CS275989B6 - Reinforcing structure for increase of building floor construction load-carrying capacity - Google Patents

Abstract

The invention relates to a reinforcing structure for increasing the loadability of old-fashioned ceilings, said structure including supporting members beneath the ceiling to be reinforced. By means of the reinforcing structure, the loads on the ceiling, to be reinforced by supporting members, are taken over directly or indirectly and transferred to the vertical force-transfer parts of the building, e.g. to the walls. Beneath the ceiling to be reinforced, a cavity is formed in the vertical force-transfer part, which cavity is optionally lined with a bushing. The supporting member is formed by a bracket engaging in the cavity. Beneath the ceiling to be reinforced, load-bearing beams are accommodated which are supported by longitudinal beams, fitted onto said brackets, and/or adjustable insert pieces. An elastic-plastic compensating layer and/or, if appropriate, load-distributing beams are introduced between the ceiling to be reinforced and the load-bearing beams. If appropriate, a false ceiling with, for example, an anti-moisture function and/or an aesthetic function is fastened beneath the brackets.

Description

The invention relates to a reinforcing structure for increasing the load-bearing capacity of ceiling structures of buildings, consisting of main beams placed under the reinforced ceiling structure, brackets mounted at their outer ends in pockets formed below the main beams in opposite vertical masonry of buildings and longitudinal beams placed on brackets.

It is known that the load-bearing capacity of horizontal parts of buildings, such as ceilings, is substantially reduced, while the load-bearing capacity of vertical parts, such as walls, almost does not change. In such cases, I reinforce the ceiling structures. The reinforcement is usually carried out by supporting the brackets under the building structure to be reinforced by which they are supported by the load on the supporting columns and / or on the wall and on the wall.

I put the DC brackets into the pockets made by hand in the vertical masonry and they pour concrete in them. These solutions are very wasteful due to the high cost of manual work. The disadvantage is wet technology, namely the need to concret at the reinforcement site. The reinforcement works are hampered by the fact that in old buildings the walls are often not parallel, the ceilings and floors are not horizontal and the walls close at right angles to each other. As a result, standardized auxiliaries are generally used in the reinforcement work.

Among the known ceilings reinforcing ceilings are the most technically perfect ceilings whose. the basic idea is that, under the ceiling structures to be reinforced, the DC is built into the load-bearing walls of the load-carrying bracket on which the DC is laid by a portable system consisting of longitudinal beams and distribution beams. The beam system is pressed against the ceiling with inserts whose height is adjusted while taking over the load of the reinforced ceiling structure, which takes the bearing walls longer to the ground. The main advantage of this method is that the height adjustment and control bracket and all the elements used are prefabricated.

According to this, the DC bracket is fitted with a sleeve using a sealant and by means of height adjustment and height adjustment inserts into a pocket drilled in the vertical masonry.

This technique has numerous advantages, of which the object of the invention is to machine pockets and to prefabricate the elements used. The disadvantage of this technique is the difficult static calculation and practical construction of the brackets.

A further disadvantage of the present invention and of all known systems is that the bracket heavily loads the load-bearing masonry, which can withstand this load only when part of the bracket is properly secured in the masonry. As a result, the above-mentioned reinforcement is usually unsuitable for the reinforcement of high ceiling constructions, since the masonry is not able to bear the required load due to its small thickness.

A further disadvantage of the present solution is that, due to the relatively high load, the cross-section of the consoles must be very large. Due to the large cross-section of the brackets, the need for space for inserts for height adjustment and regulation, the sleeve and the sealant must have a pocket in the masonry greater than 100 mm in diameter, which is associated with difficulties. It is also unsuitable that the length of the pocket must be greater than 300 mm. Pocket length In addition to the torque balance requirements, it is necessary to determine both the load and the masonry quality and the housing diameter. On the one hand, according to the load-bearing capacity of the sleeve, since the load-carrying function depends on these factors. A disadvantage is also that after installation of the brackets, there is a free space between them and the other elements inserted in the pockets, in which moisture can accumulate, which can cause corrosion. This free space is also unfavorable in terms of thermal engineering.

It is an object of the present invention to overcome the shortcomings of the known reinforcement methods, secondly to reinforce the ceiling structures by standardized means with a dry and simple technology and with minimal need for manual work on the reinforcement site.

In view of the foregoing, it is an object of the invention to provide pockets in the masonry masonry and to allow for easy leveling of height differences between the pockets in order to accurately determine the load transfer point between the reinforced structure and the masonry to be loaded.

The reinforcing structure for increasing the load-bearing capacity of the ceiling construction of buildings is the main one

CS 275 989 B6 beams, placed under the reinforced ceiling structure, of brackets mounted with their outer ends in pockets formed under the main beams in vertical masonry and provided with sleeves as required, with longitudinal beams with inserts of different heights placed on the brackets. Optionally, spreading beams and / or a plastic leveling layer are supported by the main beams and the reinforced ceiling structure, and a soffit is optionally attached below the brackets.

The principle of the invention is that at least one adjustable control element, for example a tensioning screw, is inserted between the main beams and the brackets, fixed one end to the main beam, the other end to the brackets, the main beams being solid or trussed.

In a different plan view and / or at different pitches of the main beams and brackets, the control elements are fixed transversely to the main beams by means of the upper auxiliary beams and to the brackets by the lower auxiliary beams.

With the same ground plan and / or spacing of the main beams and brackets The control elements are fixed vertically and directly to the main beams and brackets.

In the main truss girders, the control elements are fastened by their upper ends to any location of the upper strips and by their lower ends under the brackets.

In the main lattice girders, the control elements are attached to the upper lattice girder bar by means of the upper sub-girder and to the brackets by the lower sub-girders fixed below the brackets and connected by other adjusting elements to the lower lattice girders.

In the main trusses, the control elements are replaced by their diagonal rods.

The reinforcing structure according to the invention has numerous advantages. The box of advantages consists, for example, in the fact that by connecting the main beams to the brackets by means of the control elements, the reinforcing structure is not sensitive to the inaccuracies of the brackets. As these inaccuracies can be compensated by the control elements. There is therefore no need for height adjustment means, height control means located in the housings and housings. Tim It is possible to attach the brackets directly and without mastic in the pockets only by friction, thus avoiding concrete pouring at the reinforcement point and all the associated difficulties.

The advantage is also that the brackets of the reinforcing structures can extend into the masonry or only 50 to 80 mm, so that there is no need to cut the chimney shafts.

A further advantage is that, in contrast to the prior art, the brackets of the reinforcing structures are flexible due to the use of the control elements, so that they can be manufactured with a smaller cross-section, usually of round steel diameter of 32 to 40 mm. Therefore, there is no need for a special tool to drill the pocket, but can be done with conventional drills.

The fact that the load of the reinforced structure is transferred to the brackets of the reinforced structures by means of auxiliary beams is not due to the use of control elements a reinforced structure sensitive to the geometric inaccuracies of the repaired building.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in more detail with reference to the drawings, in which FIG. 1 shows an embodiment of a reinforcing structure with solid main beams and FIG. 2 shows the same reinforcing structure 9 of a truss.

In Fig. 1, the structure to be repaired is a ceiling structure J, which is shown by 9ém of a masonry that surrounds it as a vertical load-bearing structure 2 for transmitting forces vertically. The inner walls of the pockets 3 are in direct contact with the surface of the brackets 6. The tubular sleeve 4 is used only in special cases, for example masonry in a very poor condition, since Due to the low load-bearing capacity of the vertical load-bearing structure 2, the surface of the load-bearing bracket 6 needs to be increased by the sleeve 4. The surface of the pockets 3 is mostly frictional in contact with the surface of the sleeve 4 or bracket 6. Layer of sealant 5 is used only in exceptional cases

CS 275 989 B6, for example, when the masonry is weakened by the chimney shaft or when, due to porosity, the masonry is used between the chimney shaft and the pocket 3, a sealant 5 is used to prevent flue gases from entering.

Between the brackets 6 and the full-length main beams 10, according to FIG. 1, adjustable control elements 104 are inserted, which may be, for example, tensioning screws. The control elements 104 are fixed at one end to the brackets 6, while the other end to the solid-walled main beams 10, 3a, but auxiliary elements can also be used. Oako auxiliary elements are used on the upper auxiliary beams 7, the lower auxiliary beams 8, the longitudinal beams 9 and the distribution beams 12, which are supported on the main beams 10. The brackets 6, solid-walled main beams 10 or the auxiliary elements are connected .

Spatial load-bearing structure In known embodiments, it is pressed by inserts 11 of different heights at the attachment points of the elements used on the reinforced ceiling structure.

According to the invention, this function is taken over by the control elements 104, but longitudinal beams 9 can also be used outside the control elements 104. According to the circumstances, it is expedient to insert a plastic alignment layer 13 between the reinforced structure and the reinforcing structure.

If the entire reinforcement structure is to be covered from below, the soffit 14 can be suspended below the reinforcement structure.

In FIG. 2, the main girder 10, which is solid-walled in FIG. 1, is replaced by a main girder 10. In this main truss 10, the top web 101, the bottom web 102 and the diagonal rods 103 may be different. The control element 104 can be placed at any point in the strips 101, 102 or can replace any diagonal beam 103. The main truss 10 facilitates the assembly of the soffit 14.

The control element 104 is attached to the upper strip 101 and the brackets 6 either at the main beam 10 and to the brackets 6 either directly or by means of the upper auxiliary beams 7 and the lower beams 8. In this embodiment, the lower auxiliary beam is mounted on the underside of the bracket 6 of another control element, the lower belt 102.

It can be seen from FIGS. 1 and 2 that if the auxiliary beams 7, 8 and the longitudinal beams 9 are omitted, the reinforcing structure changes into a spatial supporting structure, in which the connection between the brackets 6 and the main beams 10 is fully or trussed. In this case, it is expedient to try to achieve a plan-symmetrical arrangement, for example by arranging the main beam 10 against two opposing brackets 6 or by placing the main beam 10 in position. in the middle between two adjacent brackets 6, thereby preventing the introduction of torque.

At different plan views and / or different spacing of the main beams 10 'and the brackets 6, the control elements 104 are fixed across the main beams 10 via the upper auxiliary beams 7 and to the brackets 6 via the lower auxiliary beams O.

With the same ground plan and / or spacing of the main beams 10 and brackets 6, the control elements 104 are mounted vertically and directly to the main beams 10 and brackets 6.

This embodiment is not shown in the drawings.

The assembly of the reinforcing structure begins with the marking and drilling of the pockets 3 in the vertical load-bearing structure 2. The pockets 3 are fitted with brackets S, the outer ends of which are provided with bushings 4, if necessary.

The control elements 104 are fastened to the brackets 6 directly or by means of the lower auxiliary beams 8, to the main beams 10 the control elements 104 are fixed by means of the upper auxiliary beams 7. Between the main beams 10 and the brackets 6 I, whose both belts are fitted with inserts 11 of different thicknesses.

On the main beams 10, spreading beams 12 and a leveling layer CS 275 909 BS and 13 are laid, as the case may be. Thereafter, the assembled elements are pressed down from below by means of control elements 104 or inserts 11 of different heights. the bottom surface of the reinforced ceiling con ..

In the case of the trusses, further control elements 104 are fastened and connected by means of a fixed force of the bracket 6 to the main trusses 10. After the possible installation of the soffit 14, work is finished.

reinforcing structure according to the invention It is suitable for increasing the load-bearing capacity of all types of ceiling structures irrespective of their construction.

Claims (6)

1. A reinforcing structure for increasing the load-bearing capacity of a building's ceiling structure, consisting of main beams placed under the reinforced ceiling structure, and brackets mounted at their outer ends in pockets formed below the main beams in opposite vertical masonry and provided with bushings as required. with supporting heights of different heights, between the main beams and the reinforced ceiling structure Distribution beams and / or a plastic leveling layer are optionally provided and a soffit is optionally attached below the brackets, characterized in that at least between the main beams (10) and the brackets (6) one adjustable control element (104), for example a tensioner bolt, fixed by one end to the main beams (10) and the other end to the brackets (Q). 2. Reinforcing structure according to claim 1, characterized in that the control elements (104) are fixed transversely to the main beams (10) by means of upper planes and / or at different pitches of the main beams (10) and the brackets (6). the auxiliary beams (7) and the brackets (6) by means of the auxiliary beams (8). 3. A reinforcing structure according to claim 1, characterized in that at the same ground plan and / or at the same spacing of the main beams (10) and the brackets (6), the control elements (104) are attached directly to the main beams (10) and the brackets (10). 5). 4. Reinforcing structure according to claim 1, characterized in that in the main trusses (10) the control elements (104) are fastened at their upper ends at any point of the upper strips (101) and at their lower ends under the brackets (6). 5. Reinforcing structure according to claim 1, characterized in that in the main trusses (10) the trusses (104) are attached to the upper strip (101) of the main trusses (10) by means of the upper auxiliary trusses (7) and the brackets (10). 6) by means of lower auxiliary beams (8) mounted under the brackets (6) and connected by means of other control elements (104) to the lower strips (102) of the main trusses (10). 6. Reinforcing structure according to claim 1, characterized in that in the main trusses (10) the diagonal bars (103) are adjustable by the control elements (104).