CN215248971U - Hoisting construction device for large-scale overweight electromechanical equipment of high-rise and super high-rise building - Google Patents

Abstract

The utility model discloses a high-rise, super high-rise building large-scale overweight electromechanical device handling construction equipment, include: building body, bearing structure, hanging beam, bottom brace table and drive mechanism. The building body comprises a ventilation shaft, a first structure bearing beam is arranged at the bottom of an Nth layer of structure surface of the building body, a cushion block is arranged at the position, right opposite to the first structure bearing beam, of the top of the Nth layer of structure surface, and a plurality of through holes are formed in the Nth layer of structure surface. One end of the hanging beam is supported on the cushion block, and the other end of the hanging beam is supported on the supporting structure. The bottom support platform is arranged in the ventilation shaft and is flush with the first-floor structural surface of the building body. The traction mechanism comprises a traction steel wire, a first fixed pulley and a winch, the first fixed pulley is connected to the hanging beam through a hanging steel wire, one end of the traction steel wire penetrates through the corresponding through hole to be connected to the hanging beam, and the other end of the traction steel wire penetrates through the first fixed pulley to be connected with the winch. This handling construction equipment carries out safe hoist and mount through the well that ventilates, has made things convenient for and has transported higher floor with overweight super large electromechanical device.

Description

Hoisting construction device for large-scale overweight electromechanical equipment of high-rise and super high-rise building

Technical Field

The utility model relates to a large-scale overweight electromechanical device handling technical field of high-rise building especially relates to a large-scale overweight electromechanical device handling construction equipment of high-rise, super high-rise building.

Background

In recent years, along with the rapid development of economic construction in China, the competition of the construction industry is increasingly intense. Lean construction is carried out, project construction cost is reduced and project construction quality is improved through fine management, and the advantages can be maintained in intense market competition. In addition, in the transportation process of the external elevator, the wind load is increased along with the increase of the floor height, the shaking is obvious, and the safety and reliability are low; the lifting height of the truck crane is not enough, the rent cost is very high, the safety is poor, large electromechanical equipment cannot be vertically transported to a specified floor, and the tower crane is already dismantled. In order to save cost, other physical knowledge needs to be applied to reduce the load value.

In view of this, the present invention is especially provided.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high-rise, super high-rise building large-scale overweight electromechanical device handling construction equipment carries out safe hoist and mount through the ventilation well, has made things convenient for and has transported overweight super large electromechanical device very high floor.

In order to solve the above problems, the present disclosure adopts the following technical solutions:

the utility model provides a high-rise, super high-rise building large-scale overweight electromechanical device handling construction equipment, includes:

the building comprises a building body, wherein the building body comprises a multi-layer structure surface and a ventilation shaft communicated with the structure surface of each layer, a first structure bearing beam is arranged at the bottom of the Nth layer of structure surface of the building body, a cushion block is arranged at the position, opposite to the first structure bearing beam, of the top of the Nth layer of structure surface, and a plurality of through holes are formed in the Nth layer of structure surface;

the supporting structure is arranged on one side, opposite to the cushion block, of the inner wall of the ventilation shaft;

one end of the hanging beam is supported on the cushion block, and the other end of the hanging beam is supported on the supporting structure;

the bottom support platform is arranged in the ventilation shaft and is flush with the first-floor structural surface of the building body;

the traction mechanism comprises a traction steel wire, a first fixed pulley and a winch, the first fixed pulley penetrates through a corresponding through hole to be connected to the hanging beam through a hanging steel wire, one end of the traction steel wire penetrates through the corresponding through hole to be connected to the hanging beam, and the other end of the traction steel wire penetrates through the first fixed pulley to be connected with the winch.

Optionally, the support structure includes a connecting plate and a supporting plate vertically connected to the connecting plate, the connecting plate is fixedly connected to an inner wall of the ventilation shaft, and an end of the suspension beam is supported on the supporting plate.

Optionally, the winch is arranged on the M-th floor structural surface of the building body, and the winch is connected with a ground anchor device.

Optionally, the ground anchor device comprises a limiting steel wire connected with the winch, a rope penetrating hole is formed in the M-th layer of structural surface, and the limiting steel wire penetrates through the rope penetrating hole and is connected to the column body on the M-1-th layer of structural surface.

Optionally, a second fixed pulley is arranged on the M-th layer structure surface, and the traction steel wire penetrates through the second fixed pulley and is connected to the winch.

Optionally, a second structure bearing beam is arranged at the bottom of the M-th layer of structure surface, a fixing hole is formed in the M-th layer of structure surface, a steel wire rope sleeve penetrates through the fixing hole and surrounds the second structure bearing beam, and the second fixed pulley is connected with the steel wire rope sleeve.

Optionally, the hoisting construction device for the large overweight electromechanical equipment of the high-rise and super-high-rise building further comprises a batten, wherein the batten penetrates through the steel wire rope sleeve, and the batten is arranged between the second structure bearing beam and the steel wire rope.

Optionally, the hoisting construction device for the large-scale overweight electromechanical equipment of the high-rise and super high-rise building comprises a hoisting platform and four hoisting steel wires connected with the hoisting platform, the four hoisting steel wires penetrate through corresponding through holes to be connected to the hoisting beam, and each hoisting steel wire is connected with an electric hoist.

Optionally, the hoisting construction device for the large overweight electromechanical equipment of the high-rise and super-high-rise building further comprises a safety rope, and the safety rope penetrates through the corresponding through hole to be connected with the hoisting beam.

Optionally, the hoisting construction device for the large-scale overweight electromechanical equipment of the high-rise and super high-rise building further comprises two anti-rotation sliding cables, one end of each of the two anti-rotation sliding cables penetrates through the corresponding through hole to be connected with the hoisting beam, the traction steel wire is connected with the electromechanical equipment, and two sides of the electromechanical equipment are connected with the corresponding anti-rotation sliding cables in a sliding mode through connecting rings.

By adopting the technical scheme, make the utility model discloses following beneficial effect has:

the large overweight electromechanical equipment hoisting construction device for the high-rise and super high-rise building is used for safely hoisting through the ventilation shaft, so that the overweight and super large electromechanical equipment is conveniently conveyed to a very high floor, the construction cost is reduced, the construction period is shortened, the device is energy-saving and environment-friendly, and the experience effect is very remarkable.

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention without limitation. It is obvious that the drawings in the following description are only some embodiments, and that for a person skilled in the art, other drawings can be derived from them without inventive effort. In the drawings:

fig. 1 is a schematic structural view of a corbel of a large overweight electromechanical device hoisting construction device for a high-rise and super high-rise building, provided by the utility model;

FIG. 2 is a schematic structural view of an anti-rotation sliding rope of the hoisting construction device for the large overweight electromechanical equipment of the high-rise and super high-rise building provided by the utility model;

fig. 3 is a schematic view of the installation structure of the second fixed pulley and the winch of the large overweight electromechanical device hoisting construction device for the high-rise and super high-rise building provided by the utility model;

fig. 4 is a schematic diagram of the state of the hoisting operation executed by the hoisting construction device for the large-scale overweight electromechanical equipment of the high-rise and super high-rise building;

fig. 5 is the utility model provides a high-rise, super high-rise building large-scale overweight electromechanical device handling construction equipment's hoist and mount schematic diagram.

In the figure, 1, a building body; 2. a bracket; 21. a steel plate; 22. transversely supporting; 23. an oblique beam; 24. an expansion anchor bolt; 3. a support structure; 4. a hanging beam; 5. a bottom support table; 6. a traction mechanism; 61. a traction wire; 62. a first fixed pulley; 63. a second fixed pulley; 64. a movable pulley; 65. a winch; 66. a limiting steel wire; 67. wood block; 68. a steel wire rope sleeve; 69. an anti-rotation strop; 610. a connecting ring; 7. hoisting the platform; 71. an electric hoist; 72. a chain block; 8. a safety cord; 9. an electromechanical device.

It should be noted that the drawings and the description are not intended to limit the scope of the inventive concept in any way, but to illustrate the inventive concept by those skilled in the art with reference to specific embodiments.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the drawings in the embodiments of the present invention are combined below to clearly and completely describe the technical solutions in the embodiments, and the following embodiments are used for illustrating the present invention, but do not limit the scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or component to which the description refers must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 5, an embodiment of the present application provides a large overweight electromechanical device hoisting construction device for high-rise and super high-rise buildings, including: building body 1, support structure 3, hanging beam 4, bottom support platform 5 and traction mechanism 6. The building body 1 comprises a multilayer structure surface and a ventilation shaft communicated with the structure surface, a first structure bearing beam is arranged at the bottom of the Nth layer of the building body 1, a cushion block is arranged at the position, right opposite to the first structure bearing beam, of the top of the Nth layer of the structure surface, and a plurality of through holes are formed in the Nth layer of the structure surface. The supporting structure 3 is arranged on one side, opposite to the cushion block, of the inner wall of the ventilation shaft. One end of the hanging beam 4 is supported on the cushion block, and the other end is supported on the supporting structure 3. The bottom support platform 5 is arranged in the ventilation shaft and is flush with the first-floor structural surface of the building body 1. The traction mechanism 6 comprises a traction steel wire 61, a first fixed pulley 62 and a winch 65, the first fixed pulley 62 is connected to the hanging beam 4 through a corresponding through hole by hanging down the steel wire, one end of the traction steel wire 61 is connected to the hanging beam 4 through the corresponding through hole, and the other end of the traction steel wire passes through the first fixed pulley 62 and is connected with the winch 65. The hoist 65 can wind or release the traction wire 61 to effect hoisting or lowering of the electromechanical device. N may be the highest number of layers of the building body 1, and the application does not limit the specific value of N.

In order to support and install the bottom support platform 5, holes can be drilled in the wall of the first-layer shear wall of the ventilation shaft, a plurality of brackets 2 are installed, and the bottom support platform 5 is supported on each bracket 2. In order to meet the lifting requirements of the large overweight electromechanical equipment 9, 6 brackets 2 and 36 expansion anchor bolts 24 can be arranged, each bracket 2 is supported by the 6 expansion anchor bolts 24, and the expansion anchor bolts 24 at each bracket 2 are divided into 2 rows and 3 rows. Referring to fig. 1, the corbel 2 includes a steel plate 21, a lateral brace 22, and an oblique beam 23 connecting the steel plate 21 and the lateral brace 22, and an expansion anchor 24 is fixed to the structural shear wall and the steel plate 21, respectively. The expansion anchor 24 obtained by the table lookup is used in concrete with a shear strength of not less than C30, and the shear strength is 580 kg. 36 expansion anchor bolts 24 are actually used for 6 corbels 2, and the bearing capacity of the corbels 2 can completely meet the use requirement and can bear nearly 4 tons of heavy objects.

The supporting structure 3 comprises a connecting plate and a supporting plate vertically connected with the connecting plate, the connecting plate is fixedly connected with the inner wall of the ventilation shaft, and the end part of the hanging beam 4 is supported on the supporting plate. Wherein, the connecting plate can be connected and fixed with the inner wall (shear wall) of the ventilation shaft through a chemical anchor bolt.

The winch 65 is arranged on the M-th layer structural surface of the building body 1, the winch 65 is connected with a ground anchor device, the ground anchor device comprises a limiting steel wire 66 connected with the winch, a rope penetrating hole is formed in the M-th layer structural surface, and the limiting steel wire 66 penetrates through the rope penetrating hole to be connected to a column body on the M-1-th layer structural surface. Where M is less than N, preferably M is equal to N-1.

And a second fixed pulley 63 is arranged on the M-th layer structural surface, and the traction steel wire 61 passes through the second fixed pulley 63 and is connected to the winch 65. The first fixed sheave 62 serves to share the load, and the second fixed sheave 63 serves to divert the direction.

Referring to fig. 3, a second structural bearing beam is arranged at the bottom of the M-th layer structural surface, a fixing hole is formed in the M-th layer structural surface, a steel wire rope sleeve 68 penetrates through the fixing hole and is arranged around the second structural bearing beam, and the second fixed pulley 63 is connected with the steel wire rope sleeve 68. The large-scale overweight electromechanical equipment hoisting construction device for the high-rise and super high-rise building further comprises a batten 67, the batten 67 penetrates through the steel wire rope sleeve 68, the batten 67 is arranged between the second structure bearing beam and the steel wire rope, and the protection effect is achieved.

The hoisting construction device for the large-scale overweight electromechanical equipment of the high-rise and super high-rise building comprises a hoisting platform 7 and four hoisting steel wires connected with the hoisting platform 7, wherein the four hoisting steel wires penetrate through corresponding through holes to be connected to the hoisting beam 4, and each hoisting steel wire is connected with an electric hoist. Referring to fig. 2, the device for hoisting and constructing the large overweight electromechanical equipment of the high-rise and super-high-rise building further comprises two anti-rotation sliding cables 69, wherein one ends of the two anti-rotation sliding cables 69 penetrate through corresponding through holes to be connected with the hanging beam 4, and the other ends of the two anti-rotation sliding cables are connected with the bottom support platform 5. The traction steel wire 61 is connected with an electromechanical device 9, and two sides of the electromechanical device 9 are respectively connected with a connecting ring 610 and a corresponding anti-rotation sliding cable 69 in a sliding manner.

Referring to fig. 5, the four electric hoists include two electric hoists 71 and two hand hoists 72. The traction steel wire 61 is also connected with a movable pulley which is connected with electromechanical equipment 9. After the hoisting electromechanical device 9 is slightly higher than the target layer structure surface, the anti-rotation sliding cables 69 on the two sides of the ventilation shaft are unhooked from the large electromechanical device 9. In the ventilation shaft, 2 hand hoists 72 are hung near the floor slab, and 2 electric hoists 71 are hung on the other 1 side. The hoisting construction device for the large overweight electromechanical equipment of the high-rise and super high-rise building further comprises a safety rope 8, and the safety rope 8 penetrates through the corresponding through hole to be connected with the hoisting beam 4. The safety belt of a worker is hung on the safety rope 8, the electric hoist 71 is conveyed to the inner side of the ventilation shaft through the hoisted hoisting platform 7 and hung on the anti-rotation sliding cable 69, and the lower part of the electric hoist 71 is connected with the hook of the hoisting platform 7. For hanging 2 hand hoists 72 on the other side of the ventilation shaft, an operator can stand in a floor and can be connected with the hoistable platform 7 to be hooked. After the anti-rotation sliding rope 69 is connected with the electric hoist 71 and the manual hoist 72 respectively, the manual hoist 72 is pulled slowly to make one side of the movable hoisting platform 7 close to the beam and the plate basically fixed, the electric hoist 71 is started to make the other side of the hoisting platform 7 rotate upwards by 90 degrees, and finally the hoisting platform 7 is kept flat with the structural surface of the target floor under the action of 4 hoisting points.

Then, the construction operator starts the switch of the winch 65, loosens the traction steel wire 61, and enables the large electromechanical device 9 to stably descend from the top of the roof of the target structural surface to the movable hoisting platform 7 on the bottom surface, and then starts the winch 65 to horizontally drag the large electromechanical device 9, so that the large electromechanical device 9 is transported to the corresponding position of the corresponding floor.

The utility model discloses a high-rise, super high-rise building large-scale overweight electromechanical device handling construction equipment's working procedure as follows:

step 1, manufacturing, installing and positioning a bottom support table 5, and translating an electromechanical device 9 to the bottom support table 5;

step 2, installing the supporting structure 3 and the hanging beam 4, punching and installing a first fixed pulley 62 on the Nth layer structural surface, installing a second fixed pulley 63 and a winch 65 on the Mth layer structural surface, arranging a movable pulley 64 on the electromechanical device 9, and connecting a traction steel wire 61 with the winch 65 through the movable pulley 64, the first fixed pulley 62, the second fixed pulley 63 and the winch respectively;

step 3, suspending the electromechanical equipment 9 on the movable pulley 64, connecting the electromechanical equipment 9 with the anti-rotation sliding rope 69, starting the winch 65, and hoisting the electromechanical equipment 9 above the structural plane of the target layer;

and 4, separating the electromechanical equipment 9 from the anti-rotation sliding cable 69, connecting an electric hoist 71 to the anti-rotation sliding cable 69 far away from the floor, connecting a manual hoist 72 to the anti-rotation sliding cable 69 near the floor, adjusting one end of the hoisting platform 7 to be equal to the structural plane of the target floor by adjusting the manual hoist 72, controlling the electric hoist 71 to adjust the other end of the hoisting platform 7 to be flush with the structural plane of the target floor, starting the winch 65 by an operator to operate, enabling the traction steel wire 61 to descend to stably drop the electromechanical equipment 9 onto the hoistable platform 7, and dragging the large electromechanical equipment 9 to a corresponding room of a corresponding floor in the horizontal direction to finish the hoisting working process.

The hoisting process is completed in the ventilation shaft, so that the influence of wind load on the traction mechanism 6 is avoided, and the damage of the large electromechanical equipment 9 caused by shaking is avoided. The anti-rotation sliding rope 69 is arranged in the ventilation shaft, so that the rotation, front-back and left-right shaking of the equipment during ascending are avoided, the large electromechanical equipment 9 is prevented from being damaged by collision, and the hoisting is safe and reliable.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, and although the present invention has been disclosed with reference to the above preferred embodiment, but not to limit the present invention, any person skilled in the art can make modifications or changes to equivalent embodiments by utilizing the above technical contents without departing from the scope of the present invention, and any simple modification, equivalent change and modification made to the above embodiments by the technical matters of the present invention are within the scope of the present invention.

Claims (10)

1. The utility model provides a high-rise, super high-rise building large-scale overweight electromechanical device handling construction equipment which characterized in that includes:

the building comprises a building body, wherein the building body comprises a multi-layer structure surface and a ventilation shaft communicated with the structure surface of each layer, a first structure bearing beam is arranged at the bottom of the Nth layer of structure surface of the building body, a cushion block is arranged at the position, opposite to the first structure bearing beam, of the top of the Nth layer of structure surface, and a plurality of through holes are formed in the Nth layer of structure surface;

the supporting structure is arranged on one side, opposite to the cushion block, of the inner wall of the ventilation shaft;

one end of the hanging beam is supported on the cushion block, and the other end of the hanging beam is supported on the supporting structure;

the bottom support platform is arranged in the ventilation shaft and is flush with the first-floor structural surface of the building body;

the traction mechanism comprises a traction steel wire, a first fixed pulley and a winch, the first fixed pulley penetrates through a corresponding through hole to be connected to the hanging beam through a hanging steel wire, one end of the traction steel wire penetrates through the corresponding through hole to be connected to the hanging beam, and the other end of the traction steel wire penetrates through the first fixed pulley and is connected with the winch.

2. The hoisting construction device for the large overweight electromechanical equipment of the high-rise and super-high-rise buildings according to claim 1, characterized in that the supporting structure comprises a connecting plate and a supporting plate vertically connected with the connecting plate, the connecting plate is fixedly connected with the inner wall of the ventilation shaft, and the end part of the hoisting beam is supported on the supporting plate.

3. The hoisting construction device for the large overweight electromechanical equipment of the high-rise and super-high-rise buildings according to claim 1, characterized in that the winch is arranged on the Mth floor structure surface of the building body and is connected with a ground anchor device.

4. The hoisting construction device for the large overweight electromechanical equipment of the high-rise and super-high-rise buildings as claimed in claim 3, wherein the ground anchor device comprises a limiting steel wire connected with the winch, the M-th layer structure surface is provided with a rope-passing hole, and the limiting steel wire passes through the rope-passing hole and is connected to the column body on the M-1-th layer structure surface.

5. The hoisting construction device for the large overweight electromechanical equipment of the high-rise and super-high-rise buildings according to claim 4, characterized in that a second fixed pulley is arranged on the M-th floor structural surface, and the traction steel wire passes through the second fixed pulley and is connected to the winch.

6. The hoisting construction device for the large overweight electromechanical equipment of the high-rise and super-high-rise buildings according to claim 5, characterized in that the bottom of the M-th layer structure surface is provided with a second structure bearing beam, the M-th layer structure surface is provided with a fixing hole, a steel wire rope sleeve passes through the fixing hole and is arranged around the second structure bearing beam, and the second fixed pulley is connected with the steel wire rope sleeve.

7. The large overweight electromechanical equipment hoisting construction device for high-rise and super-high-rise buildings according to claim 6, characterized by further comprising battens, wherein the battens penetrate through the steel wire rope sleeve and are arranged between the second structure bearing beam and the steel wire rope.

8. The large overweight electromechanical equipment hoisting construction device for high-rise and super-high-rise buildings according to claim 1, characterized by comprising a hoisting platform and four hoisting steel wires connected with the hoisting platform, wherein the four hoisting steel wires are all connected to the hoisting beam through corresponding through holes, and each hoisting steel wire is connected with an electric hoist.

9. The large overweight electromechanical equipment hoisting construction device for high-rise and super-high-rise buildings according to claim 8, characterized by further comprising safety ropes, wherein the safety ropes are connected with the hoisting beams through the corresponding through holes.

10. The large overweight electromechanical device hoisting construction device for high-rise and super-high-rise buildings according to claim 1, characterized by further comprising two anti-rotation sliding cables, wherein one end of each of the two anti-rotation sliding cables is connected with the hanging beam through a corresponding through hole, the other end of each of the two anti-rotation sliding cables is connected with the bottom support platform, the traction steel wire is connected with electromechanical devices, and two sides of each of the electromechanical devices are respectively connected with the corresponding anti-rotation sliding cables through connecting rings.

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