RU2471943C2 - Method to reinforce stone floor vaults of building - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method of reinforcement consists in changing of vault geometry by means of its lifting to rated working position by means of a sliding curb. At the borders of flattened sections, through transverse cuts are arranged, where segments are installed of a split beam of the sliding curb. Segments are hingedly connected in the lower part as capable of rotation in the vertical plane relative to each other. In the upper part segments are connected between each other by flexible cables. Under each slot in the area of the vault bearings there are supports installed, which have sliding support sites. The split beam is rested onto support sites. After installation of two and more beams decking is arranged between them. Ends of the split beam are connected to each other by means of a cable, in the middle of which there is a traction jack installed. By means of the jack, span length is reduced, and the vault is raised.

EFFECT: higher efficiency of process works for reinforcement.

6 cl, 3 dwg

Description

The method of reinforcing stone vaulted floors of a building relates to the field of construction and can be used to strengthen, reconstruct and dismantle stone vaulted floors of buildings.

There is a way to strengthen the floors of buildings with load-bearing beams supported on walls, and self-supporting or non-bearing arches. This method is performed by means of reinforced concrete reinforcing elements placed on both sides of the beam and connected to it by means of stops installed on the lower edge of the beam. The working reinforcement of the reinforced concrete element is made prestressed in the form of truss ties, fixed at the ends on the outer surface of the walls with the possibility of voltage regulation. Holes were made in the thickness of the arch for the passage of rod anchors equipped with tensioning devices and grips. In this case, the working reinforcement is connected through sliding ties with rod anchors, or with stops and anchors (RF Patent N 2036290 IPC E04G 23/00, 1995).

The disadvantage of this method is that the load on the foundation increases from the dead weight of the floor, because the thickness of the vaulted ceiling increases significantly. Another disadvantage is the inability to replace individual sections of the masonry vault.

Also known is a method of reinforcing a vaulted ceiling of a building, including a reinforcing reinforced concrete element supported on walls, and radial bar anchors passed through openings made in the vault (Methodical recommendations of the All-Union Scientific-Industrial-Commercial Organization “Soyuzrestavratsiya.” Ministry of Culture of the USSR, M., 1989, p. 164).

The disadvantage of this method is an increase in the load on the reinforced arch during work, which causes an increase in the horizontal spread transmitted to the walls, and can lead to collapse of the ceilings, i.e. requires additional measures to temporarily reinforce the structural elements.

The prototype of the invention for changing the geometry of the arch or its "extrusion" to the top to the calculated working position is the use of retractable formwork - the so-called umbrella. Under pressure from below, the masonry elements are moved apart, forming temporarily completely uncompressed masonry sections held on the formwork. Next, uniform caulking is performed with a solution of open joints and cracks, and the formwork is removed (Restoration of architectural monuments: Textbook for universities / S.S. Podyapolsky, G. B. Bessonov, L. A. Belyaev, T. M. Postnikova; under the general Edited by S.S. Podyapolsky. - M., Stroyizdat, 1988 .-- 264. p .: ill.).

The disadvantage of this method is the uneven application of load during the initial work on lifting the umbrella. The load is primarily applied to the husk, and when it reaches a significant rise, it passes to the heels of the arch. Such an initially uneven application of the load on the arch leads to the separation of the elementary arch of the arch in the region of the husk into two consoles emerging from the walls. The strength of such consoles due to the “monolithic” structure of the masonry can lead to their separation from the walls of the building, while forming longitudinal cracks on the lower surface of the arch in the heel area. Based on this, it can be assumed that this method of "extrusion" to the top to the calculated working position using sliding formwork is appropriate for plastic masonry (weak mortar, barren) and in the absence of any load on the arch. Also, one of the disadvantages is the fact that this method should be applied to the entire arch as a whole, regardless of the existing flattening areas, while the arch should not have transverse thickenings of masonry, such as ribs or herds. The umbrella can be assembled directly in the room, which increases the time for construction and installation work, while there are inconveniences of parallel work. This umbrella can be applied only once, after completion of work it is completely disassembled.

The proposed method is aimed at improving the efficiency of technological work to strengthen the stone vaulted floors of the building during their flattening, sagging and wave-like deformation.

The result is achieved in that in the method of reinforcing stone vaulted floors of a building during their flattening, sagging and wave-like deformation, consisting in changing the geometry of the arch by raising it to the calculated working position by means of the sliding formwork, according to the invention, through transverse sections are made along the boundaries of the laid sections, in which establish the segments of the split beam retractable formwork, while the segments are pivotally connected in the lower part with the possibility of rotation in a vertical plane and relative to each other and are interconnected by flexible cables in the upper part, under each cut in the area of the toes of the arch, supports are installed that have sliding support platforms on which the split beam is supported, after installing two or more beams, they arrange a floor between them, the ends of the split beam are connected between themselves by a cable, in the middle of which a traction jack is installed, by means of which a reduction in the length of the span and, accordingly, the rise of the arch are made.

The result is also achieved by the fact that the rise to the calculated working position of the stone vaulted floor is done in sections, or only in local hanging sections of the vault, without the need for a general rise of the vault.

The result is also achieved by the fact that the elements of the sliding formwork are reused.

The result is also achieved by the fact that in the process of lifting the arch control deformations and make adjustments to change the curvature of the arch.

The invention is illustrated in the drawings: figure 1 - vaulted overlap with the device in a cross section BB in figure 3; figure 2 - section aa in figure 1; figure 3 - view a in figure 1.

A device for changing the geometry of a stone vaulted floor of a building includes a split beam 1, consisting of separate segments 2, interconnected at two points: from the bottom by a hinge 3, providing mutual rotation of the segments of the beam 1 relative to each other in a vertical plane, from above the segments 1 have two ends loops 4, loops of two adjacent segments are mutually connected by a flexible cable 5 of the estimated length. Segments 2 of the beam 1 in the section have a T-section (in the intermediate beam) or a corner (in the extreme beam) section. The beam segment consists of the wall 6 and the lower shelf 7. On the shelf 7 of the beam 1, a flooring 8 is arranged, bearing the weight of the masonry of the arch 9 when it is lifted. The ends of the split beam 1 are supported on the sliding platforms of the support 10, the supports 10 are anchored directly into the wall 11, or they have their own racks that transfer the load from the weight of the arch directly to the base. The ends of the split beam 1 lying on the supports 10 are connected to the towing jack 12 via cables 13. To install the split beam 1 in the arch, cross sections 14 are made in the region of the jaw walls 15. The arch must accept the correct curvature 16.

Strengthening the overlap is as follows.

In the case of flattening of the stone vaulted ceiling along the entire length, through transverse sections 14 are made in the region of the jaw walls 15 and between them, if the arch length exceeds the calculated flooring length. In the case of flattening of separate zones of stone vaulted floors, this laid-out zone 9 is separated from the rest of the arch of regular curvature 16 by a through cross section of the arch along the borders of the laid-out area. Thus, the method allows you to lift to the calculated working position of the stone vaulted floors in sections, or only local hanging sections of the vault, while there is no need for a general rise of the vault. Under each cut 14, supports 10 are installed in the area of the arch heels. Supports 10 are anchored into walls 11, or they have separate racks that transfer the load directly to the base of the building. The supports 10 have an inclined sliding support platform. In the performed cut 14, segments 2 of the split beam 1 are installed, which are connected to each other from below using loops 3, leaving a gap between the lower shelf of the beam 7 and the lower surface of the roof equal to the height of the floor 8. The split beam 1 connected from the segments 2 is supported on the supports 10. The hinges 17, made at the ends of the split beam 1, are connected to the traction jack 12 using steel cables 13. After installing at least two split beams 1 according to the sequence described above, the flooring is arranged between them 8. The flooring 8 is laid on the lower shelf at beam 7 into the gap left in advance between the lower surface of the arch and the shelf of the beam 7. Lastly, the upper loops 4 of the segments 2 of the beam 1 are connected with flexible cables 5 of the calculated length, in order to limit the flexibility of the lower hinge of segments 3 during the process of lifting the arch. After all the elements are installed, the lower cables 13 are gradually tensioned by the jack 12. The tension is transmitted to the ends of the split beam 1, and the span length decreases, as a result of which the arch rise height begins to increase. The tension of the cables 13 with a jack 12 is carried out until the last of the cables 5 is fully tensioned. From the pressure from the bottom of the split beam 1, the masonry elements 9 are moved apart, forming temporarily completely uncompressed masonry sections held on the floor 8. The caulking is uniform with a solution of open joints and cracks in the masonry of the arch. Upon reaching the strength of the injected solution, the device is disassembled.

The application of this method to raise the vaulted floor allows, when performing work, first of all, to apply a uniformly distributed load on the hanging sections of the vaulted floor.

Claims (6)

1. A method of reinforcing stone vaulted ceilings of a building during their flattening, sagging and wave-like deformation, which consists in changing the geometry of the arch by lifting it to the calculated working position by means of a sliding formwork, characterized in that through the boundaries of the laid sections, through cross sections are made into which the segments are installed split beam retractable formwork, while the segments are pivotally connected in the lower part with the possibility of rotation in a vertical plane relative to each other and connected they are fused with each other with flexible cables in the upper part, under each cut in the area of the toes of the arch, supports are installed that have sliding support platforms on which the split beam is supported, after installing two or more beams, they arrange the flooring between them, the ends of the split beam are connected by a cable, in the middle of which a traction jack is installed, by means of which a reduction in the length of the span and, accordingly, the rise of the arch are made. 2. The method according to claim 1, characterized in that the segments of the intermediate split beams perform T-sections, extreme - corner section. 3. The method according to claim 1, characterized in that the rise to the calculated working position of the stone vaulted floor is made in sections or only in local hanging sections of the arch. 4. The method according to claim 1, characterized in that the elements of the sliding formwork are reused. 5. The method according to claim 1, characterized in that in the process of lifting the arch control deformations and make adjustments to change the curvature of the arch. 6. The method according to claim 1, characterized in that the sliding formwork is used when dismantling stone cylindrical arches.

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