DE809603C - Insulating concrete structure - Google Patents

Description

Insulating concrete structure It is well known that the outer wall of every structure has the load-bearing function and at the same time also the insulation against cold and heat take over.

The best masonry in terms of load-bearing capacity and insulation is the brick wall to this day, provided that it is chosen in sufficient thickness. However it has the major disadvantage that its production takes a lot of time and that by the very numerous mortar joints large amounts of water are brought into the construction, so that again a great deal of time is lost for the building to dry out.

Concrete masonry, too, which is very stable from a static point of view and in which the lack of insulation is brought in, that the concrete wall as a load-bearing part by pouring the space between two insulating plates a to 3 cm thick placed on the scfialung will have the disadvantage that the large amounts of water introduced with the concrete require a lot of time for the masonry to dry out.

With the introduction of the so-called foam concrete or aerated concrete various construction systems have been created, with which the disadvantages of the long Attempts have been made to eliminate drying times. These building systems exist in the general in the fact that prefabricated dry gas concrete slabs in a load-bearing skeleton made of iron profiles or iron pipes. But now the aerated concrete has no volume stability, so that the outer and inner surfaces are reinforced with Rabitz will must before the basic plaster can be started. A Construction produced according to the diesel dry construction system is characterized by a very good Isolation ability requested. but the disadvantage of being limited by the iron stand architectural design options and the high construction costs.

In summary, the rule is that in the known building systems an increase in the load capacity can be achieved at the expense of insulation and vice versa can and that also avoiding the introduction of large amounts of water into the structure usually causes an increase in construction costs.

The present invention relates to an insulating concrete structure which combines the following advantages: i. high load-bearing capacity of the concrete as a load-bearing Part, 2. the use of aerated concrete as an insulating layer with the elimination of through Changes caused by shrinkage of the aerated concrete, 3. the possibility of use prefabricated panels. of any size, which can be moved dry in the construction, 4. Reduced construction costs and greatly reduced construction time with savings of around six percent of working hours and 5. ' absolute fire resistance.

In order to achieve these advantages, the structure is made according to the invention prefabricated,. load-bearing and at the same time insulating panels created which two load-bearing concrete layers and one volume-inconsistent between them Have insulating compound, which is connected to the concrete layers, the building structure are laid in the association in such a way that the insulating layer forms an uninterrupted space-enclosing Coat forms and can move between the concrete layers, so that cracks form be avoided in the latter.

The drawing shows an example embodiment of the subject matter of the invention shown. It shows Fig. I a vertical partial section through the building, parallel to the ceiling beams, Fig. 2 a vertical partial section through the masonry, transversely to the ceiling beams, Fig. 3 is a vertical partial section through the building, parallel to dexi ceiling beams, across an interior supporting wall, and.

Fig. 4 a. horizonta ['en .; Section through the building, Fig. 5 is a horizontal partial section through the building with further details, Fig. 6 is a vertical partial section parallel to the ceiling beams along the line II of the. Fig. 5, Fig. 7 a vertical partial section transversely to the ceiling beams along the line II-II of Fig the ceilings on prefabricated, flat structures, which are formed from two outer concrete layers i and 2 forming the load-bearing part and from a middle insulating layer 3 made of aerated concrete, also called foam concrete, connected to the two outer layers. For the formation of the corners of the outer wall, the plates, as can be seen from FIG. 4, have an angular shape, while they form straight plates in the straight part of the wall and the inner walls. The panels have storey height, i.e. an average of 25o cm and are about 70 cm wide. In the example shown, the wall thickness of the panels is approximately 18 cm for the walls and approximately 9 to 14 cm for the ceilings. Depending on the character of the building, the dimensions of the panels can vary from the above: Dimensions at will. Depending on whether the panels are intended for external walls, internal walls or ceilings, the structures can be provided with recesses, folds, protruding ends of reinforcing iron, etc.

As can be seen from Figs. I to 3, the structures 1, 2, 3 for the exterior and interior walls of the first floor on one of the basement masonry 4 applied insulating intermediate layer 5 made of cement mortar, with a sealing additive is mixed up, put on. The buildings are with their vertical abutting sides, at which the insulating layer 3 is flush with the concrete layers 1, 2, butted against one another and on the edges of the concrete layers an insulating compound 6 (Fig. 4) with added cement applied. In this way, as can be seen from FIG. 4, a closed one Insulating jacket formed. The concrete layer on the inside takes over the outer walls 2 of the panels have the load-bearing function for the ceilings. The ceilings are formed from prefabricated and provided with reinforcing bars 7, 8 concrete beams 9 and from between these laid slabs 1, 2, 3. The lower part of the concrete beam forms a widened one Foot on whose heels the plates rest by means of a corresponding fold. Both the ceiling joists 9 and the slabs laid on them lie with their one end on the inner concrete layer 2 of the panels forming the outer wall, while the other ends of the beams and the plates supported between them rest on the facing concrete layer of the panels forming the inner wall. The cellar ceiling, on the other hand, is directly on a protruding part of the cellar walls supported, which are designated with 4 (Fig. 1, 2) and 4 (Fig. 3).

By resting the ceiling joists and those laid between them Slabs only on the inside concrete layer 2 becomes an: interruption of the insulating layer 3 avoided from one floor to the other and one completely closed off from the outside Formed insulating jacket, which is closed all around and includes all floors (See Figs. 1, 2 and 4).

The reinforcing irons 7 and 8 protruding from the ends of the ceiling beams form eyelets through which a reinforcing wire ii (Fig. 3, 4) is braided, and over the plate-provided corner balls: cn, distribution bars 12 (Fig. 2) are placed . A concrete layer 13 is poured over the supporting elements of the ceiling that are reinforced in this way. Through the over- concrete layer 13 , the ceiling support elements are connected together with their reinforcing iron to form a compact insulating concrete ceiling with high load-bearing capacity.

At the first floor ceiling and the ceilings of the other floors is between every two bars at the support on the outer wall also the Spielratttn between the ends of the panels and the insulating layer 3 of the outer wall filled with concrete, whereby pressure distribution bars 14 are formed, which by the laterally protruding .lntierttngseisen 7 and 8 at the beam ends connect these to one another (Fig. 4). In all ceilings, the overconcrete also reaches into the space between the slabs over the inner wall (Fig. 4), whereby a connecting beam lying transversely to the beams g 15 (see. Also Fig. 3) is formed, in which the Armierungseisctl i r and the protruding ends of the solve 7 and 8 are embedded. The one between the Iwiden concrete layers i and 2 lying room r! tif the height of the ground floor ceiling as well as the :: citcrcn ceilings is retrofitted with aerated concrete;: ttsgcgossen, which creates a tight connection 3 'of the . Insulating layer 3 between the floors and the same thickness as the ceiling is educated.

At the top ceiling under the roof beams, citigegosscn are cast in the pressure distribution beam 14 or in the concrete over concrete t3-I3att screws r6 at selectable intervals. The I "tißl) grease 17 is attached to this by means of nuts.

The external plaster 18 is on the outside wall and the white plaster on the inside rg applied.

FIG. 1 shows a window built into the outer wall and FIG. 2 shows a door built into the outer wall. In both cases, an artificial stone enclosure 2o is inserted into an opening in the building structure that is cut out for this purpose. A cement mortar bed 21 serves as a connection, which on the one hand engages in a recess 22 in the aerated concrete layer 3 of the liatik (> body, which is narrowed by an inwardly jumping wedge 23 of the outer concrete layer, and on the inside in a recess 24 in the stone-lined wall). The frame 2 3 for (las hctister abuts the aerated concrete on all sides and the one for the door on three sides on the aerated concrete and only at the bottom of the cement floor of the floor Place the insulating jacket in the outer wall of the building interrupted.

As can be seen from the description above, <Ictt <lcr Ülicrbcton 13 and the pressure distribution swellings 14 and 15 are brought into the building, \\ as niit (Irin connection drainage of the slabs etc. Mtr ctWa 20 percent of the brick construction - <'( 'brought Wasscrinengen corresponds.

In order to create a particularly good association, according to a further inventive concept, as shown in FIG recesses 34 ( 'er i abutting plate, z, 3 vertical channels ILDs 35 b, oval, round or rectangular f;.. may have ucrschnitt These channels advertising (lctt the Association of structure with foam' (ton poured, so that the structures are connected on the longitudinal edges by exposed concrete columns engaging in the longitudinal recesses 34.

As the sectional images from FIG. 5, namely FIGS. 6 and 7 show, the ceilings are formed from panels 36, 37 which are laid between reinforced ceiling beams g. The lower part of the ceiling joists forms a widened foot g 'as a support for the ceiling panels 36, 37. The ceiling joists g rest with their ends on the inner concrete layers 2 of the building structure. The associated ceiling panels consist of tub-shaped concrete 36, which is filled with foam concrete 37. The concrete layer 39 is poured over the ceiling panels 36, 37. In this layer 39 , the structures 36, 37, which form the infill walls parallel to the ceiling beams g, are connected to both the inner plaster base layer 2 and the outer plaster base layer i through pressure distribution bars 40 and 41, respectively, laid across the ceiling beams. For this purpose, the vertical reinforcing irons of the outer plaster base layers i are provided with ends in the form of a bracket .Ii 'on which the pressure distribution irons 41 are suspended by means of hook-shaped ends. The pressure distribution bars 4o, on the other hand, find their hold by means of bent ends in the concrete overlay.

The building structure, which the outer walls at right angles to the ceiling beams (see. Fig. 6), are provided with vertical reinforcement bars 42 and 43. the Reinforcing irons 42 of the outer plaster base layer i are above in the form of a bracket 42 'laterally out of the layer i and with a double bracket 44 the pressure distribution iron 40 connected. The vertical Artnierungseisen 43 have above also hook-shaped curved ends 43 ', which by a double bracket 45 are connected to your pressure distribution bar 40.

The wedging 35 of the building at their vertical abutting edges and the connection of the vertical reinforcements of the building of opposing walls by means of pressure distributing bars and brackets mounted in the concrete 39 of the ceilings achieve a particularly firm hold of the building.

The erection of a single wall plate of 250 X 70 ctn can be done by four men in 1/4 hour and corresponds to a brick tnatier of about 300 bricks and 2001 mortar.

In summary it can be said that a qualitative high-quality, well-insulating, pure concrete construction is created, which can be achieved with a quick construction time (3 months) is ready for occupancy immediately after completion and no moisture in the masonry having. In addition, individual construction is possible because of the size of the panels can be chosen variably. Furthermore, the construction described enables about 25 Percent cost savings on the masonry.

Claims (6)

PATENT ANSPHQCHE: i. Insulating concrete structure, characterized in that that it is formed from prefabricated panels, which consist of two outer, the load-bearing Part-forming concrete layers and a middle one, with the two outer layers connected insulating layer is formed, the plates are laid so that the insulating layer forms an uninterrupted, space-enclosing jacket and can move between the concrete layers. 2. insulating concrete structure according to claim i, characterized in that the two outer layers (1, 2) of the plates are reinforced Concrete layers are while the middle layer connected to the outer layers (3) consists of aerated concrete. 3. insulating concrete structure according to claim i, characterized characterized in that the panels used for the exterior and interior walls storey height have, the ceilings only on the inside concrete layer of the outer walls rest. 4. insulating concrete structure according to claim i, characterized in that in the case of the ceilings, the panels lie on longitudinal folds of the prefabricated concrete beams. 5. insulating concrete structure according to claim i, characterized in that the vertical Edges of the building structure (1, 2, 3) forming the outer and inner walls one from the top End to the lower end reaching longitudinal recess is attached so that between Every two plates a vertical channel (35) is created, which is connected with insulating concrete is poured out. 6. insulating concrete structure according to claim i, characterized in that that the outer plaster base layers (i) of the structure (1, 2, 3) with reinforcing iron (42) are provided, which at the top in the form of a bracket (41 ', 42') from the side Layer (i) protrude, partly by means of a connecting bracket (44) and partly directly pressure distributing bars (40, 41) cast in the concrete are connected. Insulating concrete structure according to claim 6, characterized in that the vertical reinforcing bars (43) the inner plaster base layer (2) of the panels (1, 2, 3) at their top from the layer (2) protruding ends bent bow-shaped and with a connecting bracket (45) are connected to the pressure distributing iron (40) cast in the concrete (8). B. insulating concrete structure according to claim 7, characterized in that the ceiling panels consist of a trough-shaped Concrete part (36) and a foam concrete filling (37) exist.