NO325704B1 - Method of cleaning pool basins and means for carrying it out - Google Patents

Abstract

This application relates to a method for cleaning pool bottoms and means for performing it by means of a bottom stream obtained by using a movable body which, when placed in a given position above the bottom of the pool, forms a flow channel which is in communication at one end. with the pool outlet and at the other end is open to the bulk volume of the pool, the method comprising a collection stage where the movable body is held in a position that allows particles / sediments to sink and settle on a collection area on the pool bottom, and a flushing stage where the movable body is held in a second position over the collection area, which results in the formation of bottom flow over the collection area which carries the sediments / submerged particles into the drain, and where the collection step and the flushing step are repeated cyclically as long as it is necessary to remove the particles. fish farm. Furthermore, the application applies to pools for carrying out the procedure.

Description

This application concerns a method for cleaning pool bottoms and a device for carrying it out. The method and device are particularly suitable for aquaculture facilities that use longitudinal flow channels for the cultivation of marine species including benthic species.

Background

Two of the most important functions for a farming system are the supply of sufficient amounts of oxygen and the removal of dissolved and particulate waste (faeces). The oxygen supply is normally ensured through a continuous supply of oxygen-rich water, and the removal of dissolved waste substances and, to varying degrees, particulate waste is also based on the water replacement in the tub.

In the case of aquaculture facilities based on tanks, it has been found empirically that a water flow along the bottom of the tank with a minimum speed of 4-8 cm/sec is sufficient to transport residues and excrement towards the outlet and out of the tanks. Slope at the bottom is of little importance. But such a flow along the bottom can be problematic to achieve because the water supply to the tank should be sized based on the oxygen needs of the farming organisms, and not based on the water supply needed to get a sufficiently strong current along the bottom of the tank.

For round, or nearly round vessels, this problem is solved by the fact that the water in such vessels can be set in rotation even with a small supply of water. The rotation usually produces a sufficiently strong bottom current to move the waste particles, and a flow pattern occurs in which the waste particles follow a spiral path towards the drain in the center of the vessel. Round vessels with a circular water flow are particularly suitable for pelagic fish that swim in the free water masses.

But for other types of vessels, such as raceways, where the water only moves in one direction during normal operation and a circular flow cannot be set up, it is far more difficult to achieve a sufficiently strong bottom flow with a water supply that is dimensioned according to the oxygen consumption of the farming organisms. However, such vessels have other operational advantages compared to the round ones, and are particularly popular for farming bottom-dwelling organisms - both bottom-dwelling fish and invertebrates such as crustaceans, sea urchins and abalone.

It is generally difficult to achieve a good bottom flow in vessels with benthic animals because the animals themselves will prevent the bottom flow. This problem can be solved by giving the tubs a double bottom, where the first bottom is a grate lying some distance above the lower watertight bottom in the tub. The grate has sufficiently large meshes for the waste particles to pass through, but small enough for uneaten food and the organisms themselves to be retained on the grate. In this way, the animals on the grate get a better environment in which to stay.

The challenge in a tank with a double bottom is to remove the waste particles that fall through the grate in an efficient way so that they do not accumulate and ultimately make the environment in the tank unacceptable for the animals. Manual cleaning is a widely used solution, but it is labor-intensive and inefficient. Mechanical devices can be used, but no systems have been developed that work well in practice. Local flushing of the bottom will usually stir up the particles without removing them, increase particle erosion and only make the water environment even worse. Cleaning using a sufficiently powerful bottom current is therefore desirable, but it must be arranged so that the waste particles are simultaneously transported towards the drain and removed from the vessel. Shock draining of the tub will help to increase the speed of the water flow towards the drain, but in most cases this is not sufficient to achieve a good cleaning effect either.

In summary, one can say that until today there is a lack of good solutions to the problem of particle removal in breeding tanks without a circular water flow. The problem of accumulation of particulate waste is not reserved for the farming industry. Problems with the accumulation of submerged particles may also arise for other types of liquid-filled pools.

The objective of the invention

It is therefore an objective of this invention to provide a method for achieving a sufficiently strong liquid flow along the bottom of liquid-filled vessels to be able to drag the sunken particles with it and flush them out into a drain.

It is also an objective of this invention to provide a device for forming such bottom currents for carrying out the inventive method.

Furthermore, it is an objective to provide design examples of breeding vessels for breeding marine benthic species where the problem of particulate organic waste is solved by using the inventive method.

Description of the invention

The objective of the invention can be achieved by the features that appear in the following description of the invention and/or the features defined in the patent claims.

The invention is based on the recognition that the flow rate over a cross-section goes as v = Q/A, where v is the flow rate, Q is water flow (often identical to water supply) and A is the cross-sectional area. Since Q often cannot be increased (it is, for example, determined by the animals' oxygen consumption), there is a reduction of A that is available to increase v. Furthermore, the invention utilizes the insight contained in Shield's formula for drag forces on a particle in water flow which can be written such:

where d is particle diameter, yv is water specific gravity, ys is particle specific gravity, v is flow velocity, M is Manning's roughness coefficient, R is hydraulic radius (flow area/wetted perimeter) and C is Shield's coefficient.

This formula states that drag on a particle in water flow increases with the flow rate squared. That is it is relatively easy to achieve a sufficiently efficient transport capacity for particulate waste by reducing the flow cross-section.

This realization is exploited by equipping pools with bottoms that need the removal of sediments/submerged particles with a movable body which, when lowered into contact with the bottom of the pool, forms a flow channel with a sufficiently small cross-sectional area to create a flow of liquid that pulls with it the particles that lie on the bottom inside the channel and out into a drain. This requires that the flow channel that is formed is in contact with an outlet from the pool at one end, so that water is sucked in from the bulk phase in the pool at the other end, which then flows through the channel and out into the drain.

The dimensioning of the cross-section of the flow channel and the required tapping volume per unit of time to achieve a flow that cleanly washes the bottom of the pool is, as appears from Shield's formula, dependent on which particles are to be removed, i.e. density difference between particle and liquid, particle size, roughness, shape, etc. However, it has been mapped how a liquid flow manages to drag sediments with it. This knowledge is embodied in Meyer-Peter and Muller's formula. There are also standard diagrams such as Hjulstrøm's diagram which graphically shows the relationship between grain size, flow rates and transport progress. Meyer-Peter and Muller's formula and diagrams such as Hjulstrøm's diagram are basic knowledge for a professional in the field. Thus, the invention is sufficiently defined to cover a general protection for the idea of using a movable body in the pool to create a bottom current in the pool which can sweep the bottom clean of sunken particles.

In cases where the amount of liquid that can be drained out per unit of time is limited, the requirement for a small cross-sectional area can mean that the flow channel that is formed only covers a small part of the bottom of the pool, typically a longitudinal strip on the bottom. In order to achieve cleaning of the entire bottom, it is therefore necessary that the movable body can be successively placed in adjacent positions along the bottom of the pool to obtain channels which together cover the entire bottom of the pool. This solution will require a flexible connection of the flow channel to the pool outlet. Alternatively, the bottom of the pool can be designed so that the sunken particles are collected on an area-limited collection area on the bottom of the pool and the movable body is designed to form a channel that covers this collection area when the body is placed over it. In this case too, the body should be movable because when it lies above the collection area, the body will be an obstacle for new particles to sink down to the collection area. This problem can be solved by using a repeated alternation between placing the movable body in a position away from the collection area during a period when new particulate waste is collected on the collection area and then placing it above the narrowing area to form the bottom flow that sweeps it clean. This procedure is repeated as long as there is a need to clean particulate waste from the bottom of the pool. The period in which the body is pulled away will be referred to as the collection period and the period in which the body forms the flow channel will be referred to as the flushing period in the following description of the invention.

The method according to the invention to form a sufficiently strong bottom current to sweep the bottom clean of particles can be used for any pool where there is an outlet in the bottom part and where there is a need to remove sediments, particulate waste etc. There are no limitations to physical dimensioning or physical shape of the pool bottom and the movable body beyond the requirement that the cross-section of the flow channel that is formed must be sufficiently small to achieve a bottom current that is strong enough to drag the particles/sediments with them into the pool's outlet with the flow volumes that are compatible with ordinary operation of the pool. The invention can therefore be realized for many different tanks/pools, such as swimming pools, breeding tanks, industrial tanks, etc. where it is desirable to achieve a relatively strong bottom flow without shock draining and/or where it is desirable to limit the addition of liquid to the tank/pool.

Many different designs of the movable body and the pool can be imagined. It is conceivable, for example, that pools are round, i.e. cylindrically symmetrical around a vertical central axis, with an outlet in the center of the bottom and where the movable body is designed as a disk that covers the bottom area almost to the edge of the pool. In this edition, it is imagined that the movable body is lifted out of the pool in a collection position. Alternatively, the movable body may be in the form of a rod-shaped body with a milled groove facing down towards the bottom of the pool, etc. or it may be something intermediate between the two latter designs.

In one aspect, the invention relates to a method for forming a bottom current in pools with a liquid outlet, where the bottom current can clean the bottom of sediments/submerged particles and transfer it to the outlet of the pool, characterized in that the bottom current is obtained by using a movable body which, when placed in a given position above the bottom of the pool, a flow channel forms which at one end is in communication with the outlet of the pool and at the other end is open to the bulk volume of the pool, that the method comprises a collection step where the movable body is held in a position that allows particles/sediments can sink down and settle on a collection area at the bottom of the pool, and a flushing step where the movable body is placed in a second position above the collection area which causes a bottom flow to form over the collection area which drags the sediments/the sunken particles into the drain with it, and that the collection step and the flushing step are repeated cyclically for as long as it is need to remove particulate waste from the farm.

In another aspect, the invention relates to basins for carrying out the method, comprising a vessel with a bottom and walls, a liquid outlet in the bottom section and a liquid inlet, characterized in that: - the bottom is designed so that at least one collection area is formed for submerged particulate waste/sediments, - a movable body is designed to be able to form, together with the bottom, a flow channel which at one end is in communication with the outlet of the pool and the other end is open to the bulk volume of the pool, and where the movable element can be moved between a first position that allows that the sediments/submerged particles are allowed to sink down and settle on the collection area and a second position where the element together with the bottom forms the flow channel.

The bottom of the pool can advantageously be designed so that particulate waste/sediments that sink will collect on the collection area only with the help of gravity. Alternatively, it is conceivable to use mechanical means, such as scrapers and the like to transport particulate waste/sediments that fall to the bottom outside the collection area into the collection area.

The design of the pool's bottom can, for example, be a V-shape mainly parallel to the pool's central axis, in which case the area on the bottom at the intersection axis formed by the two mutually angled surfaces in the V-shaped bottom will form the collection area. Alternatively, the collection area can be made up of a longitudinal channel, it can be in the form of a collection chamber etc. arranged mainly along the center axis of the pool. The gutter can also be combined with a V-shaped bottom.

The movable body can be any body which has sufficient mechanical strength to withstand the flow forces occurring during the flushing period and which is chemically resistant in the liquid environment applicable in the pool. The movable body can be moved using a mechanical lifting/lowering device. Alternatively, it is conceivable to use a hollow body which can alternately be filled with air and water/liquid to regulate the buoyancy to move the body between the first and second position. In cases where the collection area consists of a longitudinal gutter etc. along the central axis of the pool, the movable body should be given an elongated shape that covers the collection area from the outlet of the tub (which is located at one end of the tub) and almost to the opposite end of the pool. In this way, a longitudinal flow chamber is achieved which will flush clean the collection area along the entire central axis of the pool. In cases where a mechanical lifting/lowering device is used to move the body between the first and second position, the body can advantageously be made of a material with a density close to the density of the liquid, i.e. the ratio of the body's density and the density of the liquid phase can advantageously be in the range from 0.8 to 1.2.1 cases where the liquid is water, this means that the density of the body can advantageously be in the range of around 1 g/cm<3>.

The invention is suitable for use in breeding facilities intended for both pelagic species that swim freely in the water masses and for benthic species that live on the bottom. A non-exhaustive list of examples of suitable benthic species are bottom-dwelling fish such as catfish and halibut, and invertebrates such as sea urchins, marsupial crabs, king crabs and abalone. When breeding benthic species, the breeding facility should be equipped with a double bottom where the upper bottom is a mainly horizontal perforated plate on which the organisms can live, and where the perforation is sufficient for particulate waste to sink to the lower bottom and be collected in the collection area but small enough that uneaten food and organisms are retained on the perforated bottom.

Although the objective of the pool/tanks according to the invention is to achieve a sufficiently strong bottom flow to achieve a removal of particulate waste by draining only the quantities of water that are added during normal operation, the invention can be thought of combined with a time-limited shock tapping of the pool/tank to increase the flushing effect if necessary.

The invention has advantages in that it provides a technically simple and inexpensive method for removing particulate waste from pools. This solution is suitable for breeding facilities that use tanks. It can be used in pools of different sizes. Both the movable body and vessel can be made of different materials. It is possible to adapt the solution to tubs with a large width by designing the bottom of the tub as several parallel V-bottoms next to each other, so that the cross-section of the bottom forms a zigzag pattern. Each V-bottom must of course be equipped with its own removable body.

It is possible to carry out the procedure for cleaning particulate waste manually, but it is also easy to introduce automation that lowers and raises the movable body, possibly including shock tapping of the vessel in the correct order.

Exemplary embodiments of the invention

The invention will now be described in greater detail in the form of examples of rearing vessels of the longitudinal flow chute type. This should not be perceived as a limitation of the general idea as described above, other types of liquid-filled pools can also achieve a cleansing bottom flow using the inventive method. The invention is to be understood as a general method for cleaning particulate waste by using a movable/submersible body in the pool to alternate between a flushing period of submerged particles/sediments and a collection period.

In the case of breeding facilities for benthic species, an appropriate embodiment of the invention is a longitudinal flow vessel with a perforated bottom grid overlying a V-shaped lower bottom where a movable body can form a flow channel across the axis of intersection between the two angled surfaces that make up the V bottom. In this way, a relatively strong water flow is achieved over the vessel's collection area by draining the same amount of water that is supplied to the vessel from the organisms' oxygen needs. That is a sufficiently strong flow can be achieved to discharge particulate waste from the collection area (an area along the cutting axis) without increasing the water supply, or without having to carry out a shock drain of the farm. This is shown conceptually in Figure 1a where a rearing vessel 1 of the longitudinal flow channel type is shown schematically in profile from two sides. The tank has a perforated bottom grate 2 which allows particulate waste from the organisms to pass through, an inlet for fresh oxygen-rich water (not shown) and an outlet for used water 3. The water level in the tank is shown with a line marked 4. The movable body is indicated by reference number 5 The collection area is in the form of a channel 6 at the bottom of the tub which collects sinking particulate waste. In the figure, it can be seen that the body 5 is at a good distance above the channel 6, so that the water flow in the vessel is as in normal operation of a flow channel type breeding facility. This is mao. an ordinary operation of the breeding facility.

When sufficient particulate waste has accumulated in the collection area, the movable body is positioned so that a flow channel is formed over the collection area. In this position, it will lie at a relatively short distance from the collection area on the bottom of the breeding facility so that the body is an obstacle for particulate waste that is about to sink down to the collection area. According to the invention, this problem can be solved by defining a collection period where the movable element is placed in a position sufficiently far away from the collection area so that sinking particulate waste can reach the collection area unimpeded. This collection period should ensure that a certain amount of particulate waste has been collected in the collection area. The movable body can then be moved to the position where the flow channel above the collection area is formed, so that a water flow occurs through the chamber and out into the outlet, which drags the collected particulate waste with it. This phase will be referred to as a washout period. When the collection area is swept clean of waste, the process can be repeated by the movable body being pulled back to the collection position to form a new collection period, which is then followed by another flushing period, which is then followed by another collection period, etc.

This is conceptually shown in Figure 1b, where the rearing vessel is identical to that shown in

Figure la, except that now the floatable body 5 is positioned down towards the chute 6 so that a flow channel 7 is formed with a small cross-sectional area from the opening 8 towards the bulk phase of the rearing vessel to the outlet 3.1 this position is achieved by draining out the same amount of water as is supplied to the vessel during normal operation achieve a sufficiently strong water flow channel 7 to drag with it particulate waste which sank down to the channel 6 in the period shown in Figure la. In what follows, the situation shown in Figure la will be referred to as normal operation, and the situation shown in Figure lb will be referred to as the flushing phase.

Execution example 1

The first design example is shown schematically in Figures 2a and 2b. This is an example of a practical implementation of the vessel which is shown conceptually in Figures la and lb.

A rearing vessel 10 of the longitudinal flow type is shown in profile from two sides, in Figure 2a in the normal operating position and in Figure 2b in the flushing position. The vessel 10 is intended for

benthic species and has an upper perforated bottom 12 where the farming organisms can lie and which lets through particulate waste which sinks down towards the lower bottom of the vessel. The lower bottom is given a mainly V-shape and along the central axis a chute 16 is formed in the form of a tubular extension for collecting the sinking particulate waste. The movable body 15 is shown in an embodiment where it can be filled alternately with air and water so that varying buoyancy ensures that the body is moved from the operating position to the flushing position. This is achieved by a supply hose 20 with valves for supplying water and air, and by drain hose 21. The outlet 13 is shown in the form of a donut where the water level rises to the same level as the water level 14 during normal operation. In this operating position, the movable body 15 is filled with sufficient air so that it rises up and settles directly under the first base 12. See Figure 2a. The slanted arrows in the figure indicate the water flow in the breeding facility in this operating condition.

For the transition to flushing, the movable body 15 is filled with water until it sinks down and settles over the opening of the chute 16. A flow channel 17 is thus formed and a water flow occurs as indicated by arrows in Figure 2b. In this implementation example, shock tapping is used in addition to draining the added water. This can be achieved by, for example, the last part of the monk 13 being equipped with a removable riser 19 so that the water height in the monk is reduced to below the water level 14.

The aim of the flushing is to prevent sedimentable material from having a negative impact on the water quality in the breeding tank. The negative effect can occur both as a result of the release of unwanted substances from the sedimented particles when these dissolve, and from the release of harmful substances from the bacterial breakdown of the particles. It will be particularly bad if the layer of sediments becomes so thick that anaerobic conditions occur in the sediment. Methane and hydrogen sulphide will then be formed which can be released into the water in the form of gas bubbles. Hydrogen sulfide is extremely toxic to farmed organisms.

How often flushing is necessary depends on a number of factors such as the amount of waste produced, the nature of the waste and how quickly the waste breaks down (which again is highly dependent on the water temperature). For sea urchin farming at low temperatures, one flush per week may be sufficient, while for other species and at higher temperatures, flushing at least once a day may be necessary. In general, there will be an advantage with frequent flushing if this can be done without disturbing the organisms. The water supply to breeding vessels is often dimensioned based on the organisms' oxygen consumption, which will vary with species, growth rate, size, water temperature etc. For many breeding organisms, the water requirement is between 0.5 and 1.5 1 per kg per minute. This means that a vessel containing a biomass of 1000 kg needs 500 to 1500 liters of water per minute. However, water consumption is often reduced by adding extra oxygen to the water, either by bubbling air into the water in the tub, or by adding pure oxygen to the inlet water before it reaches the tub. When flushing without shock tapping, it is the ongoing water supply to the vessel (which depends on the vessel's biomass) that determines how much water must pass through the flow channel. Adequate water velocity is therefore most easily achieved in vessels above a certain size; that is, vessels that contain a sufficiently large biomass. In vessels that do not meet this requirement, or where the water supply has been reduced by means of extra oxygen addition, effective flushing can be achieved by shock tapping. When sizing breeding vessels, other practical conditions are also taken into account, such as how the animals are to be smoked. Preliminary calculations suggest that a vat of sea urchins 1.2 meters wide and 0.5 meters deep, and supplied with 130 liters of water per minute, must be at least 10 meters long to achieve effective flushing without shock tapping. The flow channel cannot then have a larger cross-section than about 30 cm, that is to say have a diameter of about 60 millimeters if it is tubular.

Execution example 2

The second design example is identical to design example 1, except that the movable body 15 is in the form of a concentric tube inside the tubular extension that forms the chute 16. This is schematically illustrated in Figures 3a and 3b, which show the breeding facility in normal operating position and flushing phase, respectively . In this embodiment, the movable body 15 will form a flow channel 17 when it is filled with air and has risen and closes the entire slit opening in the tubular chute 16 with the exception of the area that forms the opening 18, see Figure 3b. During normal operation, the movable body will be filled with water and lie at the bottom of the chute 16, see Figure 3a.

The conditions regarding cleaning are roughly the same as those described in embodiment 1, except that the pipe, when placed in the flow channel, will help to reduce the effective cross-sectional area in the flow channel, thereby contributing to more efficient flushing.

Implementation example 3

The third design example is a connection of two or more farming vessels as mentioned in design examples 1 and 2, where two or more vessels are arranged next to each other in parallel and are connected by removing the vertical side wall above the V-shape on facing walls towards a neighboring tank and connect the tanks so that the V-bottoms form a repeated V-shape and where the bottoms 12 are connected together to form a large bottom that covers the entire bottom surface of the combined plant.

This connection principle is schematically illustrated in Figure 4, where Figure 4a shows three connected vessels of the type discussed in design example 2 and Figure 4b shows three connected vessels of the type discussed in design example 3.

Claims (7)

1. Method of forming a bottom flow in pools with a liquid outlet, where the bottom flow can clean the bottom of sediments/sunk particles and transfer it to the pool outlet, characterized in that the bottom flow is achieved by using a movable body which, when placed in a given position above the bottom of the pool, forms a flow channel which at one end is in communication with the outlet of the pool and at the other end is open to the bulk volume of the pool, and - that the method comprises a collection step where the movable body is held in a position that allows particles/sediments to sink down and settle on a collection area at the bottom of the pool, and a flushing step where the movable body is held in a second position above the collection area which results in a bottom flow is formed over the collection area which drags the sediments/submerged particles into the drain, and where the collection step and the flushing step are repeated cyclically as long as there is a need to remove particulate waste from the breeding facility. 2. Procedure according to claim 1, characterized by an elongated movable body is used which achieves cleaning of the entire pool bottom by successively placing the movable element in adjacent positions along the bottom of the pool in order to achieve a flow channel which altogether covers the entire pool bottom. 3. Pool, comprising a vessel with a bottom and walls, a liquid outlet in the bottom section and a liquid inlet, where the bottom is designed so that at least one collection area is formed for submerged particulate waste/sediments, characterized in that - a movable body is arranged which is designed so that together with the bottom it can form a flow channel which at one end is in communication with the pool's outlet and the other end is open to the pool's bulk volume, and where the movable element can is moved between a first position which allows the sediments/submerged particles to sink down and settle on the collection area and a second position where the element together with the bottom forms the flow channel. 4. Breeding facility, comprising - a vessel 1 with bottom and walls, - a water outlet 3 in the lower part of the vessel, - a water inlet for the supply of fresh oxygen-rich water, characterized in that the bottom is designed so that a collection area 6 is formed for submerged particulate waste on the bottom of the breeding facility, - that during normal operation of the breeding facility 1, a movable body 5 is arranged in a first position which allows the particulate waste to have the opportunity to to sink down and lie down on the collection area 6, - that the movable body 5 can be moved to a second position where a flow channel 7 is formed over the collection area 6 which is in contact with the rearing vessel outlet 3 at one end and is open at the other end 8 towards the bulk volume of the rearing vessel 1. 5. Breeding facilities in accordance with requirement 4, characterized in that the breeding facility further comprises a first perforated bottom 2 lying mainly horizontally above the lower bottom of the vessel 1 and the movable body 5. 6. Breeding facilities in accordance with requirement 4, characterized in that - the rearing vessel is given a rectangular shape where the bottom of the vessel 1 is given an essentially V-shape so that the collection area 6 is formed along the intersection axis of the two mutually angled plates that make up the bottom, - that the outlet 3 is located at one end of the vessel down at the intersecting axis of the two angled plates that make up the bottom, - the movable body 5 is an elongated body that extends from one short side where the outlet 3 is located and almost to the opposite short wall, and - that when the movable body is in in the second position, a flow channel 7 is formed upwards limited by the movable body 5 and downwards limited by the collection area 6. 7. Breeding facilities in accordance with requirements 4-6, characterized by one or more vessels as defined in claims 4 - 6 are laterally bubbled together in that the V-shaped bottoms of neighboring vessels are welded side to side, that the vertical wall above the V-bottom is removed in places where the V-bottom is welded to the neighboring vessel, and where the perforated bottom 12 is welded together to form a solid bottom for the overall plant.