CN220814841U - Climbing frame auxiliary lifting equipment - Google Patents

Abstract

The utility model provides climbing frame auxiliary lifting equipment. The climbing frame auxiliary lifting device comprises a concrete slab, a lattice column, a diagonal draw bar and a rear draw bar; the concrete slab is provided with a plurality of first embedded bolts, the concrete slab is fixedly connected with a first structural floor slab and a second structural floor slab, mounting plates I are arranged on the first structural floor slab and the second structural floor slab, and the first embedded bolts are connected between the first mounting plates and the second structural floor slab and between the first mounting plates and the second structural floor slab; the lattice column is arranged on the concrete slab and is connected with the first embedded bolts; the diagonal draw bar and the rear draw bar are both connected to the lattice column, the other ends of the diagonal draw bar and the rear draw bar are respectively connected with the first pair of mounting plates, the lattice column comprises a plurality of lattice column monomers, the climbing frame auxiliary lifting device is arranged through the corresponding mechanism, and when encountering a structural appearance overhead layer or a structural appearance mutation, the climbing frame can still climb, so that the normal operation of the construction progress can be guaranteed.

Description

Climbing frame auxiliary lifting equipment

Technical Field

The utility model relates to the technical field of climbing frames, in particular to climbing frame auxiliary lifting equipment.

Background

The climbing frame, namely the attached lifting scaffold, is an operation protection frame which is independently researched, developed and popularized and applied in China, and has the characteristics of convenient assembly and disassembly, strong adaptability, high construction efficiency, low safety risk of high-altitude operation and the like compared with the traditional floor type and overhanging scaffolds. In recent years, along with the development of the building industry, particularly high-rise buildings, and the application of novel building templates such as aluminum templates, climbing frames are rapidly popularized, and industries enter a expressway.

Along with the pursuit of higher and higher building exterior modeling, the conditions such as structural appearance overhead layer or structural appearance abrupt change are inevitably encountered in the structural construction process, and the existing climbing frame can not smoothly finish climbing, such as reassembling, and the problems of construction period delay and cost increase are caused.

There is thus an urgent need to redesign a new auxiliary lifting device for a climbing frame to solve the above problems.

Disclosure of utility model

The utility model provides climbing frame auxiliary lifting equipment for solving the technical problems in the background technology.

The utility model provides climbing frame auxiliary lifting equipment, which comprises a concrete slab, lattice columns, diagonal braces and rear braces, wherein the concrete slab is arranged on the lattice columns;

The concrete slab is provided with a plurality of first embedded bolts, the concrete slab is fixedly connected with a first structural floor slab and a second structural floor slab, mounting plates I are arranged on the first structural floor slab and the second structural floor slab, and the first embedded bolts are connected between the first mounting plates and the second structural floor slab and between the first mounting plates and the second structural floor slab;

The lattice column is arranged on the concrete slab and is connected with the first embedded bolts;

the diagonal draw bar and the rear draw bar are connected to the lattice column, and the other ends of the diagonal draw bar and the rear draw bar are respectively connected with a pair of mounting plates.

Optionally, the lattice column comprises a plurality of lattice column monomers, each lattice column monomer comprises four vertical rods, a connecting plate is welded between each adjacent pair of vertical rods, an inclined rod and two first positioning rods are welded between the pair of vertical rods, the vertical rods and the inclined rods are made of square tubes with the thickness of 50 multiplied by 3mm, the connecting plate is made of steel plates with the thickness of 8mm, and the first positioning rods are used for fixing fastening bolts.

Optionally, two locating rods II are connected between the parallel connecting plates, the locating rods II are parallel to the locating rods I, the locating rods II are used for fixedly connecting the main bolts, and meanwhile the strength of the lattice column monomers can be improved.

Optionally, a supporting rod is connected between the connecting plate and the first positioning rod and used for improving the overall strength of the lattice column monomer;

one of the connecting plates is welded with a pair of first connecting plates, and the first connecting plates are hinged with the rear pull rod.

Optionally, be connected with between two lattice column monomers and connect main bolt and four and connect vice bolts, connect main bolt to locate between a pair of locating lever two, can realize the connection of a pair of lattice column monomer through connecting main bolt and four and connect vice bolts, also make things convenient for the dismouting between the lattice column monomer simultaneously.

Optionally, a second connecting plate is installed on one of the lattice column units, and the diagonal draw bar is hinged to the second connecting plate.

Optionally, the concrete slab and the uppermost lattice column monomer are both provided with attachment supports, and the integral structure is fixed on the climbing frame through a pair of attachment supports;

And a fastening bolt is connected between the attachment support and the lattice column monomer, and the fastening bolt is arranged between the pair of first positioning rods and is used for fixing the attachment support and the lattice column.

Optionally, a protection mechanism is arranged on the outer side of the first embedded bolt and used for protecting the first embedded bolt, so that the first embedded bolt is not easy to corrode and rust, and subsequent disassembly of staff is facilitated;

The protection mechanism comprises a protection sleeve, a telescopic end is connected to the protection sleeve, a magnet is connected to one side, far away from the protection sleeve, of the telescopic end, and the magnet can attract a gasket used by the first embedded bolt, so that the protection mechanism can be fixed to the outer side of the first embedded bolt, and the first embedded bolt is not easy to corrode;

The top is equipped with the location knot in the protective sheath, and the location knot corresponds with embedded bolt one, and the location knot is used for the protective sheath for protection mechanism is better to the protection effect of embedded bolt one.

The beneficial effects of the utility model are as follows:

the climbing frame auxiliary lifting device is arranged through the corresponding mechanism, and when encountering a structural appearance overhead layer or a structural appearance mutation, the climbing frame can still climb, so that the normal operation of the construction progress can be ensured.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a side view of a use state of a climbing frame auxiliary lifting device provided by the utility model;

FIG. 2 is an enlarged partial view of area A of FIG. 1;

FIG. 3 is an enlarged partial view of region B of FIG. 1;

FIG. 4 is an enlarged partial view of region C of FIG. 1;

FIG. 5 is an enlarged partial view of region D of FIG. 1;

FIG. 6 is a front view of a climbing frame auxiliary lifting device provided by the utility model;

FIG. 7 is an enlarged view of a portion of region E of FIG. 6;

Fig. 8 is a perspective view of a lattice column monomer provided by the utility model.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It is to be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present utility model are shown in the drawings. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the utility model. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

Referring to fig. 1 to 8, a climbing frame auxiliary lifting device of the present utility model includes a concrete slab 1, lattice columns 2, diagonal braces 3 and rear braces 4.

The concrete slab 1 is provided with a plurality of first embedded bolts 101, and the first embedded bolts 101 are single-gasket double nuts of M30 multiplied by 200mm bolts.

In addition, a first structural floor 102 and a second structural floor 103 are fixedly connected to the concrete slab 1, a first mounting plate 104 is arranged on the first structural floor 102 and the second structural floor 103, a second embedded bolt 105 is connected between the first mounting plate 104 and the first structural floor 102 and between the second structural floor 103, and the second embedded bolt 105 is a bolt with M30 multiplied by 500 mm.

Referring to fig. 1 to 8, lattice columns 2 are disposed on a concrete slab 1 and are connected to a pair of embedded bolts 101.

The lattice column 2 comprises a plurality of lattice column monomers, the number of the lattice column monomers is 7, and the size of each lattice column monomer is 600mm multiplied by 400mm multiplied by 300mm.

In addition, the lattice column monomer includes four montants 201, and every adjacent to each other all welded connection has connecting plate 202 between the montant 201 of a pair.

Preferably, the height of the welding seam between the vertical rod 201 and the connecting plate 202 is 1.2 times or 6mm of that of the base material, so that the welding between the vertical rod 201 and the connecting plate 202 is firm, and the welded panel cannot be deformed.

Specifically, a diagonal rod 203 and two positioning rods 204 are welded between a pair of vertical rods 201, the vertical rods 201 and the diagonal rod 203 are made of square tubes with the thickness of 50×50×3mm, the connecting plate 202 is made of a steel plate with the thickness of 8mm, and the positioning rods 204 are used for fixing the fastening bolts 212.

In addition, two positioning rods two 205 are connected between the parallel pair of connecting plates 202, and the positioning rods two 205 and the positioning rod one 204 are parallel to each other. The second positioning rod 205 is used for fixedly connecting the main bolt 208, and can also improve the strength of the lattice column monomer.

Furthermore, a supporting rod 206 is connected between the connecting plate 202 and the first positioning rod 204, so as to improve the overall strength of the lattice column unit.

Preferably, one of the connection plates 202 is welded with a pair of connection plates 207, and the connection plates 207 are hinged with the rear tie rod 4, and the shape of the lattice column unit is shown in fig. 8.

Referring to fig. 1 to 8, a connecting main bolt 208 and four connecting auxiliary bolts 209 are connected between two lattice column units, and the connecting main bolt 208 is disposed between a pair of positioning rods 205. The connection of a pair of lattice column monomers can be realized through the connection main bolts 208 and the four connection auxiliary bolts 209, and meanwhile, the disassembly and assembly among the lattice column monomers are convenient.

Preferably, the connecting main bolt 208 is an m30×250 screw, and the connecting sub-bolt 209 is an m16×180mm bolt.

Wherein, a lattice column monomer is provided with a second connecting plate 210, and the diagonal draw bar 3 is hinged on the second connecting plate 210.

In addition, the concrete slab 1 and the uppermost lattice column unit are both provided with attachment brackets 211, and the overall structure is fixed to the climbing frame by a pair of attachment brackets 211.

Specifically, a fastening bolt 212 is connected between the attachment support 211 and the lattice column unit, and the fastening bolt 212 is provided between the pair of positioning rods 204 for fixing the attachment support 211 to the lattice column 2.

Referring to fig. 1 to 8, diagonal braces 3 and rear braces 4 are each connected to lattice columns 2, and the other ends of diagonal braces 3 and rear braces 4 are each connected to a pair of mounting plates 104.

Preferably, the rear tie 4 is attached to mounting plate one 104 using M16 x 120 bolts.

Wherein, diagonal draw bar 3 adopts the Q235 steel pipe that diameter is 48 x 3mm, and diagonal draw bar 3's length is adjustable, and back draw bar 4 adopts 40mm angle steel to constitute lattice formula pull rod or diameter to be 100mm 4mm pipe pull rod to make.

Referring to fig. 1 to 8, a protection mechanism 5 is disposed on the outer side of the first embedded bolt 101 for protecting the first embedded bolt 101, so that the first embedded bolt 101 is not easy to be corroded and rusted, and is convenient for subsequent disassembly by workers.

Wherein, protection mechanism 5 includes protective sheath 501, is connected with flexible end 502 on the protective sheath 501, and the flexible end 502 is kept away from the one side of protective sheath 501 and is connected with magnet 503. The magnet 503 can attract the gasket used by the first embedded bolt 101, and then the protection mechanism 5 can be fixed on the outer side of the first embedded bolt 101, so that the first embedded bolt 101 is not easy to corrode.

In addition, the top is equipped with the location knot 504 in the protective sheath 501, and the location knot 504 is corresponding with embedded bolt one 101, and the location knot 504 is used for the protective sheath 501 for protection mechanism 5 is better to the protection effect of embedded bolt one 101.

Of course, the protection mechanism 5 of the present application includes, but is not limited to, the first pre-buried bolt 101, the connecting main bolt 208 and the fastening bolt 212 may be used.

When the protection sleeve is used, the protection sleeve 501 is sleeved on the outer side of the first embedded bolt 101, the positioning buckle 504 is clamped on the bolt, the telescopic end 502 is telescopic, the magnet 503 can be adsorbed with the gasket, the protection mechanism 5 can be fixed, the protection mechanism 5 is utilized to wrap the nut on the first embedded bolt 101, the first embedded bolt 101 and the nut are not easy to corrode in a long-time use process, and further follow-up disassembly and assembly of workers are facilitated.

According to the building external structure and the floor elevation, if the spacing between structural beams exceeds the attachment spacing of the climbing frame when meeting floors with high overhead floors and high floor heights, the assembled lattice column 2 is adopted to ensure that the climbing frame can climb normally, the existing lifting point system and lifting system are matched to assist the climbing frame to finish lifting, the utilized lattice column 2 can be recycled, the materials are convenient to construct and disassemble, and the climbing frame lifting work can be finished safely, efficiently and conveniently.

The foregoing description is only of embodiments of the present utility model, and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present utility model or directly or indirectly applied to other related technical fields are included in the scope of the present utility model.

Claims (8)

1. The climbing frame auxiliary lifting equipment is characterized by comprising

The concrete slab is provided with a plurality of first embedded bolts, the concrete slab is fixedly connected with a first structural floor slab and a second structural floor slab, mounting plates I are arranged on the first structural floor slab and the second structural floor slab, and a pair of first embedded bolts are connected between the first mounting plates and the first structural floor slab and between the first structural floor slab and the second structural floor slab;

The lattice column is arranged on the concrete slab and is connected with the pair of embedded bolts I;

The diagonal draw bar and the rear draw bar are connected to the lattice column, and the other ends of the diagonal draw bar and the rear draw bar are respectively connected with the pair of mounting plates I.

2. The climbing frame auxiliary lifting device according to claim 1, wherein the lattice column comprises a plurality of lattice column units, each lattice column unit comprises four vertical rods, a connecting plate is welded between each adjacent pair of vertical rods, and a diagonal rod and two positioning rods are welded between the pair of vertical rods.

3. The climbing frame auxiliary lifting device according to claim 2, wherein two positioning rods are connected between a pair of parallel connecting plates, and the two positioning rods are parallel to the first positioning rod.

4. The climbing frame auxiliary lifting device according to claim 3, wherein a supporting rod is connected between the connecting plate and the first positioning rod, a pair of first connecting plates are welded on one connecting plate, and the first connecting plates are hinged with the rear pull rod.

5. The climbing frame auxiliary lifting device according to claim 4, wherein a connecting main bolt and four connecting auxiliary bolts are connected between two lattice column units, and the connecting main bolt is arranged between a pair of positioning rods II.

6. The climbing frame auxiliary lifting device according to claim 5, wherein a second connecting plate is mounted on one of the lattice column units, and the diagonal draw bar is hinged to the second connecting plate.

7. The climbing frame auxiliary lifting device according to claim 6, wherein the concrete slab and the uppermost lattice column unit are provided with attachment supports, fastening bolts are connected between the attachment supports and the lattice column unit, and the fastening bolts are arranged between the pair of first positioning rods.

8. The climbing frame auxiliary lifting device according to claim 7, wherein a protection mechanism is arranged on the outer side of the first embedded bolt, the protection mechanism comprises a protection sleeve, a telescopic end is connected to the protection sleeve, a magnet is connected to one side, away from the protection sleeve, of the telescopic end, a positioning buckle is arranged on the inner top of the protection sleeve, and the positioning buckle corresponds to the first embedded bolt.