RU2196868C2 - Process of reinforcement of stone structures of building - Google Patents

Abstract

FIELD: construction industry. SUBSTANCE: process of reinforcement of stone structures of buildings includes installation of unloading members in the form of wooden supports with thrust facility which ensures specified degree of unloading of building walls. Sectional wooden supports are placed on internal and external sides of building and intercoupled with the help of coupling bolts passing through holes of walls. Then supports are joined with horizontal members to form frame protected against inflammation and guarding net is attached to them. Coupling bolts are spaced by distance that not exceeds maximum permissible value established by calculation and continuous horizontal members of frame are produced from wooden bars or boards of purlins and are placed on one or both sides of building wall. Guarding plates are positioned in thrust between supports to form vertical braces and horizontal braces come in the form of longitudinal, lateral and crossing tension bars placed at level of ceiling or covering of building and are attached to supports with tension. EFFECT: raised functional reliability of walls, provision for stability of damaged stone structures. 33 cl, 25 dwg

Description

 The invention relates to construction and can be used to increase the strength and stability of structures of an existing building with damaged masonry.

 During the operation of the building, various types of damage to the stone wall structures are observed, which reduce the operational reliability of the building as a whole or its individual parts. Strong damages to stone structures include wall collapses, thawing and weathering of masonry to a depth of 0.25-0.50 wall thickness, cracks in bearing walls to a height of 4-8 masonry rows, wall expansion within the floor by 0.15-0, 30 of their thicknesses, masonry damage over supports of girders and lintels in the form of crushing stone, displacement of floor slabs on supports of more than 0.20 of the wall embedment depth, thermal damage to masonry of walls during a fire to a depth of 2-6 cm. To ensure sufficient strength and stability of the building and its safe features operation produce reinforcement of damaged structures. In an operating building, stone structures having damage of varying severity are repaired, as a rule, without dismantling the supporting structures.

A known method of reinforcing structures and rebuilding a building with partially collapsed parts. With this method, the strengthening of the collapse zones is carried out elementwise by installing a formwork along the perimeter of the collapse zone and supplying a porous solution to it. The specified solution is poured in layers, in layers of not more than 0.5 m per day. Each subsequent layer is poured after a set of previous certain strength. Work on the filling of the solution is carried out at an ambient temperature of not lower than + 10 ^o C. Clearing the damaged structure is carried out alternately to the height of the next layer of the solution. After the final restoration of each zone of the building, they proceed to clearing and strengthening the next one (see AS USSR 949136, MKI 3, E 04 G 23/00. A way to restore a building with partially collapsed structures. Publish. 07.08.82. Bull. 29 [ 1] ).

The reasons that impede the achievement of the technical result indicated below when using the known method include the fact that in the known method, the elementwise reinforcement of damaged structures increases the restoration time of the building, the use of formwork complicates the reinforcement structure and makes it more expensive, carrying out work in cold and transitional periods of the year at a temperature below +10 ^o C leads to the need for the device structures in the area Teplyakov recovery, the volume reconstruction limited bed height room Application porizovannogo solution of 0.5 m / day .; as a result of this increase labor costs and increase the cost of work.

 A known method of reinforcing brick walls, including the device of reinforced concrete beam belts along the contour of stone structures at the level of the floor, before the device of the beam belts in the walls of the building at the level of overlap, shtabs are performed, and the beam belts are placed on one or both sides and connected to the walls with jumpers, passing them through shtrabs (see A. S. of the USSR 918408, MKI 3 E 04 G 23/00. A method of reinforcing brick walls. Publish. 07.04.82. Bull. 13 [2]).

 The reasons that impede the achievement of the following technical result when using the known method include the fact that in the known method a bulky and heavy reinforcement structure is used in the form of an reinforced concrete beam belt along the wall contour; in brick walls, on one or both sides of the building, laborious work is done to make the slabs at a height - at the level of overlap, the device of the slabs in the stone structures of the building reduces the strength and stability of damaged walls, and installing heavy beam belts in the slabs is not technologically advanced and dangerous for workers. The known method is recommended mainly for buildings located outside the seismological area, their reinforcement of stone structures is irrational and non-technological.

 The closest technical solution to the invention in terms of features is a method of reinforcing stone structures of a building, which includes strengthening and unloading from the weight of the floor or covering damaged walls of the building with wooden racks; with this reinforcement method, the wall is installed with wooden racks and linings for the floor element, and the wedges and the bed are placed on the base, then the wedges are knocked to fit the ends of the rack more tightly to the lining and the bed and this includes the rack in work (see Recommendations for strengthening stone structures of buildings and constructions. - Moscow: Stroyizdat, 1984, pp. 19-20, paragraphs 2.32 and 2.33, Fig. 5 [3]).

 This technical solution is taken as a prototype.

 For reasons that impede the achievement of the technical result indicated below when using the known method adopted as a prototype, the known method uses wooden racks operating in compression with large cross-sectional dimensions due to the articulation of the ends and the danger of loss of stability of the compressed element from the load , in the known method it is impossible to control the degree of unloading of the damaged masonry, and the reinforcement design is used as a temporary fastening on p The period of disassembling the old and performing a new masonry of the wall; the use of local strengthening of the walls does not ensure the stability of damaged walls and the spatial immutability of the building as a whole; the installation of wooden reinforcement structures with a gap from the walls reduces the working space in the room, increases the fire hazard of structures and restoration work by increasing the combustible load of the building.

 The invention consists in the following.

 The problem to which the claimed invention is directed, is to increase the operational reliability of the building and the cost-effectiveness of the method of strengthening its stone structures.

The technical result is an increase in the operational reliability of the walls, ensuring the spatial immutability of the building and the stability of damaged stone structures;
rational and safe reinforcement of a stone building with light, for example, wooden structures;
the ability to control the degree of unloading of the damaged wall;
decrease in material consumption gain;
reduction of costs for the purchase of building materials, manufacturing and installation of reinforcing elements, reducing the time of construction of reinforcement;
increase in indicators of profitability and durability, decrease in indicators of flammability of wooden reinforcement elements.

 The specified technical result in the implementation of the invention is achieved by the fact that in the known method of reinforcing stone structures of a building, including the installation of unloading elements, for example, propped racks, the reinforcement is performed in the form of a frame of vertical and horizontal rod elements, vertical elements are made in the form of rods located along at least on one side of the wall of the building, and are connected together by tie bolts passing through the through holes in the wall, then the vertical elements the frame is connected to horizontal and the enclosing mesh is attached to them, the vertical elements of the frame are made in the form of composite wooden racks with a spacer device that provides a given degree of unloading of the building wall, the tension bolts of the vertical elements are located at a distance of no more than the maximum permissible value, which is determined by calculation , horizontal elements of the frame are made continuous from wooden beams or planks and installed on one or both sides of the wall of the building, vertical The horizontal and horizontal elements of the fire-protected frame are interconnected with the formation of a vertical stiffness bond and a fencing grid, which is located in the wall plane, horizontal stiffness ties of the building structures are made in the form of elements attached with tension to the posts of the reinforcement frame.

 A distinctive feature of the invention is that the composite rack is made of two wooden beams, logs or boards, installing them respectively from the inside and / or outside of the wall of the building, connecting them with tension bolts. The installation of beams or logs on both sides of the wall involves, as a rule, the installation of guard panels on both sides of the wall of the building.

 In the case of installing a guard shield on one side of the wall, a composite stand is made of structural wood on one side and a metal patch belt, for example a strip or channel, on the other side of the building, connecting its elements with bolts.

 In the absence of severe damage to the masonry walls, the composite stand is made of beams, logs or boards, attaching them to the wall of the building with tension bolts.

 The number of tension bolts on one uncut element of an integral rack is used at least two.

 The reinforcement cage is made up of at least two racks, connecting them in the plane of the wall with girders, guard shields or stiffeners.

 In addition, the features of the method of reinforcing stone structures of a building are that the cross-sectional dimensions of each branch of a composite stand are taken structurally or by design.

 In the case when the dimensions of the cross section of the supporting branch of the composite stand are taken as calculated, the compression force is taken depending on the condition of the full or partial unloading of the stone wall.

 The supporting branches of the composite stand for the elements of the coating or floor of the building are set by surprise.

 At the same time, the supporting branch of the composite rack is loaded by turning on a spacer device, for example wedges. A support table for a spacer is provided at one of the ends of the support branch of the rack or at any height thereof.

 In the absence of load from the weight of the coating on the brick wall in the reinforcement cage, composite racks with unloaded branches, that is, patch belts, are used.

 If it is necessary to perceive only a concentrated load, for example, from a rafter beam, the reinforcement is carried out by a separate composite rack, including it in the work with spacers.

 The following differences of the proposed technical solution are that the horizontal element of the reinforcement cage is presented as a vertical connection of the building stiffness and is made in the form of a wooden continuous girder or plank board of the fence, setting it in opposition to the racks of the frame.

 The board shield is performed as a spacer element of the vertical connection of rigidity and or fencing of the damaged part of the wall of the building. In this case, the board shield is solid or sparse.

 The distance between the longitudinal ribs of the sparse plank shield of the fence is no more than the thickness of the brick or stone of the damaged wall, for example, no more than 65 mm when masonry is made of ordinary clay brick.

 To reduce the fire hazard of the board shield, the gaps between the longitudinal ribs are filled with non-combustible material, such as concrete or mortar. In this case, the board shield fencing is installed close to the wall of the building; if it is necessary to increase the bearing capacity or thermal insulation of the damaged wall of the building between the wall and the shield, a gap is provided for the reinforcement material of the wall or insulation.

 Depending on the severity of the wall damage, spacer shields of the fence are installed on one or two sides of the damaged section of the building wall.

где L_max - наибольшая длина участка опорной ветви стойки усиления между болтами, см;
λ_max - предельная гибкость элемента строительной конструкции; см. табл. 14 СНиП II.25-80 "Деревянные конструкции". - М., 1983;
К_mp=0,3-1,0 - коэффициент снижения несущей способности каменной кладки в зависимости от степени ее повреждения (см табл. 1-3 "Рекомендации по усилению каменных конструкций зданий и сооружений". - M., 1994 [1]);
М = 0,65-2,2 - коэффициент условий закрепления концов участка опорной ветви стойки; см. п. 4.21,СНиП II 25-80;
J - момент инерции поперечного сечения опорных и не опорных ветвей составной опоры, см⁴;
А - площадь поперечною сечения опорной ветви cocтaвной стойки, см².The maximum allowable length of the sections of the supporting branch of the composite rack between the coupling bolts is determined by the formula (1):

where L _max is the longest length of the section of the supporting branch of the reinforcement post between the bolts, cm;
λ _max - ultimate flexibility of a building structure element; see table 14 SNiP II.25-80 "Wooden structures". - M., 1983;
To _mp = 0.3-1.0 is the coefficient of decrease in the bearing capacity of masonry depending on the degree of damage (see table 1-3 "Recommendations for strengthening the stone structures of buildings and structures." - M., 1994 [1]) ;
M = 0.65-2.2 - coefficient of conditions for fixing the ends of the section of the supporting branch of the rack; see paragraph 4.21, SNiP II 25-80;
J is the moment of inertia of the cross section of the support and non-support branches of the composite support, cm ⁴ ;
A is the cross-sectional area of the supporting branch of the support rack, cm ² .

где С - суммарное силовое перемещение элементов опорной ветви стойки, например, нагруженной ветви стойки, подкладки, клиньев, см;
Р - нагрузка на опорную ветвь стойки, кН;
L_i - длина i-го сжатого элемента опорной ветви, см;
A_i - площадь сжатия i-гo элемента опорной ветви, см²;
E_i - модули упругости древесины вдоль и поперек волокон, МПа;
n - число элементов опорной ветви стойки усиления.To determine the required lifting height of the wedge-shaped extension device, the value of C. see the supporting branch of the composite rack from the load, with a given degree of unloading the brick wall, is determined by the formula (2):

where C is the total force displacement of the elements of the support branch of the rack, for example, the loaded branch of the rack, lining, wedges, cm;
P is the load on the support branch of the rack, kN;
L _i - the length of the i-th compressed element of the supporting branch, cm;
A _i is the compression area of the i-th element of the supporting branch, cm ² ;
E _i - elastic moduli of wood along and across the fibers, MPa;
n is the number of elements of the supporting branch of the reinforcement rack.

 The draft of the supporting branch of a given value C, cm, is selected by the wedges of the spacer, on the front surface of which mark lines or risks are applied.

 Marking lines are presented on a lighthouse made on mm-paper, sticking a lighthouse on installed wedges and cutting it at the point where the wedges join together before they are included in the work, i.e., wedging.

 To prevent individual bricks from falling out of the damaged wall sections and increase the stability of the building, a fencing grid is included in the structural scheme of the reinforcement cage, making it in the form of a wooden board.

 The board shield of the fence is made of a prefabricated span equal to the distance between the edges of the racks of the reinforcement cage.

 When installing a proppant to the lower end of the reinforcement rack, the through holes in the wall and in the supporting branch for passing the coupling bolts are oval with a gap D, cm, while the gap size should be no less than twice the required settlement of the loaded support, i.e.: D ≥ 2 C , cm.

 In the proposed invention, the spatial immutability of the stone structures of the restored building is ensured by vertical and horizontal ties of the reinforcement framework stiffness.

 The vertical connection is taken in the form of a hard disk, composing it from the racks of the reinforcement cage and the shield shields, which set in opposition between the racks.

 Horizontal communication is performed in the form of longitudinal transverse and intersecting strands, setting them at the level of overlap or coating of the building.

 The horizontal elements of the frame - girders and / or shields of the fence - are installed to the wall of the building with a gap, forming it by laying horizontal elements on the racks of the frame.

 To increase the bearing capacity and reduce wood consumption, horizontal frame elements made of continuous boards or beams are installed close to the wall of the building and pressed against it by the branches of the frame racks using tensioned bolts.

 To prevent rotting of the wood of the end parts of the support branch of the composite reinforcement posts, the latter are equipped with metal end plates and waterproofing.

 To reduce the fire hazard indicators of the reconstructed building structures, the elements of the reinforcement cage, that is, racks, wedges, girders and board shields, are coated with fire-retardant material, for example, with shingles, b 2 cm thick.

 To limit the spread of fire through the voids of the reinforcement structure, the space between the voids of the rarefied board shield of the reinforcement cage is filled with light non-combustible material, for example, foam concrete, expanded clay concrete or mineral wool wrapped in plastic film.

 To reduce the proportion of the perimeter of the cross section of a wooden beam - a run heated under fire conditions - runs of a sparse shield of the reinforcing frame fence are made in the form of bars or boards, placing them with the edge towards the heated surface of the structure in fire conditions.

 To reduce labor costs on the fire protection device of wooden elements of the reinforcement cage, large-sized sheets of fire-retardant lining are applied to their open side surfaces, for example, gypsum plasterboards in 1 or more layers with a thickness of at least 1.4 cm each.

 To reduce the cost of building materials and save cement on the fire retardant coating of the surfaces of wooden reinforcing elements installed in places that are adequately protected from moisture, a heavy mortar for plaster is made of crumpled greasy clay, sandblasted, with the composition in the following ratio of components in the dry mixture, by weight. %: oily clay 15-20, ordinary natural sand 80-85, and a solution of a thickness of at least 2 cm is applied to the cement surface protected from fire.

 When using clay of medium fat content for plaster, a solution of the composition is prepared, by weight. %: clay of medium fat content 25-30, natural sand ordinary 70-75.

 When using lean clay for plastering, a solution of the composition is made, in wt.%: Lean clay 30-40, natural sand 60-70.

 To increase the water resistance of the clay mortar for plaster, lime (5-10%) is added to the clay and a solution of the composition is prepared, in wt.%: Oily clay 14-18, slaked lime 1-2, natural sand 80-85.

 To obtain light, moderately combustible plaster, a clay mortar is prepared, by weight%: clay, fat or lean 50-60, organic light aggregate 40-50, - in the form of light shavings, straw, tow, fires, sawdust - in a plastic state the solution is applied to the surface of wooden reinforcing elements with a thickness of 3-5 cm, receiving after hardening a light, moderately combustible plaster.

 To increase the heat-insulating and fire-retardant properties of lime plaster, light natural or artificial sand, for example, ground slag, pumice, tripoli, tuff, coal, is added to the binder component of the mortar — lime — a light solution of the composition is made, in wt.%; slaked lime 20, tripoli 5-10, coal fines 70-75, and a solution with low thermal conductivity 3-5 cm thick is applied to the wooden elements.

 Drinking water is used to mix mortar mixtures.

To determine the composition of the solutions, materials with a density of g / cm ^{3 were used} : fat clay 13-1.4, clay of medium fat content 1.45-1.5, skinny clay 1.55-1.6, lime 1.4 - cement 1, 2-1.3, ordinary natural sand 1.4-1.6, tripoli 0.4-0.5, coal fines 1.2-1.4 g / cm ³ .

Therefore, the use of the proposed device for strengthening the stone structures of the building provides:
1) increasing operational reliability, that is, bearing capacity, fire resistance and durability of damaged building structures;
2) the spatial immutability of the restored building and the stability of damaged wall structures;
3) rational and safe reinforcement of stone structures due to: the use of composite pre-loaded struts of the reinforcement cage and the production of a complex stone-wooden structure, the use of wooden shingles instead of a metal mesh to fix fire-retardant material to the reinforcing elements, the use of tension bolts along the height of the reinforcements in increments, admissible from the condition of stability of the compressed elements, control control over the magnitude of the loading of the reinforcement racks;
4) multifunctionality of reinforcing elements, including an increase in the bearing capacity of stone structures; ensuring spatial rigidity of the damaged building; the possibility of building a multi-layer wall structure that increases its heat-insulating properties, preventing the loss of individual stones from damaged masonry by installing a protective shield - a hard drive of the reinforcement cage;
5) reduction of metal consumption and mass of reinforcing elements due to the replacement of reinforcing steel and heavy concrete with wood; reducing the complexity of work to strengthen stone structures in a building site; reduction of building restoration time and materials costs, installation of reinforcing elements and transportation; an increase in durability and a decrease in the flammability of reinforcing elements by constructive protection of wood from decay and fire;
6) cement savings: the use of lime instead of cement in a mortar for plastering 1 m ^{2 of a} surface with a thickness of 5 cm reduces its bulk density from 10 to 5 kg / m ² , that is, 2 times, since the mass, for example, of cement-perlite stucco makes 1000 kg / m ³ , and calcareous perlite 500 kg / m ³ . The price of lime mortar is 1.6 times lower than cement, since C _c / C _and = 270/170 = 1.6, where C _c , C _and - respectively the price of 1 ton of cement and lime, rub. The use of clay instead of cement reduces the price of plaster by more than 10 times, because C _c / C _g = 270/25 = 10.8, where C _c , C _g - respectively the price of 1 ton of cement and clay, rub. The saving of Portland cement in 1 m ^{3 of} cement mortar is 0.7 m ³ , i.e. 1,5t • 270 rub. = 405 rub / t.

 The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed invention, allowed to establish that the applicant did not find a source characterized by features identical to all existing features of the claimed invention. The definition from the list of identified analogues of the prototype as closer in the totality of the features of the analogue allowed us to establish a set of essential distinguishing features in relation to the technical result arranged by the applicant in the claimed device set forth in the claims. Therefore, the claimed invention meets the condition of novelty.

 To verify the compliance of the claimed invention with the condition of the inventive step, the applicant conducted an additional search for known solutions in order to identify signs that match the distinctive features of the claimed device from the prototype.

 The search results showed that the claimed invention does not follow explicitly from the prior art for the specialist, since the influence of the transformations provided for by the essential features of the claimed invention is not revealed from the prior art determined by the applicant to achieve a technical result.

 The described invention is not based on a change in quantitative characteristics in the relationship or a change in its form. Therefore, the claimed invention meets the condition of inventive step.

 In FIG. 1 shows the facade of the end wall of a single-story brick building with openings and the location on it of wooden racks, girders and shields of the fencing of the reinforcement device.

 In FIG. 2 - a longitudinal section of a fragment of the wall of the building, - a view from the inside of the room, - with the location on it of wooden racks, spacers and shields.

 In FIG. Figures 3-7 show plans for sections of the wall of a brick building with installed composite stands, guard shields, and sewing boards.

 In FIG. 8-10 - walls of a brick building in a section with elements of a device for unloading them from the weight of the coating.

 In FIG. 11-12 - unloading device, respectively, before and after wedging, i.e. inclusion in the work.

 In FIG. 13-22 are shown in two projections views of the board-nail boards of the reinforced wall fencing.

 In FIG. 23-25 are shown in three projections a heat-insulating curtain shield of a low flammability fence: a plan of FIG. 23; sections BB and BB of FIG. 24 and 25.

 Information confirming the possibility of carrying out the invention with obtaining the above technical result.

 The structural diagram of the reinforcement frame of the brick wall 1 without unloading is represented by vertical elements - composite wooden racks - 2, horizontal elements of wooden beams or boards - 3 and protective enclosing elements - 4. Vertical and horizontal elements 2 and 3 of the frame are connected by fixing bolts 5 with tension nuts and washers (see Fig. 1).

 The scheme of the reinforcement frame of the brick wall 1 with its unloading from the truss structure 6 is represented by composite wooden posts 2 with a spacer 7 (see Fig. 2).

 As a lining for the supporting elements of the coating using a wooden girder 8. This run is continuous, and it is provided as an element of the reinforcement cage. If it is necessary to unload a section of wall 1 from one covering beam, the lining under it is taken in the form of a piece of timber or board 28. Half-timbered racks 9 are used to reduce the length of prefabricated expansion shields for wall 4, when using continuous-cut planks of skin 11 of wall 1 or to install a curtain shield 10 on the wall .

 To strengthen the brick wall 1 and to prevent the bricks from falling out of the damaged masonry, prefabricated expansion board shields of the fence 4, hinged boards 10 or board of suture 11 are installed. 4).

 Provided that the wall 1 of the building adjoins the brick, concrete or metal column 12 and the shields perceive 4 wind loads, the wooden drains 2 of the reinforcement cage are attached to them with fastening devices, for example, bolts 5 and clamps 13 (see Fig. 6 and 7).

 The composite stand 2 is constituted by a support branch 14 mounted on the waterproofing layer 15 and the foundation 16, and an unloaded branch 17 (see Fig. 8).

 In the absence of protective shields of the fence 4, the unloaded branch of the composite rack is made in the form of a metal strip 18 (see Fig. 9).

 In a simplified version, instead of a metal strip 18, a lining 19 of metal or wood is installed under the washer of the tension bolt (see Fig. 10).

 The spacer is in the form of twin wedges. Before turning on the wedges, the amount of draft (C, mm) of the supporting branch 14 of the wooden stand is determined and a marking line 20 is applied to the surface of the pair of wedges 7. The position of the wedges before and after their introduction into operation is shown in FIG. 11 and 12.

 In FIG. 8-12, the designations G and P are parts of the load from the coating element 6, perceived respectively by the brick wall 1 and the spacer 7; in FIG. 11: a x in - cross section of a wooden girder 8.

 The design of the prefabricated board shield 4 fencing is presented in the form of a frame of boards or bars - transverse 21 and longitudinal 22 ribs - with plywood, asbestos-cement or gypsum plasterboard shelves 23 with a thickness of 6-10 mm (see Fig. 13-14).

 The board-nail board 4 is made of thin boards 24 of a solid or sparse type (see Figs. 15-18), single-layer with braces 25 or double cross, consisting of a sparse working flooring 26 and an oblique protective flooring 27 of thin boards (see Fig. . 19 - 22).

 Reducing the flammability of wooden boards 4 is obtained due to the location of the bars and boards 21 and 22 with the edge to the wall surface, filling the voids with a light non-combustible insulation 29 and applying fire-retardant material 30, for example, shingles (see Fig. 23-25).

The assembly of wooden elements for reinforcing the brick wall of the building, performed for long-term use, is performed as follows:
a) if it is necessary to strengthen and unload from the coating mass of a small portion of the damaged wall: first designate the design, material and sectional dimensions of the elements of component 2, determine the locations of the holes in the wall 1 and the elements of the rack 2 for fastening the bolts 5, provide the supporting sections with waterproofing 15 on the foundation 16, attach the elements of the rack 2 to the brick wall 1, install the elements of the rack 2 to the brick wall 1, set the length of the beam - lining 28 under the unloaded support of the rafter structure 6 and the spacer swarm, for example, wedges 7 with their subsequent knocking to a height of C, mm;
b) if it is necessary to strengthen and unload the brick wall from the weight of the coating elements of the whole or part of the building: first, with the pitch of the coating bolts, attach to the wall 1 the elements of two or more composite posts 2, placing the ends of the branch 14 on the waterproofing 15 and foundation 16, then install continuous run-lining 8 under the rafters, put and put into operation a spacer device, for example wedges 7; if necessary, half-timbered racks 9 are placed between the supporting racks 2, then wooden bars - runs 3 are attached to the racks 2 and 9, creating a rigid reinforcement cage, and the cells of the reinforcement cage are filled with board shields 4; reinforcing the brick wall 1 with continuous siding boards 11 eliminates the use of girders 3.

 The application of the proposed method and structural measures allows comprehensive protection of wooden reinforcing elements from moisture, biodegradation and fire. As a result, temporary fasteners from wood are transferred to the category of their prolonged use.

Thus, the above information indicates that when using the claimed method the following set of conditions:
a) a tool embodying the claimed method in its implementation, is intended for use in the construction industry, and in particular to methods of strengthening the stone structures of the building;
b) for the claimed method in the form described in the independent clause of the claims, the possibility of its implementation using the means described in the application is confirmed;
c) the proposed method was applied when reinforcing a damaged load-bearing outer brick wall of lightweight masonry of a part of a one-story industrial building measuring 9 x 81 m in plan, the pitch of building reinforced concrete beams is 6 m.

 Therefore, the claimed invention meets the condition of "industrial applicability".

Sources of information
1. A.S. USSR 949136, MKI-3, E 04 G 23/00. A way to restore a building with partially collapsed structures. Pinchuk V.Ya. Publ. 08/07/82. Bull. 29.

 2. A. p. USSR 918408, MKI-3, F 04 G 23/00. A method of reinforcing brick walls. Mardzhanshvili M.A., Kostrits A.I., Mindeli T.B. and other publ. 04/07/82. Bull. thirteen.

 3. Recommendations for strengthening the stone structures of buildings and structures. - M .: Stroyzdat, 1984, 36 p. (pp. 2.32 and 2.33, Fig. 5, p. 19-20).

Claims (34)

 1. A method of reinforcing stone structures of a building, including the installation of unloading elements in the form of wooden racks with a spacer device that provides a given degree of unloading of the wall of the building, characterized in that the wooden racks are made integral, placed on the inside and outside of the building and connected by tension bolts, passing through the through holes in the wall, then the racks are connected to horizontal elements with the formation of a frame protected from fire, and a fencing set is attached to them y, while the tension bolts are located at a distance of no more than the maximum permissible value determined by calculation, and the horizontal frame elements are continuous with wooden beams or planks and installed on one or both sides of the walls of the building, fence plates are installed between the racks with the formation of a vertical stiffness bond, and horizontal stiffness bonds are made in the form of longitudinal, transverse, intersecting strands at the level of the floor or building cover and attached with tension zheniem to the uprights.  2. The method according to p. 1, characterized in that the composite rack is made of two wooden beams, logs or boards, installing respectively from the inside and outside of the building and connecting them with tension bolts.  3. The method according to p. 1 or 2, characterized in that the composite rack is made of beams, logs or boards, attaching them to the wall of the building with tension bolts.  4. The method according to any one of paragraphs. 1-3, characterized in that the number of tension bolts on one threaded element of the composite racks take at least two.  5. The method according to any one of paragraphs. 1-3, characterized in that the cross-sectional size of each branch of the composite racks is taken structurally or by design.  6. The method according to any one of paragraphs. 1-3 and 5, characterized in that the cross section of the supporting branches of the composite racks are calculated on the basis of the compression force from the full or partial unloading of the stone wall.  7. The method according to any one of paragraphs. 1 or 6, characterized in that the supporting branches of the composite racks for the elements of the coating or floor of the building are installed in the spacer.  8. The method according to any one of paragraphs. 1, 6 and 7, characterized in that the supporting branch of the composite racks are loaded by the inclusion of spacers, for example, wedges.  9. The method according to p. 1, characterized in that the supporting table for a spacer, for example, wedges, is provided at one of the ends of the supporting branch or at any height of the rack.  10. The method according to p. 1, characterized in that the vertical bond stiffness is performed in the form of a wooden board.  11. The method according to p. 10, characterized in that the board shield is solid or sparse.  12. The method according to p. 11, characterized in that the distance between the longitudinal ribs of the sparse board shield fences take no more than the thickness of the brick or stone of the damaged wall, for example, no more than 65 mm, when masonry is made of ordinary clay brick.  13. The method according to p. 11 or 12, characterized in that the gaps between the longitudinal ribs of the rarefied shield are filled with non-combustible material, for example mortar or concrete.  14. The method according to p. 10, characterized in that the board shield fencing is installed close to the wall of the building or provide a gap for the material reinforcing the wall or for insulation.  15. The method according to p. 10, characterized in that the spacer boards of the fence are installed on one or two sides of the damaged section of the wall of the building. 16. The method according to any one of paragraphs. 1-4, characterized in that the maximum permissible length of the sections of the supporting branches of the composite racks between the coupling bolts is determined by the formula

where L _max is the longest length of the section of the supporting branch of the reinforcement post between the bolts, cm;
λ _max - ultimate flexibility of an element of a wooden structure; see table SNiP II. 25-80 * "Wooden structures", - M., 1983;
To mp = 0.3-1.0 is the coefficient of decrease in the bearing capacity of masonry, depending on the degree of damage; see table 1-3 "Recommendations for strengthening the stone structures of buildings and structures", - M., 1984;
M = 0.65-2.20 is the coefficient of the condition for fixing the ends of the section of the supporting branch; see paragraph 4.21 of SNiP II. 25-80 *;
J is the moment of inertia of the cross section of the support and non-support branches of the composite rack, cm ⁴ ;
And - the cross-sectional area of the supporting branches of the composite racks, cm ² . 17. The method according to p. 1, characterized in that the required amount of subsidence of the supporting branches of the composite racks from the load, with a given degree of unloading the wall, is determined by the formula

where C is the total force displacement of the elements of the support branch of the rack, cm;
P is the load on the support branch of the rack, kN;
L _i - the length of the i-th compressed element of the supporting branch, cm;
And _i is the compression area of the i-th element of the supporting branch, cm ² ;
E _i - moduli of elasticity of wood along or across the fibers, MPa;
n is the number of elements of the supporting branch of the reinforcement rack.  18. The method according to p. 17, characterized in that the draft of the supporting branch of a given size is selected by the wedges of the spacer, on the front surface of which mark lines or risks are applied.  19. The method according to p. 18, characterized in that the marking lines are presented on a lighthouse made on graph paper, sticking a lighthouse on installed wedges and cutting it at the point where the wedges join together before they are included in the work, i.e., wedging.  20. The method according to p. 10, characterized in that the board shield fencing is made precast, span equal to the distance between the edges of the racks of the reinforcement frame.  21. The method according to p. 8, characterized in that when installing the spacer to the lower end of the composite rack, the through holes in the wall and in the supporting branch for the passage of the coupling bolts are oval with a gap D, cm, while the size of the gap is not less than doubled the required precipitation of the loaded support, that is, D ≥ 2C; cm.  22. The method according to p. 12, characterized in that the horizontal elements of the reinforcement cage - girders and / or guard panels - are installed to the wall of the building with a gap, forming it by laying horizontal elements on the frame racks.  23. The method according to p. 1, characterized in that the horizontal frame elements made of continuous boards or bars are installed close to the wall of the building and pressed against it by the branches of the frame racks using tension bolts.  24. The method according to any one of paragraphs. 1-3, characterized in that the end faces of the supporting branches of the composite racks are equipped with metal plates and waterproofing.  25. The method according to any one of paragraphs. 1, 5 and 10, characterized in that the elements of the reinforcement cage are coated with a fire-retardant material, for example, with shingles, with a thickness of b ≥ 2 cm.  26. The method according to p. 10, characterized in that the space between the runs of the sparse board shield of the reinforcement frame is filled with a light non-combustible material, for example foam concrete, expanded clay concrete or mineral wool wrapped with plastic film.  27. The method according to p. 10, characterized in that the runs of the sparse shield fencing reinforcement cage are made in the form of bars or boards, setting them edge to the side of the heated surface of the structure in a fire.  28. The method according to p. 10, characterized in that on the open surface of the wooden elements of the reinforcement cage, large-sized sheets of fire-retardant cladding are applied, for example, plasterboard sheets of 1 or more layers with a thickness of at least 1.4 cm each.  29. The method according to p. 25, characterized in that for plastering the surface of wooden reinforcing elements installed in places that are adequately protected from moisture, a heavy clay mortar for plastering from crushed greasy clay, sandblasted, the composition in a dry mixture, wt. %: oily clay 15-20, ordinary natural sand 80-85, and a solution with a thickness of at least 2 cm is applied to the surface of the element protected from fire.  30. The method according to p. 25, characterized in that when using clay of medium fat content for plaster, a solution of the composition, wt. %: clay of medium fat content 25-30, natural sand ordinary 70-75.  31. The method according to p. 25, characterized in that when using lean clay for plaster a solution is made, wt. %: skinny clay 30-40, natural sand ordinary 60-70.  32. The method according to p. 25, characterized in that to increase the water resistance of the clay mortar for plaster lime is added to the clay and a solution of the composition, wt. %: oily clay 14-18, slaked lime 1-2, natural sand 80-85.  33. The method according to p. 25, characterized in that to obtain a light, moderately combustible plaster, a clay solution of the composition, wt. %: clay fat or lean 50-60, organic lightweight aggregate 40-50 in the form of fine chips, straw, tow, sawdust, in the plastic state, the solution is applied to the surface of wooden reinforcing elements with a thickness of 3-5 cm, receiving after hardening light, moderately combustible plaster.  34. The method according to p. 25, characterized in that to increase the heat-insulating and fire-retardant properties of the lime plaster, light natural or artificial sand is added to the cement component of the lime solution, for example, ground slag, pumice, tripoli, tuff, coal, a light solution of the composition is made , in a dry mixture, wt. %: slaked lime 20, tripoli 5-10, coal fines 70-75, and a solution with low thermal conductivity 3-5 cm thick is applied to the wooden elements.

Images