WO2021115533A1

WO2021115533A1 - Land-based method and apparatus for population of a carrier body with larvae of sessile aquatic animals

Info

Publication number: WO2021115533A1
Application number: PCT/DE2020/101036
Authority: WO
Inventors: Bérenger COLSOUL; Bernadette POGODA
Original assignee: Alfred-Wegener-Institut, Helmholtz-Zentrum für Polar- und Meeresforschung
Priority date: 2019-12-13
Filing date: 2020-12-08
Publication date: 2021-06-17
Also published as: DE102019134230B4; EP4072283A1; DE102019134230A1

Abstract

Known methods and apparatuses operate in a circulation system and repackage the population of carrier bodies before launch into open water. In the invention, a relatively large carrier body (03) is introduced into a container (02) of appropriately matching size, and water (05) in which vital larvae (04) are present is washed around said carrier body (03) in a flow system, with a screen (27) preventing the larvae (04) from being washed out. During the pediveliger phase, optimal ambient conditions are thus achieved which lead to maximum population of the carrier body (03) with larvae (04), in which these have already firmly settled and can no longer be so easily washed away by natural environmental influences. Upon completion of the pediveliger phase, the container (02) is decoupled from its supply and sealed with a lid (33) in a water-tight manner. The carrier body (03) is transported to the site of its launch in the container (02) in the water (05) surrounding it together with remaining free larvae (04). It is lowered there into the open sea and then serves for artificial formation of reef. In the case of population with oyster larvae, it is thus possible to create artificial oyster beds having a very high oyster density.

Description

description

Land-based method and device for populating a carrier body with larvae of sessile aquatic animals

description

The invention relates to a land-based method for populating a carrier body with larvae of sessile aquatic animals and to a land-based device for carrying out the method, comprising a container, a filling of the container with water and free-swimming larvae, at least one three-dimensional carrier body as a preferred habitat for the Larvae and a temporary arrangement of the carrier body in the container.

As a key species with a special ecological function, the European oyster played an important role in the North Sea's ecosystem. But wild stocks of this native oyster species, Ostrea edulis, are now rare and the few that exist are endangered. In the German North Sea - historically widespread here - the European oyster has been considered extinct since the middle of the 20th century, individual living specimens are rarely found, and so it is on the Red List of Threatened Species. Independent resettlement is apparently currently being prevented by intensive bottom trawling, among other things. The European oyster grows slowly and forms specific, very species-rich communities with many other invertebrate animals and fish, in which there are also numerous other Red List species Occurrence. The oyster bank habitat offers food, shelter and retreat and is a nursery for many fish species. Oyster reefs are biodiversity hotspots. Such biogenic reefs, i.e. reefs built up by living beings, have become very rare in the North Sea. A single oyster can filter up to 240 liters of seawater per day. It feeds on plankton organisms in the water such as single-cell algae and organic suspended particles. Due to their high filtration performance, oysters also improve the water quality and can thus also contribute locally to a reduction in toxic algal blooms. At the initiative of the Federal Agency for Nature Conservation and the Alfred Wegener Institute, Helmholtz Center for Polar and Marine Research, the Native Oyster Restoration Alliance (NORA) was launched at the end of 2017. This is a European network for the resettlement and reintroduction of the meanwhile very rare and endangered native European oyster. Nature conservation authorities, science, nature conservation associations and oyster farmers are jointly represented in the network. Long-term goal of the alliance: The native European oyster is to be re-established as a former key species in the North Sea and bordering the European seas and species-rich reef structures are to be restored as extensively as possible.

For restoration, the larvae have so far been collected in situ on substrates, which is only possible in regions with sufficient larvae concentration. A translocation between different regions and water bodies should be avoided for reasons of "biological security". So other solutions had to be found. In this context, the present invention was created, which is based on the knowledge that artificial reef structures that are already pre-populated with oyster larvae form a good starting point for restoration. State of the art

The prior art closest to the invention is disclosed in US Pat. No. 3,701,338. A land-based method and a land-based device for pre-populating mussel shells with oyster larvae are described. In a basin-like container filled with standing water as an artificial water environment, a large number of free-swimming larvae of the later in the adult stage stationary (sessile) oysters are kept. Above the container there is a storage container for a large number of three-dimensional carrier bodies in the form of broken oyster shells. In the container there is an upward sloping conveyor belt, which runs approximately halfway in the water and then runs out of the water. In the process, the inner shells are scattered from the storage container in the starting area of the conveyor belt. The oyster shells are then transported by the conveyor belt in the water and remain there temporarily. During this time interval, the free-swimming oyster larvae settle on the mussel shells as their preferred habitat, although it is not ensured that the largest possible number of larvae will settle in a largely homogeneous distribution over the entire surface of the mussel. Finally, the pre-filled oyster shells are transported out of the water and poured into mesh bags by the conveyor belt. These are first stored in a second container in salt water and later brought to the places for mussel breeding (mussel banks). However, there is a risk that the larvae will fall off again or even die.

From US 3495573 A a method for generating individual mussel lar ven is known, which is based on the knowledge that these settle on a substrate only after a certain period of time (12 to 48 hours) that their removal would injure them. Therefore, the mussel larvae are placed on a net-covered frame and then physically removed again before the specified time period has expired. The mussel larvae that have not yet settled are put back on the net at a later point in time given. The mussel larvae that have already attached themselves in a first phase (before permanent fixation) are removed with a hard jet of water or a squeegee and placed on another net with a smaller mesh size. By repeating this process several times, the mussel larvae can be sorted according to their size and released individually (without substrate). From US 3196833 A it is known for a method for producing clam spar bound to mussel shells in an artificial union to arrange a mesh screen on the bottom of a water-filled container so that the larvae filled in from above are slowed down when they fall through the water and not when Hitting the mesh screen may be damaged. From US 3526209 A it is known for a method and an arrangement for producing free mussel spar to place curved thin lead sheets with a smooth surface on the container bottom, which are often used by the mussel larvae for attachment. Once the mussel larvae have reached the size suitable for passing on, they can simply be stripped from the smooth metal sheets. From US 4226210 A an aquaculture for snail breeding (abalone) is known, in which the snail larvae can attach to sieves that are vertically suspended in a frame in the water. The removable sieves are exposed to intense light in the water.

The formation of a water-based oyster reef with mesh bags with pre-occupied oyster shells is known from US Pat. No. 5,269,254, for example. From US 9144228 B1 it is known to first apply scaffolds or rings as a habitat for Mu shell larvae at a natural location in the water where there is a high incidence of free-swimming larvae. After the initial phase, the pre-occupied bodies are then moved to another location in the water in order to contribute to the formation of the reef there. From WO 2018/156031 A1 vertical tubes are known which have carrier tapes pre-populated with larvae and which are then deployed in large formations in the sea. From US 3738318 A three-dimensional carrier body made of concrete are known that the attachment and the growth of oysters serve. From US 4788937 A carrier bodies for oysters made of a plastic are known. From US 2011/0250017 A1 it is known to occupy three-dimensional carrier bodies, which are stackable in a modular manner, with capsules with pre-grown seaweed in order to build artificial reefs as a habitat for aquatic animals.

Task

Starting from the generic land-based method and the device for populating a carrier body with larvae of sessile aquatic animals according to the closest prior art described above, the object for the present invention is to be seen in the known method and the therefore known device while maintaining the land-based so that an optimal pre-population of the carrier body with larvae of the best vitality and with a high population density can be achieved. Furthermore, it should advantageously be ensured in the method that the carrier bodies which are pre-loaded with larvae can be safely transported to a natural place where they are deployed. The solution to this task is to be found in the process claim and the ancillary device claim. Before partial modifications of the invention are shown in the respective subclaims and described in more detail below together with the invention, the claimed device will first be explained in more detail, since essential structural elements can be used in the claimed method.

Since the claimed device can be used particularly advantageously in the claimed method, the configuration of the device claimed with the invention will first be discussed in more detail. In the invention, carrier bodies that are significantly larger than a mussel shell are pre-populated with larvae in the container. The volume of the container is adapted according to the invention to the volume of the carrier body, ie it becomes a A correspondingly large container is provided which can comfortably accommodate the carrier body and ensures that the carrier body is well flushed with larva-enriched water. It is provided that the container in which the carrier body for the stocking is stored has a base area with a diameter that is one fifth, i.e. about 20%, larger than the diameter of the base area of the carrier body set is. At the same time, the height of the container is twice as high as the height of the carrier body. The carrier body therefore takes up approximately only a third of the container height in the container, wherein it is arranged in the lower third of the container. Furthermore, the carrier body is arranged in the middle of the base of the container. Finally, a free space between the carrier body and the base of the container is also seen. Through these dimensions according to the invention and constructive measures, an optimal flushing of the carrier body from all Be th with water and thus with free-swimming larvae is guaranteed.

In order to be able to optimally implement the rinsing of the carrier body with water, usually salt water, an inlet pipe with an inlet opening through which the water flows into the container in the operating mode, and a drain pipe with the device bean claimed with the invention are still available a drain opening through which the water flows out of the container in the operating mode is provided. The invention thus works as a flow system. A flow that is as natural as possible is generated in the tank, and stagnant water is avoided. Furthermore, according to the invention, an exchangeable sieve with a mesh size that can be selected and matched to the size of the larvae is arranged in front of the outlet opening. This prevents the larvae from being washed out of the container with the flowing water. The mesh size is selected as a function of the larvae size and thus the rate at which the stocking progresses. Finally, in the invention, at least one air feed pipe is provided with an air inlet opening through which air flows into the water in the operating mode. For optimal behavior of the larvae during the Pediveliger phase (attachment phase), a sufficient oxygen supply of great importance.

The continuous flow through the container is further improved if, according to a first modification of the invention, it is preferred and advantageously provided that the inlet opening for the water is arranged in the area of the base of the container and the drain opening for the water is arranged in the area of the upper third of the container. The drainage opening then works like an overflow and limits the water level in the container. Furthermore, the ventilation of the water in the container is improved if, according to a next modification of the invention, it is preferred and advantageous that four air supply pipes are arranged, each with one supply air openings, with two supply air openings in the area of the base area of the container and two supply air openings in the area Area of the middle of the container are arranged. Thus, fresh oxygen is introduced into the water both in the lower area of the carrier body and above it. As a result, the larvae show a particularly high affinity for attachment to the carrier body.

In order to avoid the larvae being washed out through the drainage opening, a sieve is placed in front of the opening. It is advantageous and preferred if several screens with different mesh sizes are provided for replacement in the device, at least one first screen with a smallest mesh size in the range of 150 μm and a second screen with a largest mesh size in the range of 300 μm being kept can. At the beginning of the Pediveliger phase, the larvae all have a certain (small) size. The sieve is to be adjusted to this. In the course of the phase, the larvae grow, so that the mesh size can also increase. Small mesh sizes tend to clog the sieve. It is therefore a good idea to always use the largest possible mesh size: the sieve still has to be cleaned more often.

An increase can also occur with regular cleaning of the sieve, but especially with irregular or inadequate cleaning of the sieve of the water level. In order to prevent valuable larvae from being lost, it is preferred and advantageous if an emergency drain is provided above the sieve or an electronic water level alarm is provided. Then remedial action can be taken quickly. The emergency drain is located above the sieve and below the top of the container and comprises a drain pipe and a (small) emergency container. This in turn has a covering sieve in order to be able to select the larvae that may have been flushed out and quickly return them to the container. The water level alarm (pear type) can be used to switch off the water supply pump.

The container should be stable and at the same time as light as possible; in addition, due to its shape, it should ensure good hydrodynamic conditions for the larvae during the pediveliger phase. This achieves a high degree of homogeneity in the fixation of the larvae. According to a next embodiment of the invention, it is therefore preferred and advantageous if the container is cylindrical or cylindro-conical (hollow truncated cone-shaped) and consists of a UV-resistant plastic, for example polypropylene PP. This means that after the Pediveliger phase, the container can also easily be transported together with the pre-occupied carrier body to the site of the planned application and reef formation. This ease of handling is further supported if, according to further modifications of the invention, carrying handles are provided on the container and / or a watertight lid for the container. In particular, the lid ensures that no water can slosh out of the container during transport. In principle, there are no limits to the container size. The ability to transport and the size of the carrier bodies used are the limiting factors here. As a rule, a size in the range of a water barrel will be used.

It can be used in the invention all carriers that are accepted by the larvae used and are suitable for permanent reef formation. Furthermore, they must be of such a size that they are suitable for independent reef formation, i.e. without the accumulation of a large number of carrier bodies. Three-dimensional support bodies made of a porous material and those that serve to create artificial reefs in open water can preferably be used. Such carrier bodies, which can preferably be produced by 3D printing (additive manufacturing), are commercially available on the market. Size dimensions, for example up to a cubic meter of space and beyond, can be used. In particular, terrace-like support bodies with several levels made of a shell-limestone concrete are particularly suitable for pre-stocking with sessile larvae.

Mussels that are sessile in the adult stage particularly like to settle on such a material. It is therefore advantageous and preferred if, in a further modification of the device claimed by the invention, it is provided that the container is filled with free-swimming larvae of mussels, preferably oysters, particularly preferably European oysters.

The device described above can be used particularly advantageously in a land-based method for populating a carrier body with larvae of sessile aquatic animals in an artificial water environment. According to the invention, the land-based method then basically comprises at least the following method steps:

Providing a container and a carrier body, the size of the diameter of the base area of the container being one fifth larger than the diameter of the base area of the carrier body and the height of the container being twice the height of the carrier body,

• Suspending or standing up the carrier body in the container, the carrier body being arranged centrally in relation to the base area of the container and in the lower third in relation to the height of the container and leaving a free space between the base area of the carrier body and the base area of the container, • Flow of water through an inlet opening of an inlet pipe into the container, whereby the water can flow out of the container again through an outlet opening of a drainage pipe,

• Introduction of free-swimming larvae into the container,

• Leaving the carrier in the container during a settlement phase in which the larvae can settle on the carrier,

• Arranging sieves with different mesh sizes in front of the outlet opening of the drain pipe in successive time segments during the settlement phase, whereby sieves with increasing mesh size are used,

• multiple cleaning of each sieve within its insert,

• aerating the water during the larval settlement phase,

• Feeding the larvae during the settlement phase and

• Removal of the carrier body pre-colonized with the larvae after the end of the colonization phase.

The land-based method claimed by the invention aims to optimally pre-populate a three-dimensional substrate, the carrier body, with larvae outside of their natural habitat in an artificially created environment. The land-based precast, i.e. the precast on land, is particularly advantageous because it is much less complicated than a precast in open water. After the pre-stocking, the attached larvae are then exposed to natural locations in the water for reintroduction together with the carrier body. The advantages of such a Vorbe set are in the genetic selectability, the preservation of genetic species diversity, the prevention of the hunt for juvenile animals and in the control of seed density, diseases and pathogens. In addition, there is the commercial advantage of being land-based. The method enables the definition of a fixed temporal starting point for the colonization of the carrier body, so that at this point in time all individuals of the seed are of the same age and thus approximately the same size. This makes monitoring easier and an increased survival of the young animals in the later natural habitat in the water through the previous growth within a controllable environment. Further advantages are the determinability of the point in time at which the larvae start to attach (start of the pediveliger phase), which can be selected independently of the time of year, for example, and the ability to determine when the substrate pre-colonized with the larvae is released into the natural environment, which depends on the time of year, and the applicability of the method in other areas of larval settlement (with appropriate adaptations).

Suspending or standing up the carrier in the container ensures that the water in the container completely rinses it and that no anoxic areas (areas where there is insufficient oxygen) are formed, so that the larvae can settle everywhere (pediveliger phase ). The elevation can take place, for example, by means of wedges, with the carrier body remaining in the lower third of the container. The central arrangement of the carrier body above the base of the container ensures that there is a sufficient amount of water around the carrier body for the free-swimming larvae. The height of the Trägererkör pers is approximately one third of the height of the container. The diameter of the base area is approximately one fifth larger than the diameter of the base area of the support body, compare the explanations regarding the device. Through these constructive measures, it is reliably enough in the invention that the entire support body is washed around with free-swimming larvae from water. These can thus settle homogeneously on the entire upper surface of the carrier body and remain there.

In order to obtain optimal colonization of the carrier body, it is important to use healthy and fully functional larvae. Therefore, in a next embodiment of the invention, it is preferably and advantageously provided that the larvae are checked with regard to mobility, mortality, deformation and density (that is, amount in the spat) before they are introduced into the container. So that the sund, inserted larvae also develop well, it is still given and advantageous if the water, usually artificial, ie self-composed salt water, is filtered, for example by means of a sieve with 1 μm mesh size, and sterilized with UV radiation. It is also advantageous if the water in the container is completely replaced once or twice an hour. This takes place via the continuous flow through the container (flow system). However, more than two replacement processes per hour should not be carried out in order not to remove any lining material too quickly. The bacteria content of the water should be checked regularly. Ideally, it should be equal to or less than 1000 bacteria per ml of water. The ventilation of the device via ventilation pipes must be constant and evenly distributed in order to achieve a good supply of oxygen to the water and good mixing of the water. This mixing optimizes the distribution of the feed, which is regularly supplied, and the homogeneity of the larval fixation.

The land-based method claimed by the invention enables not only the optimal pre-setting of the inserted carrier body, but rather also the protected transport of the pre-populated carrier body to the place of its use. This transport takes place while leaving the water in the container, so that the settled larvae are optimally supplied and, if necessary, larvae that have fallen off can attach themselves again. For this purpose, according to a further modification of the invention, it is preferred and advantageous if the container, which contains the pre-populated carrier body in the water at the end of the settlement phase (and before the carrier body pre-populated with the larvae is removed), decoupled from the inlet pipe and outlet pipe (with also other supply systems that are connected, for example for oxygen and feed, are decoupled), and then sealed with a lid so that it is watertight. The container is therefore taken from the flow system. The transport to a place near which an artificial reef is to be built in open water with the populated carrier body can then take place without any problems. During transport, the water can also be ventilated and filtered.

It was already pointed out at the outset that the native mussels, and with them their reefs, are threatened with extinction and damage. Therefore, attempts are increasingly being made to remedy this situation with artificial reefs. Mussels, in particular, and oysters in particular, are over-harvested and threatened. In order to be able to regenerate the stocks here, it is therefore particularly preferred and advantageous if, in the method claimed by the present invention, free-swimming larvae of mussels (class Bivalvia), preferably of oysters (order Ostreida, family oysters), particularly preferably of European oysters (genus Ostrea edulis), to be introduced into the container. But also all other aquatic animals - besides the tunicates - that are permanently sessile, for example corals, sponges, bog animals or arm pods, are suitable for use in the claimed method in order to pre-populate a suitable carrier with their larvae. Further details on this and on the device described above can be found in the following exemplary embodiment.

Embodiment

The device for populating a carrier body with larvae of sessile What sertieren and the associated method according to the invention and its advantageous modifications are explained below with reference to the schematic, not to scale figure for better understanding. In detail, the

Fig. A schematic cross-sectional view through a first Ausfüh approximate form of the immersion filter, In the Fig. A device 01 is shown with a container 02 for loading a carrier body 03 with larvae 04, in particular mussel larvae.

Water 05 flows through the container 02. In the selected exemplary embodiment, the container 02 has a cylindro-conical shape, i.e. a diameter D1 on its base area 06 is smaller than a diameter D2 on its upper side 07.

A three-dimensional carrier body 03 is temporarily arranged in the container 02. In the embodiment shown, it is a multi-storey tower 08 made of discs and struts. Such carrier bodies 03 can be produced by 3D printing and are commercially available, see for example “3D Printed Reefs”, Alex Goad, URL (accessed on December 3, 2019) https://www.reefdesignlab.com/3d-printed-reefs -1. Such carrier bodies 03 consist of concrete, sandstone or another suitable material and can have a height H2 between 0.50 m and 1.20 m. They can easily be deployed in open sea water using a rope.

The carrier body 03 has an (averaged) diameter D3 on its base surface 09. In contrast, the diameter D1 of the base area 06 of the container 02 is approximately a fifth, that is to say approximately 20%, larger. Due to the (central) positioning of the carrier body 03 in the container 02 (centered on the central axis 10 of the container 02), the base area 06 of the container protrudes circumferentially by approximately 10% of its diameter D1 beyond the base area 09 of the carrier body 03. This results in a sufficient gap 11 between the container wall 12 and the carrier body 03 for good flushing. Furthermore, the container 02 has a height H1, the carrier body 03 a height H2, H1 being twice as large as H2. The container 02 is thus approximately three times as high as the carrier body 03. Finally, below the carrier body 03 there is a free space 13 which is dimensioned so high that good rinsing with water 05 can also be achieved here. The free space 13 is generated in the illustrated Ausführungsbei game by several support blocks 14, which are on the base 06 of the container ters 02 are arranged and on which the carrier body 03 is mounted.

The claimed device 01 operates as a flow system. For a flow of water 05, an inlet pipe 15 with an inlet opening 16 is seen in front. Before flowing into the container 02, the water 05 is filtered and sterilized by means of UV radiation (not shown in the figure). The water 05 can flow out of the container 02 via a drain pipe 17 with a drain opening 18. In the exemplary embodiment shown, the inlet opening 16 is arranged in the area of the base area 06 of the container 02. The drain opening 18, on the other hand, is arranged in the area of the upper third of the height H1 of the container 02. Due to this offset arrangement, a good flow through the container 02 with water 05 or mixing with the larvae 04 is sufficient. Part of the water 05 is constantly being renewed by the flow-through operation. Preferably, all of the water 05 is exchanged once or twice an hour, depending on the proven bacterial status. A higher exchange rate would lead to unnecessary food flushing. Of course, the larvae are fed regularly throughout the entire Pediveliger phase. In order to ensure a good supply of the larvae 04 with oxygen, four air supply pipes 19, 20, 21, 22 each with an air inlet 23, 24, 25, 26 are provided, which extend into the water 05 and supply air 35 . A good air distribution results when the two air inlet openings 23, 24 are arranged in the area of the base area 06 of the container 02 and the two air inlet openings 25, 26 in the area of the middle at the height H1 of the container 02.

In order to prevent the larvae 04 from being flushed out of the drain opening 18 together with the water 05, a sieve 27 is arranged in front of the drain opening 18. This has a mesh size 28 which is adapted to the current size of the larvae 04 and holds them back in the container 02. Since the larvae 04 grow during the Pediveligerphase, several screens 27 with different mesh sizes 28 are kept and exchanged accordingly. For example, a first sieve 27 with a smallest dimension width in the range of 150 μm and a second sieve 27 with a largest mesh size in the range of 300 μm. So that the sieve 27 does not clog, it has to be freed from deposits on a regular basis. If there is a blockage and thus a rise in the water level in the container 02, an emergency drain 29 is provided in the embodiment shown, via which the overflowing water 05 can drain. It is then collected in a collecting container 30. On this there is another sieve 31, from which larvae 04 which have passed through can simply be collected and returned to the container 02. Alternatively, an electronic water level alarm 32 can also be provided, which monitors the current water level and triggers an alarm when a limit value is exceeded. The sieve 27 can then be cleaned accordingly, so that the water level drops again.

In the exemplary embodiment shown, the container 02 has a cylindro-conical shape which supports a good flow. The container 02 is stable and yet light. It consists, for example, of a UV-resistant plastic. The container 02 has two lateral handles 33 for easy transport. So that no water 05 sloshes out of the container 02 during transport, it can be closed in a watertight manner with a cover 34. All supply lines 15, 17, 19, 20, 21, 22 were of course previously removed ent. Existing valves are closed.

Transporting the carrier body 03 pre-populated with larvae 04 directly in the container 02 is particularly gentle on the larvae population. The carrier body 03 can be brought directly to a location in the open water without re-bedding or other outer packaging. There it is then removed from the water-filled container 02 and sunk directly into the seawater, where it is then used to create artificial reefs. This can in particular be an oyster reef if larvae 04 of oysters are used. The selected larvae are examined for mobility, mortality, deformation and density before they are used. List of reference symbols

01 device

02 container

03 carrier body

04 larvae

05 water

06 base area 02

07 top 02

08 tower as 03

09 Base 03

10 central axis 02

11 gap between 03 and 12

12 container wall

13 Free space between 03 and 06

14 support bracket

15 inlet pipe

16 inlet opening

17 drain pipe

18 Drain opening

19 first air supply pipe

20 second air supply pipe 21 third air supply pipe 22 fourth air supply pipe

23 first air inlet

24 second air inlet

25 third air inlet

26 fourth air inlet

27 sieve

28 mesh size

29 Emergency drain

30 collection containers 31 another sieve

32 water level alarm

33 Carrying handle

34 cover

35 air

D1 diameter 06

D2 diameter 07

D3 diameter 03

H1 height 02

H2 height 03

Claims

1.Land-based method for populating a carrier body (03) with larvae (04) from sessile aquatic animals in an artificial water environment with at least the following process steps:

• Provision of a container (02) and a support body (03), the diameter (D1) of the base (06) of the container (02) in a range of one fifth greater than the diameter (D2) of the base (09) of the Carrier body (03) and the height (H1) of the container (02) is in a region twice greater than the height (H2) of the carrier body (03),

• Suspending or standing up the carrier body (03) in the container (02), with the carrier body (03) in the middle based on the base area (06) of the container (02) and in the lower third based on the height (H1) of the container (02 ) is arranged and a free space (13) is left between the base surface (09) of the carrier body (03) and the base surface (06) of the container (02),

• Flow of water (05) through an inlet opening (16) of an inlet pipe (15) into the container (02), the water (05) through an outlet opening (18) of a drain pipe (17) from the container (02) can flow out again,

• Introduction of free-swimming larvae (04) into the container (02),

• leaving the carrier body (03) in the container (02) during a settlement phase in which the larvae (04) can settle on the carrier body (03),

• Arranging sieves (27) with different mesh sizes (28) in front of the drain opening (18) of the drain pipe (17) in successive time segments during the settlement phase, using sieves (27) with increasing mesh sizes (28),

• multiple cleaning of each sieve (27) within its insert,

• Aerating the water (05) during the colonization phase of the larvae (04),

• Feeding the larvae (04) during the settlement phase and

• Remove the carrier body (03) pre-colonized with the larvae (04) after the end of the colonization phase.

2. Land-based method according to claim 1, characterized by

• Check the larvae (4) before they are placed in the container (02) with regard to mobility, mortality, deformation and density.

3. Land-based method according to claim 1 or 2, characterized by

• Filtering and UV sterilization of the water (05) before flowing into the container.

4. Land-based method according to one of claims 1 to 3, characterized by

• Replacing the water (05) in the container once or twice an hour, taking into account the bacteria content in the water (05).

5. Land-based method according to one of the preceding claims, characterized by

• Uncoupling of the container (02) with the carrier body (03) populated with the larvae (04) after the settlement phase has ended and before the carrier body (03) pre-populated with the larvae (04) is removed from at least the inlet pipe (15) and outlet pipe (17) ),

• watertight closing of the container (02) and

• Transport of the closed container (02) to a place in the vicinity of which an artificial reef is to be built in open water with the populated carrier body (02).

6. Land-based method according to one of the preceding claims, characterized by

• Introducing free-swimming larvae (04) of mussels, preferably oysters, particularly preferably European oysters, into the container (02).

7. Land-based device (01) for populating a carrier body (03) with larvae (04) of sessile aquatic animals, having

• a container (02),

• the container (02) is filled with water (05) and the larvae (04) swim free,

• at least one three-dimensional support body (03) as a preferred habitat for the larvae and

• a temporary arrangement of the carrier body (03) in the container (02), characterized by

• a size of the base area (06) of the container (02), the diameter of which (D1) is one fifth larger than the diameter (D2) of the base area (09) of the carrier body (03),

• a height (H1) of the container (02) which is twice the height (H2) of the carrier body (03),

• a central arrangement of the carrier body (03) in the container (02),

• a free space (13) between the base (06) of the container (02) and the carrier body (03),

• an inlet pipe (15) with an inlet opening (16) through which the water (05) flows into the container (02) in operating mode,

• a drain pipe (17) with a drain opening (18) through which the water (05) flows out of the container (02) in the operating mode,

• an exchangeable sieve (27) with a mesh size (28) that can be selected and adapted to the size of the larvae (04),

• an arrangement of the sieve (27) in front of the drain opening (18) and

• at least one air supply pipe (19, 20, 21, 22) with an air supply opening (23, 24, 25, 26) through which air flows into the water (05) in operating mode.

8. Land-based device (01) according to claim 7, characterized by

An arrangement of the at least one inlet opening (23, 24) in the area of the base area (06) of the container (02) and

An arrangement of the at least one drainage opening (25, 26) in the area of the upper third of the height (H1) of the container (02).

9. Land-based device (01) according to claim 7 or 8, characterized by

• four air supply pipes (19, 20, 21, 22) each with an air supply opening (23, 24, 25, 26),

• an arrangement of two air inlet openings (23, 24) in the area of the base (06) of the container (02) and

• an arrangement of two air inlet openings (25, 26) in the area of the middle of the height (H1) of the container (2).

10. Land-based device (01) according to one of the preceding claims, characterized by

• several screens (27) with different mesh sizes (28) to change from in the device (01) and

• At least a first sieve (27) with a smallest mesh size in the range of 150 μm and a second sieve (27) with a largest mesh size in the range of 300 μm.

11. Land-based device (01) according to one of the preceding claims, characterized by

• an emergency drain (29) above the sieve (27) or an electronic water level alarm (32).

12. Land-based device (01) according to one of the preceding claims, characterized by

• a cylindrical or cylindro-conical container (02) made of a UV-resistant plastic.

13. Land-based device (01) according to one of the preceding claims, characterized by

• Carrying handles (33) on the container (02) and / or

• a watertight lid (34) for the container (02).

14. Land-based device (01) according to one of the preceding claims, characterized by

• a single three-dimensional support body (03), which is used to create artificial reefs in open water.

15. Land-based device (01) according to one of the preceding claims, characterized by

• a filling of the container (02) with free-swimming larvae (04) of mussels, preferably oysters, particularly preferably European oysters.