JP2014227651A - Building demolition system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable parallel work of demolition and unloading to be performed by providing a demolishing crane and a ground unloading crane separately, and to allow the structure of a roof frame to be weight-saved and simplified by decreasing a load borne by the roof frame.SOLUTION: A building demolition system 1 is installed on a top layer F0 of a building 10 and is used to demolish the building 10 sequentially from the top layer F0. The building demolition system 1 comprises: a roof frame 6 supported by a plurality of support masts 2 provided along the periphery of the building 10; an overhead crane fixed on a lower side of the roof frame 6 and moving in the horizontal direction; and a telpher crane 5 supported by a skeleton of the building 10 and hoisting and lowering a suspended load in an opening continuously formed from the top layer F0 to a ground layer.

Description

  The present invention relates to a building demolition system that is installed in the uppermost layer of a building at the time of demolition of a high-rise building and is used to deconstruct the building from above.

  Conventionally, as a method for dismantling a building, a method of assembling a frame scaffolding from the ground around the outer periphery of the building and covering it with a soundproof panel or the like is known. In the case of RC buildings, dismantling machines are installed on the floor to be dismantled, and dismantling is performed while dropping the dismantling material from the upper floor to the first floor. In the case of an S-structure building, steel frames, floor slabs, etc. are cut into blocks with gas cutting, road cutters, etc., and dismantled while being lowered to the first floor with a tower crane or the like.

By the way, when dismantling a skyscraper with a height exceeding 100 m, the frame scaffold cannot be assembled from the ground, making it difficult to perform curing with a soundproof panel or the like.
Also, in the case of RC building demolition, there is a situation that it is difficult to adopt because the building is tall and dropping the demolition material on the ground floor generates vibration and noise. Furthermore, in the case of dismantling the S building, the building was tall, and the unloading of the dismantling material by the tower crane could be shaken due to the influence of the wind, and the dismantling material could fly or fall. .

  Therefore, as a method for dismantling high-rise buildings, a building dismantling system that forms a closed space in which the dismantling work area is covered with a roof and walls is provided, and the dismantling material is used inside the building with a crane installed in the closed space. Then, unloading is performed, and the entire building dismantling system is lowered for each floor in accordance with the progress of dismantling (see, for example, Patent Document 1).

  Patent Document 1 includes a step of dismantling the rooftop floor leaving an m-storey large beam, a step of providing a temporary column supported by the floor below the (m-2) floor and supporting the large beam as a temporary beam, A step of forming a dismantling work space by providing a roof frame composed of a temporary roof and a temporary wall covering the temporary beam and the temporary pillar, and dismantling from the rise of the m floor to the rise of the (m-1) floor in the dismantling work space. A structure dismantling method is disclosed that includes a step and a step of moving the temporary support column downward by one layer and repeating the dismantling operation in the dismantling work space.

  In addition, when a temporary roof is provided on the rooftop floor as in Patent Document 1, a terha crane for unloading the ground having a lift corresponding to the height of the demolished building is provided on the roof frame of the temporary roof, and the roof frame Below is an overhead crane that horizontally transports the dismantling material.

JP 2011-69117 A

However, the conventional building demolition system used for high-rise buildings has the following problems.
That is, in patent document 1, since the existing rooftop was partially used for the roof, there existed a problem that the weight of the whole system became large.
Moreover, in the case of a super high-rise building, the terha crane for unloading the ground has its own weight. For this reason, the Teruha crane and the overhead crane are installed on the temporary roof, and there is a problem that the load applied to the roof frame increases. In addition, for the overhead crane under the roof frame, a sliding-type overhead crane may be used for lifting and transporting the outer wall, and since it has a cantilever structure, the installation reaction force is large and the load on the roof frame is heavy. Further increase, there was a problem in the structure of the roof frame.

  In addition, if the same overhead crane is used for horizontal transport of dismantled materials and unloading to the ground that requires a lift of over 100m without installing a Teruha crane for unloading the ground, the horizontal transport and ground There was a problem that it was not possible to perform unloading in parallel work, and the time taken for the work became long.

The present invention has been made in view of the above-described problems, and provides a building demolition system capable of performing parallel operations of demolition and unloading by separately providing a demolition crane and a ground unloading crane. The purpose is to do.
Another object of the present invention is to provide a building dismantling system capable of reducing and simplifying the structure of the roof frame by reducing the load imposed on the roof frame.

  In order to achieve the above object, the building demolition system according to the present invention is a building demolition system that is installed on the uppermost layer of a high-rise building and dismantles the building in order from the uppermost layer. A roof frame supported by a plurality of support masts provided, a horizontal crane fixed to the lower side of the roof frame and moving in the horizontal direction, and an opening supported from the top layer to the ground layer supported by the building frame And a vertical crane for raising and lowering a suspended load.

In the present invention, since the horizontal crane and the vertical crane are separately provided in the uppermost layer of the building being dismantled, the horizontal crane is used for dismantling work, and the dismantling material obtained by dismantling the vertical crane with the horizontal crane is used as the ground layer. It can be used for the work that hangs down. Therefore, the horizontal conveyance of the dismantling material in the uppermost layer and the unloading of the ground can be performed in parallel, and the work efficiency can be improved.
And since the uppermost layer becomes a demolition space enclosed by the roof frame and becomes a demolition work in the demolition space, flying from a high place, falling, etc. can be eliminated during the demolition.

  Further, according to the building demolition system of the present invention, the vertical crane is directly supported by the structural frame such as the uppermost floor slab, so that the roof frame supported by the support mast has a load due to the weight of the horizontal crane and the suspension load. Only will work. Therefore, the load burden on the roof frame can be reduced as compared with the conventional case where the load of the horizontal crane and the vertical crane is applied to the roof frame. Accordingly, the structure of the building dismantling system such as the roof frame and the supporting mast can be simplified and reduced in weight, and the increase in size can be suppressed.

  Moreover, in the building demolition system according to the present invention, the horizontal crane includes an outer peripheral crane disposed on the outer peripheral side of the building in a plan view and an inner crane disposed on the inner side, and the inner crane and the outer peripheral crane. Are preferably provided so as to be movable within each suspension region.

  In the present invention, since the inner crane and the outer crane, which form a horizontal crane, are provided separately, the outer crane is used for dismantling the outer wall and main pillars located on the outer peripheral portion of the building, and separately from the inner crane. The crane can be used to dismantle floor slabs, main pillars, main beams, etc. inside the building. Moreover, since the internal crane and the outer crane can be moved into each other's suspension area, when the vertical crane is in the suspension area of the inner crane, the outer crane with the dismantling material such as the outer wall suspended from the outer crane. Can be moved to.

  In the building demolition system according to the present invention, the internal crane moves on an internal traverse rail that is guided by an internal traveling rail that extends along the first direction of the building, and the outer crane is the first crane. A first outer peripheral crane that travels on a first outer peripheral traverse rail that is guided by a first outer peripheral travel rail that extends along a direction, and a second outer peripheral travel that extends along a direction orthogonal to the first direction in plan view. A second outer peripheral crane that moves on a second outer circumferential traverse rail that is guided by the rail, and the inner traverse rail is arranged in a straight line with respect to the first outer peripheral traverse rail via a transfer rail. The inner traveling rail is preferably arranged on a straight line with respect to the second outer circumferential traverse rail.

  In this case, when the first outer traverse rail and the inner traverse rail are arranged on a straight line with the transfer rail interposed therebetween, the first outer crane moves from the first outer traverse rail via the transfer rail to the inner traverse. Can be transferred to the rail side. Further, when the second outer circumferential traverse rail and the inner traveling rail are arranged on a straight line, the second outer peripheral crane can be transferred from the second outer circumferential traversing rail to the inner traveling rail side.

According to the building dismantling system of the present invention, by disposing a horizontal crane as a dismantling crane and a vertical crane as a ground unloading crane separately, parallel work of dismantling and unloading can be performed.
In addition, according to the building dismantling system of the present invention, the load imposed on the roof frame is reduced, so that the structure of the roof frame can be reduced in weight and simplified.

It is a perspective view which shows the whole structure of the building demolition system by embodiment of this invention. It is a perspective view which shows the state which decomposed | disassembled a part of building demolition system shown in FIG. It is the side view which looked at the building under demolition by the building demolition system from one side of the long side. It is the top view which looked at the building demolition system from the upper part of a building, Comprising: It is the figure which abbreviate | omitted the roof frame. It is the side view which looked at the upper layer part of the building under demolition by the building demolition system from one side of the short side direction. It is a perspective view which shows the structure of a pair of support mast. It is a side view of a support mast. (A)-(d) is a figure which shows the descent | fall operation | movement procedure of a support mast. It is a top view which shows typically the arrangement | positioning state of an overhead crane. It is the side view seen from one side of the short side which shows the arrangement state of an overhead crane typically. It is a perspective view which shows the structure of an internal horizontal rail, a 1st outer periphery horizontal rail, and a transfer rail. It is the side view which shows the structure of the transfer shown in FIG. 11, Comprising: It is the figure seen from one side of a short side direction. It is a side view which shows the state which the 1st outer periphery crane transferred to the internal traverse rail side in the state of the transfer shown in FIG. FIG. 13 is a side view showing a state in which the internal traverse rail is transferred to the first outer crane side in the transfer state shown in FIG. 12. It is the side view which shows the structure of the transfer of an internal traveling rail and a 2nd outer periphery traversing rail, Comprising: It is the figure seen from one side of a long side direction. (A)-(c) is a side view which shows the assembly procedure of a building demolition system. (A)-(c) is a side view which shows the assembly procedure of the building demolition system following FIG.16 (c). (A), (b) is a side view which shows the demolition procedure of the building using a building demolition system. (A)-(c) is a side view which shows the demolition procedure of the building using the building demolition system following FIG.18 (b). It is a perspective view which shows the structure of the support mast by a modification, Comprising: It is a figure corresponding to FIG. (A)-(d) is a figure which shows the descent | fall operation | movement procedure of a support mast. (A)-(d) is a figure which shows the descent | fall operation | movement procedure of the support mast following FIG.21 (d). It is a partially broken perspective view which shows the whole structure of the building demolition system by other embodiment.

  Hereinafter, a building demolition system according to an embodiment of the present invention will be described with reference to the drawings.

  As shown in FIGS. 1 and 2, the building demolition system 1 according to the present embodiment is used for demolition of a super high-rise building (hereinafter simply referred to as a building 10) exceeding 100 m, for example, and is installed in the uppermost layer F0 of the building 10. It is for dismantling each hierarchy in order from the top.

As shown in FIGS. 1 to 5, the building 10 is an example of a steel structure (S structure) having a rectangular shape in plan view, and includes a main beam 11, a main column 12, a floor slab 13, and an outer wall 14. Is built by. In addition, the floor slab 13 of each floor is provided with an opening 15 for unloading that is continuous in the vertical direction from the uppermost layer F0 to the ground layer FG (see FIG. 3). The opening 15 is used as a later-described Teruha crane 5 and a passing part of a suspended load by the Teruha crane 5.
In addition, the building 10 includes a plurality of mast openings 16 (FIGS. 1 and 2) in each floor slab 13 of the uppermost layer F0 and several lower layers (here, the first lower layer F1 and the second lower layer F2). 2 and FIG. 5).

Here, in the building 10, the long side direction is indicated by a symbol X, the short side direction is indicated by a symbol Y, the direction toward the center of the building 10 in plan view is referred to as the inside, and the opposite side is referred to as the outside.
Further, in the present embodiment, the uppermost layer F0 is the uppermost layer of the building height at the time of dismantling, the layer one layer lower than the uppermost layer F0 at that time is referred to as the first lower layer F1, and further A layer one layer below is called a second lower layer F2, which is F3, F4,.

The building demolition system 1 includes a plurality of support masts 2 provided so as to protrude upward from the uppermost layer F0 of the building 10 to be demolished, a support frame 3 supported by the support mast 2 from below, and a support frame 3 The overhead crane 4 (horizontal crane) provided, the Telha crane 5 (vertical crane) provided in the uppermost layer F0, the roof frame 6 attached to the support frame 3 and constituted by a multi-truss, and the upper part of the roof frame 6 are covered. A soundproof sheet 7 and a soundproof panel 8 covering the side surface of the roof frame 6 over the entire circumference are provided.
As a result, a closed work space (referred to as a dismantling space R) is formed above the uppermost layer F0 of the building 10. In FIG. 1, only a part of the soundproof sheet 7 and the soundproof panel 8 is shown, but the soundproof sheet 7 and the soundproof panel 8 are covered all around.

  As shown in FIGS. 6, 7, and 8 (a), the support mast 2 is formed in a cylindrical shape, is provided through the mast opening 16 described above, and is temporarily attached to the permanent beam 11 ( (Not shown) is installed, and the horizontal and vertical loads acting on the support mast 2 are supported on the structural frame composed of the floor slab 13 of a predetermined level through the temporary receiving beam, as shown in FIG. A plurality are installed at predetermined intervals along the outer peripheral edges of two opposing sides along the long-side direction X of the building 10. The support masts 2, 2 arranged at opposing positions are connected by a connecting material 27.

And the support mast 2 is provided with the descent | fall mechanism 20 provided with the hydraulic jack, and even if the floor height changes with the dismantling of the building 10, it is possible to descend | fall the support part with respect to a structural frame one by one. .
In the lowering mechanism 20, a reaction force support portion 22, an upper support leg 23, and a lower support leg 24 are connected to the mast main body 21 by wires 25 at intervals in that order from top to bottom. The upper support leg 23 and the lower support leg 24 are detachably supported by the floor slab 13 of the building 10, respectively. An upper end and a lower end of the wire 25 are respectively fixed to the reaction force support portion 22 and the lower support leg 24, and an intermediate portion in the length direction of the wire 25 is passed through the upper support leg 23. That is, the support mast 2 according to the present embodiment has a configuration in which the middle portion in the length direction of the mast main body 21 (the support portion of the upper support leg 23) is supported by the one-layer floor slab 13 (this is called a one-layer support system). ).

  The upper support leg 23 is detachably provided at an intermediate portion in the vertical direction of the mast main body 21 and has a leg portion (not shown) that can be extended in the horizontal direction. The leg portion has a predetermined floor height in advance. State that is placed so as to be able to be placed on a temporary receiving beam 17 (see FIG. 8) provided in the mast opening 16 of the floor slab 13, and in which the leg portion is stored (the state where it does not protrude outward in the horizontal direction) ) Through the mast opening 16 through which the support mast 2 is inserted.

The upper support leg 23 includes a hydraulic jack 26 that can be fixed to or released from the wire 25 passing through the upper support leg 23. With the upper support leg 23 placed on the temporary support beam described above, the load applied to the support mast 2, that is, the load of the entire building dismantling system 1 is transmitted to the floor slab 13 via the upper support leg 23. It has become.
Such a lowering mechanism 20 has a structure in which the support mast 2 is sequentially moved to the lower floor by expanding and contracting the hydraulic jack 26 while alternately fixing or releasing the upper support legs 23 with respect to the mast body 21. ing.

  The lower support leg 24 has a leg portion (not shown) that can be extended in the horizontal direction, and this leg portion is provided in advance in an opening portion (mast opening portion 16) of the floor slab 13 having a predetermined floor height. It is provided so as to be placed on a temporary receiving beam. The mast main body 21 can pass through the mast opening 16 in a state in which the leg portion is stored (not overhanging), and the mast main body 21 is placed on the temporary support beam in a state where the lower support leg 24 is placed on the temporary support beam. A load applied to the main body 21, that is, a load of the entire building demolition system 1 is transmitted to the floor slab 13 (that is, the structural frame) together with the upper support legs 23.

  As a descending procedure of the building demolition system 1 using the support mast 2, as shown in FIG. 8 (b), the leg portion of the lower support leg 24 supported by the second lower layer F2 is accommodated and the floor slab 13 is accommodated. Release the support state for.

  Next, as shown in FIG. 8C, the mast body 21 is lowered together with the wire 25 using the hydraulic jack 26 of the upper support leg 23, and the lower support leg 24 is supported by the third lower layer F3. Subsequently, as shown in FIG. 8 (d), the upper support leg 23 is released from the mast main body 21, and the leg part is accommodated to release the support in the first lower layer F1, and the upper support leg 23 is connected to the wire. Lower along 25. Then, the support mast 2 is moved down by one level by being supported by the mast opening 16 of the second lower level F2 and holding and locking the upper support leg 23 to the mast body 21 at that position. Can do.

  The support frame 3 is fixed to the upper ends of the plurality of support masts 2 and is framed in a rectangular shape along the outer periphery of the building 10 in plan view as shown in FIGS. 1 and 4. Specifically, the support frame 3 includes a pair of vertical frames 31 and 31 extending along the long side direction X of the building 10, and a pair of horizontal frames 32 and 32 that also extend along the short side direction Y. Consists of. The vertical frame 31 and the horizontal frame 32 are formed in a ladder shape when viewed from above. The inner edge of the vertical frame 31 (the edge on the center side of the building 10 in plan view) is supported by the plurality of support masts 2.

  As shown in FIGS. 1, 2, and 5, the roof frame 6 hangs downward from the outer peripheral edge of the roof portion 61 and is supported by the support mast 2, and the side surface of the dismantling space R is suspended. And a side wall portion 62 for covering. The side wall portion 62 has a first support portion 63A that supports the upper portion of the side wall portion 62 on the support frame 3 and a lower portion of the side wall portion 62 that overlaps the outside of the uppermost layer portion of the building 10 and is supported by the structural frame of the building 10. 2 is supported at the upper and lower two points of the support part 63B and corresponds to the wind load. In the drawing, the side wall part 62 is provided only on the side wall along the long side direction X of the building 10, but the same side wall part 62 is also provided on the side wall along the short side direction Y.

  The soundproof sheet 7 is laid over the entire upper surface of the roof portion 61 of the roof frame 6. The soundproof panel 8 is installed over the entire outer peripheral surface of the side wall 62 of the roof frame 6. Thereby, the side and upper side of the dismantling space R are all covered with the soundproofing sheet 7 and the soundproofing panel 8, and are the spaces blocked from the outside.

  As illustrated in FIG. 2, the support frame 3 is provided with the above-described overhead crane 4 for horizontal conveyance of the dismantling material in the dismantling space R. As shown in FIGS. 9 and 10, the overhead crane 4 is disposed on the support frame 3 and the internal crane 41 disposed on the inner side surrounded by the vertical frame 31 and the horizontal frame 32 of the support frame 3 in plan view. And an outer peripheral crane 42 (42A, 42B).

  As shown in FIGS. 2 and 9, the internal crane 41 is a well-known overhead crane provided with traveling wheels, and is fixed to the lower side of the connecting member 27 of the support frame 3 and has a long side direction X (first direction). ) Is provided so as to be movable on an internal traverse rail 44 that travels while being guided by a pair of internal travel rails 43 extending toward the center.

  As shown in FIGS. 11 to 14, the internal transverse rail 44 extends along a direction orthogonal to the internal traveling rail 43 (that is, the short side direction Y), and the vertical frames 31 and 31 of the support frame 3 are separated from each other. The length dimension is set shorter than the dimension. Thereby, the internal crane 41 is within the range surrounded by the vertical frame 31 and the horizontal frame 32 of the support frame 3, that is, in the long side direction that is the traveling direction of the internal traverse rail 44 in the region inside the plurality of support masts 2. X can be freely moved in the short side direction Y, which is the transverse direction moving along the internal transverse rail 44.

  The outer cranes 42A and 42B are well-known cranes each provided with traveling wheels. Here, in the present embodiment, a pair of first outer peripheral running rails 45 </ b> A extending in the long side direction X are fixed to the lower side of the vertical frame 31 of the support frame 3, and A pair of second outer peripheral traveling rails 45B extending along the short side direction Y is fixed to the lower side.

  Then, the first outer peripheral crane 42A moves on the first outer peripheral traversing rail 46A that travels while being guided by the first outer peripheral traveling rail 45A. The second outer peripheral crane 42B moves on the second outer peripheral traverse rail 46B that travels while being guided by the second outer peripheral traveling rail 45B.

  The first outer circumferential rail 46A provided in the vertical frame 31 has the same height as the inner horizontal rail 44 and a length dimension substantially equal to the width dimension of the vertical frame 31, and the extending direction of the first outer circumferential rail 46A. Are provided in the short side direction Y toward the internal traverse rail 44 in the same direction.

  On the other hand, as shown in FIG. 15, the second outer circumferential traverse rail 46 </ b> B provided in the lateral frame 32 (see FIG. 2) is the same height as the internal travel rail 43 and has a length substantially equal to the width dimension of the lateral frame 32. The second outer circumferential rail 46 </ b> B extends in the long side direction X, that is, in the same direction as the internal travel rail 43.

  As shown in FIGS. 13 and 14, on the inner side of the vertical frame 31, the inner horizontal rail 44 and the same height as the first outer horizontal rail 46A for the first outer crane 42A extend in the short side direction Y. Transfer rails 47 are provided at a plurality of locations at appropriate intervals in the long side direction X. These transfer rails 47 are arranged between the inner transverse rail 44 and the first outer circumferential transverse rail 46A, and are provided so that the inner transverse rail 44 and the first outer circumferential transverse rail 46A coincide with each other on a straight line. For this reason, the transfer rail 47 is set to have a length dimension that is the same as or slightly shorter than the separation dimension between the inner transverse rail 44 and the first outer circumferential transverse rail 46A.

  In this way, the first outer peripheral crane 42A is arranged so that the first outer circumferential traverse rail 46A and the inner traverse rail 44 are positioned in a straight line with the transfer rail 47 at a predetermined position in between, so that the transfer rail from the first outer peripheral traverse rail 46A. It is possible to transfer to the internal traverse rail 44 via 47. That is, the first outer peripheral crane 42 </ b> A is moved to the suspension area of the internal crane 41 while hanging the demolition material such as the outer wall of the building 10, temporarily disposing the demolition material in the suspension area, and then the first outer crane. 42A can be returned to the original first outer circumferential traverse rail 46A, and the suspended load can be transferred, such as hanging the temporarily dismantled material with the internal crane 41.

  Further, as shown in FIG. 15, the second outer peripheral crane 42 </ b> B moves from the second outer peripheral transverse rail 46 </ b> B to the inner traveling rail 43 by positioning the second outer peripheral transverse rail 46 </ b> B and the internal traveling rail 43 in a straight line. It is possible. That is, the second outer peripheral crane 42 </ b> B is moved to the suspension area of the internal crane 41 while hanging the demolition material such as the outer wall of the building 10, and after temporarily disposing the demolition material in the suspension area, the second outer crane 42B can be returned to the original second outer circumferential traverse rail 46B, and the suspended load can be transferred, such as hanging the temporarily dismantled material with the internal crane 41.

  And as a crane for the unloading of the demolition material, a high-lifting Telha crane 5 (vertical crane) having a floor-climbing function and a climbing function is adopted. As shown in FIG. 3, the Telha crane 5 is provided in the opening 15 of the floor slab 13 of the uppermost layer F0 to be disassembled. Specifically, the Telha crane 5 includes a portal frame 51 having a traveling rail 52, a suspension 53 that moves along the traveling rail 52, and a support portion 54 that can be fixed to the floor slab 13 of a predetermined level. Yes. The support portion 54 can be attached to and detached from the floor slab 13, and can pass through each opening 15 in a non-fixed state with respect to the floor slab 13. Since the Telha crane 5 is placed on the floor in the uppermost layer F0, the load of the Telha crane 5 itself and the load of the suspended load in the vertical direction can be reduced.

  The climbing of the Telha crane 5 is performed by attaching / detaching the support portion 54 to / from the floor slab 13, and can cope with the change in floor height due to the dismantling of the building 10.

  Next, a method of installing the building dismantling system 1 described above on the uppermost layer F0 of the super high-rise building 10 will be described with reference to FIGS.

  As shown in FIG. 16 (a), the assembly jib crane 9 is arranged on the rooftop (uppermost layer F0) of the building 10, and a plurality of support masts 2 provided with the lowering mechanism 20 are installed on the uppermost layer F0. At this time, the support mast 2 is installed at a position where the upper end is lowered to the vicinity of the floor slab 13 of the uppermost layer F0. Moreover, the Telha crane 5 is assembled in the position of the opening for unloading formed in the opening part 15 (refer FIG. 1) formed in the floor slab 13 of each level of the ground layer FG.

  Next, as shown in FIG. 16B, the support frame 3 is installed on the plurality of support masts 2, and the lift-up device 91 is installed on the support frame 3. Then, the Telha crane 5 that has been assembled in the ground layer FG is unloaded, and the opening for opening is sequentially raised to the upper floor and climbed to the uppermost layer F0 by climbing, above the uppermost layer F0 (ie, the uppermost layer F0). (See FIG. 16C). In the ground layer FG, the side wall 62 of the roof frame 6 is assembled around the building 10, and the soundproof panel 8 is attached to the outer peripheral surface of the side wall 62.

  Thereafter, as shown in FIG. 16C, the lift frame 91 is used to lift the roof frame 6 having only the side wall 62 assembled with the ground layer FG, and the upper end of the side wall 62 is fixed to the support frame 3. To do. Then, the overhead crane 4 is assembled below the vertical frame 31 and the horizontal frame 32 of the support frame 3 shown in FIG. Specifically, as shown in FIG. 2, an internal traveling crane 43 and an internal traverse crane 44 for the internal crane 41 are assembled, and the internal crane 41 is attached to the internal traverse crane 44. Further, the first outer peripheral traveling crane 45A, the second outer peripheral traveling crane 45B, the first outer peripheral traversing crane 46A, and the second outer peripheral traversing crane 46B for the outer peripheral cranes 42A and 42B are assembled, and the outer peripheral traversing cranes 46A and 46B have outer peripheries. Crane 42A, 42B is attached.

  Next, as shown in FIG. 17A, the roof 61 of the roof frame 6 is assembled to the upper end of the support mast 2, and the soundproof sheet 7 is laid on the surface of the roof 61. At this time, a gap is not formed between the soundproof sheet 7 and the soundproof panel 8. Thereby, the assembly of the roof frame 6 provided with the soundproof sheet 7 and the soundproof panel 8 is completed, and the entire roof frame 6 is raised by the lowering mechanisms 20 (see FIG. 6 and the like) of the plurality of support masts 2. Then, as shown in FIG. 17 (b), as the roof frame 6 rises, the Telha crane 5 is raised and installed on the floor slab 13 of the uppermost layer F0, and the dismantling space on the uppermost layer F0. The building dismantling system 1 according to the present embodiment is installed in the uppermost layer F0 of the building 10 by being arranged in R. After that, as shown in FIG. 17 (c), equipment necessary for various dismantling is carried in and set in the uppermost layer F0 using the Telha crane 5, and preparation for dismantling of the building 10 is completed.

  Next, a method for dismantling the super high-rise building 10 using the building dismantling system 1 described above will be described with reference to FIGS.

  As shown in FIG. 18 (a), in the demolition space R formed in the building demolition system 1, the internal crane 41 is used to dismantle and dismantle the main beam 11 and the floor slab 13 in the uppermost layer F0. In parallel with the dismantling work, the material is suspended from the ground layer FG (see FIG. 3) using the Teruha crane 5 and carried out.

  Subsequently, as shown in FIG. 18B, the outer peripheral beam (not shown) located on the outer peripheral portion of the building 10 and the floor slab at the same location are disassembled using the outer peripheral crane 42. The dismantled material disassembled at this time moves the outer peripheral crane 42 to the suspension region of the inner peripheral crane 41, temporarily places one end in the suspension region, and transfers the dismantled material to the Telha crane 5 using the inner peripheral crane 41. Unload to ground level.

  Next, as shown in FIG. 19A, the main beam 11 and the floor slab 13 in the first lower layer F1 that is one lower than the uppermost layer F0 are disassembled using the internal crane 41, and the dismantled material disassembled. In parallel with the dismantling work, the terha crane 5 is used to suspend and unload it from the ground layer FG (see FIG. 3). Further, as shown in FIG. 19 (b), the outer peripheral beam and the floor slab located at the outer peripheral portion of the building 10 are disassembled using the outer peripheral crane 42, and the dismantling material is removed by the same procedure as that of the uppermost layer F0 described above. It moves to the suspension area of the inner periphery crane 41, and further passes to the Telha crane 5 using the inner periphery crane 41 and unloads it to the ground layer.

  Next, as shown in FIG. 19C, the entire building dismantling system 1 is lowered by one layer. That is, the first lower layer F1 described above is the uppermost layer F0 having the dismantling space R. Specifically, the Telha crane 5 shown in FIG. 3 is moved to the lower level by moving the support portion 54 to the lower floor slab. Thereafter, the support frame 3 and the roof frame 6 are moved down by the transfer of the support mast 2 by transferring the support mast 2 to the lower layer using the lowering mechanism 20 shown in FIG.

Next, the effect | action of the building demolition system 1 mentioned above is demonstrated in detail.
In the building demolition system 1 of the present embodiment, as shown in FIG. 5, the overhead crane 4 and the Telha crane 5 are separately provided in the uppermost layer F0 of the building 10 being demolished. It can be used for dismantling work, and can be used for the work which suspends the dismantling material which disassembled the Telha crane 5 with the overhead crane 4 on the ground layer FG or the like. Therefore, the horizontal conveyance of the dismantling material in the uppermost layer F0 and the unloading of the ground can be performed in parallel, and the working efficiency can be improved.
And since the uppermost layer F0 becomes the demolition space R enclosed by the roof frame 6 and becomes the demolition work in this demolition space R, the flying from a high place, a fall, etc. can be eliminated during demolition. .

  Further, in the present embodiment, since it is directly supported by a structural frame such as the floor slab 13 of the uppermost layer F0 that disassembles the Telha crane 5, the roof frame 6 supported by the support mast 2 Only the load due to the suspended load acts. Therefore, the load burden of the roof frame 6 can be reduced as compared with the case where the load of the overhead crane 4 and the Telha crane 5 is applied to the roof frame 6 as in the prior art. Accordingly, the structure of the roof frame 6, the support frame 3, and the support mast 2 of the building dismantling system 1 can be simplified and reduced in weight, and the increase in size can be suppressed.

Further, in this embodiment, since the overhead crane 4 is provided with the inner crane 41 and the outer cranes 42A and 42B separately, the outer cranes 42A and 42B are installed on the outer wall 14 and the main installation located on the outer peripheral part of the building 10. Apart from that, the internal crane 41 can be used for dismantling the floor slab 13, the main pillar 12, the main beam 11, etc. inside the building.
Moreover, since the inner crane 41 and the outer cranes 42A and 42B can be moved into each other's suspension region, when the Telha crane 5 is in the suspension region of the inner crane 41, the outer periphery in which the demolition material such as the outer wall 14 is suspended. The cranes 42 </ b> A and 42 </ b> B can be moved to the suspension area by the internal crane 41.

Further, in the present embodiment, when the first outer circumferential traverse rail 41 and the inner traversing rail 44 are arranged on a straight line with the transfer rail 47 interposed therebetween, the first outer circumferential crane 42A is moved from the first outer circumferential traversing rail 46A. It is possible to transfer to the internal traverse rail 44 side via the transfer rail 47.
Further, when the second outer circumferential traverse rail 46B and the inner traveling rail 43 are arranged on a straight line, the second outer circumferential crane 42B can be transferred from the second outer circumferential traversing rail 46B to the inner traveling rail 43 side. .

As described above, in the building dismantling system 1 according to the present embodiment, the overhead crane 4 serving as the dismantling crane and the Telha crane 5 serving as the ground unloading crane are separately provided, so that the parallel work of dismantling and unloading can be performed. It can be carried out.
Moreover, in the building demolition system 1 of this Embodiment, there exists an effect that the structure of the roof frame 6 can be reduced in weight and simplified by making small the load borne by the roof frame 6. FIG.

  Next, a modified example of the building demolition system according to the present invention will be described with reference to the accompanying drawings. However, the same or similar members and parts as those of the above-described embodiment are denoted by the same reference numerals, and the description is omitted. A configuration different from the embodiment will be described.

(Modification)
The supporting mast 2A of the building dismantling system according to the modified example has a one-layer support system as shown in FIG. 6 in the above-described embodiment, but instead of this, the two-layer support shown in FIG. This is a system configuration. In the case of the support mast 2A based on this two-layer support system, the intermediate support leg 28 is provided between the upper support leg 23 and the lower support leg 24, and the length dimension of the mast main body 21 is also shown in FIG. It is longer than the supporting mast 2 by two layers. In addition, since the structure of the mast main body 21, the reaction force support part 22, the upper support leg 23, and the lower support leg 24 is the same structure as the said embodiment, detailed description is abbreviate | omitted here.

  The intermediate support leg 28 has the same configuration as the upper support leg 23. That is, the intermediate support leg 28 is configured to be supported by the floor slab 13 below the floor slab 13 supported by the upper support leg 23, and has a leg portion (not shown) that can project in the horizontal direction. This leg portion is provided so that it can be placed in advance on a temporary receiving beam 17 (see FIG. 21) provided in the mast opening 16 of the floor slab 13 having a predetermined floor height, and the leg portion is stored (horizontal direction). The mast main body 21 can be passed through the mast opening 16 in a state in which the mast body 21 is not projected outward. The intermediate support leg 28 also includes a hydraulic jack 26 that can be fixed to or released from the wire 25 that passes through the intermediate support leg 28.

  In addition, the descent | fall procedure of the support mast 2A by such a two-layer support system is demonstrated based on FIG.21 and FIG.22. Here, the ▲ marks shown in FIGS. 21 and 22 indicate the support state, and those attached to the left and right sides of the support legs 23, 24, and 28 indicate the support state of the horizontal load, and also on the lower side. What is attached indicates the support state of the vertical load.

  In FIG. 21A, the horizontal load is supported by the upper support leg 23 on the floor slab 13 of the uppermost layer F0, the intermediate support leg 28 is disposed on the second lower layer F2, and the horizontal load and the horizontal load are provided by the lower support leg 24. Shows a state supported by the third lower hierarchy F3.

  First, as shown in FIG. 21 (b), the mast body 21 is raised using the hydraulic jack 26 of the upper support leg 23 supported by the uppermost layer F0, and the leg part of the lower support leg 24 is accommodated to the floor. By releasing the support state with respect to the slab 13, the intermediate support leg 28 supports the horizontal load, and the upper support leg 23 supports the vertical load in addition to the horizontal load.

  Next, as shown in FIG. 21 (c), the mast body 21 is lowered together with the wire 25 using the hydraulic jack 26 of the upper support leg 23, as shown in FIGS. 21 (d) and 22 (a). Then, the leg portion of the lower support leg 24 is extended outwardly and supported on the temporary receiving beam 17 previously installed on the floor slab 13 of the fourth lower layer F4. At this time, the horizontal and vertical loads of the mast body 21 are supported by the lower support legs 24 supported by the fourth lower layer F4. That is, as shown in FIG. 22A, the vertical load of the mast main body 21 is transferred from the upper support leg 23 to the lower support leg 24. Then, the upper support leg 23 is released from the mast main body 21 and, at one end, the upper support leg 23 is slightly raised using the hydraulic jack 26 of the upper support leg 23, and the upper support leg 23 is temporarily attached to the temporary support beam 17. The upper leg F0 is released from the uppermost floor F0 by using a hydraulic jack 26 as shown in FIG. 22 (b). It is lowered along the wire 25 through the mast opening 16 of F0.

  Subsequently, as shown in FIGS. 22C and 22D, the mast main body 21 is sandwiched between the upper support legs 23 at a position above the floor slab 13 of the second lower layer F <b> 2 with a gap. While being locked, the leg portion is extended and lowered to be supported on the temporary receiving beam 17 to support the horizontal load. Next, the support mast 2A can be moved down one level by supporting the intermediate support leg 28 from the third lower layer F3 to the fourth lower layer F4, which is one level lower than the upper support leg 23, by the same procedure. it can.

  As mentioned above, although embodiment of the building demolition system by this invention was described, this invention is not limited to said embodiment, In the range which does not deviate from the meaning, it can change suitably.

  For example, in the present embodiment, the outer periphery in which the roof frame 6 including the roof portion 61 is employed and the soundproof sheet 7 provided on the surface of the roof portion 61 and the soundproof panel 8 provided on the side wall portion 62 is provided. Although it is set as the structure which can perform the demolition work in the demolition space R enclosed by the curing, it is not limited to this. For example, as shown in FIG. 20, an open-top type building dismantling system 1 </ b> A in which the roof portion 61 of the roof frame 6 is omitted can be used. Thus, in the building demolition system of the present invention, since the roof 61 can be easily removed without changing the installation method of the overhead crane 4 and the Telha crane 5, conditions such as the building height and the surrounding environment The building dismantling system 1A shown in FIG. In the case of this open top type, a tower crane 90 can be arranged in the building 10 as shown in FIG.

  Moreover, it is also possible to install a two-layer support type tower crane in the opening for unloading instead of the Telha crane 5.

  Moreover, in this Embodiment, although the internal crane 41 and the outer periphery crane 42 are provided separately as the overhead crane 4 (horizontal crane), it is not limited to this, It can also be set as one overhead crane. is there.

  Further, the configuration of the lowering mechanism 20 of the support masts 2 and 2A, the support mechanism of the Telha crane 5 and the like is not limited to the present embodiment, and can be arbitrarily set.

  Moreover, in this Embodiment, although cylindrical shape is employ | adopted as the support masts 2 and 2A of the building demolition system 1, it is not limited to this, For example, it is also possible to use a prismatic support mast.

  In addition, it is possible to appropriately replace the components in the above-described embodiments with known components without departing from the spirit of the present invention.

1, 1A Building Demolition System 2, 2A Support Mast 3 Support Frame 4 Overhead Crane (Horizontal Crane)
5 Telha crane (vertical crane)
6 roof frame 7 soundproof sheet 8 soundproof panel 10 building 13 floor slab 21 mast body 22 reaction force support portion 23 upper support leg 24 lower support leg 26 hydraulic jack 28 intermediate support leg 31 vertical frame 32 horizontal frame 41 internal cranes 42, 42A, 42B Peripheral crane 43 Internal traveling rail 44 Internal transverse rail 45A First outer circumferential traveling rail 45B Second outer circumferential traveling rail 46A First outer circumferential transverse rail 46B Second outer circumferential transverse rail 47 Transfer rail R Dismantling space X Long side direction Y Short side direction

Claims (3)

A building demolition system installed on the top layer of a high-rise building and dismantling the building in order from the top layer,
A roof frame supported by a plurality of support masts provided along the outer periphery of the building;
A horizontal crane fixed to the lower side of the roof frame and moving horizontally;
A vertical crane that is supported by the building's housing and lifts and lowers the suspended load within an opening that continues from the top layer to the ground layer;
A building demolition system characterized by comprising: The horizontal crane is composed of an outer peripheral crane disposed on the outer peripheral side of the building in plan view, and an inner crane disposed on the inner side.
The building dismantling system according to claim 1, wherein the inner crane and the outer crane are movably provided in a suspension area of each other. The internal crane moves on an internal traverse rail that is guided by an internal travel rail that extends along the first direction of the building,
The outer crane includes a first outer crane that moves on a first outer circumferential traverse rail that travels while being guided by a first outer rail that extends along the first direction, and a direction that is orthogonal to the first direction in plan view. A second outer peripheral crane that travels on a second outer peripheral traverse rail that is guided by a second outer peripheral travel rail that extends along the
The inner traverse rail is disposed on a straight line with respect to the first outer traverse rail via a transfer rail,
The building dismantling system according to claim 2, wherein the internal traveling rail is arranged on a straight line with respect to the second outer circumferential traverse rail.

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