DE962469C - Building block built on the cube system - Google Patents

Description

Building Block Built on the Cube System The invention relates to one Building block, which by its shape a firm interlocking of the individual stones with each other, namely both: in the same stone layer as well as in the individual layers one below the other causes the creation of a wide variety of components, such as walls, ceilings, Pillars, beams of particular strength, even without binding agents, made possible. on the other hand Can the stone in small dimensions for construction kits for the production of model buildings and the like. Can be used without additional binding or fastening means have firm cohesion, but also very easily without damaging the stones can be taken apart again. It is already known to be building blocks to build the cube system, with the building blocks for the purpose of mutual interlocking The neighboring stones have approaches in two directions. Furthermore is it is generally known to have stones with protrusions and depressions to secure their position to provide that interlock. For this purpose, among other things, are already Truncated pyramidal projections have been brought into proposal, which in accordingly engage trained grooves.

The invention also relates to an on-the-cube system built building block, which approaches in a manner known per se on two surfaces has two directions. The invention consists in that two each on each other Cube approaches opposite a surface nll j, e two after -the free end open keyways, two of which are keyways against each other and two Keyways after those on the other face arranged cube approaches to be directed, the pyramid-shaped on the opposing sides of the cube Have projections that can be inserted into the keyways of adjacent stones @. In particular, it is advisable to measure the length of the ruler carrying the cube attachments .equal to make four times its cross-sectional edge. Through the design according to the invention, a very tight clamping of the stones is achieved, which are additionally secured in their position in two directions, whereby the Association dex stones gets better and also transverse shifts of the stones against each other be prevented. The keyways can be cut at the closed end by an inclined surface whose inclination is greater than that of the pyramid surface of the other pair of cubes is. This has the effect that the - building blocks with the wedge effect of the pyramid surfaces cling to each other. To conclude and to fill in gaps eiri half stone proved to be favorable, which consists of only one by transverse division in the In the middle of the bar formed half of a building block and with .dem in particular Gaps in the wall bond that arise when the solid bricks are used, filled can be. Another advantageous embodiment of the module; according to the The invention results from the fact that the bar-shaped part is bent and in particular runs at a kink angle of q.5 °. The connection is sloping This makes it easy to create walls. Building blocks of the specified forms can be used in an known way as solid or hollow stones and also with larger ones Form monkeys are divided into cells. The material used for production is based according to the intended use. the stones. For buildings, pumice, slag, rubble chippings, Natural stone, clay, lime, cement, glass, etc. can be used; for metal structures eats the manufacture of metal possible :. Building blocks of the specified type made of cork, Pulp vid. The like. prove to be very favorable for purposes of soundproofing. In the end For stones for play, entertainment and teaching purposes, wood or plastic can be used etc. are used. Any of the building blocks according to the invention can be seen Components such as walls, walls, beams, ceilings, roofs, stairs, columns, pillars, towers; Build masters, shafts, tunnels, channels, dams, platforms, wall panels, etc., in all cases, due to the interlocking of the stones on all sides, a large one Stability and activity is achieved that often involve the use of binders (Mortar) superfluous. The module is also suitable for use under water particularly suitable.

In the drawing, exemplary embodiments of the subject matter of the invention and examples of use are shown, namely, FIG. 1 to FIG. the same building block in a diagrammatic representation, FIG. 5 a half-stone according to the invention in a diagrammatic representation, FIG. 6 a modified embodiment of the building block according to FIGS 7 shows a view of the wall and FIGS. 8, 9 and 10 show the first, second and third brick layers in plan, the visible building blocks of the preceding brick layer being denoted by a double cross, FIGS. II to 14 a double wall referred to in corresponding views as Figs. 7 to io, FIG. 1 5 and 1 9 a triple wall in view and the floor plans of three successive layers of stone with FIG. 7 to io blocks, Fig. 2o the outline of a Wandabzweigung and an oblique wall connection with building blocks designated according to FIG. 7 to 10, FIGS. 21 and 22 the plan of two stone layers of a column with building blocks designated according to FIG. 7 to 10, FIG. 23 combined bases a corner and a wall crossing with building blocks designated according to FIGS. 7 to 10, FIG. 24 the elevation of a beam bracketed in a wall structure, FIGS. 25 and 26 cross-sections according to the lines 25-25 and 26-26 of FIGS. 27 shows a view of a hollow beam, FIG. 28 shows the top view of the lower layer in FIG. 27, FIGS. 29 and 30 cross-sections along lines 29-29 and 30-3o of FIG. 27, FIG. 31 shows an end view of a Building blocks in the diagonal formation of a plate-shaped structure, FIG. 32 shows the top view of FIG. 3 1 and FIG. 33 shows a section along the line 33-33 of FIG. 3 i.

The building block according to FIGS. I to ¢, which is designated generally by i, has as its main piece a beam 2 of square cross-section, the length of which is equal to four times the cross-sectional edge. At the ends of two abutting longitudinal surfaces 3 and q. each lein cube 5 or 6, the edge of which is the same as the cross-sectional edge of the beam 2, placed in such a way that it cuts off flush with the end face of the beam. In this way, two angle bars 5, 6 (Fig. 3) are formed at the ends of the central bar. On the surfaces facing each other, the cubes each have a flat four-sided pyramid 7 placed on the cube surface as a base surface or 9, the triangular cross-section of which corresponds to the pyramids 7. Towards the bar 2, the keyways 8 are bounded by inclined surfaces io and diw keyways 9 .by inclined surfaces ii, which are expediently arranged somewhat steeper than the corresponding surfaces of the pyramids 7. The one in Fiig. The half-stone 12 shown in FIG. 5 corresponds completely to one half of the building block i according to FIGS. I to 4 and is formed therefrom by dividing this stone into two halves along the section line VV in FIG. It therefore has a cube 5 and 6 and the cube-shaped half 1 3 of the bar 2 of the building block i. The half-stone formed from the other half of a building block i is a mirror image of the half-stone 12 shown. The building block 14 according to FIG. 6 differs from the building block i according to FIGS. 1 to 4 in that the free beam part 15 is bent. In the illustrated embodiment, the kink angle is 45 °. It can of course also have a different size.

In FIGS. 7 to 10 the structure of a simple wall made of building blocks i and half-stones 12 is shown. The blocks are used in their normal position in which the cubes 6 protrude upwards so that the channels 8 and 9 are open at the top. The building blocks 1 8, 1 9 of the second position shown in FIG. 9 are set so as to adjacent to each other according to Fig. 8 disposed blocks 16 and half blocks 17 of the first layer that the cube-s depending zvreier adjacent blocks of the second layer between the two dice 6 of a stone of the first layer come to rest, the pyramids 7 of the stones of the second layer being pushed into the grooves 8 of the cubes 6. As a result, the stones in the first and second layer are both in the. both in the longitudinal direction and in the transverse direction. The third layer of building blocks 20 and half-stones 2 i (FIG. 10) again corresponds to the first layer. Half-stones 17, ig, 21 are inserted at the wall ends, as far as whole stones are desired for connection with connecting walls. Fig. II to 14 show in the same way the structure of a wall of double stone thickness (double wall). The first two layers of the wall (FIGS. 12, 13) correspond to the positions of two individual walls, with the stones 22 of the first layer with the cubes 5 facing one another. A transverse building block 23 serves as the end on the right. The building blocks 24 of the second layer lie with their backs against one another; half-stones 25 form the end at the left end. In the third layer according to FIG. 14, the two simple walls are clamped together by stones 26 lying transversely, whereby the transverse bond is formed. To form a triple wall according to Fig. 1 5 bis- 1 9, the first three bearing a single wall 27 corresponding to FIGS. 8, 9 and io and a double ivand 28 corresponding to FIGS. 12, 1 3 and 14 in the group consisting of the FIGS. 16, 17 and 18 are made up of building blocks 16 and 22 in the first position, building blocks 18 and 24 in the second position as well. Blocks 2o and 26 brought up next to one another in the third layer. In the fourth layer (Fig. 19) , the single wall is connected to the double wall by cross stones 29 and thus the cross connection is made. Blocks 3o arranged in the longitudinal direction complement this position. For walls of greater thickness, the fourth layer of bricks is always decisive for the first cross bracing. Four-fold walls can be built up from two double walls, five-fold walls from two double and one single wall and six-fold walls from three double walls.

According to FIG. 2o, an intermediate wall 32 is attached to a wall structure 31 at an angle of 90 ° by leaving the main wall in the structure. Interstices are formed by building blocks, in which building blocks 33 of the partition walls are clamped. This creates a firm connection between the wall and the partition: The resulting gaps are filled with half stones. The same connection can also be made with multiple wall thicknesses.

In the same figure is also the use of angle blocks 14 shown in FIG. 6 to achieve a change in direction at an angle of 45 °. Using blocks 14, polygonal, z. B. octagonal, cross-sections in columns, shafts or tunnels are made, with se for the connection an intermediate wall m bracketed an already existing wall association can. The module 14 can also be used for the transition from the outer wall of a building serve for sloping ceilings, which he also acts as in the horizontal and vertical planes Transition to a bar can leave. The outside of the corner of the wall Occurring gaps can be filled with concrete. At the column cross-section 21 in the first position there are two building blocks 34 with the backs of the beams 2 placed next to each other so that they form an H-shape. Two more stones 35 are behind Fig. 22 in the second. Position in the same way, but rotated by 90 ° in the gap bracketed. The third steeple layer in turn springs from the first. An extension The cross-section to a rectangle or a larger square is easily possible. Fig. 23 shows the execution of a corner, with the building blocks 36 of the wall with their end faces abut the longitudinal surfaces of the building blocks 37 of the other wall. Such a corner dressing can also be designed with a multiple wall thickness and is suitable in the same white for the production of a roof ridge. In the The same figure shows a cross brace 38 in plan, of two. Corner bracings that overlap in the vertical plane by the length of the building block and form a connected column at the point of intersection. The stones can be arranged in this way be that the walls protrude from a left or right side of the column: the same Corner arrangements are possible with the construction of a shaft. The in Figs. 24 to 26 of the qua.dratisChenm cross-section consists of two layers of Whole stones. The first layer of the blocks marked m5, t 39 is in the longitudinal direction arranged next to one another that the cubes 6 are horizontal.

and, the dice 5 are directed. In these stones 39 are. the building blocks 4o of the second layer laterally inserted 2n such a position that their with The cubes marked 6o are also homizontal, but the others are marked 5o Cube facing down. This creates a bar that is smooth on all sides the ends in the from Fiig. 24 apparent way by means of a block 39 of the first layer can be bracketed in a wall association 41, which widened upwards can be. Ceilings can be formed by placing several beams next to each other. Several intersecting beam layers can also be arranged one on top of the other.

In FIGS. 27 to 30 a hollow beam is shown, the thickness of which corresponds to that of l1 / 2 stones.

The hollow beam has two layers of building blocks. The lower layer consists of stones 42, which with the. Roll 5 upwards in a row are. Blocks 43 with horizontally lying cubes 5 are inserted into them. The top layer 44 shows the same structure. It is rotated 180 ° around the longitudinal axis and in this position placed on the lower log. In a vertical direction the two layers are not clamped together, but only pushed into one another, so that the top layer, if connected to the bottom layer, is made by binding agents is, can be lifted from this.

Figures 31 to 33 show. a staircase: en-shaped arrangement of the Building blocks containing plate-shaped structure.

The building blocks are in a diagonal position, i.e. H. so that the continuous Bar 2 upwards and the pairs of cubes 5 and 6 are pointing diagonally downwards, pushed together horizontally. The position of the stones to one another is indicated by the reference numbers 45 and 46 for some stones & n Figs. 31 to 33 clarified.

The plate can be used horizontally and is advantageous with arranged on the underside upwards, since they then prevent sagging. resistance performs when their ends are supported in the longitudinal direction. Then all the dice show up. The grooves formed by them can be filled and thus a smooth one Surface can be achieved. It is also possible to set up the plate at an angle as a staircase.

Claims (1)

PATENT CLAIMS: i. Building block built on the cube system, which has approaches in two directions on two surfaces, characterized in that the two surfaces carrying the approaches are the abutting longitudinal surfaces (3, 4) of the bar or rectangle (2), the cross-section of which corresponds to the cube approaches and the length of which is four times its cross-sectional edge, and that two cube projections (6) opposite one another on a surface (4) are each equipped with two keyways (8, 9) open towards the free end, two of which are keyways (8) against each other and two keyways (9) are directed towards the cube projections (5) arranged on the surface (3), which have pyramid-shaped projections (7) on the opposite sides of the cube, which can be inserted into the keyways of adjacent stones. z. Building block according to claim i; "characterized in that the keyway (8, 9) is delimited at the closed end by an inclined surface (io, ii), the inclination of which is greater than that of the pyramid surfaces (7) of the other pair of cubes. 3. Building block according to claim i or 2, characterized in that it consists of only one half (12) of a building block (i), ie half-building block, formed by transverse division in the center of the bar (Fig. 5) -4th building block according to claim i or 2, characterized in that the bar-shaped part (15) is beaded. 5. Building block according to claim 4, characterized in that the kink angle is 45 °. Relevant publications: German patent specification No. 846452; Austrian patent specification No. 588 662 ; Swiss patent specification No. 93 181, 187 041; French patent specification No. 460 346, 631 012; British patent specification No. 420 349, 570 967.