RU2547849C1 - Control method of enlargement of survivability of multi-storied bearing-wall building after explosion action and safe performance of repair and restoration work - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: when there are no cracks in floor slabs and in wall panels, horizontal and vertical boundary planes are installed, within which removal of building members will be performed. First, all below-lying floors are reinforced, starting from installation of distribution traverses and posts below the installed horizontal boundary plane. Then, all the above-lying floors are subsequently reinforced with partial and/or complete destruction. All the members of the building are reinforced by means of reserve temporary structures. Removal of damaged members is performed in series after reinforcement starting from the top floor and within the installed vertical and horizontal boundary planes for removal by means of two hoisting cranes, one of which is used for removal of the demountable structural member of the building, and the other one is used for protection of the structural members of the building, which are adjacent to it.

EFFECT: blocking of a progressive failure process of a building with further renovation of the building.

3 cl, 31 dwg

Description

The invention relates to the field of construction and, in particular, to the restoration of residential, public and administrative emergency multi-storey panel buildings after an explosive impact inside a building with partial or progressive local collapse, ensuring the survivability of the emergency building in the process of its restoration and the safe conduct of repair and restoration work.

A known method of construction, restoration or reconstruction of buildings, structures (patent RU No. 2285771, ЕВВ 1/20, ЕВВ 5/16, publ. 20.10. 2006), including preparation of the base, construction of the foundation, construction or restoration, or reconstruction of the frame or its part , including columns, crossbars and floor slabs, as well as installation or disassembly and replacement of engineering systems. The method is aimed at improving the joint work of building frame structures by creating a monolithic spatial structure. For this, the frame is prefabricated monolithic. Monolithic joints of columns. The lower part of the crossbars (prefabricated) and the upper part (monolithic) are performed with shelves, to which the slabs are monolithic.

The disadvantage of this method is that the restoration of the building can be carried out only for emergency buildings with minor damage. However, the method cannot be applied to restore buildings with progressive collapse as a result of explosive exposure.

A known method of restoration or reconstruction of a multi-storey building or structure (patent RU No. 2382859, E04G 23/00, published on 02.27.2010), which consists in the fact that they strengthen the collapse zone and carry out elementwise restoration of structures. Reinforcement is carried out using temporary structures, namely, through installation adjacent to the longitudinal vertical element with the ability to assemble and disassemble, at least fasten one column, which is made through, passing through the ceiling, at least one floor above and below the zone collapse. The ends of the column are fixed to the intact longitudinal vertical elements of the upper and lower floors with temporary connections. On the section of the column located in the collapse zone, a power mechanism is installed to unload the damaged longitudinal vertical element, which allows the transfer of a pre-calculated load, the value of which should not exceed the force acting in the vertical longitudinal element before it is damaged. Repair or remove damaged items. After carrying out repair work, the column is unloaded and dismantled.

Application of the method allows to restore only the vertical frame elements of a multi-storey building. However, the method cannot be applied to restore buildings with progressive collapse as a result of explosive exposure.

The prototype of the claimed invention is a method of ensuring the survivability of an emergency building or structure and the safety of repair and restoration work (patent RU No. 2441967, E04G 23/00, publ. 02/10/2012), including the strengthening of the source or areas of collapse with the help of backup temporary structures and the power mechanism , for example, a jack, element-wise restoration of unloaded damaged structural elements of a building or structure, their strengthening and dismantling of temporary backup structures after restoration. To block the development of the process of progressive collapse of a building, structure, strengthening of the centers of collapse is carried out by creating backup temporary structures that strengthen structures in the diagnosed emergency situation adjacent to all centers of partial damage and collapse of a building or structure, while first strengthening structures adjacent to the centers of partial damage or collapse closest to the entrance to the building or any other access to the building, starting from level soil with successive work to strengthen in other foci of partial damage or collapse, closest to the previous one within the first floor, and at the end of temporary consolidation on the first floor, they move sequentially to the upper floors, while the installation of reserve temporary structures on each overlying floor continues in the same sequence, starting from the previous fortified structural element in the diagnosed emergency position, by installing standby time structures on their surface, taking into account the actual position in the space of emergency plates or beams, then after strengthening the foci of partial damage or collapse, restoration and strengthening of the foundation or foundation and structural elements of the building located along the contour of the reserve temporary structures are carried out, restoration of the working position of all partially or completely destroyed and (or) collapsed floor slabs, beams, girders and consoles and their strengthening for all foci of partial damage and collapse I am buildings, structures. As backup temporary structures, thrust supports, or struts, or struts, or collapsible structures with minimal design values of their ground pressure are used. After dismantling the backup temporary structures, the engineering systems of the building or structure are restored. In the case of accelerating the development of the process of the progressive collapse of the building, structure or the inclusion of backup temporary structures with the occurrence of a possible situation associated with a risk to people's lives, an emergency command is given to stop the work and evacuate people conducting work inside the building, structure, diagnose the building on verification of the bearing capacity of building structures and the backup temporary structures involved in the work and in the case of ensuring the safety requirements for the restoration of the emergency iynogo building, construction continues in the same sequence.

The application of the prototype method allows to ensure the survivability of the emergency building and to ensure the safety of repair and restoration work, while the restoration of the building can be carried out with significant damage, in the presence of foci of damage and collapse of the building or structure, including with progressive collapse. However, the method cannot be used to restore the building as a result of explosive action, since at the epicenter of the explosion the supporting structures of the building lose their bearing capacity and cannot be restored without their complete dismantling. The application of the method does not provide survivability, does not prevent the progressive collapse of the emergency building and does not ensure the safety of repair and restoration work in the event of damage caused by an explosion inside the building.

The task of the invention is to control the process of increasing the survivability of an emergency building in the presence of one or more foci of damage and collapse due to explosive impact during its restoration and to ensure the safety of repair and restoration work. The technical result when implementing the method is to block the process of progressive collapse of the building, to redistribute excess loads in damaged structural elements in the foci of damage and collapse, followed by temporary restoration of the structural design of the building due to backup temporary structures, dismantling of emergency elements and complete restoration of the building.

The technical result that allows us to solve the problem is achieved as follows.

As in the prototype, the emergency state of the building is diagnosed and all the centers of partial or complete destruction of the structural elements of the building are identified, after which, by installing backup temporary structures, the structural elements of the building adjacent to the centers of collapse or, if necessary, located closest to the access point are strengthened the building, then successively, starting from the lower floor, strengthen the centers of collapse in the diagnosed emergency situation, taking into account the actual position in the emergency space the structural elements of the building, after the collapse of the strengthening foci operate unloaded exploded recovery of damaged building parts, followed by removing redundant temporary structures, as which are used ryazhevye support, racks, struts, collapsible structures, and reduced engineering building system.

In contrast to the prototype, the danger level and the degree of preservation of individual structural elements in their interaction within the building are first assessed when they first enter the building after an explosive impact and, if necessary, backup temporary structures, for example, made in the form of racks, are installed after why they diagnose the emergency state of the bearing and hinged wall panels and floor slabs, prepare the supporting surface with its alignment, if necessary, for installations of temporary backup structures with which to fix damaged load-bearing wall panels, suspended wall panels and floor slabs of the building, followed by compaction of their places of support against temporary backup structures, for example, using wooden wedges, while pre-setting the boundaries in which redistribution is necessary structural elements of the building after the explosion, determining the boundary horizontal and vertical planes by the criterion of the absence of cracking, respectively, in the plates floors and wall panels, and first strengthen all the underlying floors relative to the epicenter of the explosion in series, starting with the installation of distribution traverses and racks below the established horizontal boundary plane, and then sequentially strengthen all the floors above the epicenter of the explosion with partial and / or complete collapse; first, in the focal points of the collapse, a hinged wall panel, deprived of the bearing area, is fixed in space, and the transverse or transverse bearing wall panels conjugated with it, deprived of the bearing areas, are fixed using redundant temporary structures fixed to each other, made in the form of unloading frames installed on a preliminary prepared supporting surface perpendicular to the transverse load-bearing wall panels, one of which is located directly under the hinged wall panel for the entire length deprived area of its bearing; then they fix in space the transverse bearing walls, which are not conjugated with the hinged wall panel, devoid of bearing areas, fix them with the help of unloading frames installed on a previously prepared supporting surface perpendicular to the indicated walls; after which they fix in space longitudinal bearing wall panels devoid of bearing pads, each with a backup temporary structure in the form of an unloading frame consisting of racks installed between the lower and upper floor slabs on a previously prepared supporting surface along a longitudinal bearing wall and near its projection line supporting racks of horizontal beams located along the projection line of the emergency longitudinal load-bearing wall, and struts connecting the racks; in the foci of partial damage or collapse, the transverse load-bearing walls emerging from the vertical plane and the corresponding floor slabs are strengthened with spacer bars or frames that are installed perpendicular to the transverse load-bearing walls and are supported on struts with struts or collapsible structures installed on a previously prepared surface with seal in the lower part, while the number and step of installation of spacer bars is selected from the condition of uniform distribution of forces on the transverse carriers heating spirals and slabs; in addition, with the help of a voluminous reserve temporary structure mounted on a previously prepared supporting surface and made in the form of racks with struts pivotally connected on both sides, partially destroyed floor slabs are deprived of support; in addition, with the help of racks, struts, frame and collapsible structures, all completely destroyed floor slabs and wall panels or their fragments are fixed, respectively deviated from a horizontal or vertical position; moreover, after all damaged structural elements are reinforced with temporary backup structures, all structural elements of the building are dismantled sequentially, starting from the top floor and within the established boundary vertical and horizontal dismantling planes, and the structural elements of the building are dismantled using at least two cranes, one of which remove the dismountable structural element of the building, and another - at the same time insure the associated structural an element or structural elements of a building from changes in their spatial position and collapse, after complete dismantling, the building is restored with the dismantling of the corresponding reserve temporary structures.

Elements of building structures that do not have signs of destruction by the criterion of the absence of crack formation, after dismantling the building, it is advisable to store and use it during the subsequent restoration of the building.

They also assess the danger of collapse and loss of stability of the design position of the structural elements of the neighboring building entrances for making a decision on the evacuation or non-evacuation of residents of these entrances for the period of repair and restoration work.

The specified set of technical features in the known technical solutions is not found, which confirms the novelty of the invention.

A multi-storey building after an explosive effect can be completely restored if, as a result of the examination, it is revealed that the supporting structures of the building or structure have retained the bearing capacity. In this case, the recovery process does not violate the safety of repair work.

If the stability of the building is preserved as a result of the explosive impact, there is no cascade collapse, and the examination will reveal that the supporting structures, although damaged, can be restored, the building can be partially dismantled and / or restored.

In the latter case, it is economically feasible to dismantle and then replace only those completely or partially destroyed building elements that are located below (along the border of the lower plane, the structural elements of which have not been destroyed) and all floors above the damage centers of the part of the building destroyed by the explosion with the strengthening of the underlying floors with using redundant temporary structures, allowing to redistribute possible destructive loads to the level of safe in partially destroyed structural elements tions that may arise in the event of a sudden collapse of structures or elements in the process of dismantling. As a result of the explosion for panel and large-panel buildings, as a result of the complete destruction of the load-bearing wall panels, transverse and longitudinal walls, structures are formed that are deprived in whole or in part of the bearing areas. Excessive loads are formed in the building structure, the adaptation mechanism is activated due to the inclusion of redundant connections in the connection of structural elements, which, before the explosion, play the role of auxiliary, technological.

In this case, during the restoration of the building, backup temporary structures should be formed to replace the load-bearing structures of the building completely destroyed by the explosion. Redundant temporary structures perform until the dismantling of damaged or destroyed building elements the function of these structural elements of the building and provide full or partial restoration of the structural design of the building, which was before the explosion. All potentially dangerous structural elements subject to a possible further cascade collapse, according to the claimed method, are fixed in the identified diagnosed position using a variety of backup temporary structures until they are dismantled.

As a result, the process of gradual increase of building survivability is ensured from the minimum value of the building structure's bearing capacity as a result of an explosion at the boundary of the progressive collapse process with intermediate temporary restoration of the building structural scheme due to temporary backup structures blocking due to this development of the progressive collapse process and the stage-by-stage formation of a sufficient load reserve for subsequent safe dismantling of damaged explosive m of structural elements and its further full restoration to the initial design level. In this case, it is possible to ensure safety for the time and in the process of repair and restoration work.

As a result of the search for technical solutions in the field of restoration of emergency buildings subjected to explosive impact, no solutions have been identified that have signs that match the distinguishing features of the claimed invention. No solutions have been identified for the full restoration of buildings, which provide a controlled process to increase the survivability of an emergency building as a result of explosive action from the lower boundary of the blocking process of progressive destruction of the building with an intermediate temporary restoration of the building’s structural scheme due to backup temporary structures and its subsequent subsequent full restoration with safety repair work at all stages. Thus, the analysis of the prior art showed that the invention meets the condition of an inventive step, since it does not explicitly follow from the prior art.

The invention is illustrated by photographs of the photofixation of the restoration process on the example of an emergency large-panel 10-storey residential building as a result of a gas cylinder explosion on the 9th floor, at the following address: Tomsk, st. Siberian 33, restored using the proposed method in the 1st quarter of 2013

In FIG. Figure 1 shows the formed reserve temporary structure of a reinforced underlying floor not exposed to explosive impact, in the form of distribution traverses with collapsible structures (racks) supporting a partially destroyed floor slab (8th floor of a residential building).

Figure 2 shows the formed backup temporary structure, redistributing the load two floors below the floor exposed to the explosive impact, in the form of distribution traverses with collapsible structures from racks resting on the explosion-proof floor slab (7th floor of a residential building).

Figure 3 shows the source of the collapse with a hinged wall and transverse bearing panels without bearing areas.

Figure 4 shows the backup temporary structure installed in the center of the collapse for the hinged wall and transverse load-bearing panels devoid of bearing areas, made in the form of a spatial unloading frame before dismantling these emergency panels.

Figure 5 shows the backup temporary structure of the hinged wall and transverse load-bearing panels without support areas after their dismantling.

Figure 6 shows the center of the collapse with a transverse bearing wall, devoid of areas of support.

In Fig.7 shows the first stage of the Assembly of the backup temporary structure of the transverse load-bearing walls without bearing areas depicted in Fig.6.

On Fig shows a fully assembled backup temporary structure of the transverse load-bearing wall without bearing areas depicted in Fig.6.

In Fig.9 shows a backup temporary design of a longitudinal bearing wall, devoid of support area mounted on a pre-prepared surface.

Figure 10 shows the backup temporary design of a longitudinal bearing wall, devoid of support area, in a fixed position with a redistributed load front view.

11 shows a temporary backup design of a longitudinal load-bearing wall devoid of a bearing pad in a fixed position with a redistributed load side view.

On Fig shows a fragment of the collapse after dismantling the emergency longitudinal load-bearing wall, devoid of support area.

On Fig shows the source of damage and collapse with a damaged right load-bearing wall, emerging from a vertical plane, and completely destroyed by the left transverse load-bearing wall and the collapse of the floor slabs.

On Fig shows the source of damage and collapse with a damaged right longitudinal bearing wall and the collapse of the floor slabs.

On Fig shows a fragment of a backup temporary structure of the transverse load-bearing walls extending from the vertical plane, and floor slabs with installed spacer beam, resting on racks together with collapsible structures.

On Fig shows a fragment of the backup temporary structure of the transverse load-bearing walls that emerged from the vertical plane, and floor slabs with installed spacers between the transverse load-bearing wall, emerging from the vertical plane, and the surviving partition.

On Fig shows the installed backup temporary design of the transverse load-bearing walls, emerging from the vertical plane, and floor slabs in the source of damage and collapse, shown in Fig.13.

On Fig shows the installed backup temporary structure of the transverse load-bearing walls, emerging from the vertical plane, and floor slabs in the source of damage and collapse, shown in Fig.

In Fig.19 shows the source of damage and destruction (Fig.13-18) after applying the backup temporary design of the transverse load-bearing walls that emerged from the vertical plane, and floor slabs after dismantling the emergency transverse load-bearing walls that emerged from the vertical plane, and completely or partially destroyed floor slabs.

On Fig shows the source of damage and collapse with devoid of support and partially destroyed slabs.

In Fig.21 shows the same source (Fig.20) of damage and collapse with an installed rack, made with a hinge in the upper part with two corresponding struts with the possibility of initial safe and remote installation of the rack in the epicenter of the center of partial damage or collapse of a building or structure, the rack is strengthened by three struts and mounted on a previously remotely prepared surface.

On Fig shows the process of preparing the supporting surface with alignment by laying a bag of sand to install a backup rack.

On Fig shows the installed backup temporary design devoid of support and partially destroyed floor slabs in the center of damage and collapse.

On Fig shows the source of damage and destruction (Fig.20-23) after applying the backup temporary design devoid of support and partially destroyed floor slabs after dismantling emergency partially destroyed floor slabs.

On Fig shows a completely destroyed floor slab, fixed with a backup temporary structure of a completely destroyed floor slabs or wall panels, made in the form of a frame and strut.

On Fig shows a completely destroyed floor slab, fixed with a backup temporary structure of a completely destroyed floor slabs or wall panels, made in the form of a rack and strut.

On Fig shows a completely destroyed wall panel, fixed with a backup temporary structure of a completely destroyed floor slabs or wall panels, made in the form of a strut.

On Fig shows the destroyed 9 floor of a 10-storey residential building after exposure to an explosion.

On Fig shows the process of dismantling emergency structural elements of the building, in which one crane keeps the wall panel from falling, and the second crane provides the lifting of the dismantled structure, while all emergency structural elements of the building are fixed using local backup temporary structures.

On Fig shows the dismantling process, while one crane keeps the wall panel from falling, and the second crane allows the dismounted structure to lower to the ground.

On Fig shows a 10-storey fully restored residential building damaged by the explosion, after the completion of repair work carried out according to the proposed method.

The invention is industrially applicable, since it can be repeatedly used to restore any emergency panel buildings after an explosive action inside the building in the presence of one or more local foci of damage and collapse of the building, including progressive collapse of the entire building with the achievement of the specified technical result, which was confirmed by the application of the proposed method for the restoration of two emergency buildings, partially destroyed after the explosive action inside a multi-story panel nyh buildings in the Siberian city of Tomsk on the street, and 33 in the city of Tyumen on the street. Zapadnosibirskaya, 22 in the 1st quarter of 2013, without resettling residents of neighboring entrances who did not receive damage due to damping of the blast wave by airbags between typical temperature units.

The method is as follows.

The installation of backup temporary structures made in the form of racks or collapsible structures is carried out as necessary from the place of access to the building as it moves in the process of its examination. The emergency building is inspected and the boundaries of destruction and damage resulting from the explosive impact on the supporting and enclosing structures are determined. According to the results of the survey, a project is being carried out to strengthen the centers of damage and collapse with the help of temporary backup structures, taking into account the permissible design loads and the bearing capacity of the building elements. They compose a sequence of works to strengthen the centers of partial damage and collapse of the building, taking into account the safety of the work.

Further, in accordance with the project, the required number of racks and switchgears and collapsible structures and fastening elements with the help of a tower or wheeled crane is manufactured and delivered using a crane to the corresponding floor to the corresponding floor.

Strengthening, if necessary, of interfloor ceilings is carried out, the number of floors on which the fortifications are carried out, in general, depends on the power of the explosive device and is selected according to the criterion of the absence of crack formation of floor slabs as a result of the explosion. The floor in which the floor slabs do not have cracks determines the horizontal plane of the boundary of the subsequent dismantling of the building, and the vertical plane of the boundaries of the dismantling of the building is selected according to the criterion of the absence of cracking of the transverse wall panels as a result of the explosion. Carry out the installation of backup temporary structures on the floor with the help of distribution traverses, ensuring the permissible design pressure on the floor slabs and taking into account their relative position in space (Fig. 1). The installation of backup temporary structures is carried out on the interfloor ceilings starting from the floor located under the floor, not subjected to destruction (figure 2), taking into account permissible loads and ensuring the safety of work.

They are fixed in space with the help of temporary backup structures in the diagnosed position: hinged wall and conjugate transverse bearing panels devoid of bearing areas, transverse bearing walls devoid of bearing areas, longitudinal bearing walls devoid of bearing areas, transverse bearing walls emerging from a vertical plane, partially destroyed floor slabs devoid of supports, completely destroyed floor slabs and (or) their fragments.

After completing the fixation of all potentially dangerous structural elements subject to possible further cascade collapse, dismantle completely destroyed and partially damaged structures using at least two cranes to ensure safe operation. Restore the structural elements of the building, starting from the top floor with the dismantling of the corresponding reserve temporary structures.

After completion of the restoration of the structural elements of the building, temporary backup structures are removed in all centers of partial damage and collapse of the building, structure. Next, they carry out installation or disassembly and replacement of engineering systems of the building.

The implementation of the method is most clearly shown by examples of the use of temporary backup structures at all stages of preparation, manufacture, installation of structures and the subsequent dismantling of potentially dangerous structural elements subjected to explosive impact, when performing repair and restoration work after an explosion on the 9th floor of a 10-story large-panel residential building in Tomsk on the street Siberian 33.

During the examination, it was found that on the 7th floor, floor slabs do not have cracks. The upper floor slabs are taken as the lower boundary plane for subsequent dismantling. The vertical boundaries of the planes are formed by transverse wall panels that limit the access. First, distribution traverses and racks were installed on the 7th floor (Fig. 2), then the 8th floor was strengthened (Fig. 2).

The hinged wall and conjugate transverse load-bearing panels devoid of bearing areas (Fig. 3) were fixed using backup temporary structures and made in the form of a spatial unloading frame, consisting of two parts. The first unloading frame is installed for fixing in space of a hinged transverse supporting panel without a support area perpendicular to the panel. Depending on the degree of damage to the wall panel, completely or partially destroyed by the explosion, the bearing capacity of the first unloading frame is calculated. Unloading frames are assembled on site or installed assembled. Frame elements can be made using wooden glued structures. Each unloading frame is mounted on a pre-prepared supporting surface. Figure 4 shows a variant of supporting two wall transverse load-bearing panels on one spatial unloading frame. Next, a second unloading frame is installed for fixing in space the wall panel connected to it along the entire length, where there is no support area. Both frames are fastened together using struts or beams and secured with sealing wedges installed in the upper part of the frame along the entire length of the hinged wall panel and at the points of support of the first unloading frame and the hinged transverse panel.

After dismantling the hinged wall and conjugate transverse load-bearing panels devoid of support areas, the spatial unloading frame is dismantled.

Transverse load-bearing walls, devoid of bearing areas (Fig.6), are fixed with the help of backup temporary structures, the implementation of which is carried out in two stages. Depending on the degree of damage to the transverse load-bearing wall, devoid of the bearing area, completely or partially destroyed by the explosion, the load-bearing capacity of the unloading frame is calculated. Unloading frames are assembled on site or installed assembled. Elements of frames are made, for example, using wooden glued structures. First, one or more racks or collapsible structures are installed on a previously prepared lower supporting surface with an emphasis on the upper transverse bearing wall in a place devoid of the bearing surface (Fig. 7). In the places of support of the racks, horizontal bars are installed with subsequent fixing in the upper part of the racks using sealing wedges or tension elements of collapsible structures. At the second stage, an unloading frame is installed, located in the space perpendicular to the transverse load-bearing wall, with fastening in the upper part with the help of sealing wedges or tension elements of collapsible structures (Fig. 8).

Longitudinal bearing walls, devoid of bearing areas, are fixed using backup temporary structures (Fig.9). The backup temporary structure in the center of the collapse is in the form of a spatial structure. Depending on the degree of damage to the longitudinal bearing wall, deprived of the bearing area in whole or in part, destroyed by the explosion, the bearing capacity of the reserve temporary structure is calculated. The backup temporary structure is assembled on site from prefabricated elements using, for example, wooden glued structures. In the immediate vicinity of the projection line of the emergency wall panel along its entire length, racks are installed between the undamaged lower and upper floor slabs on a previously prepared supporting surface (Fig. 9), for example, using a horizontal beam resting on stacked sandbags and fixed with wooden wedges between the rack and the horizontal beam. Between the upper part of the racks and the floor slab, horizontal beam beams are installed (Fig. 10), fixed with wooden wedges so that the ends of the beams intersect the projection line of the emergency wall panel, and a horizontal supporting beam is installed on the horizontal beam beams along the projection line of the emergency wall panel along its entire length . The gaps between the emergency wall panel and the horizontal supporting beam are sealed with wooden wedges (figure 10, 11). In FIG. 12 shows a fragment of an emergency construction of a load-bearing wall devoid of a bearing pad after its dismantling.

The transverse load-bearing walls emerging from the vertical plane and the floor slabs (Figs. 13, 14) are fixed with the help of a temporary backup structure in the area of partial damage or collapse and, if necessary, around its perimeter. The reserve temporary structure in the collapse center is performed in the form of a spatially distributed volumetric structure, each element of which has a common function - fixing the transverse load-bearing walls emerging from the vertical plane and floor slabs with load balancing on the reserve temporary structure for the entire local zone of damage and destruction (Fig. .13, 14). Depending on the degree of damage to the transverse load-bearing walls and floor slabs, completely or partially destroyed by the explosion, the bearing capacity of the reserve temporary structure is calculated. The backup temporary structure is assembled on site from prefabricated elements using, for example, wooden glued structures. In the center of partial damage or collapse (Fig. 15) and, if necessary, along its perimeter (Fig. 16), spacer beams are installed between the bearing walls that have left the vertical plane or other structural elements of the building or structure. Spacer bars (Fig. 17) are supported on struts with struts or collapsible structures, while the number and step of installation of spacer bars and racks (Figs. 17, 18) is determined by the uniform redistribution of forces between the bearing walls and the upper and lower floor slabs. Racks are installed on a previously prepared supporting surface with their subsequent fixing with the help of sealing wedges installed in the lower part of the racks. If necessary, sandbags are placed to level the lower support area of the racks. Spatial distributed volumetric design made of several spreader bars is fastened by struts (Fig.17, 18). After dismantling the transverse load-bearing walls that emerged from the vertical plane and the floor slabs, the backup temporary structure is dismantled. On Fig shows a fragment of the emergency construction of the transverse load-bearing walls, emerging from a vertical plane, and floor slabs after dismantling.

Partially destroyed floor slabs, deprived of support, (Fig. 20) are fixed by a backup temporary structure, which is carried out in stages in the form of a spatial structure of several racks fastened together by struts. Depending on the degree of damage to the deprived of support and partially destroyed floor slabs, the bearing capacity of the backup temporary structure is calculated and the required number of racks is determined (Fig. 20). The reserve temporary structure is assembled on site from prefabricated elements using wooden glued structures. At the first stage, at the installation site of the first rack, being at a safe distance from the place of possible fall of the floor slab, the abutment surface is prepared from pre-assembled elements of wooden glued structures. A pre-assembled strut with articulated struts, also at a safe distance, is installed using struts on a previously prepared bearing surface. Fasten using struts (Fig.21) and thereby provide minimal safety measures against the possible fall of the plate. Preparing the abutment surface for the second and subsequent racks (Fig.22). Installed racks fasten struts in a single volume backup temporary structure (Fig.23). As a result of the backup temporary construction, the load reserve of the structure increases from the minimum permissible level with one rack (Fig. 1) to the level of 4 racks with the necessary safety factor, which helps prevent possible collapse during the subsequent dismantling of the building (Fig. 23). If necessary, to level the lower platform supporting the racks, horizontal beam beams are laid on sandbags and, if necessary, followed by fixing with wooden wedges in the upper and (or) lower part of the racks. On Fig shows a fragment of the emergency construction of partially destroyed floor slabs, devoid of support, after dismantling.

The reserve temporary construction of completely destroyed floor slabs or wall panels is performed separately for each identified in a position other than horizontal on the underlying floor, a completely destroyed floor slab or completely destroyed wall panel identified in a position other than vertical. Depending on the design and the degree of damage to the floor slabs or wall panels, the bearing capacity of the backup temporary structure is calculated and the required number of racks, struts or frame structures made using wooden glued structures or collapsible structures is determined. Completely destroyed floor slabs are fixed, as shown in Fig.25, using frames and struts, Fig.26 - using racks and struts. Completely destroyed wall panels are fixed, as shown in Fig.27, using struts.

The dismantling of completely destroyed and partially damaged structures of the emergency building (Fig. 28) after strengthening its structure using a variety of backup temporary structures is provided with at least two cranes (Fig. 29), one of which raises and lowers the dismantled damaged or destroyed explosion of the structure, and the other provides the function of insurance against changes in spatial position and (or) collapse of the associated structural elements, at the same time carry out dismantling Backing temporary structures, retired from work. On Fig shows the dismantling process, while one crane keeps the wall panel from falling, and the second crane allows the dismounted structure to lower to the ground.

After dismantling all emergency building structure elements, including floors above the center of the explosive impact and below to the border of the building elements that were not destroyed (within the limits of the emergency building entrance), building is restored above the 7th floor using standard technology using building structure elements that have no signs of destruction by the criterion of the absence of cracking and those obtained during the dismantling of the building.

Fig. 31 shows a 10-storey fully restored residential building damaged by an explosion after completion of repair and restoration work performed according to the proposed method.

Claims (3)

1. A way to control the survivability of a multi-storey panel building after explosive impact and the safety of repair and restoration work, according to which the emergency state of the building is diagnosed and all the centers of partial or complete destruction of the structural elements of the building are identified, after which the structural elements of the building are first strengthened by installing temporary backup structures adjacent to the centers of collapse or, if necessary, closest to the access to the building, but sequentially, starting from the ground floor, they strengthen the collapse centers in the diagnosed emergency situation, taking into account the actual position in the space of emergency structural elements of the building, after strengthening the collapse centers, perform element-by-element restoration of the unloaded damaged structural elements of the building with the subsequent dismantling of the reserve temporary structures, which are used as tension supports , racks, struts, collapsible structures, and restore the engineering systems of the building, distinguishing I mean that they first assess the level of danger and the degree of preservation of individual structural elements in their interaction inside the building when they first enter the building after an explosive impact and, if necessary, establish backup temporary structures, for example, made in the form of racks, after moving to the epicenter of the explosive why they diagnose the emergency state of the bearing and hinged wall panels and floor slabs, prepare the supporting surface with its alignment, if necessary, for installation temporary temporary structures, with the help of which they fix the damaged load-bearing wall panels, curtain wall panels and floor slabs of the building with subsequent compaction of their places of support against the backup temporary structures, for example, with the help of wooden wedges, while the boundaries are preliminarily set, in which redistribution of structural elements of the building after the explosion, determining the boundary horizontal and vertical planes according to the criterion of the absence of cracking, respectively, in floor slabs wall panels, and first reinforcing underlying all floors relatively hypocenter sequentially from the switchgear installation and traverse struts below the horizontal boundary, and then sequentially strengthen all overlying with respect to the epicenter floors with partial and / or complete collapse; first, in the focal points of the collapse, a hinged wall panel, deprived of the bearing area, is fixed in space, and the transverse or transverse bearing wall panels conjugated with it, deprived of the bearing areas, are fixed using redundant temporary structures fixed to each other, made in the form of unloading frames installed on a preliminary prepared supporting surface perpendicular to the transverse load-bearing wall panels, one of which is located directly under the hinged wall panel for the entire length deprived area of its bearing; then they fix in space the transverse bearing walls, which are not conjugated with the hinged wall panel, devoid of bearing areas, fix them with the help of unloading frames installed on a previously prepared supporting surface perpendicular to the indicated walls; after which they fix in space longitudinal bearing wall panels devoid of bearing pads, each with a backup temporary structure in the form of an unloading frame consisting of racks installed between the lower and upper floor slabs on a previously prepared supporting surface along a longitudinal bearing wall and near its projection line supporting racks of horizontal beams located along the projection line of the emergency longitudinal load-bearing wall, and struts connecting the racks; in the foci of partial damage or collapse, the transverse load-bearing walls emerging from the vertical plane and the corresponding floor slabs are strengthened with spacer bars or frames that are installed perpendicular to the transverse load-bearing walls and are supported on struts with struts or collapsible structures installed on a previously prepared surface with seal in the lower part, while the number and step of installation of spacer bars is selected from the condition of uniform distribution of forces on the transverse carriers heating spirals and slabs; in addition, with the help of a voluminous reserve temporary structure mounted on a previously prepared supporting surface and made in the form of racks with struts pivotally connected on both sides, partially destroyed floor slabs are deprived of support; in addition, with the help of racks, struts, frame and collapsible structures, all completely destroyed floor slabs and wall panels or their fragments are fixed, respectively deviated from a horizontal or vertical position; moreover, after all damaged structural elements are reinforced with temporary backup structures, all structural elements of the building are dismantled sequentially, starting from the top floor and within the established boundary vertical and horizontal dismantling planes, and the structural elements of the building are dismantled using at least two cranes, one of which remove the dismountable structural element of the building, and another - at the same time insure the associated structural an element or structural elements of a building from changes in their spatial position and collapse, after complete dismantling, the building is restored with the dismantling of the corresponding reserve temporary structures. 2. The method according to claim 1, characterized in that the elements of building structures that do not have signs of destruction by the criterion of the absence of cracking, after dismantling the building are stored and used for subsequent restoration of the building. 3. The method according to claim 1, characterized in that they preliminarily assess the danger of collapse and loss of stability of the design position of the structural elements of the neighboring building entrances for making a decision on the evacuation or non-evacuation of residents of these entrances for the period of repair and restoration work.

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