended in the medium will harvest particles and products by a growth process whereby the medium is cleaned or filtered.

The second reactor may be optional and the second reactor may also be a pass-through (buffer-type) of volume. Optionally, there may be a mechanical filter. The second reactor or volume may be a fixed bed type of reactor. The second reactor or volume may be a moving bed type of reactor. Likewise, the second reactor or vol- ume may be configured to sustain bio-carriers in the second reactor. There may be a perforated barrier such as top deck that allows the aqueous medium to flow through in an upward direction whilst restraining bio-carriers.

The degassing may involve injecting air into the medium. The medium may, from the overflow from the first and second reactors be broken into smaller drops, droplets by overflowing a perforated plate or through crown nozzles. There is an effective cascad- ing of the medium (downward by gravitation) that meet with a counter flow or counter directed stream of say air or oxygen enriched (upward) stream. There may be volume of the aqueous medium that is still and from which degassing (of C02 and N2) takes place so that the degassing leaves the medium and is removed upwardly.

In one embodiment, the percentage of the aqueous medium during the act of parting into the second reactor and the degassing section may be adjusted either before or af- ter the construction of cleansing system. A person skilled in the art would know the right percentages to obtain optimal condition.

In an aspect, parting the aqueous medium may be performed in a substantially radially directed outward flow from the first reactor section into arc-sections of a surrounding annulus section. The arc-sections include at least the second reactor and the degassing section.

The second reactor receives part of the aqueous medium. The degassing section re- ceives part of the aqueous medium. In an aspect, the second reactor and the degassing section divides the aqueous medium.

The arc-sections in the annulus section may be adjusted to adjust the division or part- ing of the aqueous medium from the first section.

In an aspect, the act of overflowing of the aqueous medium is performed in a substan tially tangentially directed flow at arc-section dividers from the second reactor and the degassing section. Thereby, the flow is controlled since the arc-section divider works or can be modified to adjust the flow and the nature of the flow into the degassing section.

Different types of perforations, holes, tubes, pipes may be applied. Furthermore, there may be valve or blinds that can adjust the flow, the level or close the flow.

In an aspect, the act of providing the aqueous medium to an inlet in the cleansing sys- tem is performed at a gravitational level that is above the act of parting the aqueous medium into the second reactor and the degassing section. Below the act of parting the act of overflowing of the aqueous medium from the sec- ond section into the degassing section is performed.

Below the act of overflowing there is the act of outletting the aqueous medium. Thus, the aqueous medium cascades from a centre inlet and is distributed radially in the first reactor and cascades radially outward over levellers or edges into respective second reactor(s) and degassing section(s). The second reactor and the degassing sec- tion being configured with a leveller or edge in between so that the aqueous medium cascades from the second reactor to the degassing section. Finally, the aqueous medi- um is outlet from a lower most or bottom part of the degassing section. Thereby the aqueous medium is effectively cleaned. That is mechanically and/or bio- logically. That includes cleaned for particulates (that is objects, biological matter or collections of biological matter). The cleaning includes to be degassed. The cleaning is achieved with reduced energy or pumping equipment than hereto. Furthermore, the arrangement results in optimisation of space and thus reduces the need of construction materials as well piping.

An object of the invention is achieved by a cleansing system configured to receive aqueous medium from at least one fish tank and to return a cleaned aqueous medium to the at least on fish tank.

The cleansing system may comprise a cleansing system inlet centrally located in the cleansing system. The inlet is in communication with a mechanical filter configured to mechanical filtering of the aqueous medium. The inlet is arranged above and substan- tially surrounded by a first reactor section configured to biological filtration of the aqueous medium. The first reactor is substantially surrounded by an annulus section.

The annulus section is parted in arc-sections of at least a second reactor; and a degas- sing section configured to degassing the aqueous medium.

There is a cleansing system outlet configured to outletting the now cleaned aqueous medium from the annulus section. The cleansing system outlet is from the degassing section. In one embodiment, there may be one or more mechanical filter(s). Thereby, the aqueous medium is filtered before entering the first reactor and larger particles are discarded. The mechanical filter may be a drum screen type of filter. In one embodiment there may be one or more degassing systems.

An effect of the degassing system may be to decrease the amount of or remove C0 _2. Thereby, the quality of the aqueous medium is maintained to secure optimal condition in the fish tank.

Another effect of the degassing system may be to decrease the amount of or remove Nitrogen from the aqueous medium. If atmospheric air is pumped into the system from below, the air may be saturated with Nitrogen. If the amount of Nitrogen is not decreased and the aqueous medium is later used in a fish tank it may cause decom pression sickness systems for the fish.

In an embodiment, the cleansing system may have a flushing outlet. The effect of the flushing outlet is to remove part of or the whole aqueous medium from the cleansing system. This may be helpful to do as colonies of small particles may build up in the system.

Furthermore, the accumulation of organic materials and other wastes materials is kept to a minimum. Fouling is thus reduced.

Overall the method and system disclosed will lower the energy consumption other wise needed. The cleansing system or method will only need or have to“lift” the wa ter once to clean the water in four processes, where big particles are cleaned by a drum filter, nitrification is performed in the first section, such as a moving bed sec tion, degassing (inch C02, N2) is performed in a degassing section, and small parti- cles may be cleaned in a second section such as a fixed bed filtration. The water flows or cascades via gravitation between the four cleaning processes.

A further advantage of the system or method is that all sections or volumes will expe- rience a continuous flow of water, which reduces or eliminates dead zones or stagnant water. Thereby further reducing or eliminating the need for piping to reduce creation or contamination with Sulphur.

Hence, the need for piping and space is reduced or eliminated. Also the need of pumps and space and energy for such pumps are reduced or eliminated.

Thus, all the cleaning of the water in“one-step” and water can be re-circulated to get an improved or optimal water quality for the fish breading. Hence, water of the required purity and with acceptable concentrations (e.g. of C02) can be recirculated thus allowing for aquaculture whilst reducing environmental im pact.

In an aspect of the cleansing system, a second reactor is configured with an overflow leveller arranged at a gravitational level that is above the gravitational level in the de- gassing section for overflowing of the aqueous medium from the second reactor into the degassing section.

In an aspect of the cleansing system, the annulus section comprises a pair of second reactors and a pair of degassing sections; which pairs separate each other. The parting may be performed into a pair of opposite second reactors and a pair of opposite degassing sections. The act of overflowing is performed at tangentially di- rected and oppositely directed flows at annulus dividers from the second reactors into the degassing sections.

In an aspect of the cleansing system, the degassing section comprises a cross-flow or counter-flow applicator arrangement of air arranged below crown nozzles for cascad- ing the aqueous medium onto an upper part of the cross-flow or counter flow applica- tor arrangement. There may be air communicators arranged to guide air to a lower part of the cross-flow or counter flow applicator arrangement.

Thereby is provided as large a surface contact between air and the aqueous medium as possible. The cross-flow applicators may be arrangements of plates that are bent and having as large a surface as possible. The plates may be coated with anti-fouling coat- ings. The plates or arrangements may be suspended in the degassing section and air may be directed to the bottom of the plates or channels formed, whereas the medium drizzles or cascades down to the top of the plates or channels formed.

The aqueous medium may drizzle down and experiences a free fall of say 1 to 2 me- ters to form small droplets. Crown nozzles may be used to initiate the droplets or cas cade process.

In an aspect of the cleansing system, the second reactor comprises a deck arranged to cover the second reactor and configured with deck perforations for an up-ward pene- tration of the aqueous medium. The deck may withhold bio-carriers or particular matter. Furthermore, the deck perfo- ration may be altered or distributed to generate or balance pressure differentials so as to provide an even water level in the tangential level, thereby ensuring the overall flow performance or characteristics.

In particular, there may be differential pressure at edge or at the leveller between the second reactor and the degassing section. The pressure differential may be countered by having larger perforations towards the leveller. In an aspect of the cleansing system, the first reactor section comprises transverse plates substantially arranged in vertically and in parallel.

Thereby, enabling or providing a substantial vertical flow-pattern between the plates and thereby, a desired or complete suspension of bio-elements during operation. There may be aeration or an air lift in every other chamber, section or volume between two plates.

In an aspect of the cleansing system, the annulus section is formed by prefabricated plates/arc-sections, such as metal plates or glass-fibre plates and configured for receiv- ing the first reactor section inserted substantially in the centre.

In an aspect, the foundation or base may be concrete or a plate. Using metal plates, glass-fibre plates or the like will greatly reduce the use of materials and the like. Us- ing plates, such as pre-fabricated elements will also reduce maintenance costs and efforts and allow for adjustments. The mentioned elements may also easily be modified to balance the overall flow char acteristics of the system.

An object is achieved by a recirculating aquaculture system (RAS), the system com- prising a cleansing system and at least one fish tank, wherein the water is recirculated between the least one fish tank and the cleansing system.

In one embodiment, the RAS system may have one or more buffer tanks. One effect of a buffer tank may be to maintain suitable conditions for optimal function in both the cleansing system and the fish tank. The buffer tank may be a buffer to maintain temperature. The buffer tank is further advantageous during fish outtake since it al- lows to maintain the state of the aqueous medium.

In one embodiment, the fish tank may be intended for salmons or other sensitive spe- cies. To breed salmons, the water temperature should be stable around l4°C and the level of C0 ₂ should be lower than 15 mg/L. Therefore, it may be important to have an affective cleansing system, and a buffer tank.

In one embodiment, there may be a motor/a pump for recirculating the aqueous medi- um in the RAS system. The motor/pump may be placed after the cleaning system out- let. Thereby, the motor is located after the aqueous medium is cleansed. This may help to keep the maintenance at a minimum and the lifespan at a maximum.

In one embodiment, there may be walls between the fish tank and the cleansing sys- tern. Thereby, the fish are shielded of any possible noise from the cleansing system and the stress levels of the fish may be reduced. In an aspect of the RAS, each of least one fish tanks has a fish tank outlet in commu- nication with the cleansing system inlet which cleansing system inlet is at a gravita- tional level that is lower than a fish tank outlet leveller of each of the least one fish tank. The cleansing system outlet is in communication with a flow-setter in each of the least one fish tanks. There is a pump in the communication between the cleansing system and the least one fish tanks.

In an aspect of the RAS, the cleansing system is as outlined in this disclosure. In an aspect of the RAS, the fish tank has a fish tank wall that is cylindrical with the fish tank outlet coaxially arranged; and wherein the flow-setter is arranged and ex- tends upwards at the fish tank wall and has flow-setter perforations in the upward di- recti on. In one embodiment, the fish tank may be cone-shaped towards the bottom of the tank.

The cleansing system may thus be driven by gravitation, since the inlet is at a highest level, below which the level of the overflow from the central first reactor into the an nulus section is arranged. There may be a level from the first reactor into the second reactor. There may be the same level or another (lower) level from the first reactor into the degassing section. With the arc-sections there may be a level between the sec- ond reactor into the degassing section. The levels may be adjusted or configured to be adjusted so as they generate a flow through the cleansing system in accordance with the necessary levels of cleaning, including nitrification and degassing of C02.

In combination with one or more fish tanks, the level of the input level in the cleans- ing tank may be arranged below the level of the output of the (dirty) aqueous water from the one or more fish tanks. Thereby, only one pump may drive the flow. The pump may be placed just after the output from the cleansing system thereby experi encing the cleanest possible medium. At the same time, the pump may provide the required pressure to one or more flow setters in one or more fish tanks.

Description of the Drawing

Embodiments of the invention will be described in the figures, whereon:

Fig. 1 illustrates a method of cleansing an aqueous medium;

Fig. 2 illustrates a perspective view of a cleansing system;

Fig. 3 illustrates a perspective view of a cleansing system and the interior of a sec- ond reactor and a degassing section;

Fig. 4 illustrates a cross section view of a cleansing system, the cross section being through a first reactor and a second reactor;

Fig. 5 illustrates a cross section view of a cleansing system, the cross section being through first reactor and a degassing section;

Fig. 6 illustrates a side view of a RAS-system comprising a cleansing system and a fish tank;

Fig. 7 illustrates a top view of multiple RAS-systems, where each RAS-system comprises a cleansing system in connection with two fish tanks;

Fig. 8 illustrates a side view of a fish tank;

Fig. 9 illustrates a top view of a fish tank with a central fish tank outlet;

Fig. 10 illustrates a perspective and a side view of a flow-setter with perforations;

Fig. 11 illustrates a recirculation aquaculture system (RAS)

Fig. 12 illustrates a recirculation aquaculture system (RAS) comprising a cleansing system and a fish tank;

Fig. 13 illustrates a cleansing system for a cascading flow through three volumes;

Fig. 14 illustrates a cleansing system with a fourth volume; and Fig. 15 exemplifies the aspects illustrated in fig. 14.

Item list

Detailed Description of the Invention

Figure 1 illustrates a method 1000 for cleansing an aqueous medium (not shown) from an aquaculture system (not shown) in a cleansing system (not shown).

The method 1000 comprises the acts of providing 1050 the aqueous medium to a cleansing system. Next followed by an act of mechanical filtering 1100 of the aqueous medium. Afterwards followed by an act of biologically filtering 1150 of the aqueous medium.

Next followed by an act of parting 1200 the aqueous medium into a second reactor (not shown) and a degassing section (not shown). In the second reactor there is an act of overflowing 1300 of the aqueous medium from the second reactor into the degas- sing section. In the degassing section there is an act of degassing 1350 the aqueous medium.

In the degassing section there is an act of outletting 1400 the now cleaned aqueous medium through an cleansing system outlet (not shown).

Figure 2 illustrates a perspective view of the cleansing system 10.

The cleansing system 10 has a mechanical filter 70 intended for mechanically filtering 1100 the aqueous medium 5 (not shown).

The mechanical filter 70 is surrounded by a first reactor section 50. The first reactor section 50 (or volume/chamber) is intended for biological filtration 1150 of the aqueous medium 5.

The first reactor has transverse plates 60 arranged vertically and in parallel.

The first reactor section 50 is surrounded by an annulus section 20. The annulus sec- tion 20 comprises two arc-sections 30.

The parting 1200 of the aqueous medium 5 is performed in a substantially radially directed 1320 outward flow from the first reactor section 50 into arc-sections 30.

The flow from the first reactor section 50 into the arc-sections 30 is enabled (or ad- justed) by levels of or perforations in a wall between the first reactor section 50 and the arc-sections 30.

The levels of or perforations/holes may form the degassing inlet 105 as illustrated. In this embodiment there is a second reactor inlet pipe 110 connecting the first reactor 50 with the second reactor 100. There are valves on each inlet pipe 110 to adjust the level and flow.

Each arc-sections 30 include a second reactor 100 (or volume/chamber) and a degas- sing section 150 (volume/chamber). Thereby, the annulus section 20 comprises a pair 102 of second reactors 100 and a pair 152 of degassing sections 150. The arc-sections 30 are divided by arc-section dividers 25. There is an overflowing 1300 of the aqueous medium 5. The overflowing 1300 is per formed in a substantially tangentially directed 1330 flow at arc-section dividers 25 from the second reactor 100 and into the degassing section 150. The second reactor 100 has an overflow leveller 130 arranged at a gravitational level that is above the gravitational level in the degassing section 150. The overflow leveller is intended for overflowing 1300 of the aqueous medium 5 from the second reactor 100 into the degassing section 150. The second reactor 100 has a flushing outlet 18 intended for emptying the cleansing system 10 for the aqueous medium 5 during maintenance and cleaning.

The degassing section 150 has a cleansing system outlet 16 intended for providing cleansed aqueous medium 5 to a fish tank 500 (not shown).

The degassing section 150 has a degassing section deck 160. The degassing section top deck 160 is perforated.

Figure 3 illustrates a perspective view of a cleansing system 10 and the interior of a second reactor 100 and a degassing section 150.

The second reactor 100 is an up-flow second reactor. The aqueous medium 5 (not shown) enter the second reactor 100 through four second reactor inlet pipe 110 near the lower part of the second reactor 100.

The second reactor comprises a deck 120. The deck 120 is located near the top of the second reactor 100 and covers the second reactor 100. The second reactor deck has deck perforations 122. The degassing section has crown nozzles 170 and a counter-flow applicator arrange- ment 180 arranged below crown nozzles 170. The crown nozzles are intended for cas- cading the aqueous medium 5 onto an upper part of the counter flow applicator ar rangement 180. The degassing section 150 has an air communicator 190 intended for guiding air to the lower part of counter-flow applicator arrangement 180.

The air communicator 150 has an air communicator outlet 192 and an air communica tor inlet 191.

Figure 4 illustrates a cross section view of a cleansing system 10, the cross section being through a first reactor 50 and a second reactor 100.

The cleaning system 10 has two cleansing system inlets 15 located at the centre 12 of the cleansing system.

The cleansing system 10 has a mechanical filter 70. The mechanical filter is a drum filter. Figure 5 illustrates a cross section view of a cleansing system 10, the cross section being through first reactor 50 and a degassing section 150. The cleaning system 10 has two cleansing system inlets l5a,b and is capable of re- ceiving an aqueous medium 5 (not shown) from two fish tanks 500 (not shown).

The degassing section 150 has a degassing section deck 160. The degassing section top deck 160 is perforated.

Figure 6 illustrates a side view of a recirculating aquaculture system 1 comprising a cleansing system 10 and a fish tank 500. The cleansing system 10 has a cleansing system inlet 15 for receiving water from a fish tank 500 and a cleansing system outlet 16 for providing the cleansed aqueous me- dium to the fish tank 500.

The cleansing system outlet 16 has a pump 700 intended for pumping the cleansed aqueous medium 5 to the fish tank 500.

The fish tank 500 has a fish tank inlet 510. The lower part of the fish tank 500 is cone- shaped and a fish tank outlet 520 located at the centre of the fish tank 500. The fish tank 500 has a fish tank outlet 520 in communication with the cleansing sys- tem inlet 15 which cleansing system inlet 15 is at a gravitational level that is lower than a fish tank outlet leveller 525 (see figure 9) of the fish tank 500. The cleansing system outlet 16 is in communication with a flow-setter 600 in the fish tank 500. There is a pump 700 in the communication between the cleansing system 10 and the fish tank 500. Figure 7 illustrates a top view of multiple RAS-systems 1, where each RAS-system 1 comprise a cleansing system 10 in connection with two fish tanks 500.

The cleansing system 10 comprises a pair 102 of second reactors 100 and a pair 152 of degassing sections 150.

The RAS-system 1 has a buffer tank 400.

Aquaculture system wall 3 shields the fish tanks 500 from the cleansing system 10.

Figure 8 illustrates a side view of a fish tank 500.

The fish tank 500 is cone-shaped towards the bottom end and has a central fish tank outlet 520.

Figure 9 illustrates a top view of a fish tank 500 with a fish tank wall 530.

The fish tank 500 has a central fish tank outlet 520 surrounded by a fish tank outlet leveller 525.

The fish tank 500 has two flow-setters 600a, b located inside the tank 500 and near the wall 530. The flow-setters 600a, b are arranged and extend upwards at the fish tank wall 530.

Figure 10A illustrates a side view of a flow-setter 600 and figure 10B illustrates a per spective view of a flow-setter 600. The flow-setter has flow-setter perforations 610 to provide the cleansed aqueous me- dium 5 (not shown) to the fish tank 500 (not shown). The flow-setter perforations 610 extend in the upward direction 650. The flow-setter perforations are intended for out- letting the aqueous medium 5 to the fish tank 500.

The flow-setter has a flow-setter inlet 620 to receive the aqueous medium 5 from the cleansing system 10 (not shown). The flow-setter inlet 620 is located at the lower part of the flow-setter 600. The flow-setter has mountings 630 for mounting the flow-setters in the fish tank 500.

Figure 11 illustrates a recirculating aquaculture system 1, the system comprising a cleansing system 10 a fish tank 500. The water is recirculated between the fish tank 500 and the cleansing system 10.

From the fish tank 500 water overflows into the fish tank outlet 520 at fish tank outlet leveller level 526 determined by a fish tank outlet leveller 525 and flows via a piping system to a cleansing system inlet 15 at a cleansing system inlet level 17 into the cleansing system 10. From the cleansing system 10 there is a cleansing system outlet and by a pump 700 the water is elevated back into the fish tank 500 and a flow is es- tablished by a flow-setter 600.

The cleansing system 10 may be configured as disclosed in the figure, configured as disclosed in the previous figures or as in figures 12 and 13.

Figure 12 illustrates, in continuation of figure 11, a cleansing system 10 and a fish tank 500 interconnected as a RAS-system. The cleansing system 10 is arranged with a first volume 41 surrounded by an annulus section 20 with a first arc forming a second volume 42 and a second arc forming third volume 43. From the first volume 41 there is radial flow 1320 parting the medium into the second volume 42 and into the third volume 43. There is a tangential directed flow 1330 from the second volume 42 to the third volume 43. The cleansing system 10 is configured with leveller arrangements so that ordered gravitationally from a highest level, the order is fish tank outlet leveller level 526, cleansing system inlet level 17, first-second-overflow leveller level 45, and lowest second-third-overflow leveller level 49. The first-third overflow leveller level 47 is not shown, but it may be at the first-second overflow leveller level 45 or between that and the second-third overflow leveller level 49.

Figure 13 illustrates a cleansing system 10 configured to receive aqueous medium 5 from at least one fish tank 500 (not shown) and to return a cleaned aqueous medium (5) to the at least one fish tank 500.

The cleansing system 10 comprises a cleansing system inlet 15 arranged at a cleansing system inlet level 17 to inlet the aqueous medium 5 into a first volume 41. The first volume 41 is substantially surrounded by an annulus section 20 having at second vol- ume 42. The first volume 41 and the second volume 42 are in communication via at least a first-second-overflow leveller 44 arranged at first-second overflow leveller level 45 and to radially overflow the aqueous medium 5 from the first volume 41 to the second volume 42.

In this embodiment, there is a radially directed outward flow 1320 from the first vol- ume 41 to respective second volume 42 and third volume 43. The radially directed outward flow 1320 is from the first volume 41 to the second volume 42 via a first- second overflow leveller 44 arranged with a first-second overflow leveller level 45. The leveller is at the wall here formed as the inner circle of the annulus section 20. The leveller may be a barrier or valve which may be adjustable to adjust the first- second overflow leveller level 45. Similarly, the radially directed outward flow 1320 is from the first volume 41 to the third volume 43 via first-third overflow leveller 46 arranged with a first-third overflow leveller level 47.

There is also a tangentially directed flow 1330 from the third volume 43 to the second volume 42 via a second-third overflow leveller 46 at a second-third overflow leveller level 47.

There is a cleansing system outlet 16 arranged in the annulus section 20 configured to outletting the now cleaned aqueous medium 5 from the annulus section 20. In this embodiment, the cleansing system outlet 16 is from the third volume 43.

With reference to figures 2 to 5, the first volume 41 may be configured as a first reac- tor 50. The second volume 42 may be configured as a second reactor 100. The third volume 43 may be configured as a degassing section 150.

The first-second overflow leveller 44 may be configured as the degassing inlet 105 between the first reactor 50 and the degassing section 150 as seen in figures 2 and 3.

The first-third overflow leveller 46 may be configured as one or more of the reactor inlet pipe(s) 110, see figure 3, between the first reactor 50 the second reactor 100. The second-third overflow leveller 48 may be configured as the overflow leveller 130 between the second reactor 100 and the degassing section 150 e.g. in figure 3.

Figure 14 discloses an additional configuration and features of a cleansing system 10. For illustrative purposes the cleansing system 10 is shown in connection with two fish tanks 500 each supplied by pumps 700. The return system is not shown.

Figure 14 uses elements readily available from figures 11 to 13 such as the levellers 48 and level 49. Other overflows levellers and flows are understood in view of previ- ous figures and the arrows show the intended or implied resulting flow directions.

A first volume 41 is enclosed or surrounded by an annulus section 20 comprising a second volume 42, and here two third volumes 43. The cleansing system 10 has an annulus section 20 that is parted in arc-sections 30 forming at least a further volume 140. The further volume 140 is a fourth volume 144 that is in the annulus section 20. The first volume 41 and the fourth volume 144 are in communication via at least a first-fourth-overflow leveller 145 arranged at a first-third overflow leveller level 146 to radially overflow the aqueous medium 5 from the first volume 41 to the fourth volume 43.

Optionally there may be return flow means 141 for returning the aqueous medium 5 from a volume in the annulus section 20 to the first volume 41 in a return flow 142. The return flow 142 is here shown from the fourth volume 144 back into the first vol- ume 41. The return flow means 141 may be perforations in the wall section between the annulus section 20 and the first volume 41. Alternatively, the return flow means 141 may be a pump arrangement. The third volume 43 and the fourth volume 144 are in communication via at least a third-fourth-overflow leveller 147 arranged at third-fourth overflow leveller level 148 and to tangentially overflow the aqueous medium 5 from the fourth volume 144 to the third volume 43.

Optionally there may be return flow means 141 for returning the aqueous medium 5 from the fourth volume 144 to the first volume 41 as a return flow 142. The volumes disclosed in figure 14 may be configured as follows. The first volume 41 is configured to for nitrification of the aqueous medium 5. The second volume 42 is configured for degassing the aqueous medium 5. The third volume 43 is configured for nitrification of the aqueous medium 5. The fourth volume 144 is configured for de- nitrification of the aqueous medium 5.

In this particular embodiment, the cleansing system 10 may be considered as being configured as follows. The first volume 41 is configured as a moving bed type of reac- tor. The second volume 42 is configured for degassing the aqueous medium 5. The second volume 42 is sandwiched between two third volumes 43. Each third volumes 43 are configured as a fixed bed type of reactor. The fourth volume 144 is between the two third volumes 43 and configured for de-nitrification of the aqueous medium 5. In this embodiment, the flow from the first volume 41 to volumes (second 42, third 43 or fourth volumes 144) is through a permeable retainer 149 that is configured to allow the aqueous medium 5 to flow into volumes in the annulus section 20 whilst retaining say bio-cleaning elements in the first volume 41. In this embodiment, the first volume 41 is separated with other volumes by individual permeable retainers 149. A permea- ble retainer may be a screen with perforations or holes impermeable to bio-cleaning elements.

Figure 15 exemplifies the aspects illustrated in figure 14 and the reference numbers are readily recognisable from figure 14.

A person skilled in the art will readily be able to install one or more pumping systems to provide the aqueous medium to the chamber or to move the aqueous medium from the chamber.

In this example, the additional chamber 140 i.e. the fourth volume 144 is configured for de-nitrification 200. There is a cover 210 or lid. There is an air lift 220 arrange- ment seen in the volume.

Also shown are details of the third volume 43, which here is arranged as a fixed bed type of chamber for nitrification. The third volume 43 has air lifts arranged. The generic configuration disclosed in figures 11 to 14 may be implemented in special configurations derived from figure 1 to 11 and according to the following aspects.

Aspect 1. A method (1000) for cleansing an aqueous medium (5) from an aquaculture system (1) in a cleansing system (10), the method (1000) comprising acts of

- providing (1050) the aqueous medium (5) to a cleansing system inlet (15) in the cleansing system (10) followed by an act of: mechanical filtering (1100) the aqueous medium (5) in a mechanical filter (70) followed by an act of:

- biologically filtering (1150) the aqueous medium (5) in a first reactor section (50) followed by an act of:

- parting (1200) the aqueous medium (5) into a second reactor (100) and a de- gassing section (150), wherein there are acts of:

- degassing (1350) the aqueous medium (5) in the degassing section (150); and

- overflowing (1300) of the aqueous medium (5) from the second re- actor into the degassing section (1350); and from which degassing section (1350) there is an act of

- outletting (1400) the now cleaned aqueous medium (5) through an cleansing system outlet (16). Aspect 2. The method according to aspect 1, wherein the parting (1200) the aqueous medium (5) is performed in a substantially radially directed (1320) outward flow from the first reactor section (50) into arc-sections (30) of a surrounding annulus section (20), which arc-sections (30) include at least

- the second reactor (100); and

- the degassing section (150) receiving;

each receiving part of the aqueous medium (5).

Aspect 3. The method according to aspect 1 or 2, wherein the act of overflowing (1300) of the aqueous medium (5) is performed in a substantially tangentially directed (1330) flow at arc-section dividers (25) from the second reactor (100) into the degas- sing section (150). Aspect 4. The method according to any one or more of the preceding aspects, wherein

- the act of providing (1050) the aqueous medium (5) to the cleansing inlet (15) in the cleansing system (10) is performed at a gravitational level that is above

- the act of parting (1200) the aqueous medium (5) into the second reactor (100) and the degassing section (150); and below which

- the act of overflowing (1300) of the aqueous medium (5) from the second re- actor section (100) into the degassing section (150) is performed; and below which there is

- the act of outletting (1400) the aqueous medium (5).

Aspect 5. A cleansing system (10) configured to receive aqueous medium (5) from at least one fish tank (500) and to return a cleaned aqueous medium (5) to the at least on fish tank (500); the cleansing system (10) comprising:

an cleansing system inlet (15) centrally located in the cleansing system (10) and in communication with

a mechanical filter (70) configured to mechanically filtering (1100) the aque- ous medium (5) and arranged above and substantially surrounded by:

a first reactor section (50) configured to biological filtration (1150) of the aqueous medium (5) and being substantially surrounded by an annulus section (20) parted and in communication with arc-sections (30) of at least

• a second reactor (100); and

• a degassing section (150) configured to degassing (1350) the aqueous medium (5)

a cleansing system outlet (16) configured to outletting (1400) the now cleaned aqueous medium (5) from the annulus section (20). Aspect 6. The cleansing system (10) according to aspect 5, wherein the second reactor (100) is configured with an overflow leveller (130) arranged at a gravitational level that is above the gravitational level in the degassing section (150) for overflowing (1300) of the aqueous medium (5) from the second reactor (100) into the degassing section (150).

Aspect 7. The cleansing system (10) according to aspect 5 or 6, wherein the annulus section (20) comprises a pair (102) of second reactors (100) and a pair (152) of degas- sing sections (150); which pairs (102, 152) separate each other.

Aspect 8. The cleansing system (10) according to any one or more of aspects 5 to 7, wherein the degassing section (150) comprises a cross-flow or counter-flow applicator arrangement (180) arranged below crown nozzles (170) for cascading the aqueous medium (5) onto an upper part of the cross-flow or counter flow applicator arrange- ment ; and with air communicators (190) arranged to guide air to a lower part of the cross-flow or counter flow applicator arrangement (180).

Aspect 9. The cleansing system (10) according to any one or more of aspects 5 to 8, wherein the second reactor (100) comprises a deck (120) arranged to cover the second reactor (100) and configured with deck perforations (122) for an up-ward penetration of the aqueous medium (5).

Aspect 10. The cleansing system (10) according to any one or more of aspects 5 to 9, wherein the first reactor section (50) comprises transverse plates (60) substantially arranged in vertically and in parallel. Aspect 11. The cleansing system (10) according to any one or more of aspects 5 to 10, wherein the annulus section (20) is formed by a prefabricated plates/arc-sections, such as metal plates or glass-fiber plates and configured for receiving the first reactor sec- tion (50) inserted substantially in the center (12).

Aspect 12. A recirculating aquaculture system (1), the system (1) comprising a

a cleansing system (10);

at least one fish tank (500)

wherein the water is recirculated between the least one fish tank (500) and the cleansing system (10).

Aspect 13. The recirculating aquaculture system (1) according to aspect 12, wherein each of the least one fish tanks (500) has a fish tank outlet (520) in communication with the cleansing system inlet (15) which cleansing system inlet (15) is at a gravita- tional level that is lower than a fish tank outlet leveller (525) of each of the least one fish tank (500); and which cleansing system outlet (16) is in communication with a flow-setter (600) in each of the least one fish tanks (500); wherein there is a pump (700) in the communication between the cleansing system (10) and the least one fish tanks (500).

Aspect 14. The recirculating aquaculture system (1) according to aspect 12 or 13, wherein the cleansing system (10) is according to any one or more of aspects 5 to 11.

Aspect 15. The recirculating aquaculture system (1) according to any one or more of aspects 12 to 14, wherein the fish tank (500) has a fish tank wall (530) that is cylindri cal with the fish tank outlet (520) coaxially arranged; and wherein the flow-setter (600) is arranged and extends upwards at the fish tank wall (530) and has flow-setter perforations (610) in the upward direction (650).

A person skilled in the art will appreciate the individual aspects as well as combina- tions of aspects including which aspects or elements of aspects that are optional as- pects or alternative aspects. Furthermore, a skilled person would be able to alter or adjust aspects or elements to achieve the desired effect or improve the effect.