CN118581980A - A steel beam lifting device for assembling steel structure workshop - Google Patents

Abstract

The invention discloses steel beam jacking equipment for steel structure factory building assembly, and belongs to the technical field of steel structure jacking construction. It mainly comprises: lifting platform, climbing device, pusher, from fixing device, drive arrangement, its characterized in that: the climbing device is arranged on one side of the lifting platform; the pushing device is arranged adjacent to the climbing device and comprises a traction assembly and a claw assembly; the self-fixing device is arranged on one side of the traction assembly, which is far away from the climbing device; the driving device is movably arranged on one side of the lifting platform and meshed with the driving device. The lifting platform with the automatic butt joint and automatic fixing functions is adopted, so that the vertical conveying, the transverse butt joint and the fixed connection of the standard section can be automatically completed after the ground personnel are configured, the construction efficiency of the steel structure jacking operation is effectively improved, and the construction safety is also improved. The invention is mainly used for jacking construction of the steel structure.

Description

A steel beam lifting device for assembling steel structure workshop

Technical Field

The invention belongs to the technical field of steel structure jacking construction, and in particular relates to a steel beam jacking device for assembling a steel structure workshop.

Background Art

At present, with the development of society, the demand for steel structures suitable for large-span spaces such as large sports plazas, exhibition centers and factories is gradually increasing, resulting in the need to speed up the construction of steel structures in large-span spaces while ensuring construction safety and quality. In the existing steel structure jacking construction, the jacking device is equipped with a corresponding lifting platform to transport the standard sections used for support. During the steel structure jacking process, manpower or cranes are required to transport the standard sections to the supporting position; and manual correction and fixation are required. This working method results in the inability to effectively improve the efficiency of the steel structure jacking work. At the same time, this method of transporting standard sections makes the standard sections at risk of falling off during transportation.

Summary of the invention

The technical problem to be solved by the present invention is: to overcome the shortcomings of the prior art and provide a steel beam jacking equipment for assembling steel structure workshops, which adopts a lifting platform with automatic docking and automatic fixing functions, and can automatically complete the vertical transportation, horizontal docking and fixed connection of standard sections after the ground personnel are deployed. It not only effectively improves the construction efficiency of the steel structure jacking work, but also improves the safety of the construction.

The steel beam jacking equipment for assembling a steel structure factory building comprises: a lifting platform, a climbing device, a pushing device, a self-fixing device, and a driving device, characterized in that: one side of the lifting platform is provided with a plurality of slideways adapted to a partial structure of the pushing device, and the other side is provided with a rack and a plurality of sliding bars, and adapted to be connected with the driving device; the climbing device is installed on one side of the lifting platform and is located on both sides of the sliding bar; the pushing device is arranged adjacent to the climbing device, and comprises a traction assembly and a claw assembly, wherein the claw assembly is movably arranged in the slideway and is movably connected with the traction assembly on the other side of the lifting platform; the self-fixing device is installed on a side of the traction assembly away from the climbing device, is movably connected with the lifting platform, and a partial structure extends to the outside of the lifting platform and is connected with a fastening assembly; the driving device is adapted to be connected with the rack and the sliding bar, is movably arranged between the climbing device, the pushing device, and the self-fixing device, and moves to a specific position in a sliding manner to engage with the climbing device or the pushing device or the self-fixing device, and engages with the driving device.

Preferably, the climbing device includes a linkage box, a rotating shaft, a fixing buckle, a linkage gear, a climbing gear, and a bracket. The linkage boxes are provided in plurality and fit with the side wall of the lifting platform; the rotating shaft is rotatably embedded in the top of the linkage box, with a linkage gear fixed at one end and a climbing gear fixed at the other end, and the climbing gear extends into the linkage box; wherein, one end of the rotating shaft on which the linkage gear is installed is rotatably connected to the bracket fixed on the lifting platform.

Preferably, a climbing through groove is provided in the linkage box, and a plurality of auxiliary wheels are embedded on one side of the climbing through groove; at the same time, a slot adapted to the climbing gear is provided on the side wall facing the climbing through groove, and the climbing through groove is connected to the slot.

Preferably, the traction assembly is installed on one side of the climbing device, including a frame, an axle, a driven gear, a winch wheel, a first guide wheel, a second guide wheel, and a cable. The winch wheel is fixed at both ends of the axle, and a driven gear adapted to the driving device is also installed on the axle, adjacent to the winch wheel; the axle is rotatably connected to the frame fixed on one side of the lifting platform; the first guide wheel is provided in multiple groups, which are respectively installed on both sides of the frame; the second guide wheel is fixed at both ends of the lifting platform, located below the end of the slide; wherein the winch wheel, the first guide wheel, and the second guide wheel are on the same straight line; a total of multiple cables are provided, one end of which is fixed to the winch wheel, and the other end is fixed to the claw assembly.

Preferably, the claw assembly includes a slider, a connecting seat, and a claw, wherein both sides of the slider are provided with sliding grooves adapted to the slideway; a groove is provided on the top of the slider; the connecting seat is detachably fixed to the top of the slider, and part of the structure is embedded in the groove; the claw is hinged at the top of the connecting seat and rotates toward one side; wherein the connecting seat can be reversely connected to the slider.

Preferably, the self-fixing device includes a telescopic joint, an inner connecting rod, a tooth plate, and an outer connecting rod. The telescopic joint is symmetrically connected to the side wall of the lifting platform, and one end located inside the lifting platform is connected to the inner connecting rod; the tooth plate is fixed to one side of the inner connecting rod and engages with the driving device; the outer connecting rod is sleeved and fixed on the other end of the telescopic joint, and the other end of the outer connecting rod is connected to a fastening assembly.

Preferably, the fastening assembly comprises an upper splint, a lower splint, a connecting plate, an electric telescopic rod, a fastening wheel, a screwdriver bit, a fastening platform, a fastening motor, a fastening gear, a guide column, and a steel chain, and the electric telescopic rod is provided with at least two, both of which are embedded in the outer connecting rod; a plurality of connecting plates adapted to the electric telescopic rod are installed at one end of the upper splint, and the connecting plate is fixedly connected to the electric telescopic rod; a plurality of fastening wheels and guide columns are distributed on the top of the upper splint, wherein one end of the fastening wheel extends to the bottom of the upper splint and is provided with a screwdriver bit; the fastening platform is fixed to one side of the top of the upper splint, and a fastening gear is embedded on its inner side; the fastening motor is installed on the top of the fastening platform, and its power output end extends into the fastening platform and is fixedly connected to the fastening gear; the lower splint is located below the upper splint, and a plurality of connecting plates adapted to the electric telescopic rod are installed at one end of the upper splint, and the connecting plate is fixedly connected to the electric telescopic rod; the top of the lower splint is provided with an empty slot 422 adapted to the screwdriver bit.

Preferably, a rectangular through groove adapted to the rack and a circular through groove adapted to the slide rod are provided on the side wall of the driving device; a sliding motor is installed on one side of the driving device, and a sliding gear adapted to the rack is installed on the power output end of the sliding motor; driving gears are installed on the power output ends at both ends of the driving device.

Preferably, it also includes a standard section and a climbing rail, the standard section includes a first frame and a second frame, the two have the same structure, are arranged opposite to each other, and are spliced into a whole; at the same time, both are composed of a support column, a first flange, a crossbeam, a diagonal brace, and a second flange, the first frame and the second frame each include two support columns arranged in parallel, and the support columns are connected by a crossbeam and a diagonal brace; the two ends of the support column are fixed with a first flange; the ends of the crossbeam and the diagonal brace arranged opposite to each other in the first frame and the second frame are fixed with a second flange; the climbing is fixed on one side of each support column.

Preferably, the climbing rail is adaptably connected to the climbing through groove, and the side of the climbing rail facing away from the support column is provided with climbing teeth adapted to the climbing gear; the side of the climbing rail facing the support column is fixed with equidistantly arranged fixing rings and embedded rings, wherein one side of the embedded ring abuts against the first flange.

Compared with the prior art, the present invention has the following beneficial effects:

1. The lifting platform with automatic docking and automatic fixing functions can complete the vertical transportation, horizontal docking and fixed connection of the standard section by itself after the ground personnel are deployed, which not only effectively improves the construction efficiency of the steel structure jacking work.

2. Improved the safety of standard section transportation in steel structure jacking work.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a front view of the present invention;

FIG2 is a front view of the lifting platform of the present invention;

FIG3 is a schematic structural diagram of a lifting platform of the present invention;

FIG4 is a schematic structural diagram of the lifting platform of the present invention from another angle;

FIG5 is a schematic diagram of the internal structure of the lifting platform of the present invention;

FIG6 is a front view of the climbing device of the present invention;

FIG7 is a schematic structural diagram of a climbing device according to the present invention;

FIG8 is an enlarged structural view of the climbing device of the present invention;

FIG9 is a schematic diagram of the structure of a pushing device of the present invention;

FIG10 is a schematic diagram of the shaft structure of the present invention;

FIG11 is a front view of the claw assembly of the present invention;

FIG12 is a schematic diagram of the structure of the claw assembly of the present invention;

FIG13 is a schematic cross-sectional structure diagram of a connecting seat of the present invention;

FIG14 is a front view of the self-fixing device of the present invention;

FIG15 is a schematic structural diagram of a self-fixing device according to the present invention;

FIG16 is a front view of the fastening assembly of the present invention;

FIG17 is a schematic diagram of the structure of the fastening assembly of the present invention;

FIG18 is a schematic diagram of the structure of a driving device of the present invention;

FIG19 is another schematic diagram of the structure of the drive assembly of the present invention;

FIG20 is a schematic diagram of the structure of a standard component of the present invention;

FIG. 21 is a schematic diagram of the climbing rail structure of the present invention.

In the figure, 100, lifting platform; 101, slideway; 102, rack; 103, embedded groove; 104, slide bar; 105, bearing; 200, climbing device; 210, linkage box; 211, climbing groove; 212, auxiliary wheel; 213, slot; 220, rotating shaft; 221, fixing buckle; 222, linkage gear; 223, climbing gear; 230, bracket; 300, pushing device; 310, traction assembly; 3 11. frame; 312. shaft; 313. driven gear; 314. strand wheel; 315. first guide wheel; 316. second guide wheel; 317. cable; 320. claw assembly; 321. slider; 322. slideway; 323. groove; 324. buckle; 330. connection seat; 331. hinged ear; 332. claw; 400. self-fixing device; 401. telescopic joint; 402. inner connecting rod; 40 3. Tooth plate; 404. External connecting rod; 410. Fastening assembly; 411. Upper clamping plate; 412. Lower clamping plate; 413. Connecting plate; 414. Electric telescopic rod; 415. Fastening wheel; 416. Batch head; 417. Fastening platform; 418. Fastening motor; 419. Fastening gear; 420. Guide column; 421. Steel chain; 422. Empty slot; 500. Driving device; 501. Rectangular through slot; 502. Circular through slot Groove; 503, extension plate; 504, hinged plate; 505, drive gear; 510, sliding motor; 511, sliding gear; 600, standard section; 601, first structure; 602, second structure; 610, support column; 611, first flange; 620, crossbeam; 621, diagonal brace; 622, second flange; 700, climbing rail; 710, climbing teeth; 720, fixing ring; 730, embedded ring.

DETAILED DESCRIPTION

The present invention will be further described below in conjunction with the accompanying drawings:

The directional terms involved in the detailed description paragraphs are only for the convenience of those skilled in the art to understand the technical solutions described in this application according to the visual orientation shown in the accompanying drawings. Unless otherwise clearly specified and limited, the terms "setting", "installation", "connection", etc. should be understood in a broad sense. For ordinary technicians in this field, the specific meanings of the above terms in the present invention can be understood according to the specific circumstances.

As shown in Figures 1 to 6, a steel beam lifting device for assembling a steel structure workshop includes: a lifting platform 100, a climbing device 200, a pushing device 300, a self-fixing device 400, and a driving device 500, characterized in that: one side of the lifting platform 100 is provided with a plurality of slideways 101 adapted to the partial structure of the pushing device 300, and the other side is provided with a rack rail 102 and a plurality of slide bars 104, which are adapted to be connected with the driving device 500; the climbing device 200 is installed on one side of the lifting platform 100, located on both sides of the slide bar 104; the pushing device 300 is arranged adjacent to the climbing device 200, and includes a traction assembly 310 and a claw assembly 320, wherein the claw The component 320 is movably arranged in the slideway 101 and is movably connected to the traction component 310 on the other side of the lifting platform 100; the self-fixing device 400 is installed on the side of the traction component 310 away from the climbing device 200, and is movably connected to the lifting platform 100, and part of the structure extends to the outside of the lifting platform 100 and is connected to the fastening component 410; the driving device 500 is adaptively connected to the rack 102 and the slide rod 104, and is movably arranged between the climbing device 200, the pushing device 300, and the self-fixing device 400, and moves to a specific position in a sliding manner to engage with the climbing device 200 or the pushing device 300 or the self-fixing device 400, and engages with the driving device.

Optionally, an embedding groove 103 is provided on the opposite side wall of the lifting platform 100. In this way, the self-fixing device 400 can extend to the inner side of the lifting platform 100 through the embedding groove 103, and the self-fixing device 400 can also slide telescopically along the embedding groove 103.

Optionally, a special-shaped through groove is provided on one side of the lifting platform 100, which is adapted to the climbing device 200. In this way, the lifting platform 100 and the climbing device 200 are connected to each other through the special-shaped through groove, and the movement of the climbing device 200 is not affected.

Optionally, a plurality of bearing seats 105 are fixed to one side of the lifting platform 100, and the bearing seats 105 are connected to both ends of the slide bar 104. In this way, the slide bar 104 is supported by the bearing seats 105, so that a certain distance is left between the slide bar 104 and the lifting platform 100.

As shown in Fig. 6 to Fig. 8, the climbing device 200 comprises a linkage box 210, a rotating shaft 220, a fixing buckle 221, a linkage gear 222, a climbing gear 223, and a bracket 230. The linkage box 210 is provided with a plurality of linkage gears, which are fitted with the side wall of the lifting platform 100. The rotating shaft 220 is rotatably embedded in the top of the linkage box 210, with a linkage gear 222 fixed at one end and a climbing gear 223 fixed at the other end, and the climbing gear 223 extends into the linkage box 210. Among them, one end of the rotating shaft 220 with the linkage gear 222 installed is rotatably connected to the bracket 230 fixed on the lifting platform 100. In this way, the linkage gear 222 is meshed with the driving device 500, thereby driving the rotating shaft 220 and the climbing gear 223 connected in series with the linkage gear 222 to rotate synchronously. The rotating shaft 220 is fixed and limited by the cooperation of the fixing buckle 221 and the bracket 230, which reduces the possibility of the rotating shaft 220 being offset or disengaged during the rotation process, and effectively improves the working stability of the rotating shaft 220, the linkage gear 222, and the climbing gear 223.

As shown in FIG8 , a climbing groove 211 is provided in the linkage box 210, and a plurality of auxiliary wheels 212 are embedded on one side of the climbing groove 211; at the same time, a slot 213 adapted to the climbing gear 223 is provided on the side wall facing the climbing groove 211, and the climbing groove 211 is connected to the slot 213. In this way, the auxiliary wheels 212 provided in the climbing groove 211 can reduce the friction of the linkage box 210 during the climbing process of the lifting platform 100, thereby extending the service life of the linkage box 210 and the lifting platform 100. On the other hand, the inner diameter of the climbing groove 211 can be reduced by the auxiliary wheels 212, so that the linkage box 210 can be more closely connected to the climbing object.

Optionally, the outer peripheral wall of the auxiliary wheel 212 is made of rubber material. In this way, the rubber material has good flexibility, and when the inner diameter of the climbing groove 211 is smaller than the climbing object, the climbing object can still pass through the climbing groove 211 by virtue of its flexibility. Thus, the firmness of the connection between the linkage box 210 and the climbing object is improved.

As shown in FIGS. 9 and 10 , the traction assembly 310 is installed on one side of the climbing device 200, and includes a frame 311, a shaft 312, a driven gear 313, a winch wheel 314, a first guide wheel 315, a second guide wheel 316, and a cable 317. The winch wheel 314 is fixed at both ends of the shaft 312, and a driven gear 313 adapted to the drive device 500 is also installed on the shaft 312, adjacent to the winch wheel 314; the shaft 312 is fixed to the lifting device 200, and the driven gear 313 is fixed to the lifting device 200. The frame 311 on one side of the lifting platform 100 is rotatably connected; the first guide wheel 315 is provided with multiple groups, which are respectively installed on both sides of the frame 311; the second guide wheel 316 is fixed at both ends of the lifting platform 100, and is located below the end of the slideway 101; wherein the winding wheel 314, the first guide wheel 315, and the second guide wheel 316 are on the same straight line; the cable 317 is provided with multiple cables, one end of which is fixed to the winding wheel 314, and the other end is fixed to the claw assembly 320. In this way, when the driven gear 313 is engaged and rotated with the driving device 500, the winding wheel 314 connected to the shaft 312 can be driven to rotate synchronously. Therefore, the cable 317 connected to the winding wheel 314, under the rotation of the winding wheel 314, synchronously performs the winding and releasing actions, so as to pull the claw assembly 320 to slide along the slideway 101 in different directions. The winding wheel 314, the first guide wheel 315, and the second guide wheel 316 arranged on the same straight line can guide the cable 317 when it is wound and released, so as to prevent the cable 317 from deviating from the original running track, thereby improving the stability of the traction component 310.

It can be understood that the cables 317 are fixedly connected to the winch wheel 314 in different directions, that is, one cable 317 passes through the first guide wheel 315 on one side of the frame 311 and contacts the second guide wheel 316 on the same side, and then is connected to one end of the claw assembly 320. The other cable 317 passes through the first guide wheel 315 on the other side of the frame 311 and contacts the second guide wheel 316 on the same side, and then is connected to the other end of the claw assembly 320. When the winch wheel 314 rotates clockwise, the cable 317 at one end is reeled in, pulling the claw assembly 320 to move toward one end of the lifting platform 100, and the other cable 317 connected thereto is released following the claw assembly 320. On the contrary, when the winch wheel 314 rotates counterclockwise, the two cables 317 move in opposite ways, pulling the claw assembly 320 to move toward the other end of the lifting platform 100.

As shown in Figures 11 to 13, the claw assembly 320 includes a slider 321, a connecting seat 330, and a claw 332. The slider 321 is provided with a slide groove 322 adapted to the slideway 101 on both sides; a groove 323 is provided on the top of the slider 321; the connecting seat 330 is detachably fixed to the top of the slider 321, and part of the structure is embedded in the groove 323; the claw 332 is hinged on the top of the connecting seat 330 and rotates toward one side; wherein the connecting seat 330 can be connected to the slider 321 in reverse. In this way, the connecting seat 330 is a semi-enclosed structure, that is, only one end is provided with an opening. When an object moves from the opening direction toward the other end, the claw 332 will be continuously squeezed. At this time, during the squeezing process of the claw 332, the upper part of the claw 332 will automatically flip toward the moving direction of the object to prevent the claw 332 from hindering the movement of the object; when the object passes over the claw 332, the claw 332 will automatically return to its initial state. When the object moves in the opposite direction, since only one end of the connecting seat 330 is provided with an opening, the claw 332 is blocked by the other end of the connecting seat 330. Therefore, even if the claw 332 is squeezed by the object, it will not flip, so that the claw 332 can hook the object and push the object to the designated position under the drive of the winding wheel 314. On the contrary, if the object needs to be pushed to the other end, it only needs to remove the mounting seat in advance and install it in the opposite direction. Thereby, the flipping direction of the claw 332 is changed, and the object can be hooked and moved toward the other end.

Optionally, the top of the connecting seat 330 is provided with hinged ears 331 arranged opposite to each other, and a hinge rod is embedded between the hinged ears 331. In this way, the claw 332 can be movably installed between the hinged ears 331 through the hinge rod, so that the claw 332 can be flexibly turned over, thereby improving the stability of the turning of the claw 332.

Optionally, buckles 324 are installed at both ends of the slider 321. In this way, the slider 321 can be connected to the cable 317 through the slider 321.

As shown in Figures 14 and 15, the self-fixing device 400 includes a telescopic joint 401, an inner connecting rod 402, a tooth plate 403, and an outer connecting rod 404. The telescopic joint 401 is symmetrically connected to the side wall of the lifting platform 100, and one end located in the lifting platform 100 is connected to the inner connecting rod 402; the tooth plate 403 is fixed to one side of the inner connecting rod 402 and meshed with the driving device 500; the outer connecting rod 404 is sleeved and fixed to the other end of the telescopic joint 401, and the other end of the outer connecting rod 404 is connected to the fastening assembly 410. In this way, after the tooth plate 403 is meshed with the driving device 500, the tooth plate 403 moves toward or in the opposite direction under the drive of the driving device 500. Through the inner connecting rod 402, the telescopic joint 401, and the outer connecting rod 404 connected to each other, the fastening assembly 410 installed at the end of the outer connecting plate is driven to move toward or away from the lifting platform 100.

As shown in FIGS. 16 and 17 , the fastening assembly 410 includes an upper clamping plate 411, a lower clamping plate 412, a connecting plate 413, an electric telescopic rod 414, a fastening wheel 415, a screwdriver bit 416, a fastening platform 417, a fastening motor 418, a fastening gear 419, a guide column 420, and a steel chain 421. The electric telescopic rod 414 is provided with at least two, both of which are embedded in the outer connecting rod 404; a plurality of connecting plates 413 adapted to the electric telescopic rod 414 are installed at one end of the upper clamping plate 411, and the connecting plates 413 are fixedly connected to the electric telescopic rod 414; a plurality of fastening wheels 415 and guide columns 420 are distributed on the top of the upper clamping plate 411, wherein the fastening wheels 415 and the guide columns 420 are arranged on the top of the upper clamping plate 411. The end of the upper clamping plate 415 extends to the bottom of the upper clamping plate 411 and is installed with a screwdriver 416; the fastening platform 417 is fixed to one side of the top of the upper clamping plate 411, and a fastening gear 419 is embedded in the inner side thereof; the fastening motor 418 is installed on the top of the fastening platform 417, and its power output end extends to the inside of the fastening platform 417 and is fixedly connected to the fastening gear 419; the lower clamping plate 412 is located below the upper clamping plate 411, and one end of the upper clamping plate 411 is installed with a plurality of connecting plates 413 adapted to the electric telescopic rod 414, and the connecting plates 413 are fixedly connected to the electric telescopic rod 414; the top of the lower clamping plate 412 is provided with an empty slot 422 adapted to the screwdriver 416. In this way, driven by the electric telescopic rod 414, the upper clamping plate 411 and the lower clamping plate 412 connected to the electric telescopic rod 414 through the connecting plates 413 can move synchronously in opposite directions or in reverse directions. When the upper clamping plate 411 and the lower clamping plate 412 move toward each other, the tightening wheel 415 and the screwdriver bit 416 connected thereto rotate synchronously with the cooperation of the tightening motor 418, the tightening gear 419 and the steel chain 421 until they stop when they move to a specific position between the upper clamping plate 411 and the lower clamping plate 412. In addition, a screw is embedded in the screwdriver bit 416, and a nut adapted to the screw is embedded in the empty groove 422. With the opposite movement of the upper clamping plate 411 and the lower clamping plate 412 and the rotation of the screwdriver bit 416, the screw can connect with the nut by itself and complete the tightening.

Optionally, the screwdriver bit 416 and the empty slot 422 are both detachable structures. In this way, screwdriver bits 416 of different specifications and the corresponding empty slots 422 can be selected according to actual work needs, so as to adapt and connect the screw rod and the nut, which effectively improves the applicability of the device.

Optionally, a magnet is fixed in the screwdriver bit 416. In this way, the screw can be fixed in the screwdriver bit 416 by the magnet, so that it is not easy to fall off during the movement of the device. In addition, the screw is fixed in the screwdriver bit 416 by the magnet, so that after the screw is tightened, it will automatically separate from the screwdriver bit 416 during the separation process of the upper clamping plate 411 and the lower clamping plate 412, and no other operation is required.

Optionally, a magnet is fixed in the empty slot 422. In this way, it has the same function as the magnet fixed in the screwdriver bit 416, and is used to fix the nut, and no further description is given.

As shown in Fig. 18 and Fig. 19, the side wall of the driving device 500 is provided with a rectangular through slot 501 adapted to the rack 102 and a circular through slot 502 adapted to the slide bar 104; a sliding motor 510 is installed on one side of the driving device 500, and a sliding gear 511 adapted to the rack 102 is installed on the power output end of the sliding motor 510; driving gears 505 are installed on the power output ends of both ends of the driving device 500. In this way, through the cooperation of the rectangular through slot 501 and the circular through slot 502, the driving device 500 can make a straight line reciprocating motion along the rack 102 and the slide bar 104, effectively avoiding the occurrence of deviation or separation of the driving device 500 during the sliding process, and ensuring the stability of the operation of the driving device 500. At the same time, the driving device 500 can run to a predetermined position under the cooperation of the sliding motor 510 and the sliding gear 511, so as to achieve the purpose of driving the climbing device 200, the pushing device 300 and the self-fixing device 400 to run respectively.

Optionally, an extension plate 503 connected to the driving device 500 is fixed between the rectangular through slot 501 and one of the circular through slots 502. In this way, the sliding motor 510 can be fixed on the extension plate 503, so that the sliding motor 510 can move synchronously with the driving device 500.

Optionally, a hinge plate 504 is further provided on the side wall of the driving device 500, which is in the same straight line as the power output end of the sliding motor 510 and the sliding gear 511, and the end of the sliding gear 511 away from the sliding motor 510 is rotatably connected to the hinge plate 504. In this way, the hinge plate 504 is provided to limit the sliding gear 511, thereby preventing the sliding gear 511 from jumping due to excessive torque when meshing with the rack 102. This allows the sliding gear 511 to maintain a tight meshing connection with the rack 102, thereby ensuring the stability of the operation of the sliding gear 511.

As shown in Figure 20, it also includes a standard section 600 and a climbing rail 700. The standard section 600 includes a first frame 601 and a second frame 602. The two have the same structure and are arranged opposite to each other and spliced into a whole. At the same time, both are composed of a support column 610, a first flange 611, a crossbeam 620, a diagonal brace 621, and a second flange 622. The first frame 601 and the second frame 602 each include two parallel support columns 610, and the support columns 610 are connected with a crossbeam 620 and a diagonal brace 621; both ends of the support column 610 are fixed with a first flange 611; the ends of the crossbeam 620 and the diagonal brace 621 of the first frame 601 and the second frame 602 that are arranged opposite to each other are fixed with a second flange 622; the climbing rail is fixed on one side of each support column 610. In this way, after the first frame 601 and the second frame 602 are butted against each other, the second flanges 622 provided on the cross beams 620 and diagonal braces 621 of the two frames are fixed, so that the first frame 601 and the second frame 602 form a complete standard section 600. At the same time, multiple standard sections 600 are stacked and connected in sequence from top to bottom, and the first flanges 611 provided thereon are butted against each other and aligned, and fixed by a fastening device.

Optionally, when two standard sections 600 are superimposed and connected, their first flanges 611 abut against each other and are aligned. The driving device 500 moves to a specified position, meshes with the rack of the self-tightening device, and drives the fastening assembly 410 to move toward the flange. When the fastening assembly 410 moves to a specified position, the screws and nuts are distributed perpendicular to the threaded holes on the flange. Driven by the fastening device, each screw aligned with the threaded hole is rotated and sequentially passed through the superimposed first flange 611 and fastened to the nut. Thereby achieving the purpose of completing the fastening of multiple screws at the same time, effectively improving the working efficiency of the connection and fixation of the standard section 600.

Optionally, a positioning notch is provided at the edge of the first flange 611. In this way, the positioning connection of the climbing rail 700 is facilitated, so that the climbing rail 700 can always be in a straight line after installation, and the lifting platform 100 is convenient to move up or down along the climbing rail 700.

Exemplarily, the outer sides of the first frame 601 and the second frame 602 are both installed with a lifting platform 100, and are used to transport the first frame 601 or the second frame 602 respectively. When the first frame 601 or the second frame 602 is transported, the first frame 601 or the second frame 602 is placed on the surface of the lifting platform 100, and the bottom crossbeam 620 of the first frame 601 or the second frame 602 is connected with the claw 332 to ensure that the first frame 601 or the second frame 602 remains stable during the lifting process, so that it is not easy to fall off. When the lifting platform 100 is driven by the climbing device 200 to run to the top of the first flange 611, it stops automatically. At this time, the climbing device 200 is locked by itself, and the driving device 500 moves to the preset position to engage with the pushing device 300, and drives the winch wheel 314 to rotate, so that the claw 332 pushes the first frame 601 and the second frame 602 to move in a counter manner until the second flanges 622 of the two are abutted and fixed to each other. At this time, the two vertically stacked first flanges 611 are aligned with each other, the driving device 500 is separated from the driving device 500, moved to a predetermined position to engage with the self-fixing device 400, and drives the upper clamping plate 411 and the lower clamping plate 412 of the fastening device to move above and below the two overlapping first flanges 611, so that the fastening device can fasten the two flanges by itself. Then, the driving device 500 is separated from the self-fixing device, and moves toward the climbing device 200, and engages with the climbing device 200, driving the climbing device 200 to move downward along the climbing rail 700 until it lands on the ground, and performs loading work on the first frame 601, the second frame 602, the screw, and the nut.

On the contrary, if the first frame 601 and the second frame 602 need to be disassembled, the connection seat 330 equipped with the claw 332 needs to be removed and installed in reverse. After the preliminary work is completed, the driving device 500 drives the climbing device 200 to move the lifting platform 100 to the specified position, and the driving device 500 drives the claw 332 of the pushing device 300 to move toward the first frame 601 or the second frame 602. When the claw 332 abuts against the first frame 601 and the second frame 602, the claw 332 folds itself under the action of the extrusion force. When the claw 332 moves to the other side of the first frame 601 or the second frame 602, the claw 332 recovers itself and abuts against the crossbeam 620 of the first frame 601 or the second frame 602. Then, the driving device 500 engages with the self-tightening device, so that the upper clamping plate 411 and the lower clamping plate 412 of the fastening assembly 410 are connected to the screw and the nut respectively, and rotate in the opposite direction to separate the screw and the nut. After removing the screws and nuts on the first flange 611 and the second flange 622, the driving device 500 returns to the engagement position of the pushing device 300 again, and pulls the first frame 601 or the second frame 602 to the surface of the lifting platform 100. Finally, the driving device 500 drives the lifting platform 100 to fall back to the ground position, thereby completing the disassembly of one standard section 600.

As shown in FIG21 , the climbing rail 700 is adapted to be connected with the climbing groove 211, and a climbing tooth 710 adapted to the climbing gear 223 is provided on the side of the climbing rail 700 facing away from the support column 610; a fixing ring 720 and an embedding ring 730 arranged equidistantly are fixed on the side of the climbing rail 700 facing the support column 610, wherein one side of the embedding ring 730 abuts against the first flange 611. In this way, the fixing ring 720 and the embedding ring 730 not only enhance the lateral connection force between the climbing rail 700 and the support column 610, but also enhance the longitudinal compressive strength between the climbing rail 700 and the support column 610, thereby ensuring that the lifting platform 100 can stably perform lifting and lowering motion under the drive of the climbing device 200, and effectively improving the stability of the device operation.

Optionally, an alignment protrusion adapted to the alignment notch is provided on the inner wall of the embedded ring 730 .

Finally, although this specification is described according to implementation methods, not every implementation method contains only one independent technical solution. This narrative method of the specification is only for the sake of clarity. Those skilled in the art should regard the specification as a whole. The technical solutions in each embodiment can also be appropriately combined to form other implementation methods that can be understood by those skilled in the art.

Claims (10)

1. The utility model provides a steel construction factory building equipment is with girder steel jacking equipment, includes lifting platform (100), climbing device (200), pusher (300), from fixing device (400), drive arrangement (500), its characterized in that: one side of the lifting platform (100) is provided with a plurality of slide ways (101) which are matched with part of the pushing device (300) in structure, and the other side of the lifting platform is provided with a toothed rail (102) and a plurality of slide bars (104) which are connected with the driving device (500) in an adaptive manner; the climbing device (200) is arranged on one side of the lifting platform (100) and is positioned on two sides of the sliding rod (104); the pushing device (300) is arranged adjacent to the climbing device (200) and comprises a traction component (310) and a claw component (320), wherein the claw component (320) is movably arranged in the slideway (101) and is movably connected with the traction component (310) at the other side of the lifting platform (100); the self-fixing device (400) is arranged on one side of the traction component (310) far away from the climbing device (200), is movably connected with the lifting platform (100), extends to the outer side of the lifting platform (100) in a part of structure, and is connected with the fastening component (410); the driving device (500) is connected with the toothed rail (102) and the sliding rod (104) in an adapting way, is movably arranged between the climbing device (200), the pushing device (300) and the self-fixing device (400), moves to a specific position in a sliding way, is meshed with the climbing device (200) or the pushing device (300) or the self-fixing device (400), and is meshed with the driving device.

2. The steel beam jacking equipment for steel structure factory building assembly according to claim 1, wherein: the climbing device (200) comprises a linkage box (210), a rotating shaft (220), a fixed buckle (221), a linkage gear (222), a climbing gear (223) and a bracket (230), wherein a plurality of linkage boxes (210) are arranged and are attached to the side wall of the lifting platform (100); the rotating shaft (220) is embedded at the top of the linkage box (210) in a rotating mode, one end of the rotating shaft is fixedly provided with a linkage gear (222), the other end of the rotating shaft is fixedly provided with a climbing gear (223), and the climbing gear (223) extends into the linkage box (210); one end of the rotating shaft (220) provided with the linkage gear (222) is rotatably connected with a bracket (230) fixed on the lifting platform (100).

3. The steel beam jacking equipment for steel structure factory building assembly according to claim 2, wherein: a climbing through groove (211) is formed in the linkage box (210), and a plurality of groups of auxiliary wheels (212) are embedded on one side of the climbing through groove (211); meanwhile, a groove (213) matched with the climbing gear (223) is formed in the side wall opposite to the climbing through groove (211), and the climbing through groove (211) is communicated with the groove (213).

4. The steel beam jacking equipment for steel structure factory building assembly according to claim 1, wherein: the traction assembly (310) is arranged on one side of the climbing device (200) and comprises a frame (311), a shaft lever (312), a driven gear (313), a stranded wire wheel (314), a first guide wheel (315), a second guide wheel (316) and a cable (317), wherein the stranded wire wheel (314) is fixed at two ends of the shaft lever (312), and the driven gear (313) matched with the driving device (500) is further arranged on the shaft lever (312) and is adjacent to the stranded wire wheel (314); the shaft lever (312) is rotationally connected with a frame (311) fixed on one side of the lifting platform (100); the first guide wheels (315) are provided with a plurality of groups and are respectively arranged at two sides of the frame (311); the second guide wheels (316) are fixed at two ends of the lifting platform (100) and are positioned below the end parts of the slide ways (101); wherein the wire twisting wheel (314), the first guide wheel (315) and the second guide wheel (316) are on the same straight line; the mooring ropes (317) are provided with a plurality of mooring ropes, one ends of the mooring ropes are fixed with the wire twisting wheels (314), and the other ends of the mooring ropes are fixed with the claw assemblies (320).

5. The steel beam jacking equipment for steel structure factory building assembly according to claim 1, wherein: the clamping jaw assembly (320) comprises a sliding block (321), a connecting seat (330) and clamping jaws (332), wherein sliding grooves (322) matched with the sliding ways (101) are formed in two sides of the sliding block (321); a groove (323) is formed above the sliding block (321); the connecting seat (330) is detachably fixed at the top of the sliding block (321), and part of the connecting seat is embedded into the groove (323); the clamping jaw (332) is hinged to the top of the connecting seat (330) and rotates towards one side; wherein, the connecting seat (330) can be reversely connected with the sliding block (321).

6. The steel beam jacking equipment for steel structure factory building assembly according to claim 1, wherein: the self-fixing device (400) comprises an expansion joint (401), an inner connecting rod (402), a toothed plate (403) and an outer connecting rod (404), wherein the expansion joint (401) is movably connected with the side wall of the lifting platform (100) in a symmetrical mode, and one end positioned in the lifting platform (100) is connected with the inner connecting rod (402); the toothed plate (403) is fixed on one side of the inner connecting rod (402) and meshed with the driving device (500); the outer connecting rod (404) is sleeved and fixed at the other end of the telescopic joint (401), and the other end of the outer connecting rod (404) is connected with a fastening assembly (410).

7. The steel beam jacking equipment for steel structure factory building assembly according to claim 1, wherein: the fastening assembly (410) comprises an upper clamping plate (411), a lower clamping plate (412), a connecting plate (413), electric telescopic rods (414), fastening wheels (415), a screwdriver head (416), a fastening bearing platform (417), a fastening motor (418), fastening gears (419), guide posts (420) and steel chains (421), wherein at least two electric telescopic rods (414) are arranged and are embedded into the outer connecting rods (404); one end of the upper clamping plate (411) is provided with a plurality of connecting plates (413) which are matched with the electric telescopic rods (414), and the connecting plates (413) are fixedly connected with the electric telescopic rods (414); a plurality of fastening wheels (415) and guide posts (420) are distributed on the top of the upper clamping plate (411), wherein one end of each fastening wheel (415) extends to the bottom of the upper clamping plate (411) and is provided with a screwdriver head (416); the fastening bearing platform (417) is fixed on one side of the top of the upper clamping plate (411), and a fastening gear (419) is embedded in the fastening bearing platform; the fastening motor (418) is arranged at the top of the fastening bearing platform (417), and the power output end of the fastening motor extends into the fastening bearing platform (417) and is fixedly connected with the fastening gear (419); the lower clamping plate (412) is positioned below the upper clamping plate (411), one end of the upper clamping plate (411) is provided with a plurality of connecting plates (413) which are matched with the electric telescopic rods (414), and the connecting plates (413) are fixedly connected with the electric telescopic rods (414); the top of the lower clamping plate (412) is provided with a hollow groove (422) which is matched with the batch head (416).

8. The steel beam jacking equipment for steel structure factory building assembly according to claim 1, wherein: a rectangular through groove (501) matched with the toothed rail (102) and a circular through groove (502) matched with the sliding rod (104) are formed in the side wall of the driving device (500); a sliding motor (510) is arranged on one side of the driving device (500), and a sliding gear (511) which is connected with the toothed rail (102) in an adapting way is arranged on the power output end of the sliding motor (510); and the power output ends at two ends of the driving device (500) are respectively provided with a driving gear (505).

9. The steel beam jacking equipment for steel structure factory building assembly according to any one of claims 1 to 8, wherein: the climbing rail comprises a climbing rail body, and is characterized by further comprising a standard section (600) and a climbing rail (700), wherein the standard section (600) comprises a first framework (601) and a second framework (602), and the standard section and the second framework are identical in structure, are oppositely arranged and are spliced into a whole; simultaneously, both are composed of support columns (610), a first flange plate (611), a cross beam (620), inclined struts (621) and a second flange plate (622), wherein the first framework (601) and the second framework (602) comprise two support columns (610) which are arranged in parallel, and the cross beam (620) and the inclined struts (621) are connected between the support columns (610); a first flange plate (611) is fixed at both ends of the supporting column (610); the ends of a cross beam (620) and a diagonal brace (621) which are arranged opposite to the first framework (601) and the second framework (602) are respectively fixed with a second flange plate (622); the climbing is fixed on one side of each support column (610).

10. The steel beam jacking equipment for steel structure factory building assembly of claim 9, wherein: the climbing rail (700) is connected with the climbing through groove (211) in an adaptive manner, and a climbing tooth (710) which is matched with the climbing gear (223) is arranged on one side of the climbing rail (700) back to the supporting column (610); and a fixed ring (720) and an embedded ring (730) which are equidistantly arranged are fixed on one side of the climbing rail (700) facing the supporting column (610), wherein one side of the embedded ring (730) is abutted against the first flange plate (611).