DE102005046794A1 - Floatable structure - Google Patents

Abstract

The The invention relates to a buoyant structure for carrying Loads as a rigid entity and in particular to such a structure, the from buoyant individual bodies is composed, which with elongated connecting means are connected, the cavities exhibit.

Description

Field of the invention

The The invention relates to a buoyant structure for carrying Loads as a rigid entity and in particular to such a structure, those from buoyant individual bodies is composed, which with elongated connecting means are connected, the cavities exhibit.

Floatable structures according to the invention can for one Variety of applications, they may e.g. Carry loads like roads, Houses, movable installations, gardens, Terraces and objects that are hanged under the structures like liquid containers, pipes and walk-in spaces under water for observation of marine animals.

From the prior art is off DE 202 07 585 a floating foundation known as a rigid platform. The invention is based on the object to develop a frictional connection of concrete floating bodies with Styrofoam insert or other floating basic elements with the aim to produce floating foundations as a supporting, rigid platform for receiving different sized loads. This object is achieved by reinforced concrete floating body with Styrofoam insert, which are arbitrarily assembled depending on the structural design, existing recesses in the webs by means of reinforced concrete beams in place in the water, so that different sized loads can be transferred to the floating foundation.

One Disadvantage of such a known floating foundation is that an elongated foundation either has a relatively low torsional rigidity or his production is associated with relatively high material costs. Furthermore, it is disadvantageous that the construction of the known Foundation is not suitable, any shapes, in particular rounded Shapes, to approximate.

Summary the invention

Therefore It is an object of the present invention, an improved buoyant structure to provide as a rigid unit, in particular less material needed.

These Task is according to the independent claim 1 solved. Advantageous embodiments are in the dependent claims described.

According to the invention becomes a buoyant Structure formed as a rigid unit of a plurality of floatable individual bodies, being the buoyant single body are each provided with one or more elongate recesses. These recesses are preferably provided in the same direction, in which the structure is its greatest extension having. In the recesses elongated connecting means are inserted, at least two of the buoyant Single body with each other combines.

Around a high torsional rigidity of the buoyant structure if possible low material use, the connecting means according to the present Invention have suitable profiles, e.g. a box profile or a triangular hollow profile or a honeycomb profile. A box profile made of reinforced concrete can be used advantageously as a connecting means become. Such a box profile not only allows the savings of material and thus reduces costs, but it also leads to a weight reduction. Low weight is just great for buoyant structures greater Importance. For further optimization can further struts be provided inside the profile.

About the In addition to saving weight, the cavities according to the invention provide Lanyard the possibility same with light, buoyant Materials such as e.g. To fill out styrofoam. As internal buoyancy bodies can also Interior linings of non-corrosive material, e.g. Plastic material, be used. So can a box profile made of plastic material are introduced, which are optionally closed at its ends can, thus becomes a water-protected Room created, the other equipment can record. This avoids that in the case of Leaks in the outer wall larger amounts of water can accumulate inside the connecting means. The same applies as well for the floatable Single body.

The cavities the connecting means can can also be used to supply supplies, such. Pipes or Cable to record. In conjunction with openings in the top of the Box profiles can so houses or other facilities on the buoyant structure.

Reinforced concrete is treated with reinforcement overlays to protect against corrosion, which are above 1.5 cm, usually in the range of 2 cm to 5 cm. For the choice of suitable reinforcement overlay is buoyant Structures in addition to usual parameters and the water composition. For buoyant structures, an overlap of 4.5 cm or more is usually used. Carbon fibers or glass fiber materials can be used according to the invention for the connecting means. In textile-reinforced concrete, in contrast to reinforced concrete, there is no risk of corrosion. This can also be worked with significantly lower probation coverage. This leads to lighter constructions and more efficient use of materials.

For a special high torsional stiffness of the buoyant structure can be several, in particular four, mutually parallel connecting elements be used. The exact arrangement or alignment of the recesses, in which the connecting means are inserted depends on the geometry and requirements for the buoyant structure from. There are also constructions conceivable in which connecting means not parallel to each other. If a plurality of connecting means can be used these, according to the requirements to the buoyant Structure, made of different materials and / or different Have profiles / dimensions.

Prefers extend the connecting means over the entire length of Structure, this becomes the structural unit of the rigid structure ensured in an advantageous manner.

The Walls of buoyant single body can as well as the connecting means carbon fiber or glass fiber materials contain. For reinforcement overlays across from To reduce reinforced concrete, can also be used here textile reinforced concrete be, thereby a weight reduction is achieved.

To the Forming a buoyant Structure, the curved or uneven outlines are in accordance with the invention floating single bodies used, which in plan view show a shape that is essentially corresponds to the shape of an equilateral triangle. The floating one single body has preferably the shape of a straight prism with the base of a equilateral triangle. When the element floats, its surface is parallel to the water surface. This is essential for a buoyant structure.

Would you e.g. use a non-equilateral triangle and no special ones Arrangements regarding take the weight distribution, so would the surface of the floatable Single body not parallel to the water surface be.

One another advantage of equilateral triangles lies in the fact that from them larger structures can be assembled without gaps. Any outlines of buoyant Structures can be easily approximated. However, desired areas can also be left blank be used to rooms for obstacles or components such as columns release.

According to the invention Show the buoyant single body Reinforced concrete or carbon fiber or glass fiber walls, in particular textile-reinforced concrete, up. It can profiled walls showing profiles such as they were described above. The caves of the profiles can with Styrofoam filled become. A uniform cover layer is preferred over one Plurality of individual bodies upset, this is for the rigid connection of the single body of advantage. A sealing floor plate protects the inside of the single body Water and damage, but it is not mandatory. Preferably, the interior of the single body filled with Styrofoam or other buoyant material.

to Stabilization can floating items with one or more retaining means at the bottom of the water anchored, in particular by anchored nylon ropes, the e.g. are preloaded with 15 kN. This can, with a suitable choice of Attachment positions, vibrations of the structure, e.g. by Waves are caused to be efficiently reduced. To it is especially at elongated Structures expedient that the support means in the central region are fixed to the structure and are each biased obliquely outwards. Nylon ropes opposite conventional used chains have the advantage that they can not corrode.

Short description of drawings

1 is a spatial representation of a buoyant structure according to the invention.

2 is a cross-sectional view of a connecting means 1 ,

3 is a plan view of a buoyant structure according to a second embodiment of the invention.

4 is a cross-sectional view parallel to the top of a buoyant single body 3 ,

5 is a cross-sectional view ent long line II 1 with holding means.

detailed Description of the drawings

1 is a spatial representation of a buoyant structure representing the buoyant single body 2 and the connecting means 1 shows. A variety of buoyant individual bodies 2 is provided with recesses which are aligned perpendicular to their longer extent and parallel to the water surface. The recesses are arranged so that the connecting means 1 can be inserted into it, which then for a rigid connection of the individual body 2 to care. To reduce twisting in the buoyant structure, preferably more than two, namely, for example, as shown here four, connecting elements 1 used. These extend as possible over the entire length of the structure.

2 is a cross-sectional view of a connecting means 1 out 1 , which is a box profile 3 having. The box profile 3 is preferably made of reinforced concrete. First, a U-shape in the recesses of the single body 2 manufactured. The top plate of the box profile 3 is manufactured later, this allows the trouble-free introduction of polystyrene 4 in the interior of the box profile.

3 is a plan view of a buoyant structure according to a second embodiment of the invention, which consists of a plurality of buoyant individual bodies 5 is formed. The buoyant single body 5 each have the shape of a straight prism with the base of an equilateral triangle. An example is shown of how to obtain a desired outline with recess by the combination of many individual bodies 5 achieve. When forming a larger structure, a honeycomb structure is created, as in FIG 3 As can be seen, such a structure distributes distributed forces particularly well and thus ensures a high load capacity and resilience of the buoyant structure.

4 is a cross-sectional view parallel to the top of a buoyant single body 5 out 3 , The floating single body 5 has an equilateral triangle as the base. When it floats, its surface is parallel to the water surface. This is essential for a buoyant structure. For example, if one were to use a non-equilateral triangle and not take special precautions with regard to weight distribution, the surface of the buoyant body would not be parallel to the water surface.

The wall 5 of the buoyant single body 5 is optionally made of reinforced concrete or carbon fiber or glass fiber, in particular of textile-reinforced concrete. There can be profiled walls 6 The profiles show how they are used up for the fasteners 1 have been described. The cavities of the profiles can be filled with Styrofoam. The interior of the single body 5 is with Styrofoam or other buoyant material 7 filled, this is the accumulation of water inside the buoyant body 5 prevented.

5 is a cross-sectional view taken along the line II 1 that the use of retaining agents 8th . 9 illustrated. The retaining means 8th . 9 Kings, with a suitable choice of mounting positions, vibrations of the structure, which are caused for example by waves, efficiently reduce. For this purpose, it is particularly useful in elongated structures that the support means are fixed in the central region of the structure and are each biased obliquely outwards. The retaining means 8th . 9 consist of an anchor or anchoring means 9 and a rope 8th , especially a nylon rope. This rope 8th Depending on the application, it is pretensioned, eg with 15 kN, to reduce movements of the structure.

alternative to the anchoring described here, buoyant structures can also with the help of anchored chains or pole mounts anchored. According to need, the anchor chains with Equipped with rider weights.

Claims (25)

Floatable structure for carrying loads as a rigid unit of a plurality of floatable individual bodies ( 2 ), the floatable individual bodies ( 2 ) are each provided with one or more elongate recesses into which one or more elongate connecting means ( 1 ) containing at least two of the buoyant single bodies ( 2 ), are inserted, characterized in that the elongate connection means ( 1 ) Have cavities. Floatable structure according to claim 1, characterized in that the connecting means ( 1 ) a box profile ( 3 ) or a triangular hollow profile or a honeycomb-like profile. Floatable structure according to claim 2, characterized in that the connecting means ( 1 ) a box profile ( 3 ) of rock concrete. Floatable structure according to one of claims 1 to 3, characterized in that the connecting means ( 1 ) have further struts inside the profile. Floatable structure according to one of claims 1 to 4, characterized in that the cavities of the connecting means ( 1 ) with a buoyant material ( 4 ), in particular Styrofoam, are filled. Floatable structure according to one of claims 1 to 5, characterized in that in cavities of the connecting means ( 1 ) A box profile of a non-corrosive material, in particular a plastic material, is introduced. Floatable structure according to one of claims 1 to 5, characterized in that the connecting means ( 1 ) Openings in the top of the box profile ( 3 ) exhibit. Floatable structure according to claim 7, characterized in that the connecting elements ( 1 ) Take up supplies, in particular pipes or cables. Floatable structure according to one of claims 1 to 8, characterized in that the plurality of floatable individual bodies ( 2 ) by at least three, in particular four, connecting means ( 1 ) are connected at the same time. Floatable structure according to one of claims 1 to 9, characterized in that at least one of the connecting means ( 1 ) over the entire length of the buoyant individual bodies ( 2 ). Floatable structure according to one of claims 1 to 10, characterized in that the plurality of connecting means ( 1 ) have a plurality of different shapes and / or profiles and / or materials. Floating structure, in particular according to one of claims 1 to 11, characterized in that the connecting means ( 1 ) Contain carbon fiber and / or glass fiber materials, in particular textile-reinforced concrete. Floatable structure according to one of claims 1 to 12, characterized in that the buoyant individual bodies ( 2 ) are filled with a floating material, in particular Styrofoam. Floatable structure according to one of claims 1 to 13, characterized in that the buoyant individual bodies ( 2 ) Contain walls of carbon fiber or glass fiber materials, in particular textile-reinforced concrete. buoyant Structure according to one of the claims 1 to 14, characterized in that all reinforced concrete parts a Rebar Cover have sufficient protection against corrosion, in particular probation coverage, which is 4.5 cm or larger. Floating structure in particular according to claim 1, characterized in that the buoyant structure as a rigid unit of at least one buoyant single body ( 5 ), the floatable individual bodies ( 5 ) each have a shape that is in plan view, substantially the shape of an equilateral triangle. Floatable structure according to claim 16, characterized in that the floatable individual bodies ( 5 ) lateral walls ( 6 ) and / or deck and or bottom walls containing reinforced concrete or carbon fiber or glass fiber, in particular textile-reinforced concrete. Floatable structure according to claim 17, characterized in that walls ( 6 ) Have profiles, such as a box section or a triangular hollow profile or a honeycomb-like profile. Floatable structure according to claim 18, characterized in that the walls ( 6 ) have further struts inside the profile. buoyant Structure according to one of the claims 18 or 19, characterized in that the cavities of Wall profiles with a buoyant material, in particular Styrofoam, filled are. Floatable structure according to one of claims 16 to 20, characterized in that the buoyant individual bodies ( 5 ) with a floating material ( 7 ), in particular Styrofoam, are filled. Floatable structure according to one of claims 16 to 21, characterized in that the weight distribution of the floatable individual bodies ( 5 ) is adapted such that the surface of the buoyant individual body ( 5 ) is substantially parallel to the water surface. Floatable structure according to one of claims 16 to 22, characterized in that any free-forms by a plurality of floatable individual bodies ( 5 ) can be approximated. Floatable structure according to one of the preceding claims, characterized in that the buoyant structure with one or more support means ( 8th . 9 ) is anchored to the bottom of the water body, in particular by anchoring te nylon ropes ( 8th ), which are biased with 15 kN, for example. Floatable structure according to claim 24, characterized in that the retaining means ( 8th . 9 ) are fixed in the middle region of an elongated structure, wherein the retaining means ( 8th . 9 ) are braced obliquely to the outside.