DE896860C - Pre-stressed reinforcement element made of shaped stones - Google Patents

Description

Pre-tensioned reinforcement element made of shaped bricks It is known Beams made of pressure-resistant material, especially concrete, to be produced in such a way that tension members are concreted in individual molded bodies provided with recesses. The traction organs are clamped by means of clamping devices attached to the end of the beam, and in this way a centric or eccentric prestress is created in the beams generated. Bricks have also been used for the moldings.

The pre-tensioning of an individual element by means of special tensioning devices in the above-mentioned sense, however, is in most cases uneconomical. According to a Another process is the production of a centrally pre-tensioned reinforcement element has been proposed, which also consists of a pre-tensioned tension member, which is concreted in a molded body made of bricks.

In contrast to the first-mentioned method, there is the above-mentioned one Reinforcement from an outer shell made of bricks that completely encloses the core and a core of steel wires and mortar. The complete covering of the reinforcement However, having a cladding made of brick material is disadvantageous, once because it is that Bringing the mortar very difficult and, secondly, because the insertion of hangers, which have a good bond. ensure the reinforcement with the overconcrete, is made impossible.

The reinforcing element forming the subject of the invention in the form a steel stone board serves to avoid the disadvantages mentioned and draws is essentially characterized by the fact that it is made up of flat, in cross-sonic comb-like Form pieces made of pressure-resistant material, one broad side of which alternately has longitudinal ribs and grooves, the prestressed, of Reinforcement inserts surrounded by mortar contain a central prestress in the Create board.

Further features of the invention, in particular the method for Production of the prestressed steel stone board can be seen from the drawing and their explanation.

Several exemplary embodiments of the subject matter of the invention are shown in the drawing Fig. 1 shows, in perspective, a prestressed steel stone board; Fig. 2 shows in cross section the use of boards according to Fig. I for production of window and door lintels, Fig. 3 in cross section the application of boards according to Fig. I for the production of roller shutter boxes, Fig. 3a shows a variant of Fig. 3, Fig. 4 the application for the production of load-bearing panels, Fig. 5 the application of the boards for the production of load-bearing beams and joists, Fig. 6, 7 and 8 cross-sections by three further exemplary embodiments and FIGS. 9, 10 and ii units of FIG. B.

The board produced according to the embodiment shown in FIG consists of shaped stones i made of pressure-resistant material, e.g. B. Bricks that come with comb-like, adjacent longitudinal grooves 2 are provided for receiving of tendons 3: serve; these can be made from notched steel wires or steel strands exist. The individual shaped stones i are used in the manufacture of the board a special track laid one behind the other. The prestressing wires are placed in the grooves 2 3 inserted and pre-tensioned. By means of a special vibrator, the grooves 2 with Mortar 41 filled so high that the wires in the center of gravity of the molded stone, the reinforcement and the mortar formed composite cross-section come to rest. the Wires 3 do not receive any special anchoring at the ends, but they are transferred the preload due to its increased adhesion to the due to a special notch surrounding mortar, which in turn, the prestress through its adhesion to the Transfers shaped stones to these and thus puts them under pressure. Because the board is one-sided is open, the later added part of the complete structural member can be well connected to the board by stirrups. The one formed by the shaped blocks i Board can expediently with a pressure layer 5 forming overconcrete or be provided with a brickwork. To secure the bond between the board and the overlaying or overconcrete, special stirrups can be mortared into the board will.

The shaped blocks i can expediently have cavities for better thermal insulation 6 be provided in the form of longitudinal or other holes.

Fig. 2 shows in cross section the use of boards according to Fig. I for the production of window and door lintels, with two boards a, which are made from the shaped bricks i, the reinforcements 3 and the mortar q exist, offset in height next to each other are arranged and connected to one another by a wall covering 5. -According to Fig. 3 boards according to Fig. I are used for the production of roller shutter boxes. For this is on two boards a1 and a2 arranged vertically next to each other at a distance a third board a. arranged horizontally and this is provided with a covering 5.

In the variant of FIG. H. in Fig. 3 a, the two boards ai and a., z. B. factory-made, by non-prestressed Concrete parts 6 and 7 held together on a roller shutter box, the boards ai and a2 engage in the concrete 6 with brackets 7.

The production of load-bearing panels from boards a according to Fig. I shows Fig. 4, after which the plate of joined boards a with an overconcrete or a brickwork 5, exists.

Fig. 5 is about the manufacture of load-bearing beams or joists. On a horizontal board a are two spaced apart and on edge more boards a. The space between the three boards a is filled with concrete.

That used as reinforcement and at the same time as formwork and plaster base Due to its sufficient rigidity and prestressing, the board can be used to a limited extent Dimensions can also be used as a rigid beam; next to the actual formwork the undergrowth can thus also be largely reduced. The board is used in primarily for the production of beams, slabs and beams, then in particular for the production of door and window lintels as well as roller shutter boxes and other components. The particular advantage of the board lies in the combination of steel savings, freedom from cracks, Formwork savings as well as (when using brick material) in the good thermal insulation.

In addition to the technical advantages and material savings, this results still a substantial saving in assembly time, because the board is delivered prefabricated will.

In the embodiment of FIG. 6 are to form the individual Board shaped bricks i made of pressure-resistant material, e.g. B. Bricks, used that > Are provided with comb-like, adjacent longitudinal grooves 2, in which Prestressing wires 3, preferably in the form of notched steel wires, lie and with mortar q, are poured into the grooves 2, the mortar 4, the upper parts of the grooves 2 leaves free. 7 are cast in grooves 2 with the mortar 4 Hanger.

The boards are lying next to each other in a ceiling undersurface Filling in number arranged to think so that they are a load-bearing underlayer of the Form ceiling. This sub-layer is at the same time formwork, insulation layer and plaster base the ceiling. A transverse reinforcement in the form of a layer lies on this lower layer of wires 8, on which ceiling filler with a light volume weight, here in shape of hollow bodies 9, which extend in parallel to the boards and are Rows extending over the entire length of the board are arranged between the brackets 7 are and lie between the board longitudinal joints io. These hollow bodies 9 have hexagonal shape, so taper towards the board layer and, after above.

A second transverse reinforcement i i is located above the hollow bodies 9. This is connected to the bracket 7.

In the ceiling between the boards and the screed 12 is located the upper base layer, which consists essentially of concrete ü3. consists. This building material firmly adheres to the surface of the lower, formed from the steel stone boards Base course, with the not fully mortared grooves 2 and according to the tapered design of the hollow body 9 a large contact area with the boards is present, which greatly increases the adhesion of the concrete. So that the lower transverse reinforcement can be embedded as perfectly as possible in the concrete 13, have the hollow bodies along their edges narrow elevations in the longitudinal direction, which form the support surface reduce the hollow body to a minimum. The hollow body 9 save a large amount Part of the volume of the ceiling from the concrete, so that the weight of the ceiling is proportionate is small.

In the embodiment according to Fig. 71 (the upper transverse reinforcement and the brackets are not drawn here) the hollow bodies 9 are somewhat flattened, octagonal outline and can be flat or be laid upright. The composition of the ceiling is otherwise the same as in the first embodiment.

The configurations described result in a ceiling with an ideal static Cross-section and high load-bearing capacity with low weight and a clean, level view from below, the otherwise often necessary additional effort for a special (suspended) Suspended ceiling and the like unnecessary.

Furthermore, the lower supporting layer forms the formwork when installing the Ceiling and, after installation, at the same time good thermal insulation and impeccable Plaster base.

In the embodiment of Fig. & Are to form the individual Steel stone board also shaped stones i made of pressure-resistant material, for. B. bricks, used, which are provided with comb-like, adjacent longitudinal grooves 2, in which tendons 3 "are preferably in the form of notched steel wires, lie and are poured with mortar 4 in the grooves 2, the mortar 4 the upper Parts of the grooves: 2 leaves free.

The board described is in plurality in a ceiling undersurface Think of it as being arranged with a gap, and in the gaps there are packing elements 25 provided with shoulders 6, which are engaged from under by two of the boards, wherein the lower part of the packing is in one plane with the underside of the boards, so that the boards and the fillers together form the lower layer of the ceiling. The height of the packing corresponds to the thickness of the ceiling, and theirs from the shoulders 6 protruding side walls are provided with grooves 27 and jump near the top edge of the ceiling 28 back at 29. 40 are reinforcements, especially in the end supports of the boards can be provided to accommodate negative supporting moments and the parallel run to the boards and lie in concrete 41, the space between his Limiting the tops of the boards and the side walls of the ceiling stones 25 fills in. The concrete q; 1 adheres well to the boards as well as to the packing, because it fills the grooves 27 of the side walls of the packing and thus a large one Has contact surface.

As indicated by dotted lines in FIG. 8, the side walls 16 of the Filler bodies protrude far into the concrete 4i, which means that it is concrete and therefore its own weight the ceiling can be saved. The lower slope of this projection enables that the concrete can adhere to the board in its full width.

The fillers are reinforced near the ceiling surface upper (pressure) zoneq2, which is at the end face of the packing according to the line 43 (Fig. G) springs back, so that transverse recesses arise in which Reinforcements 14 lie. These recesses are filled with concrete 15, which at the same time acts as a potting compound of the upper pressure zone qsc of the individual packing and the Furthermore, the transverse reinforcement 14 envelops effectively.

By using particularly low fillers 17, (Fig. io), one end face 18 of which can be cut at an angle, can be used with continuous Ceilings over two or more fields favorable static conditions are created, by placing the concrete 2o and the reinforcements i9 are able to produce significant negative Record supporting moments. Furthermore, the arrangement of lower packings allows 2 with angled cut 22 according to FIG. I i the production of one or more effective Transverse ribs, consisting of the concrete 24 and the transverse reinforcement 23, which are particularly are important for large (individual) loads and large spans.

It is quite possible to top the ceiling with a 4 to 6th concrete and to develop more centimeters of thickness; in this case need the packing no To have particularly strong upper (pressure) zone, and it will be the transverse reinforcement laid the packing.

Also due to the alternating arrangement of different heights of packing A sufficient upper pressure zone can be achieved with an appropriate leveling layer of concrete will.

In the manufacture of the board, the procedural feature is of particular importance Meaning that a vibrator is guided over the boards lined up one behind the other, which engages in individual channels with tooth-shaped sheet steel lamellas, which transmit the vibration given to them to the mortar. This is useful a funnel connected to the vibrator, e.g. B. made of sheet metal, provided for Feeding the mortar into the gutters is used. This mortar application device can be of such a nature (broad) that at the same time two or more adjacent Rows of boards are grouted using the same method.

The ceiling described has the advantage of having a large load-bearing capacity can be laid quickly by using lightweight elements (boards and fillings) consists.

The following advantages should be mentioned: The soffit is completely in clay (Thermal insulation plaster base), small deflections due to the prestress. the The ceiling described is for building construction and especially for normal residential construction extremely economical.

Claims (14)

PATENT CLAIMS: T. Centrally prestressed reinforcement element, composed of shaped stones, which are placed under compressive stress by concrete tendons are set, characterized in that the tendons (3) in the grooves (2) the shaped stones (i), which are comb-like in cross-section, are concreted in, thus creating a Form steel stone board. 2. Steel stone board according to claim i, characterized in that that the mortar surrounding the tendons (3) the grooves (2) not all the way to Fills the margin. 3. Steel stone board according to claim i or 2, -da-.characterized in that cavities are arranged in the shaped stones (i) parallel to the grooves (2). 4. Steel stone board according to one of claims i to 3, characterized in that the reinforcement (3 ) is in the focus of the cross-section formed by the shaped stone (i), the reinforcement (3) and the mortar _ (4). . Steel stone support plate, -bars or the like, consisting of a steel stone board according to one of claims i to 4, its through the grooves (2) and the intermediate ribs of the shaped stones formed outer surface with a printing layer (5), e.g. B. of concrete, masonry or. Like., is provided. 6. Support plate, beam or the like. According to claim 5, characterized in that that to secure the bond between the steel stone board and the pressure layer (5) special stirrups are grouted in the board. 7. With steel stone boards after one of claims i to 4 reinforced ceiling, characterized by embedded transverse reinforcement (8,11,14). B. Cover according to claim 7, characterized in that between one upper (ii) and a lower transverse reinforcement (8t) filler body (9) with a low volume weight are arranged and bracket (7) connected to at least one transverse reinforcement (i i) are. 9. With steel stone boards according to one of claims z to 4 reinforced ceiling, in particular according to claim; 7 or 8 ', characterized in that the boards are tight next to each other and above ceiling filling body (9) with a low volume weight in parallel to the boards running rows are arranged. ok With steel stone boards according to one of claims i to 4 reinforced ceiling, in particular according to claim 7, characterized characterized in that between the boards ceiling filler (25) with a low volume weight lie. i i. Ceiling filling body for the production of with steel stone boards according to a of claims 8 to io reinforced ceilings, characterized by downwards and optionally also tapering upwards, e.g. B. round or polygonal cross-section. 12th Method for producing a steel stone board according to claim i, characterized in, that a vibrator over the boards lined up one behind the other and possibly at the same time is guided over at least two rows of boards next to each other, which is divided into individual Grooves with sheet steel lamellas engages, which the vibration given to them transfer the mortar. 13 ;. Apparatus for performing the method according to claim 12, characterized in that a funnel is connected to the vibrator, the serves to feed the mortar into the channels. 14. The method according to claim i, 2, characterized in that the production of the boards successively in at least two superimposed layers takes place.