CN221093498U - Tower crane construction intelligent building platform is exempted from in assembled house engineering - Google Patents

Abstract

The utility model discloses a tower crane-free intelligent construction platform for assembled residential engineering, which comprises the following components: the device comprises a bailey frame platform, a support frame, a truss vehicle assembly and a track assembly; the support frame is arranged at the bottom of the bailey frame platform, and a floor slab is arranged on the upper side of the support frame; the material and the prefabricated components can be lifted from one layer to the appointed position of the operation layer through the ascending truss car assembly to be stacked under the condition of auxiliary construction without a tower crane, the descending truss car assembly can lift the material and the prefabricated components to the construction position along the track assembly, and the material and the components can be transported to each position of the operation layer through the ascending truss car assembly and the descending truss car assembly, so that the construction efficiency is improved, the safety performance of the operation layer is improved, and the operation environment is improved.

Description

Tower crane construction intelligent building platform is exempted from in assembled house engineering

Technical Field

The utility model relates to an intelligent building platform for tower crane-free construction of an assembled residential engineering, and belongs to the field of buildings.

Background

With the continuous development of the building industry in China, more and more high-rise residential buildings appear in the field of vision of people, and the traditional super high-rise construction lifting formwork system has high integration level, large overall load and high investment cost.

Aiming at the problems that when prefabricated components are hoisted, transported and hoisted simultaneously by a plurality of buildings, the operation of a tower crane cannot meet the requirement of simultaneous hoisting operation of a plurality of working surfaces, and aluminum film plates, auxiliary materials and prefabricated components in the building are required to be transported to each construction part in the construction process, the material transportation in the operation layer is mainly finished manually at present, and the problems of low speed and low efficiency exist.

Disclosure of utility model

Aiming at the defects existing in the prior art, the utility model aims to provide an intelligent building platform for tower crane-free construction of an assembled residential engineering, so as to solve the problems.

In order to achieve the above object, the present utility model is realized by the following technical scheme: a tower crane construction intelligent construction platform is exempted from in prefabricated housing engineering, includes: the device comprises a bailey frame platform, a support frame, a truss vehicle assembly and a track assembly; the support frame is arranged at the bottom of the bailey frame platform, and a floor slab is arranged on the upper side of the support frame;

The track assembly is arranged on the bailey frame platform and the support frame and is provided with an uplink slideway and a downlink slideway;

The truss car assembly comprises an uplink truss car assembly arranged on an uplink slideway and a downlink truss car assembly arranged on a downlink slideway; the upstream truss car component and the downstream truss car component are arranged in parallel;

And comprises the following steps of;

Step 1; building a support frame and a wall body;

step 2; building a bailey frame platform at the top of the support frame; a track assembly is arranged on the bailey frame platform and the support frame so as to enable the truss assembly to move;

step 3; installing an uplink truss vehicle assembly on an uplink slideway, and connecting the movable end of the uplink truss vehicle assembly with materials on the ground through a floor slab;

Step 4; based on the step 3, the ascending truss car component brings the material into the floor slab;

step 5; installing a descending truss car assembly on a descending slideway, and connecting the movable end of the descending truss car assembly with the materials arranged on the descending slideway;

step 6; based on step 5, the down truss assembly drives the material to displace between floors until reaching a designated discharge area.

Preferably, the bailey frame platform comprises a plurality of bailey pieces and connecting fittings for connecting the bailey pieces; the plurality of bailey pieces form at least 2 lifting wellheads through connecting fittings.

Preferably, the movable end of the up-going truss car assembly moves through the lifting wellhead.

Preferably, the support frame is an oil cylinder support column, the oil cylinder support column is connected with the wall body through a wall-attached guide seat, and the support frames are distributed at the bottom of the bailey frame platform in a staggered manner.

Preferably, the ascending slide way and the descending slide way are both fixed on a base frame; the base frames are arranged on the staggered supporting frames, the base frames are provided with 2 mounting parts extending inwards, and the ascending slide ways and the descending slide ways are respectively mounted on the respective mounting parts.

Preferably, the base frames are arranged on staggered supporting frames, and the base frames are provided with 2 mounting parts extending inwards, and the ascending slide ways and the descending slide ways are respectively mounted on the respective mounting parts.

Preferably, the upper mounting portion is fixed to the bailey frame platform by a connecting bolt, and the lower mounting portion is fixed to the upper mounting portion by a sleeve assembly and a bolt.

Preferably, the uplink truss vehicle component comprises an uplink truss vehicle crane, an uplink sliding device and an uplink lifting device; the uplink truss crane is arranged on the uplink slideway; the uplink sliding device is arranged on the uplink truss crane and used for enabling the uplink lifting device to move on the uplink truss crane; the lifting end of the ascending and descending device is connected with the material.

Preferably, the uplink truss crane and the downlink truss crane are respectively provided with a laser range finder and a control unit.

Advantageous effects

According to the utility model, materials and prefabricated components can be lifted from one layer to the appointed position of the operation layer through the ascending truss car assembly without auxiliary construction of the tower crane, the descending truss car assembly can hoist the materials and the prefabricated components to the construction position along the track assembly, and the materials such as the aluminum membrane plate, the auxiliary material and the prefabricated components can be transported to each position of the operation layer through the ascending truss car assembly and the descending truss car assembly, so that the construction efficiency is improved, the safety performance of the operation layer is improved, and the operation environment is improved.

Drawings

Other features, objects and advantages of the present utility model will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

fig. 1 is a schematic structural view of a method of using the bailey platform of the present utility model;

FIG. 2 is a schematic diagram of a top view structure of an intelligent building platform for tower crane free construction in an assembled residential project according to the present utility model;

FIG. 3 is a schematic top view of the floor slab of the present utility model;

FIG. 4 is a schematic view of the structure of the support frame of the present utility model

Fig. 5 is a schematic side view of a tower crane-free intelligent construction platform for an assembled residential engineering.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

Referring to fig. 1-5, the utility model provides a technical scheme of an intelligent building platform for tower crane free construction of an assembled residential engineering, which comprises the following steps: the device comprises a bailey frame platform 1, a support frame 3, a truss car assembly and a track assembly 5; the support frame 3 is arranged at the bottom of the bailey frame platform 1, and a floor slab 2 is arranged on the upper side of the support frame 3; the floor slab 2 is mainly used for standing and placing building materials during the operation of workers, and the mode of constructing and fixing the floor slab 2 on the supporting frame 3 is in the conventional technology, so that the description is not repeated.

The bailey frame platform 1 comprises a plurality of bailey pieces 11 and connecting fittings 12 for connecting the bailey pieces 11; the plurality of bailey pieces 11 form at least 2 lifting wellheads a through the connecting fittings 12, wherein the connecting fittings 12 are conventional hardware fittings for mutually connecting and fixing the bailey pieces 11. The bailey frame platform 1 is used for building a peripheral hanging frame (not shown in the figure), and the hanging frame is mainly hung on the bailey pieces 11 and serves as an operation surface for protecting and constructing.

The track assembly 5 is arranged on the bailey frame platform 1 and the support frame 3 and is provided with an ascending slide way 51 and a descending slide way 51; the ascending slide way 51 and the descending slide way 51 are both fixed on a base frame 4; the base frames 4 are arranged on the staggered supporting frames 3, and the base frames 4 are provided with 2 mounting parts 41 (46) extending inwards, and the ascending slide ways 51 and the descending slide ways 51 are respectively mounted on the respective mounting parts 41 (46); the preferable support frames 3 are fixed below the bailey frame platform 1 in a staggered manner, and firstly, the mounting positions of the support frames 3 can be selected to be mounted at proper positions according to the terrain in a staggered manner, so that the additional leveling of the terrain is avoided before construction; secondly, the bearing materials can be more uniformly distributed in the building, so that the bearing is more balanced, and the structural non-uniformity is reduced; thirdly, because the base frames 4 are arranged on the supporting frame 3, the base frames 4 are also distributed in a staggered way, and the running of the downstream truss vehicle components which are needed to be used in the building is convenient.

The support frame 3 is an oil cylinder support column, and the oil cylinder support column is connected with a wall body 33 through a wall attaching guide seat 32. The oil cylinder support upright post is provided with a plurality of oil cylinders 34 and support upright posts 31; the oil cylinders 34 are arranged on the supporting upright posts 31, and the tail parts of the oil cylinders 34 are movably connected with the supporting upright posts 31 through hinge pieces. The support column 31 is reserved with a plurality of vertically distributed grooves, the piston hinge of the oil cylinder 34 is provided with a connecting arm 35, and the connecting arm 35 is inserted into the grooves until the connecting arm is hinged with the wall attaching guide seat 32, so that when the piston of the oil cylinder 34 extends forwards, the connecting arm 35 props against the grooves to drive the support column 31 to move upwards.

The top of the supporting upright 31 is a lattice upright 32, and the structural strength is enhanced by adopting the lattice upright 32, so that good supporting force is provided.

And the top of the lattice upright post 32 is fixed with a base 13, the base 13 is provided with a mounting end face 131, and the bailey frame platform 1 is mounted on the mounting end face 131 of the base 13. In one embodiment, the base 13 is square, and the side length of the base 13 is larger than the width of the bailey platform 1 in contact, so that the base 13 increases the bearing area, which will increase the good supporting force for the bailey platform 1. The base 13 is further provided with a plurality of hollowed through holes 132 which are regularly arranged, so that the structural stability of the base 13 can be ensured, and the base 13 can be lightened.

The mounting part 41 of the ascending slide way 51 is a main stress point, the mounting part 41 at the position is mounted and fixed with the mounting end surface of the base 13 through bolts and gaskets thereof, and the fixing of the mounting part 41 and the base 13 is formed, so that conditions are provided for mounting the ascending slide way 51; it should be noted that the mounting portion 41 is placed on the bailey piece 11 at the bottom of the bailey frame platform 1 and then fixed with the base 13 through bolts and gaskets, so that the mounting portion and the mounting of the bailey frame platform 1 on the base 13 can be prevented from collision, and the fixing of the mounting portion 41 and the base 13 can form a clamping effect on the bailey frame platform 1, so that the fixing strength of the bailey frame platform 1 and the base 13 is enhanced. While the outside bottom of the mounting portion of the up run 51 is fixed by a sleeve assembly and a bolt other mounting portion 46 (the mounting portion 46 is for the down run 51). Specifically, the sleeve assembly is divided into a plug rod 43 and a sleeve 44; the inserting rods 43 are provided with a plurality of inserting rods and are divided into 2 groups, the 2 groups of inserting rods 43 are vertically fixed on the 2 mounting parts 41 (46), and the sleeve 44 is hollow, so that the inserting rods 43 are inserted into the sleeve 44 to form sleeve joint; in addition, a hole 45 for inserting a bolt is reserved on the inserted link 43 and the sleeve 44, so that the inserted link 43 and the sleeve 44 are fixed by the bolt, and the purpose of fixing the mounting part 46 of the downlink slide 51 to the mounting part 41 of the uplink slide 51 is achieved. It should be noted that the length of the 2 mounting portions 41 (46) is greater than the side length of the base 13, so as to provide enough space for mounting the corresponding track assembly 5, and the length of the mounting portion 41 (46) exceeding the side length of the base 13 is 3 times to 5 times that of the mounted track assembly 5; this will provide sufficient length for the track assembly 5 to be mounted in place for rotation while avoiding problems with the structural strength of the lengthy mounting portion 41 (46) and the occurrence of stress deformation. In one embodiment, the length of the mounting portion 41 of the ascending slide 51, which is the main stress point, exceeds the side length of the base 13 by 3 times the width of the ascending slide 51, and the length of the mounting portion 46 of the descending slide 51 exceeds the side length of the base 13 by 4 times the length of the descending slide 51.

The truss car assembly comprises an uplink truss car assembly arranged on the uplink slideway 51 and a downlink truss car assembly arranged on the downlink slideway 51; the upstream truss car assembly and the downstream truss car assembly are arranged in parallel, and the upstream truss car assembly is located above the downstream truss car assembly. The up-truss car assembly comprises an up-truss car crane 61, an up-sliding device 62 and an up-lifting device 63. The up-truss crane 61 is mounted on the up-slide 51, the up-truss crane 61 is mounted on the up-truss crane 62, and the up-truss crane 61 drives the up-truss crane 62 and the up-lifting device 63 to displace along the up-slide 51. The upward sliding device 62 is used for enabling the upward lifting device 63 to move on the upward truss crane 61; the lifting end of the lifting device 63 is connected with the material X, and mainly adopts a steel rope shrinkage mode to lift the material X; the up-link truss crane 61, the up-link sliding device 62 and the up-link lifting device 63 are conventional devices, and can be purchased directly in the market, so that detailed description thereof will not be provided in the specification. It should be noted that the uplink truss crane 61, the uplink sliding device 62 and the uplink lifting device 63 are controlled by a control unit (not shown) mainly comprising a PLC controller, a laser range finder 7 is arranged on the uplink truss crane 61, the laser range finder 7 is used for collecting the position information of the material X, and in the running process of the uplink lifting device 63, the control unit optimizes the track and running speed according to the target position distance between the uplink truss car assembly and the material X, and adjusts the related parameters of the track of the uplink truss car assembly in real time so as to realize the target of accurate positioning of the uplink truss car assembly; according to the analysis of the operation conditions of different working conditions, data are collected for analysis, so that the requirements of the fast load swing elimination and the accurate positioning of the uplink truss car assembly are well met during the operation of the uplink truss car assembly, and the requirements of stable and safe hoisting and accurate installation and positioning are met. The control unit and the laser range finder 7 can be purchased directly in the market, and the above-described effects can be achieved by simple programming.

Similarly, the downstream truss car assembly comprises a downstream truss car crane 64, a downstream sliding device 65 and a downstream lifting device 66; the descending truss crane 64 is installed on the descending slideway 51; the downlink sliding device 65 is installed on the downlink truss crane 64 and is used for enabling the downlink lifting device 66 to move on the downlink truss crane 64; the lifting end of the descending lifting device 66 is connected with the material X. The downstream truss car assembly is the same as the upstream truss car assembly, and can be purchased from the market by a downstream truss crane 64, a downstream sliding device 65 and a downstream lifting device 66, and the downstream truss crane 64 is also provided with a laser range finder 7 and a control unit thereof.

The method also comprises the following steps:

Step 1; the support frame 3 is constructed with the wall 33. The wall attaching guide 32 is mounted on the wall body 33 of the building, the wall attaching guide 32 is nailed into the wall body 33 through pins to form fixation, and then the support upright posts 31 are hinged with the wall attaching guide 32. The lifting of the support upright 31 can be realized through the extension and retraction of the piston of the oil cylinder 34, so that the levelness of the integral bailey frame platform 1 can be adjusted subsequently.

Step 2; setting up a bailey frame platform 1 at the top of a support frame 3; a track assembly 5 is arranged on the bailey frame platform 1 and the support frame 3 for the truss assembly to move; on the basis of the step 1, a base 13 is arranged at the top of an oil cylinder supporting upright post, and then the bailey pieces 11 are mutually connected through connecting fittings 12 according to construction requirements to complete assembly, and at least 2 lifting well heads A are reserved. And the base 13 is provided with the base frame 4 through bolts, and then the base frame 4 is provided with the ascending slide rail 51 and the descending slide rail 51 for the movement of the truss assembly. By constructing the bailey frame platform 1 in a step-by-step height building mode, the structural strength of the whole construction platform can be ensured, the construction difficulty is reduced, and the lifting wellhead A can be reserved according to construction topography, namely the running direction of the truss vehicle assembly is planned, so that the construction period is shortened.

Step 3; the up-going truss car assembly is mounted on the up-going chute 51 and the free end of the up-going truss car assembly is connected to the material X on the ground through the floor slab 2. Building floor 2 on hydro-cylinder support post, floor 2 can adopt the grid board of the steel that is used commonly in the building trade to carry out mutual concatenation and form the floor layer, building floor 2 on the preferred support post 31 that relies on, because of having a plurality of grooves on the support post 31, make floor 2's fixed more convenient, reduce the degree of difficulty of construction. It should be noted that the width of the floor layer needs to be smaller than that of the Yu Beilei frames of the platform 1, so that the lifting wellhead a reserved in the step 2 is disposed at the outer side of the floor layer, so that the steel rope and the hook of the ascending lifting device 63 can smoothly extend from the lifting wellhead a to the ground. And an elevator shaft 21 is reserved in the floor slab 2 for installing a building elevator for constructors to go up and down.

Step 4; based on the step 3, the ascending truss car component brings the material X into the floor slab 2; the material X is fixed by the steel rope and the hook of the ascending and descending device 63, then the steel rope is contracted to enable the material X to be positioned on the same plane with the floor slab 2, and then the material X is taken down and placed on the floor slab 2 by constructors.

Step 5; the down-truss car assembly is mounted on the down-chute 51 and the free end of the down-truss car assembly is connected to the material X placed thereon. The descending truss car component is mainly used for material X on the floor slab 2, replaces the effect of manually carrying the material X on the floor slab 2, and solves the problem well by adopting the descending truss car component because the floor slab 2 is in a grid shape and the uneven floor slab 2 can increase the carrying difficulty during manual carrying.

Step 6; based on step 5, the downstream truss assembly drives the material X to displace between floors 2 until reaching the designated discharge area. According to the material X loaded and unloaded by constructors in the step 4, the material X is connected by the descending lifting device 66 of the descending truss car assembly, and then the material X is carried on the floor slab 2 through the cooperation of the descending truss car crane 64 and the descending sliding device 65, so that the waste of manpower resources is saved, and meanwhile, the construction efficiency is improved.

While the fundamental and principal features of the utility model and advantages of the utility model have been shown and described, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (9)

1. The utility model provides a tower crane construction intelligence building platform is exempted from in assembled house engineering which characterized in that: comprising the following steps: the device comprises a bailey frame platform, a support frame, a truss vehicle assembly and a track assembly; the support frame is arranged at the bottom of the bailey frame platform, and a floor slab is arranged on the upper side of the support frame;

The track assembly is arranged on the bailey frame platform and the support frame and is provided with an uplink slideway and a downlink slideway;

The truss car assembly comprises an uplink truss car assembly arranged on an uplink slideway and a downlink truss car assembly arranged on a downlink slideway; the upstream truss car component and the downstream truss car component are arranged in parallel.

2. The intelligent building platform for tower crane free construction of fabricated residential engineering according to claim 1, wherein: the bailey frame platform comprises a plurality of bailey pieces and connecting fittings for connecting the bailey pieces; the plurality of bailey pieces form at least 2 lifting wellheads through connecting fittings.

3. The intelligent building platform for tower crane free construction of fabricated residential engineering according to claim 2, wherein: the movable end of the ascending truss car assembly moves through the lifting wellhead.

4. The intelligent building platform for tower crane free construction of fabricated residential engineering according to claim 1, wherein: the support frames are oil cylinder support columns which are connected with the wall body through wall attaching guide seats and are distributed at the bottom of the bailey frame platform in a staggered mode.

5. The intelligent building platform for tower crane free construction of fabricated residential engineering according to claim 4, wherein: the ascending slide way and the descending slide way are both fixed on a base frame; the base frames are arranged on the staggered supporting frames, the base frames are provided with 2 mounting parts extending inwards, and the ascending slide ways and the descending slide ways are respectively mounted on the respective mounting parts.

6. The intelligent building platform for tower crane free construction of fabricated residential engineering according to claim 5, wherein: the installation department that is located the upside passes through connecting bolt to be fixed on bailey frame platform, and the installation department that is located the downside passes through sleeve pipe subassembly and bolt fastening on the installation department that is located the upside.

7. The intelligent building platform for tower crane free construction of fabricated residential engineering according to claim 1, wherein: the uplink truss car assembly comprises an uplink truss car crane, an uplink sliding device and an uplink lifting device; the uplink truss crane is arranged on the uplink slideway; the uplink sliding device is arranged on the uplink truss crane and used for enabling the uplink lifting device to move on the uplink truss crane; the lifting end of the ascending and descending device is connected with the material.

8. The intelligent building platform for tower crane free construction of fabricated residential engineering according to claim 7, wherein: the descending truss car assembly comprises a descending truss car crane, a descending sliding device and a descending lifting device; the descending truss crane is arranged on the descending slideway; the descending sliding device is arranged on the descending truss crane and used for enabling the descending lifting device to move on the descending truss crane; the lifting end of the descending lifting device is connected with the material.

9. The intelligent building platform for tower crane free construction of the prefabricated residential engineering according to any one of claims 7-8, wherein: and the uplink truss crane and the downlink truss crane are respectively provided with a laser range finder and a control unit.