NO348567B1 - Land-based purification plant and method for purifying wastewater from fish farming facilities - Google Patents

Description

Land-based purification plant and method for purifying wastewater from fish farming facilities.

Field of the invention

The present invention relates to a land-based purification plant for purifying wastewater from fish farming facilities as stated in the preamble of independent claim 1, comprising a purification basin with an inlet for wastewater from one or more fish farming facilities and an outlet for discharging purified water, as well as a method for purifying wastewater from the fish farming facility using the purification plant.

Background of the invention

Land-based fish farming is a priority area, nationally and internationally.

Excrement and feed waste are the main part of emissions, and almost 100% of the particulate waste.

The amount of faeces and feed waste discharged from fish farming constitutes a source of organic matter that is taken up by a number of marine organisms. If the amount of faeces and feed waste becomes too high, the environment will not be able to process all the material, and there will be an accumulation of organic matter on the bottom. The amount of faeces released will vary with the size of the production, feed composition, feeding regime, fish size and temperature, and the total amount can be calculated using mass balance budgets or operational models. The amount of feed waste will depend on the feeding regime and method and will vary between facilities.

Land-based hatchery production takes place in closed tanks, raceways, earthen ponds, etc., where the discharge is led to the sea, river or water. Discharges from aquaculture facilities can affect the aquatic environment in the recipient if it is overloaded with organic matter and nutrients. Residues of feed and excrement can accumulate on the bottom and lead to oxygen deficiency, so that the decomposition process in the bottom sediments stops.

This in turn can lead to local extinction and changes in the benthic fauna.

In marine systems, most of it falls to the bottom and/or is carried away by currents and waves.

Many onshore facilities have sewage pipes that run directly into the sea, often with little or no treatment, so that feed waste and excrement flow freely and pollute the recipient, both water and bottom. Furthermore, it is not unknown for wild fish to stand at the outlets and eat the waste with the feed waste and excrement, with associated disease and reduced fish welfare.

In onshore facilities, drum filters are widely used to capture particulate waste.

Using drum filters and other mechanical filter types will grind and crush parts of the waste into smaller particles that are released through the filter cloth, or via the small holes in the drum filter.

The result is that a significant portion of the particulate waste is broken down into very small particles that are difficult to separate/collect, and thus ultimately end up in the wastewater and in the recipient.

The rate of particle sinking depends on the size and weight of the particles. Faeces are often fragile and break up easily into smaller pieces that sink at different rates. Most have a sinking rate of 5–10 cm per second. A small proportion are very small and sink at a rate of less than 1 cm per second. Feed pellets are relatively firm, do not break easily and have sinking rates of over 10 cm per second.

Review of prior art

US 2001017281 A1 shows a device for purifying wastewater. The device comprises a purification basin with an inlet for wastewater and an outlet for purified water. Lamella filters are placed in the purification basin, these can be found both near the inlet and the outlet. The wastewater flows over the lamella filter, from here sludge particles are separated from the wastewater and sludge is collected at the bottom of the basin.

US 2018087262 A1 shows a device for purifying surface water. Water to be purified is fed into a purification basin consisting of several separation/sedimentation chambers, with an inlet for contaminated water and an outlet for clean water.

WO 2023043479 A1 also discloses a device for removing contaminants from surface water, and comprises a container having an inlet for contaminated water and an outlet for clean water.

NO 129327 B shows a device for sedimentation of particles from a liquid.

The device has the form of a box with a funnel-shaped bottom, it contains a lamella filter, and upstream and downstream of the lamella filter there are distribution containers and collection channels.

RU 2696434 C1 discloses a device and a system for treating water in a closed aquaculture system. The primary purification step comprises separation using a lamella filter followed by a biological purification step and finally a further purification step using a lamella filter.

Purpose of the present invention

It is an object of the present invention to provide a purification plant for land-based fish farming, as well as a method for purifying wastewater from a fish farming facility.

The treatment plant can be used for FTS (flow-through plant), FTS-R (reuse plant), RAS (recirculating aquaculture system), and/or for other treatment needs.

The purpose is to purify wastewater before discharge to the recipient, or for full or partial reuse for fish, algae, kelp, etc., as well as recycling of organic material such as excrement, feed waste, etc.

The aim is to collect the largest possible proportion of organic waste for recycling and processing.

The invention can provide affordable purification technology, and less energy use. For example, energy can be recovered (due to headroom) in turbines by returning kWh.

The treatment plant is based on two-stage sedimentation and energy recovery.

Excrement and feed particles have a defined sinking rate. The purification basin according to the invention has a shape (rectangular, tube, slope), a volume and a flow rate that causes particulate waste to sink to the bottom, and is carried on the bottom towards a filter. A chamber below the filter draws water and particulate waste out to separate sedimentation tanks.

By using the purification plant according to the invention, separation of the wastewater into two purity levels can be achieved. Large amounts of water and small amounts of particulate waste make effective purification difficult, and this is something that the present invention seeks to avoid.

The invention achieves a low water flow with a very high particulate content. This facilitates later separation, purification and reuse, and also ensures that excrement is damaged to a small extent, making it better suited for reuse.

Summary of the invention

According to a first aspect of the present invention, a land-based treatment plant for treating wastewater from aquaculture facilities is provided, comprising a treatment basin with an inlet for wastewater from one or more aquaculture facilities and an outlet for discharging purified water. The treatment basin comprises a flow straightener located downstream of said inlet for wastewater, which flow straightener is adapted to straighten a low-speed water flow into a sedimentation chamber in the treatment basin, and that a bottom of the sedimentation chamber comprises a lamella filter, particles, related to their sinking speed, fall towards the bottom and are drawn towards the lamella filter, whereupon sludge/sludge-containing water is collected in an underlying collection channel connected to a sedimentation tank arranged to receive said sludge/sludge-containing water. The purification basin comprises a level chamber arranged downstream of the sedimentation chamber, in which the level chamber and the sedimentation chamber are separated by a second transverse partition wall comprising several slots or pipes equipped with adjustable dampers and a third transverse partition wall, and which functions as a control mechanism that prevents turbulence and ensures smooth and stable water flow out of the sedimentation chamber.

Alternative designs of the treatment plant are specified in the respective dependent claims.

The flow straightener may comprise a first transverse partition wall which divides a pre-chamber upstream in the purification basin, the flow straightener comprising several pipes or channels for said straightening of low-velocity water flow into the sedimentation chamber.

Said lamella filter may comprise slots which lie flush with the bottom of the sedimentation chamber.

The slots of the lamella filter can, in one embodiment, be arranged at an angle to the flow direction in the sedimentation chamber of between 5-10º.

Furthermore, the bottom of the sedimentation chamber may be surface-treated with a surface coating and/or have a slope that provides reduced friction and cavitation for waste moving along the bottom towards the lamella filter.

Said regulating mechanism is arranged to maintain a water level in the sedimentation chamber and the level chamber at a desired level before the water is discharged through said outlet.

Said outlet for discharging purified water may be connected to one or more downstream arranged Kaplan turbines for energy recovery.

The treatment plant may comprise several sedimentation tanks which are arranged to be used in a constant sequential or linear sedimentation process.

The sedimentation tanks may be connected to a return line for transporting treated wastewater from the sedimentation tanks back to the treatment basin.

The return line can run to the pre-chamber and/or to the sedimentation chamber in the purification basin.

The purification plant may further comprise a dewatering tank connected to said sedimentation tanks, which dewatering tank is arranged for receiving sediment from the sedimentation tanks.

The treatment plant may also include a surface skimmer designed to capture smaller particles, proteins, and oils that may float to the water surface.

In the treatment plant, the smallest sedimentation chamber may have a rectangular shape or a circular-cylindrical shape.

According to a second aspect of the present invention, a method is provided for purifying wastewater from fish farms in a land-based purification plant, the method comprising the steps of:

- receiving wastewater in a purification basin comprising a flow rectifier that straightens the wastewater into a low-velocity water flow into a sedimentation chamber in the purification basin,

- the wastewater is brought to maintain a smooth, stable and calm water flow in the sedimentation chamber so that particles, related to their sinking speed, fall towards the bottom of the sedimentation chamber and are drawn towards a lamella filter with an underlying collection channel,

- collection of sludge/sludge-containing water in the collection chute, after which said sludge/sludge-containing water is transported to a sedimentation tank,

- storing said sludge/sludge-containing water for a sufficient period of time for waste to sink to the bottom of the sedimentation tank as sediment,

- pumping clean water from the sedimentation tank back to the cleaning basin, and - pumping sediment from the sedimentation tank to a dewatering tank for forming dewatered pulp.

Alternative embodiments of the method are set forth in the respective dependent claims.

According to the method, multiple sedimentation tanks can be used in a constant sequential sedimentation process, the method comprising the steps:

- pumping of sludge/sludge-containing water into a first sedimentation tank until the tank is full or nearly full, followed by

- pumping of sludge/sludge-containing water to a second sedimentation tank until the tank is full or nearly full, followed by

- pumping sludge/sludge-containing water to a third sedimentation tank until the tank is full or nearly full, and

- emptying sediment from the first sedimentation tank when the third sedimentation tank is filled, as well as pumping clean water back to the cleaning basin and pumping sediment to a dewatering tank from the first sedimentation tank, - and repeating the process for each sedimentation tank as preceding sedimentation tanks are filled or emptied.

Multiple sedimentation tanks can be used in a linear sedimentation process, where the method includes the steps:

- pumping sludge/sludge-containing water into the sedimentation tank below the tank's water level, and

- pumping purified water from the upper water layer of the sedimentation tank back to the purification basin or to a further sedimentation tank for further purification, and

- emptying of sediment to the dewatering tank.

Said sequential and linear processes can be combined between the sedimentation tanks.

Furthermore, the dewatered mass from the dewatering tank can be further processed into reusable products, such as fertilizer, methane gas, feed for micro- and smaller organisms, and marine proteins.

The purification basin may comprise a level chamber arranged downstream of the sedimentation chamber, the method comprising maintaining a water level in the sedimentation chamber and the level chamber being maintained at a desired level.

The method may also include adding flocculant to the purification basin, causing the flocculant to bind to both particulate waste, suspended material, and dissolved liquids/gases.

Description of figures

Preferred embodiments of the invention will be described in more detail below with reference to the accompanying figures, in which:

Figure 1 shows in perspective a purification plant according to the invention.

Figure 2 shows a plan view of the purification plant according to the invention.

Figures 3 and 4 show respective side views of the purification plant according to the invention. Figures 5 and 6 show respective end views of the purification plant according to the invention. Figure 7 shows the lamella filter and collection chute in the purification plant according to the invention.

Figure 8 shows a treatment plant with at least one circular cylindrical sedimentation chamber.

Description of preferred embodiments of the invention

The purification plant according to the invention can be constructed and calculated so that it can constitute the foundation and/or foundation wall for buildings such as slaughterhouses, smolt plants, feed warehouses, offices, etc. This also reduces the total investments and space requirements.

As shown in Figure 1, the invention comprises a land-based treatment plant 10.

The treatment plant 10 comprises a treatment basin 12 for treating wastewater from one or more fish farming facilities (not shown). It would be natural for the fish farming facility or facilities to also be located on land, but it is conceivable that the treatment plant could also be used with sea-based fish farming facilities from which the wastewater is pumped via pipelines.

The purification basin 12 comprises one or more inlets 14 for receiving wastewater from said fish farming facility. Upstream in the purification basin 12, a first transverse partition wall divides the purification basin 12 into a pre-chamber 20, adjacent said inlet 14, and a sedimentation chamber 18. The inlet 14 or inlets may be provided in the end wall or side wall of the purification basin 12 so that the wastewater flows into the pre-chamber 20.

The first transverse partition wall comprises a flow straightener 24 with pipes or channels arranged to straighten a low velocity water flow into the sedimentation chamber 18 of the purification basin 12. The water flow is substantially straightened and prevents turbulence from keeping particulate waste suspended in turbulent water flows. The flow straightener 24 forms the first transverse partition wall and may comprise a pipe stack, as illustrated in the figures.

The sedimentation chamber 18 may have a smooth bottom 18a which may be treated with a surface coating, and which provides reduced friction and cavitation for waste moving along the bottom. The bottom 18a may further alternatively or additionally have a slope which contributes to a corresponding effect. The bottom 18a of the sedimentation chamber 18 also comprises a lamella filter 28, so that particles, related to their sinking speed, fall towards the bottom 18a and are drawn towards the lamella filter 28. Sludge or water containing sludge is collected in an underlying collection channel 30 connected to a sedimentation tank 32. It will be natural that the lamella filter 28, and to some extent also the collection channel 30, are placed downstream in the sedimentation chamber 18. As shown in Figure 2, the lamella filter 28 and the collection channel 30 are placed at the opposite end of the sedimentation chamber 18 than where the water flow enters from the pre-chamber 20.

The water flow in the sedimentation chamber 18 will be unidirectional and homogeneous.

The design of the sedimentation chamber 18 can be calculated in length, width, height or, in the case of a circular tank, diameter, to maintain a smooth, laminar, linear, parallel, stable and/or calm water flow. Particles, related to their sinking rate, fall into the sedimentation chamber 18 and towards the bottom 18a and are drawn towards the lamella filter 28. Safety margins for different sinking rates can be included in the calculation of the best possible water velocity, flow, length, width, depth or diameter.

As mentioned, the lamella filter 28 and the collection chute 30 are preferably located at the end of the sedimentation chamber 18, i.e. downstream in the sedimentation chamber 18.

The lamella filter 28 can be designed so that no changes occur in the water flow, which in turn will lead to agitation of waste materials and reduced purification.

The lamella filter 28 is designed to create a smooth, parallel, homogeneous, laminar and stable water flow. The lamella filter 28 may in one embodiment comprise one or more rows of slots which lie completely flush with the bottom 18a of the sedimentation chamber 18. The slots may, for example, be about 1 meter long and have a slight angle (about 5 - 10 degrees) in the longitudinal direction (flow direction), as shown in Figure 7. The slots may be located longitudinally or alternatively transversely on the bottom 18a of the sedimentation chamber 18.

It is further apparent from Figure 7 that the collection chute 30 may, for example, have a V shape and be equipped with a device, for example in the form of one or more perforated pipes 40, which sucks the sludge from the entire collection chute 30. The collection chute 30 may alternatively have an approximate W shape or a U shape, preferably with a flat bottom.

After (downstream) the lamella filter 28 and the collection chute 30, a second transverse partition wall is located and separates the cleaning basin 12 in the sedimentation chamber 18 and a level chamber 22. The second partition wall comprises slots or pipes 26 equipped with dampers to regulate the water flow out of the sedimentation chamber 18, as well as a third transverse partition wall 38. The second transverse partition wall with the pipes 26 can, similarly to the current rectifier 24, be designed as a pipe stack, and functions as a regulation mechanism together with the third partition wall 38.

The second transverse partition with the adjustable slots or tubes 26 prevents turbulence and velocity changes at the end of the sedimentation chamber 18 and out of the sedimentation chamber 18. This is to avoid creating water currents that can swirl up particulate waste.

The level chamber 22 further helps to stabilize the water level in the pre-chamber 20 and the sedimentation chamber, and the regulation mechanism (the pipes 26 or the slits with dampers and the third partition 38) in the level chamber 22 keeps the water level in the sedimentation chamber and the level chamber 22 at a desired level, before discharging water out of the outlet 16. The lines in Figures 1 and 2 are intended to illustrate level regulation in the sedimentation chamber 18.

The water can also be aerated in the level chamber 22. Aeration in each sedimentation tank 32 can remove much of the dissolved substances such as nitrogen, phosphorus, CO<2>, ammonia, etc.

Said outlet 16 may comprise one or more outlets and which are connected to Kaplan turbines (not shown). The wastewater may flow from the level chamber and pass the Kaplan turbines via, for example, a drop chamber before discharge to the recipient. The energy recovery will in principle be able to provide a 40 - 60% reduction in (pumping costs) energy consumption.

Figure 8 shows an alternative embodiment of the purification plant 12 according to the invention, where the purification plant 12 comprises at least a circular cylindrical sedimentation chamber 18. However, the entire purification basin 12 may also have the same shape. The lamellar filter 28 is located inside and at the lowest point of the sedimentation chamber 18, and is similarly located above a collection channel 30 which is connected to sedimentation tanks 32, as previously explained.

The purification plant shown in Figure 8 may be similarly equipped with the flow straightener 24 comprising the first transverse partition wall that divides the pre-chamber 20 upstream in the purification basin 12, where the flow straightener 24 comprises several pipes or channels for said straightening of low-speed water flow into the sedimentation chamber 18. In a similar manner, the purification basin 12 comprises the level chamber 22 arranged downstream of the sedimentation chamber 18, where the level chamber 22 and the sedimentation chamber 18 are separated by the second transverse partition wall with several slots or pipes 26 equipped with adjustable dampers and the third transverse partition wall 38, and which functions as a control mechanism that prevents turbulence and ensures smooth and stable water flow out of the sedimentation chamber 18.

The sludge or sludge-containing water that is captured by the lamella filter 28 in the collection chute 30 will have a volume that has little water and a high concentration of excrement and feed waste, and which is brought and/or pressed/sucked from the collection chute 30 through lines or pipes to the sedimentation tanks 32 and subsequent sedimentation process. Openings - slots, in the lamella filter 28 will be adapted to the water velocity, waste type, and operating model. The collection chute 30 may be equipped with a device, such as one or more perforated pipes 30a, that sucks all the sludge from the entire collection chute.

Particles that float up into the cleaning basin 12 can be captured by a skimmer (not shown) for surface cleaning and collected in a separate tank, which is part of the total sludge collection.

A flocculant can further be added to the cleaning basin 12, which will bind to both particulate waste, suspended material, and dissolved liquid gases.

The flocculating agent can be adapted so that the sinking rate can be calculated, and in the case of flotation-flocculation, the skimmer can function as an ordinary surface skimmer in the plant. The skimmer for surface water can capture smaller particles, proteins, and oils that can float up, and that which binds to the flotation-flocculation.

As shown in the figures, the treatment plant 10 may comprise several large sedimentation tanks 32.

From the collection chute 30, the sludge or the sludge-containing water can be pumped up into, for example, three large sedimentation tanks 32 which are used in a constant sequential and/or linear sedimentation process.

The wastewater with sludge/sludge-containing water in the sedimentation tanks 32 should be stagnant for a required number of hours, so that all waste materials sink to the bottom. After specified hours of standstill, clean water will be pumped back to the pre-chamber 20 or the sedimentation chamber 18.

After specified hours, the sediment in the sedimentation tanks 32, consisting of excrement and feed waste, will be pumped to the dewatering tank 34. The compact dewatered mass can be further processed into a number of products such as fertilizer, methane gas, feed for micro- and smaller organisms, and for marine proteins, etc.

An example of a constant sequential sedimentation process may be as follows. Sludge and sludge-containing water) are pumped into a first sedimentation tank 32<1> until it is full or nearly full. Sludge and sludge-containing water are then pumped into the next sedimentation tank 32<2>. The first sedimentation tank 32<1> then has a total stagnant water in a given time unit, which is calculated from the sinking rate of waste particles. Waste will then fall to the bottom.

When the second sedimentation tank 32<2> is full or nearly full, the filling (pumping) of sludge and sludge-containing water to a third sedimentation tank 32<3> begins. At the same time as the third sedimentation tank 32<3> is filled, sludge is emptied from the bottom of the first sedimentation tank 32<1> and the water is returned to the treatment plant 12.

When the third sedimentation tank 32<3> is full or nearly full, the first sedimentation tank 32<1> is empty, and the process then continues, from tank to tank.

This repeats itself in a "perpetual" process, in a purely sequential mode of operation.

In a linear collection, sludge will be sent into the sedimentation tank 32 below the water level in the tank. Waste particles will sink to the bottom, while the outlet of purified water is taken from the top of the sedimentation tank 32, i.e. the upper water layer. The sediment is sent to the dewatering tank 34 for further drainage. Purified water is collected from the top and can be sent to a sedimentation tank 32 for further purification, alternatively back to the purification basin 12 or to the recipient.

Cleaning equipment, tank volume, water volumes and time program for sinking rate are calculated so that a tank can be maintained, pumps serviced, etc., without affecting cleaning capacity.

The time the wastewater with sludge/sludge-containing water should remain stagnant in the sedimentation tanks 32 can be calculated based on volume, water quantity and waste type, so as to ensure that most of the waste sinks to the bottom. The purified water is then pumped back as explained, and sediment, consisting of excrement and feed waste, is pumped to the dewatering tank 34.

The present invention provides a treatment plant that achieves a very high degree of purification and wastewater with almost no particulate waste. Reuse of all organic - particulate material.

Purified water can be reused in the fish farming facility, but purified water can also be used as purified freshwater for farming of several species, and for agriculture, greenhouses, etc. Or as purified seawater for farming of other fish species, own use, and for farming of seaweed, kelp, algae, shells and benthic animals (especially bristle worms). When producing bristle worms, which is very relevant, the correct and controlled amount of waste from the sedimentation tanks can be treated and positioned as bristle worm feed.

The main goal is a high degree of purification for aquaculture facilities on land, where waste materials are destroyed and ground to the minimum extent possible, the greatest possible separation between water and waste materials, and energy-efficient and cost-effective purification.

The purification method is suitable for preserving the values and resources contained in the waste for further processing.

The purification plant 10 may further be equipped with mechanisms to keep the collection chute 30 free from the accumulation of waste materials.

The treatment plant will be able to be divided into modules and have access from the top for modular cleaning and maintenance without unnecessary operational disruptions.

Claims (20)

Patent claims 1. Land-based purification plant (10) for purifying wastewater from fish farming facilities, comprising a purification basin (12) with an inlet (14) for wastewater from one or more fish farming facilities and an outlet (16) for discharging purified water, the purification basin (12) comprises a flow straightener (24) located downstream of said wastewater inlet (14), said flow straightener (24) being adapted to straighten a low velocity water flow into a sedimentation chamber (18) in the purification basin (12), and a bottom (18a) in the sedimentation chamber (18) comprises a lamella filter (28), particles, related to their sinking speed, fall towards the bottom (18a) and are drawn towards the lamella filter (28), whereupon sludge/sludge-containing water is collected in an underlying collection trough (30) connected to a sedimentation tank (32) arranged for receiving said sludge/sludge-containing water, characterized in that the purification basin (12) comprises a level chamber (22) arranged downstream of the sedimentation chamber (18), wherein the level chamber (22) and the sedimentation chamber (18) are separated by a second transverse partition wall comprising several slots or pipes (26) equipped with adjustable dampers and a third transverse partition wall (38), and which functions as a control mechanism that prevents turbulence and ensures smooth and stable water flow out of the sedimentation chamber (18). 2. The purification plant (10) according to claim 1, characterized in that the flow straightener (24) comprises a first transverse partition wall that divides a pre-chamber (20) upstream in the purification basin (12), the flow straightener (24) comprising several pipes or channels for said straightening of low-velocity water flow into the sedimentation chamber (18). 3. The purification plant (10) according to claim 1, characterized in that said lamella filter (28) comprises slots that lie flush with the bottom (18a) of the sedimentation chamber (18). 4. The purification plant (10) according to claim 3, characterized in that the slots of the lamella filter (28) are arranged with an angle to the flow direction in the sedimentation chamber (18) of between 5-10º. 5. The purification plant (10) according to claim 1, characterized in that the bottom (18a) of the sedimentation chamber (18) is surface-treated with a surface coating and/or has a slope that provides reduced friction and cavitation for waste moving along the bottom (18a) towards the lamella filter (28). 6. The purification plant (10) according to claim 1, characterized in that said control mechanism is arranged to maintain a water level in the sedimentation chamber (18) and the level chamber (22) at a desired level before the water is discharged through said outlet (16). 7. The purification plant (10) according to claim 1, characterized in that said outlet (16) for discharging purified water is connected to one or more downstream arranged Kaplan turbines for energy recovery. 8. The purification plant (10) according to claim 1, characterized in that the purification plant comprises several sedimentation tanks (32) which are arranged to be used in a constant sequential or linear sedimentation process. 9. The purification plant (10) according to claim 1 or 8, characterized in that said sedimentation tanks (32) are connected to a return line (36) for transporting purified wastewater from the sedimentation tanks (32) and back to the purification basin (12). 10. The purification plant (10) according to claim 9, characterized in that the return line (36) runs to the pre-chamber (20) and/or to the sedimentation chamber (18) in the purification basin (12). 11. The purification plant (10) according to claim 1, characterized in that the purification plant comprises a dewatering tank (34) connected to said sedimentation tanks (32), which dewatering tank (34) is arranged for receiving sediment from the sedimentation tanks (32). 12. The purification plant (10) in accordance with claim 1, characterized in that the purification plant comprises a surface skimmer arranged to capture smaller particles, proteins, and oils that can float to the water surface. 13. The purification plant (10) according to claim 1, characterized in that at least the sedimentation basin (18) has a rectangular shape or a circular cylindrical shape. 14. Method for purifying wastewater from fish farming facilities in a land-based purification plant (10) in accordance with one or more of claims 1-13, characterized in that the method comprises the steps: - receiving wastewater in a purification basin (12) comprising a flow straightener (24) that straightens the wastewater into a low-velocity water flow into a sedimentation chamber (18) in the purification basin (12), - the wastewater is brought to maintain a smooth, stable and calm water flow in the sedimentation chamber (18) so that particles, related to their sinking speed, fall towards the bottom (18a) of the sedimentation chamber and are drawn towards a lamella filter (28) with an underlying collection chute (30), - collecting sludge/sludge-containing water in the collection chute (30), after which said sludge/sludge-containing water is transported to a sedimentation tank (32), - storing said sludge/sludge-containing water for a sufficient time for waste to sink to the bottom of the sedimentation tank (32) as sediment, - pumping clean water from the sedimentation tank (32) and back to the cleaning basin (12), and - pumping sediment from the sedimentation tank (32) to a dewatering tank (34) to form dewatered pulp. 15. A method according to claim 14, characterized in that several sedimentation tanks (32) are used in a constant sequential sedimentation process, the method comprising the steps of: - pumping sludge/sludge-containing water into a first sedimentation tank (32<1>) until the tank is full or nearly full, followed by - pumping sludge/sludge-containing water to a second sedimentation tank (32<2>) until the tank is full or nearly full, followed by - pumping sludge/sludge-containing water to a third sedimentation tank (32<3>) until the tank is full or nearly full, and - emptying sediment from the first sedimentation tank (32<1>) when the third sedimentation tank (32<3>) is filled, as well as pumping clean water back to the cleaning basin (12) and pumping sediment to a dewatering tank (34) from the first sedimentation tank (32<1>), and - repeating the process for each sedimentation tank (32) as preceding sedimentation tanks (32) are filled or emptied. 16. A method according to claim 14, characterized in that several sedimentation tanks (32) are used in a linear sedimentation process, the method comprising the steps of: - pumping sludge/sludge-containing water into the sedimentation tank (32) below the tank's water level, and - pumping purified water from the upper water layer of the sedimentation tank (32) back to the purification basin (12) or to a further sedimentation tank (34) for further purification, and - emptying of sediment to the dewatering tank (34). 17. Method according to claims 15 and 16, characterized in that said sequential and linear processes are combined between the sedimentation tanks (32). 18. Method according to claim 14, characterized in that the dewatered mass from the dewatering tank (34) is further processed into reusable products, such as fertilizer, methane gas, feed for micro- and smaller organisms, and marine proteins. 19. A method according to claim 14, characterized in that the purification basin (12) comprises a level chamber (22) arranged downstream of the sedimentation chamber (18), wherein a water level in the sedimentation chamber (18) and the level chamber (22) is maintained at a desired level. 20. A method according to claim 14, characterized in that the method comprises adding flocculant to the purification basin (12), the flocculant being caused to bind to both particulate waste, suspended material, and dissolved liquids/gases.