NO20100465A1 - Use of tanker and bulk vessels for conversion to fish and shellfish farms - Google Patents

Abstract

Tankers and bulk carriers have tanks that can be converted into fish and shellfish breeding facilities. With such a closed facility, a well-controlled aquaculture environment / facility is obtained physically separated from the sea, where disadvantages related to escape, salmon lice, disease will no longer pose a problem.

Description

Field of the invention.

The invention concerns the use of tankers and bulk carriers for conversion into fish and shellfish farming facilities.

Background for the invention

There has been a lot of focus on the negative environmental consequences of today's modern aquaculture facilities (cages). In particular, this has been linked to problems with escape, salmon lice, disease and algae blooms.

Despite a strong focus on the problem and a strict set of regulations, there are still quantities of fish escaping from the facilities. The escape not only causes large financial losses to farmers, but also poses a major environmental problem. In the extreme, fish can mix with wild fish and destroy its genetic diversity.

In addition, escaped fish can be infected with different types of parasites and diseases which can in this way be transferred and spread to wild fish stocks in the area.

When it comes to salmon lice, this is a crustacean parasite that lives naturally in the sea, but can flourish in aquaculture where there are large numbers of fish, and harm the fish. Large amounts of insecticides are therefore used today (which, among other things, attack and inhibit enzymes involved in chitin production and thereby inhibit the development of the shell as well as other chitin-containing organs, for example the reproductive organs and grasping organs of the salmon louse) and other medicines to keep the parasite part down. The problem is that the parasites will eventually be able to develop resistance to these agents, and may eventually make it impossible to farm in cages. The wild fish that live around the facilities will be de-fleshed to a small extent and as a result could be weakened, and thus die from the damage they suffer.

In addition, escaped and lice-infected fish could spread resistant salmon lice to other fish and thereby further destroy the wild fish population.

An ecological alternative that has been tried and tested is to use wrasse such as rock gilt which eats lice and can keep the parasite population down in a natural way. However, there are still a number of problems linked to the use of wrasse, such as the fact that they escape from the cages and that they are difficult to obtain. Algal blooms in the sea as a result of the accumulation of nutrients from feeding etc. is also a problem that can have negative consequences for the farming industry. Large concentrations of algae can give the water an unwanted colour, smell and taste, and some types of algae can even develop toxins that can be harmful to animals and people. In addition, blooms of large amounts of algae can make water oxygen-free, which can be a problem, among other things, in aquaculture facilities for freshwater fish.

Consequently, there is a need for breeding facilities for fish and also other aquatic organisms (shellfish (crabs, lobsters), shells (mussels, scallops, oysters, etc.), etc.) which reduce or completely avoid the above-mentioned problems with infection, escape, pollution, etc. Farming in closed systems can achieve this, but the construction of such closed facilities represents greater costs and investments that the farming industry or smaller farming facilities can hardly bear. The need for closed breeding facilities will therefore be able to be satisfied if it is possible to find reuse of other devices that can be converted into breeding facilities for aquatic organisms.

Prior art.

It is previously known to use well boats as a temporary storage place for fish to be transferred alive from one dam to another or from breeding facilities to land-based fish processing companies. The water is circulated in such well boats with the help of the vessel's speed through the water by intake of water in the bow of the boat where water is pressed into valves and sucked out at the stern of the boat when the boat is in motion Salmon and trout can also be transported in a so-called "closed system" where fresh water is not supplied to the wells and where the well is closed and where the water is recycled using a pump system where oxygen is added to the water. In case of closed transport, it is important that the carbon dioxide that is formed is vented out. According to prior art, this is achieved in a separate system where the water is pumped up into an "air box" where the water is whipped up and carbon dioxide is released.

According to prior art, well boats are also used to transport fish in bulk. Part of the coastal fishing fleet collects the fish they catch in nets or rods because they do not have the capacity to transport the fish themselves. If necessary, a well boat is hired to transport the fish to packaging/further processing. Here, the fish is cooled during transport by the boat's RSW system. The catch can also be mixed with ice, but this is less common and the method is preferably used in summer when the temperature is high.

In contrast to the present invention, such well boats are only used for temporary transport and storage of fish, and are not intended for long-term/permanent farming of fish.

General description of the invention.

According to the present invention, it has been found that the use of decommissioned bulk/tankers or similar ships which for other reasons are no longer in operation, will be able to satisfy the above-mentioned need. By using the internal tanks that such ships have, these tanks will be able to be used as closed fish farming tanks and where filling and emptying devices for liquid in the tanks already exist, as these devices can easily be converted into purification devices and water circulation devices for the closed breeding facilities into which the tanks can be converted.

A sketch of a section of a tank or bulk ship seen from the side with internal tanks 1,2,3,4 is shown in figure 1, and a corresponding sketch, but seen from above, is shown in figure 2.

Figure 3 shows a principle sketch of an embodiment of a composition/construction of tanks, purification plant, separation plant and waste management for a converted tank or bulk ship for the cultivation of aquatic organisms according to the invention.

A modified tanker or bulk carrier as shown in Error! Could not find the reference source.Figure 1 and Error! Couldn't find the reference source. According to the invention, Figure 2 will prevent many or all of the problems that are currently linked to today's open cages in aquaculture as outlined above. The present invention achieves a well-controlled farming environment/facility physically separated from the sea. This means that you can safely and effectively clean and control the tank's contents and its emissions, so that you do not expose nature to irreversible environmental damage. Likewise, the problem of farmed fish escaping will also be completely removed. It is also a big environmental benefit that you can reuse tankers and bulk carriers in this way.

The tanks in such tankers and bulk carriers which are suitable for conversion according to the present invention need few modifications to be suitable as breeding tanks for fish and other aquatic organisms. Some of the conversion needs for such ships are mentioned below.

The tankers and bulk carriers must be rebuilt so that:

• Fish and shellfish have good opportunities for movement and other natural behaviour, and possibly have suitable substrate for support and hiding, • sharp edges and projections are removed and the choice of material must not be harmful to fish and shellfish, • there is minimal risk of injury and unnecessary stress on fish and shellfish during release and capture and it must be easy to inspect the fish, • it is possible to give the fish good care and good treatment, including effective medical treatment for all individuals,

• it is arranged for good cleaning,

• construction and maintenance of installations and production units protect fish and shellfish as best as possible against attacks from predators, • it has alarm systems that warn in the event of a power failure and systems that ensure oxygen supply, • inlet and drainage systems in the aquaculture facility are designed and maintained in a way that ensures sufficient water flow, • the aquaculture facility must have a backup system which, in case of failure, can ensure the fish's basic physiological needs with regard to oxygen and metabolites, • Systematic measurements of the water quality parameters 02, pH, salinity and temperature can be carried out.

In order to achieve the above-mentioned objectives, the tanks in such bulk and tankers as proposed can, in one embodiment, be equipped with internal removable structures such as nets or ropes which can hang down from the upper side of the tanks in question. This can, for example, be done by equipping the tanks with rotatable rods on which lengths of rope or twine material are coiled. Since fish in many environments thrive on having structures where they can hide, such structures as proposed above can form an environment where the fish have a more natural way of life than in open cages according to prior art. Since the fish stay in the enclosures until they are ready for slaughter (up to several years), such structures as mentioned above can form a substrate for organisms and plants (seaweed, kelp, sea grass, reeds, shells, etc.) that will form natural ecosystems with the the organisms that are reared in the tank in question. Since the purpose of the tanks in question is ultimately to catch the fish in order to process them into human food or animal feed or to obtain components of the fish (fish oil, cod liver oil, proteins (enzymes etc.), fish meal, etc.) or to breed for eg genetically modified fish that produce medically active compounds, it is preferred that the relevant structures can be removed for easier access to the fish in a capture situation. For this reason, it is preferred to be able to hoist up the relevant structures, for example by rotating the rods from which they hang in order to coil the entire structures onto the rods and thereby free access to the fish.

In an alternative embodiment, such closed breeding facilities can facilitate combination cultivation of relevant organisms. For example, it is proposed to grow fish (which will swim around the relevant structures) together with mussels (which will attach to the structures). In such a system, the mussels will be able to act as a "purification plant" in that the mussels can reduce, for example, algae production at the same time that the mussels themselves can be harvested and used for the purposes mentioned above. Alternatively, it may be relevant to grow mussels symbiotically with the fish, where the mussels are present in nets that can be lowered into the rearing tanks. The quantity of shells and the size of such nets (or other structures) will be up to the professional to decide, but one of the considerations that should be considered is the reduction of the farming volume for fish when placing other internal structures in the breeding tank such as nets/bags with mussels or other growth structures for aquatic organisms. Examples of shellfish/fish farming combinations can be salmon/trout and mussels, salmon/trout and scallops, cod/halibut with mussels and cod/halibut with scallops. Other combinations may also be possible with all combinations of corresponding freshwater organisms (carp/freshwater mussel, catfish/freshwater mussel, etc). It may also be possible to farm different fish types and/or shell types and/or seaweed/kelp/seagrass types in one and the same tank, but it is preferred to grow/raise cultures of the same organism (monocultures). Farming will preferably be carried out by monocultures of salmon, trout, cod, halibut.

The actual technical arrangement/change of the tanks in bulk and tankers into breeding cages will to a large extent resemble the arrangement of saltwater aquariums (or freshwater aquariums to the extent that it is relevant to breed freshwater organisms such as carp or catfish). Thus, the tanks in the relevant tankers can be equipped with filters (internal or external) which filter and recycle the water in the tanks after it has been cleaned. Equipment for breeding in saltwater and freshwater aquariums is known to the specialist.

Preferably, the bulk and tankers according to the present invention will be converted into closed farming systems without discharge of water to the surroundings. The fish's survival, growth and welfare are largely determined, among other things, by the water quality it is offered and how the water quality varies over time. Control and adaptation of optimal growth and well-being conditions can best be controlled in closed systems. Among other things, it is better to administer drugs to the fish in closed systems and the intake of harmful organisms (algae and/or bacteria) from the environment when farming in closed systems will also be avoided.

Within fish farming in closed systems, it will be necessary to carry out cleaning and recycling of the water continuously. In order to ensure favorable living conditions for the fish and the other aquatic organisms, it is preferred to place a filter (internal or external) in connection with cleaning the water, where the filtering capacity of such a filter is at least filtering 10% of the tank volume per day. Thus, for a closed installation system, for example, a filtration/purification plant for a tank volume of 300,000 m3 (see example 1) should be able to filter at least 30,000 m<3>water per day/24 hours, i.e. 1,250 m<3>water/hour .

If it turns out that it is impossible to improve growing conditions or get rid of diseases in such closed systems as explained above, it may be possible to replace all or part of the water with fresh water (seawater or freshwater), but this is considered more of a emergency solution than a normal improvement measure. Alternatively, it may of course be possible to replace water continuously from the external environment, but this is considered more of an emergency solution if, for example, the purification plant in connection with the upstream right tank has to be closed for one reason or another (purification, defective parts, other mechanical downtime , etc). Farming can of course also be carried out with continuous supply and discharge of water from and to the surroundings, although this is not preferred.

Tankers and bulk carriers are particularly well suited to being converted into a fish farm. The main reason for this is the large tanks (1,2,3 and 4) which can easily be adapted to the purpose of the invention. In addition, the ships have loading, unloading and ballast systems that can be modified and used to ensure a fresh supply of oxygen-rich water to the tanks. The modification of such systems can be carried out by professionals with knowledge of fish farming in saltwater and freshwater aquariums. Most ships also have cleaning systems such as mobile high-pressure flushing systems where the waste water can be sucked up into special waste tanks where it is then cleaned and reused. The waste can then be transported away and deposited in a safe and environmentally friendly way. An alternative to utilizing such waste could be to dry it and use it as fertilizer in agriculture.

When it comes to scooping up bottom waste, in one embodiment it is intended to design the bottom of the rearing tank as a funnel where a suction can be added to the bottom of such a funnel so that bottom water and waste can be transferred into a separation tank (for example a filter or a decanting system). Absorption and purification as well as the reintroduction of purified water will preferably be done under control of the water quality in the breeding tanks (including control of hardness, salinity, pH, phosphate, ammonia, nitrite, nitrate, temperature, algae and bacteria content, content of dissolved waste substances, etc).

In addition to the devices for changing/purifying water and cleaning the tanks, devices for feeding and medication must be provided. A hatchery, laboratory, cold room, hatchery, etc. may be appropriate to implement on such a ship.

In one embodiment, it is intended that the rearing tanks are provided without a lid so that sunlight can escape to these tanks. This i.a. to ensure a natural light/dark rhythm in the breeding pens. Alternatively, it may also be possible to supply light artificially (for example via lamps), but this will represent a greater energy consumption and will therefore normally be more expensive than farming without covering the tanks.

It may also be appropriate to strip the ships of all equipment so that the ship's total volume is utilized for breeding tanks. Then the necessary equipment that takes care of cleaning/replacing water, feeding, medication, cleaning etc. can be placed on land. However, such converted ships with a land-based cleaning system will be stationary. If converted tankers or bulk carriers according to the invention include pumping, cleaning and water recycling systems that are located on board the vessel, such ships can be mobile. To some extent, this can represent an advantage as such ships can then be moved to areas where there is a need for them (for example, if there is a need in other farming facilities for renovation or disinfection, such as in the event of an uncontrollable attack of salmon lice or other disease, where it is desired to process the fish closed or where such converted bulk or tankers can be leased to breeders who need to expand the breeding capacity, but where, for example, too little space prevents expansion of the breeding facility in question).

A possible construction of a rebuilt tank, pipe, cleaning and control system for a tanker or bulk carrier is shown in figure 3. In this figure, the rearing tanks are shown with reference numbers 1-4 (as in figure 1-2). The rearing tank(s) 1-4 are, via water-releasing pipes/hoses 5,6 which run from the tanks 1-4, in connection with a separation tank 7 for rough separation of waste from the rearing tank(s) 1-4. Such coarse separation can, for example, be carried out with a coarse filter. The material of such a coarse filter is known to the person skilled in the art. The water output from the rearing tank(s) 1-4 can be controlled using, for example, pumps 8,9. The waste from the coarse separation tank 7 can be separated continuously or intermittently and can go to, for example, a waste landfill for destruction or further use (for example as fertiliser). The coarse-cleaned water from the separation tank 7 can further be pumped using pipes or hoses 10 and a pump 9 and to a filter 11 for fine particles. At the downstream end of this fine filter 11, there may be an area where the purified water is alternatively led past a passage where microorganisms in the form of algae and bacteria are killed using UV light or other radiation (for example microwave radiation). The cleaned and disinfected water is carried on via pipes or hoses back to the rearing tank(s) 1-4.

The above-mentioned composition of breeding tanks 1-4, separation tanks 7 and disinfection tanks 11 constitutes a recycling and cleaning system for the water in the breeding tanks. In Figure 3, this system has been given the reference number I.

For emptying and filling the breeding tank(s) 1-4, the ship's ballast tank(s) 13 can be used, for example. Such ballast tank(s) 13 can be used as a reservoir for fresh water for farming fish and for regulating the water level in the rearing tanks) 1-4. Water supply to the ball feed tank(s) 13 can take place both from the coarse purification plant 7 via a pipe or hose line 14 whose water flow can be controlled by pump(s) 8 from the rearing tank(s), as well as from the coarse separation tank(s) 7 via a pump 15 which can carry water from this/these coarse separation tank(s). In addition, the ballast tank(s) 13 can be supplied with water from outside. Water from such an external water source will preferably be passed through a filter and a disinfection device 14 similar to that explained for the fine cleaning system 11.

The rearing tank(s) 1-4 and the ballast tank(s) 13 (and thereby also the coarse and fine separation devices 7,11) can be emptied of water via water outlet 15 from the ballast tank(s) 13. Water supply from the ballast tank(s) 13 to the breeding tank(s) 1-4 can be done via a pipe or hose line 16 and a pump 17.

The composition of rearing tank(s) 1-4, ballast tank(s) 13 as well as supply and discharge pipes 15,16 has been given the reference number II and this can constitute a system for regulating the water level in rearing tank(s) 1-4. System II can, in addition to being used for checking the water level as well as for filling and emptying the breeding tank(s) 1-4, be used as a safety system (emergency solution) in the event of any problems with system I, for example for emptying the entire breeding facility of water (then possibly after having previously transferred the fish in breeding tanks 1-4 to another facility or after slaughtering them).

Control of the operational parameters as mentioned above (water level, water quality, temperature, pH, salinity, etc.) can be carried out from a control room using probes placed in the individual parts of the farming facility, shown in Figure 3 by dashed lines running out from the control room 18.

When converting tankers or bulk carriers to aquaculture facilities, it may be necessary to replace and/or protect the interior of existing tanks, pipe systems, pumps and other equipment that comes into contact with water, especially seawater. If such structures as mentioned above are made of water-corrosive material (which may be the case if the ship in question was not initially intended for internal water loading), it may be relevant to either replace all or parts of such corrosive equipment with water-resistant ones equipment, or tanks and internal surfaces can be coated with a protective coating (plastic layer, water-resistant paint or similar). For example, it may also be relevant to replace old pipes with plastic hoses or the like. It may also be relevant to convert all or only some of the tanks in tankers or bulk carriers into breeding tanks.

It may also be relevant in one embodiment to equip the bulk/tanker which has

breeding tanks with pumping devices that can pump the fish over to fish processing plants (for example, filtration plants). Such pumping devices can alternatively be equipped with cooling systems to stun the fish before it is transported to slaughter. Cooling fish before slaughtering does not impair the fish's meat quality and taste since the fish then experiences as little stress as possible before slaughtering.

Fishing tanks in converted bulk or tankers can also be equipped with lining devices similar to those used in aquariums.

In order to possibly remove carbon dioxide from the water in the breeding tanks, devices similar to those known from well boats used for temporary transport of fish can be used

Examples

Example 1.

To illustrate the invention's potential, we can start from a VLCC (Very Large Cargo Container?) with a tank volume of 300,000 m<3>, a fish density of approx. 10-25 kg/m<3> and a farming period of 2.5 years for to reach a slaughter weight of 5 kg. Based on these figures, minimum salmon production over a 2.5 year period will be between 600,000 and 1.5 million farmed salmon.

Claims (10)

1. Use of tankers and bulk carriers for rebuilding the tanks and possibly pipe and pump systems in such ships for fish and shellfish farming. 2. Application according to claim 1, where the entire volume of the tanks has been converted into breeding tanks. 3. Application according to claims 1-2, where sharp edges and projections in the tanks have been removed. 4. Application according to claims 1-3, where the farming of fish and shellfish consists of simultaneous farming of fish and shellfish in the same tank. 5. Application according to claim 4, where the farming comprises the farming of saltwater fish together with the farming of mussels. 6. Use according to any of the preceding claims, where the farmed fish is selected from among salmon, trout, cod and halibut. 7. Farming facility for breeding aquatic organisms, characterized by the fact that the breeding facility includes at least one converted tank or bulk ship where the tanks (1,2,3,4) as well as any pumps and pipelines are adapted to rearing such water-conducting organisms. 8. Breeding facilities according to claim 7, characterized by the fact that the pumps and the plant are adapted as a closed farming system including a filter for purifying the water. 9. Breeding facility according to claim 8 or 9, characterized in that the filter is adapted to clean at least 10% of the water in the tanks (1,2,3,4) per day. 10. Breeding facilities according to any of claims 7-9, characterized in that it includes structures for the cultivation of shellfish.