DE809247C - Construction with hollow balls as a component - Google Patents

Description

Construction with hollow balls as a component The invention relates to a Construction method for the production of structural and civil engineering, walls, panels, construction and Construction parts of all kinds, protective walls, protective layers also for heat and Sound insulation or against bullet or penetration, made of stones, earth, Wood, metal and other natural or artificial materials.

The stone construction method adopted from antiquity is based on that cuboids are put together and on top of each other. The brick building is that Continuation. The newer cement-concrete construction has in common with the first-mentioned construction methods, that the masonry is completely filled with building material. Only for a relatively short time Time has gone over to non-load-bearing walls and non-load-bearing parts of the Ceilings etc. to be executed in hollow stone (hollow bricks), but their strength is desirable leaves. In order to achieve greater savings in building materials and transport costs, In order to build lightly yet firmly, it is imperative to break away from the old principles to avert the construction in stone.

Nature teaches with the example of the bird's egg, the coconut, the skull shape, of the cell structure of mechanically stressed organs in plants and animals, that the hollow spherical shape or the shape of the hollow egg offers great strength with little building material expenditure. The consistent application of this principle leads to a new building material-saving Construction in which, according to the invention, hollow balls or similar hollow bodies as Component are used.

By lining up and stacking hollow spheres as a component (building block, construction cell) and connection of the individual elements or By embedding the same in a filler, a structure of high strength is achieved at light weight. When embedding the hollow spheres, you can save on building materials increase by the fact that the spaces and edge areas through hollow fittings fills out. Further details of the invention are given below with reference to the drawing explained.

The balls can be lined up and stacked in various associations. Two basic shapes result from grouping the balls in three or four on one level. Ball layers in a triple association (Fig. I) are alternately a, b, c, a, b, c layered one on top of the other in such a way that each ball center of the middle layer b comes to lie over a center point of the equilateral triangles formed by the ball centers of the lower layer a and that the next higher layer c is offset in the same sense as the middle layer b is offset from the lower a. In the foursome (Fig. 2) there are only two layer sequences a, b, a, b. Each sphere center of the upper layer b lies above the center point of the squares formed by the sphere centers of the lower layer a.

The practical implementation of the inventive concept can, in each case given building materials and building conditions accordingly, in different embodiments take place: a) Hollow spheres of the desired wall thickness are manufactured separately, and although it is useful for cast metal in one piece, for non-metals and sheet metal in two parts (Fig. 3). In the case of bricks, ceramics, concrete, the dry ones half hollow spheres joined together using binding material and fired, Hardening or setting made into a hollow unit. The finished hollow spheres are connected to the desired bond at the points of contact in the building itself (Fig. 4). The gaps remain free. Applicable e.g. B. for monumental buildings, then with metal as a building material for a wide variety of purposes down to the smallest Objects.

b) Hollow spheres, manufactured separately as in a), are in the building put together in the desired association and by filling or potting the gaps combined with the same building material or a binding material (Fig. 5).

c) Thin-walled spherical hollow shapes are made separately, expediently in two parts, manufactured (e.g. from very thin sheet metal or from thin-walled concrete), in the building accordingly laid and layered, while maintaining the desired wall thickness is achieved by using small adapters (core supports, feet). The spaces in between are with building material, z. B. concrete, filled (in layers, or larger potting Games). The spaces between the load-bearing hollow spheres can be used in this Execution by using thin-walled hollow forms are also left out (Fig. 6).

d) cast bodies are produced with spherical cavities interspersed, which are arranged in a group of three or four (Fig. 7). The spaces in between between the hollow spheres are filled with building material. Manufacture z. B. in normal Casting process when using cores for the interior of the ball.

e) Cast body as in d), but with the spaces between the hollow spheres remain free (unfilled), so that the entire cast body inside consists only of hollow spheres of a given wall thickness (Fig. 8). Production at 13th under Use of cores for the interior of the ball and special cores for the spaces in between between the hollow spheres. Especially for metal bodies of larger dimensions or bodies made of valuable material. The outer wall can also be omitted in special cases, so that finally the same picture results as in a) (Fig. 9).

f) Individual hollow bodies (building blocks) «earths are produced separately, expediently in two parts. They form a hollow sphere and are delimited on the outside by flat enveloping bodies of the sphere (diameter equal to inner diameter plus double the wall thickness). The main polyhedron in question is the rhombic dodecahedron, which can be used both for cyclically interchanged triple lattices a, b, c, a, b, c (Fig.ioa, b) and for quadruple lattices (Fig.ioc, d), then for Triple bond with only two alternating layers a, b, a, b a rhombus-trapezoidal polyhedron, which is delimited by six rhombic and six trapezoidal surfaces (Fig. Ii). The installation space can be completely filled (without any gaps) using both rhombic dodecahedra and twelve-sided rhombic-trapezoidal polyhedra. When these bodies are put together correctly as building blocks in the structure, the hollow spheres come into the desired association by themselves. By rounding off the corners and edges, you can save more on building material, you can then cut out non-load-bearing parts of the surface to absorb binding material (mortar). This construction method can be used for brick, concrete, artificial pumice, glass and other fabrics; it is also suitable for paving stones hollow and full. Half polyhedra should not be used. For the edge areas, special stones with a size of t1! 2 polyhedra are used.

g) Building blocks (Fig. i2), plates or sheets (Fig. 13) with hemispherical recesses on both sides in a triple or quadruple formation are manufactured separately., The height (thickness) of the stones, plates or sheets must be the same vertical distance. the centers of the spheres between two layers of the given association. The stones, plates or sheets are joined together in such a way that the half hollow spheres of each plate and those of the counterplate complement each other to form full hollow spheres, so that the building that is created is interspersed with the desired triple or quadruple association. -Metallic plates or sheets are produced by casting, rolling, pressing or punching in factory lengths and widths. B. rolled together into a thicker plate. Fastening from sheet metal to sheet metal using dowels and the like is also possible. Metal plates or sheets in a hollow spherical bond are characterized by high flexural strength and buckling resistance, and are therefore well suited for self-supporting ceiling and roof constructions, etc. In makeshift construction for residential purposes, they offer the further advantage of inexpensive heat and sound insulation compared to simple sheet metal. Lightweight metal panels made according to these principles are also suitable as a substitute for wood for many uses, e.g. B. in building construction or in furniture production (doors, window frames, stairs, table tops, etc.), but also, for example, for containers and cases, especially if you choose light metal as the building material for the panels. The same basic embodiment can also be used for lightweight materials and plastics of all types.

14 shows a special construction in a perspective view Such plates or sheets for dome construction and the like, the boundary surfaces of the individual Plates lie on the surfaces of concentric spheres; Fig. 15 illustrates a single plate; 16 shows the assembly of such individual panels to form a dome structure.

: 2us thin plates or sheets of this type can be used in large halls Assemble hollow container and the like. Even if you only use a single layer, one can because of the large section modulus of such hollow spherical sheets smooth sheet metal achieve a high level of resistance to dents caused by wind or air pressure, so that in further consequence when using appropriately developed building material constructions 16 also as a replacement for larger tents, even for evacuated balloon envelopes come into question.

h) 1lohlktigelplatten (sheets) are made of brick, concrete, metal and other materials produced separately. Two corresponding hemispherical plates each combined result in a coherent layer of entire hollow spheres. In Fig. 17 sees such a composite plate in plan view and in section.

1 and II are the uppermost, slightly raised for a better understanding drawn, two hemispherical layers, 11I, IV, V, VI the underlying. Even Embedding the hollow spherical plates (layers) can be considered. In this case the intermediate piece can be completely or partially cut out between the individual hollow spheres or be omitted. With thinner sheet metal, the intended overall effect by bracing the individual sheets against each other, e.g. B. screwing together, hot riveting, to be achieved; stronger hollow spherical slabs can be made by rolling the two on top of each other Half-shifts can be obtained in the production plant. Application and advantages of this version are similar to embodiment g).

A combination of stone and hollow metal spherical layers in one The plate can be advantageous in individual cases when it is subject to bending stress.

There are further variants for all basic forms of solution through the transition from a sphere to an egg shape or to a polyhedron (rhombic dodecahedron, rhombic trapezoidal dodecahedron, Diamond hexahedron, cube on top, etc.). According to the polyhedron variant Manufactured sheets or plates of type g) have the property that all wall thicknesses between the hollow polyhedra are of the same size and that none Gaps occur. Fig. 18 shows rhombic dodecahedron sheets, Fig. 19a and igb Rhombus-hexahedron sheets and Fig. 2o a and 2o b sheets with turned on top Dice.

Instead of joining whole hollow polyhedra to form a seamless structure, you can also assemble polyhedron halves in such a way that, for example, only upper Halves are used, which are lined up again to form the lower halves of the polyhedron of the next higher layer, as shown in FIGS. 21a and 21b, for turned upside down Show cubes as a building cell for brick construction as an example. The cut is in the drawing under 45 ° immediately behind the front wall of the half hollow cube (cube roof) and led parallel to this wall. The approaches that appear nose-shaped in section run along the edges and are intended to receive the mortar.

A bottle-shaped cell formation, which can be derived from the execution 13 for bricks as a building material, for example, show the two following Figures 22 and 23. Figure 22 shows a plate construction. The pans P are intended to receive the mortar. Fig. 23 shows the same type on individual elements transfer.

Combinations of polyedas and spherical shapes are possible, for example with execution f) (Feg. io and i i).

The wall thickness of the hollow body can be adapted to the load. Different wall thicknesses can be used in one association; also full body next to hollow bodies. For special cases, e.g. B. pavement, can also be beneficial full rhombic dodecahedron etc. used in the association instead of cubes in the previous association will.

A ceiling or wall according to the hollow-sphere construction is particularly beneficial in the execution forms a); f) and h) good resistance to puncture or Bullet. One that attacks a (hollow) ball on the wall or ceiling surface Power is distributed to the layers below in the form of a spherical pyramid (in which the attacked ball forms the tip) for example in a four-man association in layers on 4, 9, 16, 25 etc. balls. You can still get the dielectric strength by increasing the uppermost spherical layers in greater wall thicknesses, optionally up to the full ball in the outermost layer.

Where in special cases it comes down to individual components, e.g. base, more difficult to make, the hollow spheres can e.g. B. with sand or water to be filled; Water with additives that lower the freezing point, and in areas where severe frosts do not occur. Where it is on the other hand particularly light Design matters, components can evacuate with a vacuum or light gas-filled hollow spheres are used.

The possible application of the inventive idea in its various ways Variations on land, water and in the air are very diverse.

Claims (1)

PATENT CLAIMS: i. Construction method for the production of civil engineering structures, walls, panels, building and construction parts of all kinds, protective walls, protective layers; also for heat and sound insulation or against bullet or penetration, made of stone, earth, wood, metal and other natural or artificial materials, characterized in that hollow spheres are strung together and stacked as a structural element (building block, building cell) in a pebble (pyramid) bond , possibly embedded in a filling compound, or connected to one another in some other way, are used. a. Construction according to claim i, characterized in that fitting pieces are inserted between the components; which can be hollow (Fig. 6). 3. Construction according to claim i and a, characterized in that the hollow components and fittings are used empty of air or filled with gas, liquids or solid substances such as sand. 4. Construction according to claim i; characterized in that the individual components are formed by polyhedra enveloping the hollow sphere, mainly rhombic dodecahedra, which, when joined together, fill the space completely (without gaps) (Fig. 10). 5. Construction according to claim i, characterized in that blocks, plates or sheets, which are provided on both sides with lined-up hemispherical recesses, optionally with recesses for spaces, which are arranged within the plate so that only the desired minimum of building material remains , are joined together in such a way that the half hollow spheres and half the spaces between them complement each other with the recesses in the counter stone (the counter plate, etc.) to form full hollow spheres and spaces and that the hollow spheres that are created in this way produce the desired bond among each other in the structure (Fig. 12 and 13 ). 6. Construction according to claim i, characterized in that, instead of the individual hollow spheres, coherent hollow spherical layers are used, which consist of two complementary plates (sheets), each of which is formed from closely spaced half hollow spheres (Fig. 17). 7. Construction according to claim i, applied to foundry technology, characterized in that, for. B. by spherical cores and possibly also cores for gaps in the cast body hollow spheres and possibly gaps so that the finished casting is penetrated by hollow spheres in the intended association or with the associated gaps. B. Construction according to one of claims i or 4 to 7, characterized in that hollow egg shapes, hollow polyhedral shapes or similar hollow shapes are used in place of the hollow spheres. 9. Construction according to one of claims i or 4 to 8, characterized in that only the half hollow spheres, the half hollow egg shapes, the half hollow polyhedra are used as a component and are superimposed in such a way that they become whole hollow spheres, hollow polyhedra or add to other structurally favorable building cells. ok Construction according to one of claims i or 4 to 8, characterized in that; that instead of or in addition to the hollow elements, solid elements of the same external shape are used.