FR2762032A1 - PROCESS OF DEMOLITION OF A BUILDING AND EQUIPMENT FOR THE IMPLEMENTATION OF THIS PROCESS - Google Patents

Abstract

The invention concerns a method for pulling down a storied building (1) consisting of an assembly of structural walls (2) and an assembly of slabs (3). The method comprises the following steps: sectioning the slab (3) of a predetermined storey, parallel to the structural walls (2), in a zone located beyond the structural wall next but one to the external wall; installing a push ram (10) in the resulting opening, parallel to the slab (3) and perpendicular to the structural walls (2); rigidifying the push ram (10) rear support zone; consolidating the push ram front support zone; installing at least a stay (30) in at least one of the rooms (4) located behind the push ram to form a transverse bracing; controlling the pressurisation of the push ram (10) to push forward the structural walls (2) and triggering at least the collapse of the slabs (3) and the structural walls (2) of the top storeys.

Description

METHOD FOR DEMOLMING A BUILDING AND EQUIPMENT FOR
THE IMPLEMENTATION OF THIS PROCESS
The present invention relates to a method of demolishing a multi-storey building consisting of a set of load-bearing walls which are substantially parallel to one another, commonly called sails, and a set of slabs forming the floors, the slabs being substantially parallel to one another and substantially perpendicular to said load-bearing walls, this process consisting in demolishing the building from top to bottom in sections of at least two floors. The invention also relates to equipment for implementing this method.

To demolish dilapidated buildings or any other building, made of reinforced concrete for example, one of the following solutions is generally used depending in particular on the height of the building, its environment, the cost and the time of the operation demolition: the oldest ball solution, which consists of deforming walls and slabs
under the action of a massive ball projected repeatedly against the building,
this ball being suspended at the end of the arm of a mechanical machine or a
crane,. the classic mechanical solution: snacking using a construction machine
hydraulic equipped with an arm up to about 30 meters and a shovel.

which is limited to buildings of approximately 8 to 10 floors maximum,. the explosive caving solution, which consists of disposing of the charges
explosives i predetermined locations to cause the overall collapse of the
building.

This last quick and effective solution is also very expensive since it is necessary to add to the own cost of the explosives and their installation, an external cost for locating and clearing a security perimeter around the building. , for example within a radius of 300 meters. This external cost includes all the administrative procedures and the deployment of security forces for the evacuation of dwellings, the interruption of land and air traffic, etc.

One can easily imagine the difficulties of implementing this process for a building located in the heart of a city. In known manner, this explosive caving solution only becomes profitable from a building of approximately 16 floors. In addition, it presents certain risks for operators when placing explosives since they must remove the shoring and bracing of the load-bearing walls, thus weakening the mechanical strength of the building which can under the effect of 'a seismic tremor collapse quickly.

 There is a priori no other cost-effective and time-efficient solution for buildings between 10 and 16 floors, representing a potential market of around 95% of buildings.

The purpose of the present invention is to remedy this lack by proposing a demolition process and equipment adapted to this height of buildings, without resorting to explosives, which allow the demolition of the building by slice of upper floors downward, not exceeding the footprint of the building on the ground, the cost of implementation of which is lower than that of the caving since it is not necessary to provide for the evacuation of a perimeter of security, or interruption of traffic, and whose completion time is less than that represented by a conventional or ball solution, or even by the manual dismantling of the building. In addition, this process is safe for operators since it is not necessary to weaken the entire structure of the building, by removing the bracing.

To this end, the present invention relates to a demolition process characterized in that it comprises the following stages: the slab of a determined floor is cut, parallel to the load-bearing walls, in
an area beyond the second load-bearing wall from the outer wall,. a thrust cylinder is installed in the opening thus created, substantially
parallel to the slab and substantially perpendicular to the load-bearing walls, the rear support area of the cylinder is stiffened, the front support area of the cylinder rod is consolidated, at least one forestay is placed in at least one room located at rear of cylinder
to form a brace,
the cylinder is pressurized to push the load-bearing walls in
before and at least trigger the collapse of slabs and load-bearing walls
upper floors.

So that the jack can rest on a uniformly flat area, a sealant is injected into the rear support area of the jack to fill the existing cavities.

An additional step can be provided which consists in creating rupture zones in the load-bearing walls by notching them parallel to the slab, in particular in the case of walls reinforced with metal reinforcements.

After the demolition of a first section of floors, the pushing and consolidation equipment is preferably recovered and the said steps are repeated.

The present invention also relates to equipment arranged for the implementation of this method characterized in that it comprises at least one thrust cylinder mounted in an opening formed in a slab by means of a chassis.

In a preferred embodiment of the invention, the chassis comprises at least one retaining plate positioned in front of the edge of the sectioned slab and fixed on two transverse profiles provided on either side of this slab.

The chassis may include longitudinal members arranged substantially perpendicular to the transverse sections and fixed to the slab to stiffen it.

Preferably, a sealant is injected between the retaining plate and the edge of the slab to fill all the cavities and form a uniform support plane for the jack.

In the preferred embodiment, the chassis comprises a support plate mounted parallel to the retaining plate by means of a hinge provided at the base of these plates, this support plate comprising a receptacle intended to receive the body of the actuator. thrust, which can be sealed in the barrel by means of at least one injected polyurethane foam.

The free end of the rod of the push cylinder advantageously comprises a partially spherical support head designed to press on the opposite edge of the slab cut and reinforced by at least one support profile fixed integrally.

In the preferred embodiment of the invention, the equipment comprises at least one forestay positioned in the diagonal of at least one part of the building arranged at the rear of the thrust cylinder to form a bracing.

This forestay may comprise at least two tubes sliding one inside the other, their free end being housed in a corner of said part reinforced by a metal angle. It is advantageously energized by at least one jack arranged between at least two brackets provided on said tubes and then fixed in position by a weld bead at the junction of the two tubes.

The present invention and its advantages will appear better in the following description of an exemplary embodiment, with reference to the accompanying drawings, in which: - Figure 1 schematically shows a building to be demolished with the positioning of the demolition equipment according to the invention, - Figure 2 is a view of the mounting of the jack in a slab in the pushing position, - Figure 3 is a perspective view of the mounting of the jack of Figure 2 after the pushing, and - Figure 4 is a view of the mounting of a forestay.

Referring to Figure 1, the building I to be demolished consists of a set of load-bearing walls 2 commonly called sails and a set of slabs 3 defining the floors numbered in Figure 1 from the ground floor to 8th. The load-bearing walls 2 and the slabs 3 schematically form a grid of rooms 4. The demolition process according to the invention consists in demolishing this building from top to bottom in sections of at least two floors, and in the example three floors , by exerting on a selected floor and on one side of the building a horizontal thrust in a slab in a direction substantially perpendicular to the load-bearing walls, having the effect of moving and laying these load-bearing walls forward in the direction of thrust shown by arrow P, causing the collapse of the other load-bearing walls and the slabs of the upper floors which collapse on top of each other. This slaughter operation is repeated three or four floors below and so on. For an eight-story building, only two operations are necessary, the remaining parts being demolished with a hydraulic shovel.

This demolition process involves the following stages: 1. Slab 3 of the determined floor is cut, for example the slab of the 7th,
parallel to load-bearing walls 2 and in an area beyond the second
load-bearing wall from the exterior wall, 2. a hydraulic thrust cylinder 10 is installed in the opening thus created,
parallel to slab 3 and perpendicular to load-bearing walls 2, by a
chassis 20 which makes it possible to stiffen the rear support zone of the jack, 3. the front support of the jack rod is consolidated, 4. stays are put in place in the parts located at the rear of the jack and floors
lower to make bracing, 5. the hydraulic pressurization of the jack 10 is controlled to push the walls
forward carriers and trigger the collapse of slabs and load-bearing walls of
upper floors and load-bearing walls of the lower floor as explained above
above.

It is clearly understood that, depending on the width of the building, several jacks 10 are installed in parallel in order to distribute the thrust force over its entire width.

To facilitate the felling of load-bearing walls 2, a step can be added to the above process in which rupture zones are created by forming notches 5 in the load-bearing walls 2 parallel to the slabs 3 and at determined locations for shearing, for example the metal reinforcements which are in the form of lattices incorporated into the walls or tie rods provided at the ends of these walls.

To demolish the second section of floors, the material used for the first section is recovered beforehand, namely the jacks 10, the frames 20 and the stays 30 to replace them, for example, three floors below.

It is easy to understand that this demolition process comparable to the demolition of a house of cards allows the demolition of the building from top to bottom while remaining substantially in the axis of the building without practically leaving the footprint of the building. A minimum security perimeter of around 3 meters around the site is sufficient.

With reference also to FIGS. 2 to 4, the demolition equipment allowing the implementation of the method described above comprises at least one thrust cylinder 10 of several tonnes (max. 100 tonnes), preferably hydraulic, a chassis of mounting 20 of the jack and braces 30 of bracing.

The frame 20 for mounting the actuator comprises a metal holding plate 21 positioned in front of the edge 3a of the sectioned slab 3 and fixed on two metal profiles 22 in the shape of a U, transverse and provided on either side of this slab .

U-shaped metal beams 23 are provided perpendicular to the transverse profiles 22, fixed on the slab 3 to stiffen it so that it resists the thrust of the jack 10. A sealing product, such as fast cement grout, is injected between the retaining plate 21 and the edge 3a of the slab to fill any cavities that may exist and form a uniform support plane for the jack 10. This chassis 20 also includes a metal support plate 24, mounted parallel to the holding plate 21 by means of a hinge 25 provided at the base of these plates. This support plate 24 comprises a metal barrel 26 intended to receive the body 11 of the thrust cylinder 10. The latter is positioned in the barrel 26 by needle screws 27 and then sealed by means of an injected polyurethane foam or any other appropriate system. An orifice 28 is arranged in the barrel 26 to receive the fittings 12 of the supply pipes of the jack 10, these fittings also intervening in the mechanical holding of the jack. The free end of the rod 13 of the thrust cylinder 10 comprises a partially spherical support head 14 made for example of hardened steel and intended to press on the opposite edge 3b of the sectioned slab. This section 3b is also reinforced by a support profile 29 fixedly attached to it by means of two transverse U-shaped profiles 22.

The presence of the support head 14 at the end of the rod of the jack 10 allows it to provide support whatever the thrust angle which is not always precisely at 900. The stays 30 are provided to consolidate the existing parts 4 located at the rear and on the lower floors relative to the jack 10 by forming braces.

Each forestay comprises two metal tubes 31, 32, preferably of square section and sliding one inside the other, provided at their free end with a round drawn profile 33 intended to be housed in a corner of the part 4 reinforced by a metal angle 34.

Each stay is placed in the diagonal of the part 4, tensioned by a jack 35 disposed between two brackets 36 provided on said tubes 31, 32 and fixed in the stretched position by a weld bead at the junction 37 of the two tubes. After welding, the tensioning jack 35 is removed.

During felling and during pushing, the jack 10 is held in the opening of the slab 3 between the two sections 3a and 3b. As soon as the load-bearing walls 2 fall, the edge 3b of the slab moves away, the jack 10 is no longer held and retracts automatically under the remaining slab, according to arrow A shown in FIGS. 1 and 3, thanks to the hinge coupling the support 21 and holding plates 24. For this purpose, the near bearing wall 2 is cut to provide an opening intended to receive the jack in the rest position. The jack 10 is thus protected from falling rubble and can be reused. Similarly, the struts 30 are also recoverable after removing the weld bead which keeps them under tension.

This description clearly shows that all the objects mentioned above are achieved by the invention.

The present invention is not limited to the embodiment described but extends to any modification and variant obvious to a person skilled in the art. In particular, the number of parts, their shape and dimensions, their location can vary while remaining within the protective field defined by the appended claims.

Claims (15)

Claims 1. Method of demolishing a building (1) of several floors consisting of a set of load-bearing walls (2) substantially parallel to each other commonly called sails and a set of slabs (3) forming the floors, the slabs being substantially parallel to each other and substantially perpendicular to said load-bearing walls, this process consisting in demolishing the building from top to bottom in sections of at least two floors, characterized in that it comprises the following steps:. we cut the slab (3) of a given level, parallel to the load-bearing walls  (2), in an area beyond the second load-bearing wall from the wall  outside,. a thrust cylinder (10) is installed in the opening thus created, substantially  parallel to the slab (3) and substantially perpendicular to the load-bearing walls  (2),  the rear support area of the jack (10) is stiffened,  the front support area of the cylinder rod is consolidated, at least one forestay (30) is placed in at least one part (4) located at the rear  of the jack to form a brace, the pressurization of the jack (10) is controlled to push the load-bearing walls  (2) forward and at least trigger the collapse of the slabs (3) and walls  carriers (2) of the upper floors. 2. Demolition method according to claim 1, characterized in that a sealant is injected into the rear support zone of the jack. 3. Demolition method according to claim 1, characterized in that an additional step is provided which consists in creating rupture zones (5) in the load-bearing walls (2) by notching them parallel to the slab (3). 4. Demolition method according to claim 1, characterized in that, after the demolition of a first section of floors, the pushing material (10) and consolidation are recovered and said steps are repeated. 5. Demolition equipment for implementing the method according to any one of the preceding claims, characterized in that it comprises at least one thrust cylinder (10) mounted by means of a frame (20) in an opening formed in a slab (3). 6. Equipment according to claim 5, characterized in that the frame (20) comprises at least one retaining plate (21) positioned in front of the edge (3a) of the sectioned slab and fixed on two transverse sections (22) provided on the side and other of this slab (3). 7. Equipment according to claim 6, characterized in that the chassis (20) comprises longitudinal members (23) arranged substantially perpendicular to the transverse profiles (22) and fixed on the slab (3) to stiffen it. 8. Equipment according to claim 6, characterized in that it comprises a sealant injected between the retaining plate (21) and the edge (3a) of the slab to fill all the cavities and form a uniform support plane for the cylinder. 9. Equipment according to claim 6, characterized in that the frame (20) comprises a support plate (24) mounted parallel to the holding plate (21) by means of a hinge (25) provided at the base of these plates, this support plate comprising a casing (26) intended to receive the body (11) of the thrust cylinder (10). 10. Equipment according to claim 9, characterized in that the body (11) of the jack (10) is sealed in the lût (26) by means of at least one injected polyurethane foam. 11. Equipment according to claim 5, characterized in that the free end of the rod (13) of the thrust cylinder (10) comprises a support head (14) partially spherical intended to press on the opposite edge (3b) of the slab (3) cut. 12. Equipment according to claim 11, characterized in that the opposite edge (3b) of the slab is reinforced by at least one support profile (29) fixed integrally. 13. Equipment according to claim 5, characterized in that it comprises at least one forestay (30) positioned in the diagonal of at least one room (4) of the building disposed at the rear of the thrust cylinder (10 ) to form a brace. 14. Equipment according to claim 13, characterized in that the forestay (30) comprises at least two tubes (31, 32) sliding one inside the other, their free end being housed in an angle of said piece reinforced by a metal angle (34).  15. Equipment according to claim 14, characterized in that the forestay (30) is placed under  tension by at least one jack (35) arranged between at least two brackets (36) provided  on said tubes then fixed in position by a weld bead at the junction (37) of  two tubes (31, 32).