Patent Description:
In many contexts there is a need to keep a large volume separated from the surroundings with the help of an enclosing barrier, where the primary criterion is to prevent physical exchange of material. Secondary criteria can relate to e.g. thermal insulation.

Examples of the above are holding tanks for liquids, bioreactors and enclosed fish farms. In many cases the delimited volume can be very large. Furthermore, in addition to tanks and retaining vessels of various types, large scale facilities that contain or process liquid-borne materials shall generally require physical infrastructure on a correspondingly large scale.

Traditionally, these challenges have been met by creating heavy structures with high inherent strength, employing traditional materials such as masonry, reinforced concrete and high strength steel. Examples of this are large bioreactors, protected by elaborate security constructions.

Considering first state of the art in constructing large land-based structures, a basic strategy has been to add incrementally a large number of building blocks that are linked together and immobilized by mortar or cement. Drawbacks of such "wet" methods are well known: They require skilled labour, they are time consuming and labour intensive and create irreversible structures that cannot be modified or dismantled without demolition. Over time, improvements have included generic strategies for guiding and supporting the building blocks by "dry" means, e.g. by shaping the mutually contacting surfaces of the building blocks with protrusions and cavities that fit into each other, assisting the building process and stabilizing the structure. Further improvements include shaping the building blocks with grooves or channels that communicate from one block to the next when they are assembled, being adapted to receive elements that hold the structure together, e.g. in the form of reinforcing rods that may be stabilized in castable concrete or in the form of metal bars or tie cables that are secured by nuts, clips or other means. Examples of solutions where modular building blocks are adapted to employ techniques referred above include:.

Prior art as exemplified above presents substantial problems when attempting to implement it on large scale marine and water-immersed structures: Whereas land-based structures are static and immutable, large structures in water shall generally be exposed to wave- and tidal-induced forces and motion. This may damage or cause disintegration of stiff and unyielding structures, particularly when acting on large assemblies of building blocks across long distances encountered with large structures. In situ construction in water is generally not practicable with "wet" methods, and typical prior art building materials are generally heavy, making deployment of prefabricated large structures or modules difficult.

Attempting to avoid the problems adhering to using prior art modular components, materials and building techniques to create large sea-borne constructions, proposals have been made for building enclosed fish farms offshore using the same principles as seagoing ships and offshore drilling platforms, i.e. rigid structures in steel able to withstand large waves and ocean swells, extending across tens to hundreds of meters. A considerable number of such solutions have been proposed but have so far proved too expensive for commercial viability. An example of a large scale heavy structure based on offshore technologies is described in International Publication Number <CIT>. The latter structure is budgeted to cost in excess of <NUM> million NOK.

Thus, the solutions according to state of the art carry with them a number of undesirable consequences related to cost of construction, limited design flexibility, limited resilience to mechanical stresses and strains, large carbon footprint, and high cost of ultimate removal and clean-up.

It is thus a main purpose of the present invention to provide a system for establishing of large and scalable physical infrastructure in a marine environment, encompassing buoyant structures disposed above and below water.

It is further a main purpose of the present invention to provide a method for the construction of such infrastructure in a simple and inexpensive manner.

It is further a main purpose of the present invention to provide a system for establishing of partly or completely submerged tanks capable of storing or processing of large volumes of substance at low cost.

It is further a main purpose of the present invention to provide a system for establishing of floating platforms supporting production and other facilities.

It is still further a main purpose of the invention to provide structures that respond elastically when subjected to bending forces.

The present invention achieves the purposes defined above by a synergetic combination of strategies which can be summarized as follows:.

Briefly summarized, the present invention achieves the purposes defined above by a modular structure, a macro structure, and a method for construction of a structure as defined in the claims, where the modular structure and the macro structure comprise structure elements as defined in the claims, and mainly according to the strategies outlined above.

A first aspect of the invention according to claim <NUM> is a modular structure for being at least partly submerged in a body of water, where the modular structure comprises a plurality of structure elements, where each structure element comprises polymers. Each structure element comprises one or more protruding and receiving parts, wherein the protruding parts of a structure element are arranged for mating connection with the receiving parts on another structure element, the direction of mating motion defining a longitudinal direction of the structure element. Further, the modular structure comprises strengthening elements for providing structural integrity to the modular structure, where the strengthening elements are enveloping and/or penetrating at least parts of at least two structure elements of the modular structure. The structure elements are adapted to form longitudinal channels inside the protruding and receiving parts, where the channels communicate across two or more structure elements that are in a mated connection. The structure elements have apertures adapted to form channels through the structure elements in at least one direction transverse to the longitudinal direction. The channels are adapted to guiding elongated strengthening elements. Further, the structure elements and strengthening elements are adapted to provide flexibility to the modular structure while maintaining its structural integrity by at least one of the following i) comprising material with inherent elasticity, and ii) being formed to allow relative movement between at least two structure elements. Further, the modular structure forms at least one closed structure, where a number of structure elements that overlap partially or completely in the longitudinal direction are connected in a network that closes upon itself around a volume.

The structure elements can have linear dimensions not exceeding <NUM>,<NUM>, and each structure element can comprise at least <NUM>% by volume of polymers. The structure elements and strengthening elements can be adapted to provide flexibility to the modular structure while maintaining its structural integrity when the structure is subjected to bending up to <NUM> degrees pr. linear meter.

The closed structure can be a tank structure delineating a volume for the storage or processing of media in fluid form or materials carried in a fluid, where the closed structure can be a cylinder.

A longitudinal dimension of the closed structure can be smaller than the largest dimension in a plane transversal to the longitudinal direction, such that the closed structure forms a circular or polygonal disk or annulus.

The protruding parts and the receiving parts of the structure elements can each be provided with at least one set of two apertures positioned so that the apertures in the protruding part align with the respective apertures in a receiving part in longitudinally attached adjacent structure elements and thus forming transversal channels perpendicular to the longitudinal direction.

The modular structure can comprise strengthening elements of which at least one is inserted in at least one of the longitudinal and the transversal channels.

The strengthening elements comprise at least one of the following: i) an elongated strengthening element, and ii) a surface element for enveloping at least parts of the structure, and said elongated strengthening element can comprise at least one of the following: a strap, a cable, a container, a tube, and a rod, and said surface element can comprise at least one of the following: a foil, a tarp, a flexible plate, and a band. Further, said elongated strengthening element can form a closed loop attaching at least two structure elements and/or modular structures, and can be arranged according to one or more of the following alternatives: i) in the longitudinal channel and ii) along an outside of each of the at least two structure elements.

The strengthening element can comprise a container or a tube adapted to be filled with one ore more of the following materials: sand, gravel, earth and pellets, gas filled bodies, expanded polystyrene and polymeric-based pellets.

The strengthening element can act as a buoyancy controlling device as one of the following: i) a flotation element by the container being filled with a material giving the strengthening element a positive buoyancy, and ii) a ballast element by the container being filled with a material giving the strengthening element a negative buoyancy.

The modular structure can comprise a strengthening element for attaching at least a first and a second structure element wherein the strengthening element is arranged to pass through a hole in each of the adjacent structure elements.

Further, the strengthening element can comprise at least one of the following: pin, bolt, and clasp. The strengthening can be arranged with one or more through holes for introduction of a strengthening element.

The protruding part and the receiving part of the structure elements can be provided with polygonal mating surfaces so that the mating connection is made at predetermined angles between the structure element and an adjacent structure element.

The modular structure can comprise at least one of a top floor and a bottom floor respectively arranged in a transversal plane perpendicular to the longitudinal direction, where the at least one of the top and bottom floors can comprise a number of disks or annuli. The at least one of the top and bottom floors can be in contact with an inside of the closed structure at an end in the longitudinal direction.

A further aspect of the invention according to claim <NUM> is a macro structure comprising at least a first and a second modular structure, wherein the first and second modular structures are attached to each other.

The at least first and second modular structures can contribute to form a perimeter wall of a closed modular structure delineating a macro volume. The perimeter wall can comprise an inner and/or an outer wall sandwiching the closed structures of the perimeter wall.

The at least two of the closed modular structures can be attached by an elongated strengthening element, where the elongated strengthening element is looped through a longitudinal channel or around a part of one of the at least two attached modular structures, and through a longitudinal channel or around a part of another of the at least two attached modular structures.

At least two contiguous closed structures of a macro structure can be coupled by at least one surface element.

An additional aspect of the invention according to claim <NUM> is a method for construction of a modular structure, characterized by the following steps:
assembling of the structure elements, such that at least a first structure element connects by mutual connection and fastening to a second structure element,
in that the first and second structure elements when connected form at least one longitudinal channel.

The method for construction of a modular structure can comprises can further comprise the following steps:.

The assembling step of the method can occur by sequential application of the structure elements, layer by layer.

The invention shall be described with reference to the figures showing several examples of embodiments.

The invention is based upon the building of structures over all size scales based upon assembling and mechanical consolidating of modular elements, discussed as structure elements and strengthening elements.

A significant insight related to the preferred embodiment of the present invention is that it is considerably easier to establish structures for the storage of large volumes of liquid in tanks submerged in water than up in the open air. This is because the internal hydrostatic pressure from the liquid in a submerged tank is balanced by water pressure from the outside. Thereby, the tank's walls and bottom mainly have a limiting function between the liquid inside and outside the tank, which places considerably less demand on the tank's mechanical strength. Furthermore, deliberate use of buoyancy forces in the water reduces the demands for mechanical strength even further. By building the tank's different parts out of materials with approximately neutral buoyancy in water, for example plastic or hollow elements, there will be a greatly reduced need for strengthening elements that can bear the tank's own weight.

The construction of large structures underwater has the potential to be very costly and demanding. In a preferred embodiment of the present invention, this problem is solved by constructing the structures of special building elements that are assembled and locked in a dry zone over the water line in a continuous process where the structure slowly sinks deeper into the water as construction progresses.

The net result has dramatic effects on the volume of the structure that can be constructed within given cost limits. It also opens the way for structures constructed of light, cheap materials based upon recycled plastics. It remains to secure the structures against dynamic forces, for example: waves and underwater currents, which require special methods against stretching and bending stresses, cf.

<FIG> discloses a principle drawing of a tank in water with respect to the current invention, comprising a large number of modular structure elements (<NUM>) that are connected to each other in a contiguous or overlapping relation. Typical dimensions of the individual elements can be chosen in a wide range from sub-cm to several meters, but typically considerably less than the tank's linear dimensions and preferably less than <NUM>. Elements made of polymers are preferred, but a tank can comprise elements of several types of materials and produced via one or more types of forming techniques.

<FIG> shows a section of the tank wall where three elements are connected via topographic structures on each element. The topographic structures, in the form of receiving parts (<NUM>) shown as tubular channels and protruding parts (<NUM>) shown as hollow pipes in <FIG>, fit into each other to form a mated connection with a longitudinal internal channel, the direction of the mating motion being defined as a longitudinal direction of the structure elements.

<FIG> further shows how each element has apertures (<NUM>), (<NUM>), (<NUM>), (<NUM>) in directions transverse to the longitudinal direction. Multiple apertures can be brought into alignment when structure elements are connected together, constituting channels that can accommodate strengthening elements (<NUM>), (<NUM>) that penetrate the structure elements. Thus, the structure elements can be assembled to form internal channels in three dimensions through the tank's walls and possibly bottom and top, cf. (<NUM>), (<NUM>), (<NUM>), (<NUM>), (<NUM>) on the segment in <FIG>. The elements can have channels with different cross sectional shapes and sizes.

The internal channels can contribute to the tank's structural strength by employing them as guides or containment volumes for strengthening elements or materials in the form of cables, pipes, rods, beams, fill or casting material. Sand-filled stockings of strong textiles are relevant in this context.

Interconnection between structure elements via topographic details can occur in several ways. Direct methods include, among others, friction and male/female type click-connections of supporting elements, hooks, bayonet couplings, etc. It can also occur through indirect methods comprising the use of helping components, for example: locking pins, rods, and columns through hole and channels in contiguous or nearby elements. Indirect methods can also comprise supporting elements, as well as clips, clamps, cables, and bands. On the segment in <FIG> the structure elements are locked to each other with massive rods or clips through the channels in three dimensions. Vertical (i.e. longitudinal) pipes and rods (<NUM>) can be locked into position by their holes or channels (<NUM>) that interact with the element's transverse channels by fitted locking bars (<NUM>), (<NUM>). The large number of vertical (i.e. longitudinal) channels in the tank walls can serve many different purposes: in <FIG> there are two neighboring channels filled with hole pipes (<NUM>) that are locked with a transverse locking rod (<NUM>), while this is fitted with a smooth pipe (<NUM>) through the one of the channels in <FIG>. Such pipe can, among other things, be used for the transport of gas or liquid.

By treading lashing bands through the channels and stretching the bands, the tank is given elasticity and improved resistance against external physical effects. The structure maintains tight connections between the individual structure elements over time, even with mechanical wear, matter flow, etc..

Additional structural strength, and possibly other functions, can be achieved with the help of bands that stretch and tighten over the tank's outer surface and/or by enveloping parts of either the whole tank's outer and/or inner surfaces with foil, tarp, or bendable plates that are anchored in the tank's walls and possibly bottom and top. Relevant fastening techniques include, but are not limited to, the following: glue, Velcro bands, buttons, pins, and screws. A preferred fastening method is to use a mechanical fastening system where the structure elements are textured on the surface that forms the tank's outer and/or inner side. The texturing can, for example, be in the form of spikes, columns, pimples, hooks, or pipes, shaped such that it binds with reciprocal texturing on the foil, tarp, or the bendable plate to be fastened. Several layers of foil, tarp, or bendable plates can be laid on top of each other, such that they are textured on both sides and possibly added in several layers and stretching directions.

With big tanks, where the radius of curvature far exceeds the size of the structure elements, the linear structure elements can form segments with linear facets in curved macro-surfaces that form in other ways than by the shape of the individual structure elements. Tensile and bending forces can occur between anchoring points inside or outside the tank's walls, from stiffening and tension elements that follow the channels through the structure in strategic directions or by connecting via elements and struts to anchoring points on other parts of the structure or outside this. Examples of structures that can be stabilized by tensile forces are domes and arches with radial stress and cylinders with tangential and axial stresses.

It will be clear that tank structures based on structure elements and strengthening elements that are assembled and connected according to the present invention may be built and utilized on dry land.

At the same time, it will be obvious that the building of large, floating, and light weight tanks such as discussed in <FIG> on land with subsequent launching entails considerable practical problems. The present invention solves these problems by building tanks in situ, in that they utilize a system based upon modular structure elements that are added incrementally to the structure that is always partly submerged in water. <FIG> shows a principle drawing of a preferred building method according to the present invention. The construction occurs from floating platforms (<NUM>) inside and/or outside the volume of the tank. The tank is built from the bottom (<NUM>) by adding individual elements (<NUM>) or groups of assembled individual elements. In the example shown, the construction is performed by a robot (<NUM>). The tank structure initially has close to neutral buoyancy and may, with moderate action, be brought to float with the construction zone at an appropriate height above the surface of the water. Such action can comprise floating elements coupled to the structures upper part and weight or ballast coupled to the upper part of the structure. The net buoyancy can also be controlled via material that fills the channels in the structure. Thus, sand or cement can be poured directly into the channels to increase weight, or bags may be inserted that are pre-filled with material or are filled after having been fitted into the channels. An alternative is to employ empty beverage bottles that fit inside the channels: Such bottles may be filled with sand or another material to provide ballasting weight, and may be stacked end to end inside the channels. In their empty state and with the cap on they can function as flotation elements, filling the channels in the structure.

The result of this building method is that the work can always be performed in a dry zone that is easily accessible at moderate height above the waterline. As the construction progresses (<FIG>) the structure sinks deeper into the water and the tank can in principle achieve unlimited depth. The locking of neighboring elements with straps, rods, staples, or clips occurs as new elements are mounted upon or against the previous ones. The global structural consolidation of the tank is achieved by a long strengthening element, for example a pipe, being inserted through channels that penetrate the structure in strategic directions. Such strengthening elements can, for example, be fastened in the structure's bottom and be joined stepwise in height as construction progresses.

<FIG> shows a tank that is resting on the seabed and anchored to it by means of vertical columns (<NUM>). Here the vertical through channels from the surface act as guides for the columns. After the tank is built high enough, the columns are driven down into the bottom. The columns can have several functions, for example as solid anchoring and as a support structure for the tank. Hollow columns can be used for the guiding of probes and transport of gas and fluids to and from the area under the tank and under ground.

The tank can be equipped with a floor (ref (<NUM>) on <FIG>) or it can have an open bottom with a free water volume underneath. An alternative is that the tank can rest upon the seabed and be open in the bottom, ref. <FIG>, which gives direct access to the area under the tank. This is relevant in situations where material shall be collected from the benthonic zone for processing within the tank's volume. In such situations and where the floor is uneven, the closing of the area underneath the tank can be formed by a column formed from a dense fence work (<NUM>) from the bottom of the tank's side wall and down into the under ground, cf. To achieve a seal between the columns, the lowest part can have a flexible surface coating that expands when the column comes out of the guide channel into the water under the tank. This will result in that the structure in the example shown in <FIG> is suited to allow digging and processing of the ground under the tank without the water mass outside being polluted. With the removal of mass within the enclosed area, the columns in fence work can be driven further down as the digging progresses to prevent collapsing of the edges.

This construction technique, where a tank without a bottom is built downwards in a water mass until it reaches the seabed, occurs with a minimum amount of disturbance of the relevant water volume. This gives unique possibilities to survey the local environment and investigate plant and animal life at different depths in the water column.

In many situations it is especially important that the tank is sealed, such that there is no material transport between the tank's volume and the surrounding water mass. This can be achieved in many ways:.

It can also be relevant to control the atmosphere in the volume over the fluid surface inside the tank, for example when there are poisonous gasses present in the tank or when the contents must be protected from contamination from outside. When plants and animals are cultivated in the tank, it may be desirable to collect CO<NUM> that is produced. This can be achieved with a number of possible techniques that will be known for one skilled in the art.

The structure elements according to the present invention incorporate the essential enabling features for the assembling of structures where tanks, walls and connecting elements form large scale consolidated complexes with advanced functionalities and unlimited dimensional scalability. This shall now be demonstrated by some preferred embodiments with reference to the structure elements shown in <FIG> , <FIG> and <FIG>,<FIG>.

The structure element in <FIG> is terminated at either end by a flat surface with sharp corners and straight walls. It represents a class of structure elements with a geometry that aligns two structure elements when they are assembled end to end in a wall-like structure. This class of structure elements shall resist being brought out of alignment and shall be preferred when building "hard shell" structures. Such structure elements need to be pre-shaped if they are to form part of a curved structure, and the structure element in <FIG> is slightly curved such that it can form part of a cylindrical wall as shown in <FIG>,c.

The structure elements in <FIG> represent a different class of structure elements where the end surfaces of a structure element are rounded such that the structure element can pivot relative to an over/underlying and/or contiguous structure element when connected via their protruding and receiving parts. This shall allow for incorporation in straight as well as curved structures, cf. <FIG> shows such a structure element with straight sidewalls and two internal channels, while the structure element in <FIG> has three channels and forms a V shape defined by the angle α as shown. The latter type of structure element is particularly suited for incorporation into structures with corners.

<FIG> and <FIG> provide some examples of how the two classes of structure elements can be linked separately or in combination to create macrostructures with special properties and geometries: In <FIG> is shown a top view of a wall with straight parts separated by bends at specific pivot points. In this case, structure elements (<NUM>) of the type shown in <FIG>, but with straight sidewalls constitute the straight parts, while the pivot points incorporate structure elements (<NUM>) of type shown in <FIG> as well as a hybrid variant (<NUM>) where one end is straight and one end is rounded. As shown in <FIG>, the different parts of the wall can articulate in a predefined fashion when subjected to an outer force. As shown in <FIG>, a hinged corner can be created in a wall by means of structure elements of the type (<NUM>), where at the same time the wall adjacent to the hinge retains stiffness against bending forces. This enables the construction of polygons of various shapes. In <FIG> only structure elements of the rounded type are used. <FIG> shows a top view of a freely curving wall, while <FIG> shows several curving walls that branch from each other. <FIG> shows a top view of a helix-shaped wall where the innermost structure elements are connected at near right angles to each other.

<FIG> <FIG>,<FIG>,<FIG> show examples of how the basic structure elements shown in <FIG> can be modified to provide a branching structure element. In <FIG> the structure element defines connections in three directions separated by <NUM>°, and can constitute a coupling node in a hexagonal network as indicated in <FIG>. Analogously, the structure element in <FIG> defines connections in four directions separated by <NUM>°. The protruding ends of the structure elements in <FIG>,<FIG> are rounded and shall allow pivoting of coupled structure elements in a flexible macrostructure. Structure elements similar to that in <FIG>,<FIG> can also be made with sharp corners and straight end walls, in analogy to the structure element shown in <FIG>, leading to "stiff" structures that resist shape change.

A central feature of the present invention is that structure elements can "dry lock" to each other, i.e. they can be reversibly assembled into macroscopic structures with considerable structural integrity without the need to employ glue or cement. This has obvious advantages in many instances (rapid prototyping, test assemblies, etc) and may be followed up by subsequent mechanical consolidating of the macrostructures. In addition to friction coupling between protruding and receiving parts in the structure elements, the elements may have topographic features as exemplified in <FIG> and <FIG> where the structure elements have "keyhole" openings (<NUM>) for accommodating locking pins (cf. below) as well as ridges (<NUM>) and matching holes (<NUM>) to provide a steering and click function during assembly.

Structure elements according to the present invention are preferably made from polymers by means of a thermal shaping technique such as injection molding. Polymers can be given a wide range of mechanical properties by selection of polymer type and loading with reinforcing fibers. A central property in the present context is the degree of dimensional precision and the complexity of structural details that can be achieved. This enables highly controlled friction and displacement tolerance properties between mating and contacting structure elements, which contribute to predictable compliance and resilience of assembled structures when subjected to external forces.

When high mechanical strength is required, structure elements can be locked in the vertical and horizontal directions by various means as described previously. One solution is shown in <FIG> where coupling pins (<NUM>) are inserted through the keyholes in the structure elements and twisted to effect locking. This prevents the structure elements from being pulled out from each other vertically. At the same time, the long pins shown in <FIG> can link one structure of stacked structure elements to another, parallel structure. This is illustrated for the case of cylindrical tanks in <FIG> and <FIG>, where pin keyholes on structure elements in different structures are exactly aligned in a <NUM>° and a <NUM>° geometry, respectively (coupling pins indicated as (<NUM>)). As shall be evident to a person skilled in the art, many variants of locking pins are possible, depending on the materials and geometries in the structure and strengthening elements. In certain cases where channels in the structure elements contain in-filled sheet or textile materials, penetrating bolts or nails with sharp points may be inserted through holes in the structure elements, in analogy to the coupling pins shown in <FIG>, <FIG> and <FIG>.

<FIG>, <FIG>, <FIG> show how a large barrier or wall can be constructed by combining the structure elements in <FIG> and <FIG>: In the figures, cylindrical tanks are locked together between an inner and outer sheet, forming a very large circular enclosure (only a segment is shown here). The structures are kept together by means of strengthening elements not shown in the figures. When coupling pins are used to link separate substructures in a macroscopic curved structure as exemplified in <FIG>, <FIG>, <FIG>, they may be inserted at quasi-random contact points where keyhole alignment occurs opportunistically, the required degree of alignment being reduced by shaping and scaling the keyholes with a tolerance margin. Very strong and resilient constructions can be obtained by employing cables, straps or strips that are weaved through the keyholes instead of coupling pins. This reduces the importance of alignment and makes possible short- as well as long-distance cross-linking between individual elements and macrostructures.

Structures made from structure elements with sharp corners as shown in <FIG> shall provide hard shells that resist flexing, whereas rounded structure elements as shown in <FIG> in addition to allowing integration in curves and corners in constructions shall permit flexing and motion in the horizontal plane. Macrostructures in water can thus be built with a combination of "hard shell" tanks, cylinders and walls that are connected or enclosed by flexing walls or other structures, all of which are kept together, by one or more of the following:.

Together, these features shall enable such macrostructures to absorb and tolerate ocean currents and wave motion while maintaining the structural integrity of critical substructures.

In-filled bags, tubes and containers in the vertical channels may serve multiple functions where they in addition to strength and integrity contribute various functionalities to the structure: In <FIG> is shown an example where tubular plastic pipes (<NUM>) have been inserted in selected vertical channels traversing a wall and a cylinder structure. These pipes may be partly or completely in-filled (<NUM>) with high density ballasting material (sand, gravel, etc) or light weight flotation material (expanded polystyrene pellets, air filled plastic balls, etc), distributed so as to regulate the buoyancy properties of the overall structure. Alternatively, reinforced canvas hoses may be used instead of tubing, whereby the overall structure can retain a high degree of flexibility when flexible strips, cables and straps are employed for crosslinking a structure. In-filled material may be selected with specific material properties in mind, such as high thermal insulation or high heat capacity. A given channel may contain several materials and objects along its length, e.g. a sequence of strata of granulated material of different types, a string of plastic bottles containing gas or liquids, etc. In general, the channels in the structures can be used to accommodate technical equipment for heating/cooling, lighting, sound, etc as well as serving as conduits for cables and tubing of various types.

<FIG> shows an example of macrostructures where ocean farming habitats are protected by circular enclosing walls formed from a double layer of coupled tanks or cylinders according to the present invention. Another example is shown in <FIG>, where the water surface within and outside the enclosures is covered by a network of floating, linked tanks or cylinders of smaller size.

The basic architecture of the present invention permits virtually limitless scaling and cross-linking in <NUM> dimensions to achieve the strength and functionality required in a given situation. As an example, the wall construction in <FIG>, <FIG>, <FIG> with a single layer of coupled cylindrical tanks can be extended to two layers as shown in <FIG>, and cylinders and components of different sizes can be combined in a single macrostructure as illustrated in <FIG>, <FIG>,<FIG>. Internal volumes in large constructions may be partly or completely filled with sub-structures and networks of coupled cylinders, tanks, walls, beams, etc made according to the basic principles taught in the present invention, providing strength and functionality to the overall construction. <FIG> shows an example where multi-layered outer and inner walls enclose a central volume which is filled by a network of coupled cylindrical structures. Such structures may extend through the whole width and depth of the enclosed volume, or they may subdivide the volume. An example is shown in <FIG> where planar structures (<NUM>) subdivide a tank, creating separate chambers and stiffening the walls of the tank against collapsing inward or bulging outward when subjected to differential pressure between the inside and outside.

A particularly useful type of planar structures is achieved by coupling together a plurality of low aspect ratio cylinders (annuli). An example of an annulus is shown in <FIG>. It can be put side by side with similar units and connected to them by one of the methods described previously, where the walls are penetrated by pins or straps (cf. e.g. <FIG>, <FIG>, <FIG>).

<FIG> shows a method where structures are lashed together by straps that are threaded through the longitudinal channels at or near the points of contact or by straps (<NUM>) that are looped around the walls of the structures. Depending on the circumstances, several types of attachment may be used at the same time.

Point or line connections in the form of straps or pins may be undesirable in situations where movement in the structure may cause wear and tear at contact points between different parts of a macrostructure. In such cases, surface-covering sheets may be wrapped tightly around each cylinder to provide strength. In addition to having high stretch strength, the sheet may be backed by an adhesive and incorporate a shock absorbing layer. The same type of sheet can be used on bundled tanks and cylinders in a coupled macrostructure. Added strength can be achieved ad libitum by wrapping sheets in multiple layers.

A plurality of annuli can be coupled side by side form a planar macrostructure, where the pattern of annuli is determined by the couplings between them, e.g. random, square or close-packed hexagonal (HCP) where each annulus is surrounded by six other annuli. Maximum strength against in-plane deformation or compression is generally achieved in a HCP configuration, which also provides the highest in-plane packing density of annuli. The macrostructure may be given positive, neutral or negative buoyancy in water through the choice of construction materials, by in-filling of high- or low-density materials in the vertical channels and/or by positioning buoyancy or ballast elements in the volume inside the annuli.

<FIG> shows how an enclosed volume can be formed by a perimeter wall of cylindrical tanks encircling top and bottom floors consisting of coupled annuli. The structure is submerged in water (not shown), with the waterline typically defined on the sidewalls of the top floor annuli. The annuli forming the submerged bottom floor have neutral or negative buoyancy. In general, the perimeter may have any shape, e.g. circular, elongated or polygonal, and the same is the case with top and bottom floors that are accommodated inside and/or outside the perimeter and linked or tethered to it, cf. the floating floor of coupled annuli surrounding the perimeter of the macrostructure in <FIG>. In the example shown in <FIG>, the whole structure forms a hexagon of high strength, which may be coupled with similar hexagons as illustrated in <FIG> to form a large scale basis for floating habitats.

In addition to providing a flexible and scalable basis for integration into a variety of macrostructures, floating and submerged floors formed by coupled units such as annuli can form functional macrostructures in their own right. <FIG> shows an example where a basic macrostructure, a floating triangle of coupled annuli within a framing wall, can form higher level macrostructures (in this case a rosette with <NUM> triangles) by linking up in aggregates.

Claim 1:
A modular structure for being at least partly submerged in a body of water, where the modular structure comprises a plurality of structure elements (<NUM>), where each structure element (<NUM>) comprises polymers, where each structure element (<NUM>) comprises at least one protruding part (<NUM>) and at least one receiving part (<NUM>) wherein the protruding parts (<NUM>) of a structure element (<NUM>) are arranged for mating connection with the receiving parts (<NUM>) on another structure element (<NUM>), the direction of mating motion defining a longitudinal direction of the structure element (<NUM>);
- the modular structure comprises strengthening elements (<NUM>, <NUM>, <NUM>) for providing structural integrity to the modular structure, where the strengthening elements (<NUM>, <NUM>, <NUM>) are enveloping and/or penetrating at least parts of at least two structure elements (<NUM>) of the modular structure;
- the structure elements (<NUM>) are adapted to form longitudinal channels inside the at least one protruding part (<NUM>) and at least one receiving part (<NUM>), where the channels communicate across two or more structure elements (<NUM>) that are in a mated connection;
- the modular structure forms at least one closed structure, where a number of structure elements (<NUM>) that overlap partially or completely in the longitudinal direction are connected in a network that closes upon itself around a volume; and
- where the structure elements (<NUM>) and strengthening elements (<NUM>, <NUM>, <NUM>) are adapted to provide flexibility to the modular structure while maintaining its structural integrity by at least one of the following i) comprising material with inherent elasticity, and ii) being formed to allow relative movement between at least two structure elements (<NUM>);
where the modular structure is characterized in that:
- the structure elements (<NUM>) have apertures adapted to form channels through the structure elements (<NUM>) in at least one direction transverse to the longitudinal direction;
- the channels are adapted to guiding elongated strengthening elements.