RU2347047C2 - Method for building floor panel reconstruction - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention concerns construction industry, in particular it can be used for reconstruction of hollow core slabs of building or structure floors damaged by fire. The result from using the invention is achieved by the fact that according to the method for reconstruction of floor panels, which include additional reinforcement pieces and concrete, at fist reinforcement products are made in the form of flat grid frames or coupled flat composite frames with clamps on the support part of the panels, then slots are cut in the middle of the panel flange bottom with a length not less than that of the wiring bar of the reinforcement frame and with a width not less than that of the frame cross-section, holes on the ends of the panel top flange are cut with an interval of 1.5÷2 m, reinforcement pieces are installed into the hollow channels of the panels, concrete is supplied through the slots (holes) cut in the panel top flange.

EFFECT: efficient reconstruction of hollow core slab performance (strength, stiffness, crack resistance and fire resistance), improved performance reconstruction quality, metal saving, reduced material cost and power consumption during repair work, reduced risk of collapse of damaged floor panels during their reconstruction.

11 cl, 15 dwg

Description

The invention relates to the field of construction and for the restoration of multi-hollow reinforced concrete floor panels damaged due to various reasons, including those struck by fire in a fire or a technological accident in a building.

During the fire exposure, reinforced concrete floor panels are heated from below. The maximum heating temperature (800 ± 200) ° C is observed on the heated surface of the panels and at a depth of 10-20 mm. Concrete and reinforcement in the compressed sectional area of the panels warm up more slowly and slightly. Damage to multi-hollow panels by fire includes:

random arrangement of surface heat-shrinkable cracks, destruction of part of the section of the panel heated above the critical heating temperature (600 ± 50) ° С, cracking of concrete, delamination of the destructive part of the protective layer of concrete, change in the mechanical properties of the heated reinforcement.

A higher degree of thermal stress damage to multi-hollow panels is possible: longitudinal and oblique cracks 3-10 mm wide in the walls separating the hollow channels. As a result, there is a significant decrease in the strength and stiffness of multi-hollow panels.

The invention is intended to restore operational characteristics (strength, stiffness, crack resistance, fire resistance) of multi-hollow reinforced concrete floor slabs of a building.

A known method of repairing fire-damaged floor panels of a building, including the installation of additional reinforcement in the form of individual reinforcing bars or bent grids strung on rods of existing reinforcement / Pat. 2087653 of the Russian Federation, IPC-6 E04G 23/02. The method of repairing damaged bent reinforced concrete elements / Ilyin NA .; applicant and patent holder Samarsk. arch-build. institute - No. 94 012398/03; declared 04/07/94; publ. 08/20/97, Bull. No. 23, - 12 p. Fig. 9. [one].

The reasons that impede the achievement of the technical result indicated below when using the known method of repairing damaged multi-hollow floor slabs of a building include the fact that additional reinforcement reinforcements are performed discretely in the form of a number of reinforcing elements that are placed in the plane of the existing mesh from the bottom of the panels. Therefore, the known method of restoration is not rational for restoring the operational characteristics of multi-hollow panels, is not economical and time-consuming.

A known method of restoring the floor panels of a building by installing in some hollow channels through grooves punched in the upper flange along these channels, additional reinforcing frames with subsequent monoling of these frames / Recommendations for the inspection of buildings and structures damaged by fire / NIIIZhB. - M .: Stroyizdat, 1987. (Clause 9.24, C.41, Fig. 16, C.44) [2].

For reasons that impede the achievement of the technical result indicated below when using the known method of restoring building floor panels, it is not rational to restore the operational characteristics of reinforced concrete panels with installing reinforcement frames through grooves (cracks), destroying the compressed zone of the panels; material and energy costs during construction work are quite large; possible collapse of damaged plates in the process of their restoration.

A known method of restoring the floor panels of a building, including punching a hole under the void of the slab, installing reinforcing bars into it, by introducing them alternately from the opposite ends of the voids through the holes under the voids, after fixing the rods with anchors, fill the voids through the holes in the upper shelf from the side opposite to the reinforcing bar rod / Pat. 1 823909 SU, IPC-5 E04G 23/02. The method of reinforcing multi-hollow floor slabs / Kochetov I.A. and Barygin B.YU, declared. 02/08/91, publ. 06/23/93. Bull. No. 23 / [3].

The reasons that impede the achievement of the technical result indicated below when using the known method of restoring building floor panels include the fact that in the absence of transverse reinforcement reinforcing bars (clamps, bends), force cracks can form near the supports and subsequent destruction of the floor panels along an inclined section to the element axis from the impact of shear forces during operation;

due to the fact that the coefficient of thermal diffusion of fine-grained concrete (D _m = 35.6 mm ² / min) is more than 1.5 times higher than that of ordinary heavy concrete (D _t = 19.4 mm ² / min) and more than 2.5 times higher than that of structural expanded clay (D _to = 12.1 mm ² / min), therefore, the fire resistance of the restored panel according to the known method using fine-grained concrete is significantly lower than when using expanded clay concrete; in addition, fine-grained concrete, compared to heavy concrete, can be destroyed explosively under conditions of high fire temperatures;

reducing fire resistance of panels is possible due to the formation of "bridges" of heat transfer from the concrete surface to the working reinforcement reinforcement in the places of installation of anchor rods;

therefore, the restoration of the main operational characteristics (strength, rigidity, crack resistance, fire resistance) of damaged multi-hollow panels in a known manner is irrational and poor quality.

There is a method of restoring building floor panels, including making holes in the support zones of voids on top of the panels and from below in the span under adjacent voids, installing stops with a tensioning device on the upper surface of panels and gaskets on the lower surface of panels, introducing flexible reinforcement into adjacent voids in the direction from one holes in the support zone to another hole in the span and its voltage / Pat. 2020234 RU, IPC-5 E04G 23/02. The method of reinforcing multi-hollow reinforced concrete floor panels. / Lazovsky D.N., Maslennikov S.D., Avdoshka A.V. et al. 04/22/1991, publ. 09/30/1994, Bull.No. 27, silt / [4].

For reasons that impede the achievement of the technical result indicated below when using the known method of restoring building floor panels, reinforcement of the hollow panel is made in the form of prestressed truss reinforcement with a small (4-5) ° angle to the longitudinal axis of the floor panel with the section height h, cm, and span l, cm (at tg α = h / 0.5 · l = 22 / 0.5 · 580) = 22/290 = 0.076, - angle α = (4 ÷ 5) degrees). Consequently, a compressive force N _c arises at the supporting section of the overlapping panel, equal to N _c = 0.96 · P ₁ , where P ₁ is the force from the prestressing of the truss reinforcement; this is more than 1.3 times the value of P ₂ arising in the spindle at the standard (optimal) angle of inclination α _opt = 35 °.

On the supports during anchoring of the truss reinforcement, an additional bending moment M _add = N _c · h occurs, the action of which the truss reinforcement does not perceive.

Therefore, when using the known method of restoration, a bendable floor panel reinforced with truss reinforcement turns into an eccentrically compressed one, substantially changing its initial bending scheme.

Heavily damaged floor panels cannot be reliably repaired using the proposed truss reinforcement; destruction of the damaged panel during its reinforcement from additional compression forces and bending moment occurring at the supporting sections is possible.

In industrial production, when choosing a gain option, preference is given to solutions with a clear design scheme, which ensures the joint work of the reinforced structure with reinforcing elements and which reliably determines the additional perceiving load.

Determined by the known method, the cross-sectional area of the additional prestressed reinforcement is too high, which leads to unreasonable consumption of steel.

It is impossible to introduce reinforcing reinforcement in the form of a welded frame for perceiving the transverse force on the supporting sections into the paired holes (holes) punched in the lower shelf of the panel above the adjacent voids and the inner edge of the panel.

Prestressing in the truss reinforcement is carried out after the concrete has hardened in the embedment of the anchors, that is, not earlier than 7 days after the concrete is laid. This increases the gain of the floor panels.

Therefore, the restoration of the main operational characteristics (strength, stiffness, crack resistance, fire resistance) of damaged multi-hollow panels in a known manner is irrational and unreliable.

A known method of restoring the floor panels of a building, including making holes (holes) on the bottom side of the panel in the support area along the voids, into which the reinforced frame knitted or folded or welded in a horizontal position is introduced, then the reinforcing frame is brought into working position and pumped into the panel void concrete mix / A.S. 1783101 SU, MPK-5, E04G 23/02. The method of reinforcing precast multi-hollow concrete floor slabs. / D.N. Lazovsky and S.D. Maslennikov; declared 11/30/90; publ. 12/23/92. Bull. No. 47 / [5].

The reasons that impede the achievement of the technical result indicated below when using the known method of restoring building floor panels include the fact that the welded reinforcing cage is made with frequent installation of transverse rods located with equal pitch along the entire length of the frame. This leads to an overspending of steel for the manufacture of transverse bars by (25-50)% compared with the frame, the transverse rods of which are made with double step or in the absence of them in the middle part of the reinforcing frame. Knitted reinforcing cage is laborious to manufacture. In the case of supporting the floor panels on the bearing walls of the building, it is impossible to introduce a reinforcing cage into the hole (hole) cut in the supporting section of the panel. Due to the limited space for the rotation of the reinforcing cage, it is possible to bend it against the reinforcement project. Therefore, the introduction of the reinforcing cage into the punched hole in the support section in this case is not technologically advanced, including due to the inability to control the installation of the cage along the length of the panel void and the impossibility of quality control of filling the panel void with new concrete.

Due to the installation of the reinforcing cage on the top of the lower shelf in the emptiness of the panel, the axial tension (laying depth) of the additionally laid longitudinal working reinforcement increases from 15 to 50 mm. In this regard, the working height of the cross section of the panel is reduced by 20%. Therefore, the application of the known method of reinforcing a multi-hollow panel leads to an overrun of longitudinal working reinforcement by 20%.

The inaccuracy of the installation of reinforcing bars in the section of the panels, their significant displacement or curvature, the lack of control over the quality filling of the voids of the panels with concrete, are the reasons for the hidden (most dangerous) marriage of reinforcing panels.

Therefore, the restoration of the basic operational characteristics of damaged multi-hollow floor panels in a known manner is uneconomical and does not meet technological requirements.

The closest technical solution to the invention in terms of features is a method of reconstructing hollow-core reinforced concrete floor panels with round or oval voids by using part of the hollow channels into which (after punching the upper shelf along the entire length of the panel) additional reinforcing cages are laid with subsequent concreting of voids / Recommendations for evaluation state and strengthening of building structures of industrial buildings and structures. / NIISK. - M .: Stroyizdat, 1989 (p.1.1, C.3; cl. 2.11-2.14, C.9-14; cl. 4.37, C.38; fig. 7, C.34-35) [6] - taken as a prototype.

The reasons that impede the achievement of the technical result indicated below when using the known method for restoring multi-hollow reinforced concrete floor slabs adopted as a prototype include the fact that in the known method, existing concrete and reinforcement of the compressed section section of a reinforced concrete panel are not damaged by fire; - as a result, significantly reduce the strength of the compressed zone in particular and the panel as a whole, increasing the risk of collapse of the restored building floor panel, weakened earlier by fire from the bottom side; in this case, additional costs are required for the design, manufacture and installation of safety supports in the building; after the installation of additional frames in hollow channels, the working height of the cross-section of the reinforced concrete panel is reduced by 20% compared to the design, therefore, the structural qualities of the panel restoration device are reduced; increase energy and labor costs when punching (breaking) on top of the slit panel (grooves) for the passage of reinforcing products into hollow channels; increase metal consumption in the manufacture of flat reinforcing cages, using longitudinal rods of the same diameter along the entire length of the hollow channel of the plate, i.e. do not take into account the change in the magnitude of the bending moment on the support and in the span of the panel.

Therefore, the restoration of operational characteristics (strength, stiffness, crack resistance, fire resistance) of multi-hollow panels damaged by fire in a known manner is irrational and poor quality.

The invention consists in the following.

The problem to which the claimed invention is directed is to strengthen annealed working reinforcement, simplify the manufacture of reinforcing products for the restoration of multi-hollow reinforced concrete panels damaged by fire, to rationally restore its operational characteristics, reduce the volume of construction work and reduce the consumption of new concrete and metal for additional reinforcement .

The technical result is an increase in strength, rigidity, crack resistance, fire resistance during the restoration of damaged reinforced concrete panels, improving the quality of restoration and its structural characteristics, saving metal, reducing material and energy costs during construction work, reducing the risk of collapse of damaged floor panels during the restoration process.

The specified technical result when using the invention is achieved by the fact that in the known method of restoring building floor panels, including visual-instrumental examination, verification tests, assessing the condition of damaged multi-hollow reinforced concrete panels, installing safety supports for badly damaged panels, cutting openings along the lower shelves of panels axis of symmetry of the hollow channels, nailing holes into the hollow channels in the upper shelves of the panels, the introduction of arm holes into the hollow channels reinforced concrete products and reinforced concrete, a feature is that reinforcing reinforced products are first manufactured in the form of flat composite frames with clamps on the support part or in the form of flat frames - nets, then slits are cut in the middle of the lower shelves of damaged reinforced concrete panels along the axis of symmetry of the hollow channels with a length of not less than the length of the mounting core of the frame, a width of not less than the width of the cross-section of the reinforcing frame, punch holes in the hollow channels on the supporting sections in the upper shelves of the panels (with a step of 1.5 ÷ 2 m), Then, composite reinforcing frames or frames - meshes are installed into the hollow channels through the cut-through slots and concreted by introducing reinforced concrete into the hollow channels through openings in the upper shelves of the restored floor panels.

In addition, the features consist in the fact that the reinforcing product in the form of a composite flat reinforcing cage - mesh is performed with a single arrangement of reinforcing bars, with welding of the legs of the transverse rods by arc welding, with elongated rods of the working reinforcement, with a bend of the legs of the working rods by 45 degrees.

The reinforcing product in the form of paired flat composite frames with clamps on the supporting part is performed by welding the legs of the transverse rods by arc welding, with elongated rods of the working reinforcement.

The longitudinal working rod of the composite grid frame is cut with a length equal to the sum of half the length of the hollow channel of the panel and the length of the bypass rod of the working reinforcement, that is:

where L _article , L _pan - respectively, the length of the working core of the frame - mesh and the length of the hollow channel of the panel, mm; l _n , _min = 40 · d _max - the length of the bypass (overlap) of the working rods, mm; d _max - nominal diameter of the working rod, mm.

The slot located in the middle of the lower shelf of the panel, through which flat composite frames - grids are introduced into the hollow channel, is cut out with a length equal to:

where l _slots , l _mount - respectively, the length of the slit and the length of the mounting rod of the reinforcing cage, mm; z ₁ - the gap value equal to (40 ± 10) mm.

The slot in the lower shelf of the panel for entering a flat composite frame-mesh into the hollow channel is cut out with a width equal to:

where b _slots - the width of the slit, mm; d ₁ and d ₂ - respectively, the diameter of the longitudinal and transverse rod, mm; z ₂ is the gap value equal to (5 ± 2) mm.

A flat frame is made with a width that is adopted depending on the height or diameter of the hollow channel of the panel, i.e. (4):

where B is the width of the frame along the axes of the extreme longitudinal rods, mm;

C ₁ - the distance from the axis of the longitudinal rods of the frame to the end of the transverse rods, but not less than 10 mm; D - height (diameter) of the hollow channel of the panel, mm

Holes at the end sections of the upper shelf of the panel to fill concrete with its hollow channel are cut through with dimensions taken from the conditions for pouring and vibrating reinforced concrete, for example, b ₀ × l ₀ = 40 × 160 mm; here b ₀ and l ₀ are the width and length of the hole, respectively, mm.

According to the calculation, an additional rod is attached to the longitudinal rods of the working reinforcement of the composite frames for the entire length of the slit cut in the lower shelf of the panel.

In the zone of action of the maximum bending moment, longitudinal rods of additional reinforcement are installed with a bypass in a dangerous section of the panel to reinforce it along the rebar diagram.

As concrete monolithic additional frames in the hollow channels of the panel pour light structural concrete, for example, expanded clay concrete.

The causal relationship between the totality of features and the technical result of the work is as follows.

Using the proposed method of restoring the floor panel of a building provides an improvement in the quality of restoration, reducing material costs and rational restoration of the operational characteristics of the damaged floor panel.

Improving the quality of panel restoration is achieved by:

- increasing the working height of the cross section of the reinforced concrete panel due to the approach of the longitudinal reinforcement of the additional frames to the bottom of the lower shelf of the panel;

- replacement of the destructive layer of concrete of the lower shelf of the panel, significantly damaged by fire, with new reinforcement concrete;

- ensuring normative fire resistance of the restored floor panels by applying a protective layer of lightweight concrete of at least the required size;

- perception of transverse forces due to the installation of additional frames with a more frequent arrangement of transverse rods (clamps) at the supporting parts of the restored reinforced concrete floor panels.

The reduction in material costs during the restoration of damaged reinforced concrete floor slabs of a building is achieved by:

- the use of severely damaged floor panels for reuse after their restoration by the proposed method;

- reducing the mass of restored floor panels due to the filling of the voids of the panel with light structural concrete;

- reducing the complexity of the installation of additional reinforcement due to the cutting of concrete only part (30-50%) of the length of the hollow channel of the panel;

- reducing the time for restoration of damaged panels and reducing losses in the structural part of the building due to the possibility of repairing even emergency panels instead of dismantling them;

- reducing metal consumption for additional working reinforcement due to an increase in the working height of the section of the panel and reinforcing it along the length of the channel, taking into account the magnitude of the bending moment. The rational restoration of damaged multi-hollow panels using the proposed method is achieved by:

- restoration of damaged sections of floor panels in their previous dimensions without significant changes in its original height, preventing the formation of concrete buildup;

- increase the working height of the cross section of the restored floor panels with unchanged initial dimensions due to the attachment of new reinforcement to the bottom of the additional frame;

- increase the bearing capacity of the restored section due to an increase in the working height of reinforced concrete floor panels and the installation of additional reinforcement;

- ensuring the required safety of the floor panels during the restoration process and when it is allowed for reuse due to the reduction in the volume of concrete cutting down of the compressed zone;

- improving the quality of restoration and reducing material costs during the repair of damaged floor panels.

Figure 1, 2 and 3 shows a diagram of the additional reinforcement of the emergency multi-hollow reinforced concrete floor slab (plan, longitudinal and transverse sections; execution 1):

1 - additional reinforcement bar;

2 - slots in the lower shelf of the panel (for skipping a flat frame);

3 - additional concrete (for reinforced concrete rib panels);

4 - flat composite reinforcing reinforcement cages;

5 - holes in the upper shelf of the panel (to fill the hollow channels with reinforced concrete);

6 - reinforcing mesh (for reinforcement in the compressed overlap zone);

7 - monolithic reinforced concrete reinforcement plate;

8 - electric arc welding;

9 - V-shaped shortys with a step equal to (1400 ± 100) mm;

10 - reinforced concrete multi-hollow overlapping panel.

Figures 4, 5 and 6 show flat composite reinforcing cages - grids with a single arrangement of longitudinal working rods of the reinforcement, with welding of the legs of the transverse rods by arc welding, with elongated longitudinal rods of the working reinforcement, with a bend of the legs of the longitudinal rods of the working and mounting reinforcement by 45 degrees .

11 - longitudinal rods of the working reinforcement of the reinforcement cage;

12 - longitudinal mounting rods of the reinforcement cage;

13 - transverse rods of the reinforcement cage - clamps - (at the end sections with a pitch of 100 mm);

14 - transverse rods of the reinforcement cage - clamps, in the middle part of the reinforcement cage with a step (250-300) mm.

Figures 7, 8 and 9 show a plan of a multi-hollow reinforced concrete floor panel with moderate damage, its longitudinal and transverse sections, main dimensions (version 2):

2 - slots in the lower shelf of the panel (for missing composite reinforcement cages);

5 - holes in the upper shelf of the panel to fill the hollow channels with reinforced concrete.

Figure 10, 11 and 12 shows a reinforcement diagram of a multi-hollow reinforced concrete floor slab having moderate damage (designations are shown in Figs. 1-3).

On Fig, 14 and 15 shows the transverse rods of the reinforcement cage - clamps - 13 on the support part, with elongated longitudinal rods of the working reinforcement cage 11 and the longitudinal mounting rods of the reinforcement cage 12 of the reinforcement, with welding of the legs by arc welding (node A).

Information confirming the possibility of applying the invention to obtain the above technical result.

Technical inspection of the building damaged by the fire revealed that the reinforced concrete floor of the hall of the 8th floor to be restored consists of multi-hollow reinforced concrete floor panels 10 with round voids D = 159 mm, the cross-sectional height is 220 mm; panel dimensions in terms of 1.2 × 5.86 m.

In the project for the restoration of damaged panels, rod reinforcement of class A 400 (A-III) is used for longitudinal rods of working reinforcement with a diameter of (14 ÷ 18) mm, class A 240 (A-I) - for transverse rods - clamps with a diameter of (8 ÷ 10) mm; lightweight concrete rebuilding grade D 1800 grade B35 for compressive strength; for sealing cracks - lightweight concrete class B15.

Flat composite reinforcing reinforcement cages 4 are installed in four (out of 6) hollow channels through slots in the lower shelf of panel 2, which are cut in the middle of the floor panel; slot width (40 ± 10) mm; slot length 3000 mm (version 1) and 1600 mm (version 2).

An additional reinforcing product for emergency panels is performed in the form of a composite flat reinforcing cage - grids with a single arrangement of reinforcing bars, with welding of the legs of the transverse rods 13 and 14 by arc welding, with elongated longitudinal rods of the working reinforcement of the reinforcement frame 11, with a bend of the legs of the working rods by 45 degrees . Flat composite reinforcing cages - nets have longitudinal rods of working reinforcement of reinforcement cage 11 with a length of 2920 mm; reinforcement cage width B = 150 mm.

An additional reinforcing product for plates with an average degree of damage is performed in the form of flat composite reinforcing reinforcement cages 4 with clamps 13 on the support part, with welding of the legs of the transverse rods by arc welding, with elongated rods of the working reinforcement. Reinforcing reinforcement cages have longitudinal working rods with a length of 3520 mm and mounting rods with a length of 1520 mm; reinforcement cage width B = 128 mm.

With a bending moment of M = 66 kN-m, four additional rods with a diameter of 14 mm of class A400 (A-III) are installed to restore the emergency panel.

The thickness of the monolithic reinforced concrete reinforcement slab 7 of the compressed zone of the panel is 60 mm; plate reinforcement - nomenclature light welded reinforcing mesh 6, core diameter (3-6) mm; pitch of rods 200 mm.

The installation of the reinforcing product inside the hollow channel is made through the cut-out slots in the lower shelf of the floor panel, pouring reinforced concrete through the holes cut in the upper shelf of the panel.

In the process of restoration work: technical inspection of the building, examination of the floor panels, assessment of the technical condition of damaged panels, selection of materials and development of working drawings of the reinforcement device, manufacturing of reinforcing products, their installation in place, pouring reinforced concrete into the hollow channels with subsequent vibration of concrete.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed invention:

a) a tool embodying the claimed invention in its implementation, is intended for use in the construction industry, namely, to restore damaged multi-hollow reinforced concrete panels for overlapping a building; b) for the claimed recovery 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 is intended for use in the restoration of multi-hollow reinforced concrete floor panels of a 9-story building in Samara damaged by fire.

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

Information sources

1. Pat. 2087653 Russian Federation, IPC-6 E04G 23/02. The method of repairing damaged bent reinforced concrete elements / Ilyin N.A .; applicant Samarsk. arch-build. institute - No. 94012398/03; declared 04/07/94; publ. 08/20/97, Bull. No. 23, - 12 p. Fig. 9.

2. Recommendations for the inspection of buildings and structures damaged by fire. / NIIZHB. - M .: Stroyizdat, 1987. (Clause 9.24, C.41, Fig. 16, C.44).

3. Pat. 1823909 SU, IPC-5 E04G 23/02. A method of reinforcing multi-hollow floor slabs. / Kochetov I.A. and Barykin B.Yew., declared. 02/08/91, publ. 06/23/96. Bull. Number 23.

4. Pat. 2020234 RU, IPC - 5 E04G 23/02. A method of reinforcing multi-hollow reinforced concrete floor panels. / Lazovsky D.N., Maslennikov S.D., Avdoshka A.V. et al. 04/22/1991, publ. 09/30/1994, Bull.No. 27.

5. A.S. 1783101 SU, MPK-5 E04G 23/02. The method of reinforcing precast multi-hollow concrete floor slabs. / D.N. Lazovsky and S.D. Maslennikov, declared. 11.30.90, publ. 12/23/92. Bull. Number 47.

6. Recommendations for assessing the condition and strengthening of building structures of industrial buildings and structures. / NIISK. - M .: Stroyizdat, 1989, (p.1.1, C.3; p.4.37, C.38; Fig. 7, C.34-35).

Claims (11)

1. A method of restoring building floor panels, including visual and instrumental examination, performing verification calculations, assessing the condition of damaged multi-hollow reinforced concrete panels, installing safety supports for badly damaged panels, punching holes in hollow channels in the upper shelves of panels, introducing reinforcing products into hollow channels and reinforcement concrete, characterized in that the reinforcing reinforcement products are first manufactured in the form of flat composite frames with clamps on the supporting part or in the form of flat grid frames, then cut in the middle part of the lower shelves of damaged reinforced concrete panels, slots along the axis of symmetry of the hollow channels with a length of at least the length of the mounting core of the frame, a width of at least the width of the cross-section of the reinforcing frame, punch holes in the hollow channels on the supporting sections in the upper shelves of the panels with a step of 1.5 ÷ 2 m), then install through reinforced slots composite reinforcing cages or wire-frames in the hollow channels and concrete them, introducing reinforced concrete into the hollow channels through the holes at the top their shelves restored ceiling panels. 2. The method according to claim 1, characterized in that the reinforcing product in the form of a composite flat reinforcing wire mesh frame is performed with a single arrangement of reinforcing bars, with welding of the legs of the transverse rods by arc welding, with elongated rods of the working reinforcement, with bending of the legs of the working rods by 45 °. 3. The method according to claim 1, characterized in that the reinforcing product in the form of paired flat composite frames with clamps on the support part is performed by welding the legs of the transverse rods by arc welding with elongated rods of the working reinforcement. 4. The method according to claim 1, characterized in that the longitudinal working rod of the composite grid frame is cut with a length equal to the sum of half the length of the hollow channel of the panel and the length of the bypass rod of the working reinforcement, that is:
L _article = 0.5 · L _pan + l _{n, min} , mm,
where L _article , L _pan - respectively, the length of the working core of the frame-mesh and the length of the hollow channel of the panel, mm;
l _{n, min} = 40 · d _max - the length of the bypass (overlap) of the working rods, mm;
d _max - nominal diameter of the working rod, mm. 5. The method according to claim 1, characterized in that the gap located in the middle part of the lower shelf of the panel, through which flat composite wire-mesh frames are introduced into the hollow channel, is cut out with a length equal to:
l _slots = l _mount + z ₁ , mm,
where l is the _gap ; l _mount - respectively, the length of the slit and the length of the mounting rod of the reinforcing cage, mm;
z ₁ - the gap value equal to (40 ± 10) mm. 6. The method according to claim 1, characterized in that the gap in the lower shelf of the panel for entering a flat composite frame-mesh into the hollow channel is cut with a width equal to:
b _slots = 2 · (d ₁ + d ₂ ) + z ₂ ,
where b _slots - the width of the slit, mm;
d ₁ and d ₂ - respectively, the diameter of the longitudinal and transverse rod, mm;
z ₂ is the gap value equal to (5 ± 2) mm. 7. The method according to claim 1, characterized in that the flat frame is made with a width that is adopted depending on the height or diameter of the hollow channel of the panel, that is:
B = D-2 · (C ₁ +2), mm,
where B is the width of the frame along the axes of the extreme longitudinal rods, mm;
C ₁ - the distance from the axis of the longitudinal rods of the frame to the end of the transverse rods, but not less than 10 mm;
D - height (diameter) of the hollow channel of the panel, mm 8. The method according to claim 1, characterized in that the holes in the end sections of the upper shelf of the panel for filling concrete with its hollow channel are cut with dimensions taken from the conditions for pouring and vibrating reinforced concrete, for example, b ₀ × l ₀ = 40 × 160 mm;
here b ₀ and l ₀ are the width and length of the hole, respectively, mm. 9. The method according to claim 1, characterized in that to the longitudinal rods of the working reinforcement of the composite frames, an additional rod is calculated for the entire length of the slit cut in the lower shelf of the panel. 10. The method according to claim 1, characterized in that in the zone of action of the maximum bending moment, longitudinal rods of additional reinforcement are installed with a bypass in a dangerous section of the panel to reinforce it along the rebar diagram. 11. The method according to claim 1, characterized in that as concrete monolithic additional frames in the hollow channels of the panel pour lightweight structural concrete, such as expanded clay concrete.

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