CN218708400U - Construction elevator guide rail frame self-installation advanced device for engineering construction - Google Patents

Abstract

The utility model relates to a construction elevator technical field specifically is an engineering construction is with construction elevator guide rail frame is from installing advanced device, including installing the mount on construction elevator is connected with the wall of guide rail frame, the mount is provided with the F spout that perpendicular construction elevator wall runs through and is "F" type, be provided with the elevating system that drives guide rail frame lift in the F spout, be provided with the centre gripping lead screw chamber in the elevating system, centre gripping lead screw intracavity is provided with the fixture who is used for centre gripping guide rail frame, be provided with the manipulator chamber in the elevating system, be provided with the bolt mechanism who is used for driving the bolt to reach the connecting hole top in the manipulator chamber, be provided with in the elevating system and tighten the gear chamber, can realize self-service lifting guide rail frame to install on having had the guide rail frame.

Description

Construction elevator guide rail frame self-installation advanced device for engineering construction

Technical Field

The utility model relates to a construction elevator technical field specifically is an engineering construction is with construction elevator guide rail frame is from installing advanced device.

Background

The modern concrete changes the traditional construction mode, and under the application of high-performance concrete and steel, projects such as high (super high) floors, large-span bridges and the like with various forms are built, such as Guangxi Nanning Huarunong center office building, guangxi finance plaza, guangdong Guangzhou center, guangdong Shenzhen deep industry Shangcheng, shandong chatting Xinghua Lianzhi river bridge, guangxi Pinnan triple bridge, guangxi Tian Long super bridge and the like. The vertical transportation of materials and personnel in the process of constructing engineering such as super high-rise buildings, large-span bridges and the like requires the use of a special elevator for construction sites, namely a construction elevator. The construction elevator is a high-efficiency vertical construction machine capable of conveying building materials and personnel in a layered mode, is suitable for construction of projects such as high-rise buildings, bridges, television towers, chimneys, power stations and the like, and has the characteristics of stable performance, safety, reliability, no need of additionally arranging machine rooms and well ways, convenience in disassembly and assembly, flexibility in carrying, large lifting height, strong carrying capacity and the like, so that the construction elevator is an ideal vertical transport machine in construction buildings. When the construction elevator runs, the suspension cage is moved on the guide rail frame through the gear rack, so that the free lifting of the suspension cage is guaranteed, the reaching height of the construction elevator can be easily improved, and only the guide rail frame needs to be increased.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to the problem that prior art exists, provided an engineering construction is with construction elevator guide rail frame from installing advanced device, can realize promoting the guide rail frame by oneself to install on having the guide rail frame.

The utility model provides a technical scheme that its technical problem adopted is: the utility model provides an engineering construction is with construction elevator guide rail frame is from installing advanced device, is including installing the mount on the wall that construction elevator is connected with the guide rail frame, the mount is provided with the F spout that perpendicular construction elevator wall runs through and is "F" type, be provided with the elevating system who drives the guide rail frame and go up and down in the F spout, be provided with centre gripping lead screw chamber in the elevating system, centre gripping lead screw intracavity is provided with the fixture who is used for centre gripping guide rail frame, be provided with the manipulator chamber in the elevating system, the manipulator intracavity is provided with and is used for driving the bolt mechanism of bolt arrival connecting hole top, be provided with in the elevating system and screw up the gear chamber, it is used for driving the nut and reachs the connecting hole below and screws up the mechanism of screwing up on the bolt to screw up the gear intracavity.

As a preference, the first and second liquid crystal compositions are, the lifting mechanism comprises two cylindrical pins which are positioned in the F sliding groove and slide, a first-order lifting block which is fixed on the two cylindrical pins at the same time, a moving frame which is positioned on the fixed frame and is far away from the end of the first-order lifting block to move transversely, an inclined sliding groove which is positioned on the moving frame and is penetrated through the vertical construction lifter wall and is extended into by the cylindrical pins, an electric guide rail which is fixed on the upper lower wall of the moving frame and the fixed frame, a first-order sliding groove which is positioned on the wall of the first-order lifting block and is far away from the cylindrical pins, a first-order sliding block which is positioned on the first-order sliding groove to slide, a second-order lifting block which is fixed on the wall of the first-order lifting block and is far away from the first-order lifting block, a second-order sliding groove which is positioned on the wall of the second-order lifting block and is far away from the first-order lifting block, a third-order lifting block which is fixed on the wall of the second-order lifting block, a reversing cavity which is communicated with the top wall of the second-order sliding groove, a reversing cavity which is positioned on the top wall of the second-order lifting block, a reversing wheel which is fixed on the bottom wall of the first-order lifting block, and is positioned on the lifting wheel cavity, and a winding wheel cavity which is fixed on the outer surface of the lifting wheel and is parallel to the lifting wheel, and is fixed on the outer surface of the lifting wheel.

Preferably, the inclined chute is an inclined strip-shaped through groove, and is matched with an F-shaped chute, so that the first-order lifting block completes a 7-shaped path.

Preferably, the first-order slider and the second-order slider are provided with protruding blocks protruding from side walls thereof and used for being clamped in the first-order sliding groove and the second-order sliding groove to prevent the second-order lifting block and the third-order lifting block from falling, the cylindrical pins are provided with protruding rings which are clamped in the F sliding groove to prevent the first-order lifting block from falling, and the two cylindrical pins are arranged up and down to prevent the first-order lifting block from rotating.

Preferably, the clamping mechanism comprises two clamping screw cavities, two clamping screws, two clamping nuts, two clamping cavities, two inner hidden cavities, two outer clamping cavities, two clamping hooks, two clamping gears and two clamping hooks, wherein the two clamping gears are located on the outer surface of each clamping shaft and can be meshed with the clamping racks, the clamping hooks are fixed on the outer surface of each clamping shaft.

Preferably, the clamping hooks on the front side and the rear side are designed according to the shape of the vertical rod of the guide rail bracket.

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Preferably, the bolt grabbing sleeve is downward in opening and provided with an electromagnet for adsorbing the bolt, a damping assembly is arranged in the damping channel, damage caused by too fast descending of the bolt is avoided, and the positioning block can prevent the manipulator from deflecting in the descending process.

Preferably, the tightening mechanism comprises tightening gear cavities which are positioned at the bottom wall of the second-order lifting block and are symmetrical front and back and far away from openings in the two directions of the center line and the construction lifter, tightening manipulator cavities which are positioned in the vertical direction wall of the manipulator cavities and are far away from openings in the two directions of the center line and the construction lifter, tightening rack cavities communicated with the wall of the tightening manipulator cavities close to the center line, tightening racks which are positioned in the tightening rack cavities and slide, tightening electromagnets which are fixed between the two tightening rack cavities and extend into the tightening rack cavities, tightening compression springs fixed between the tightening racks and the tightening rack cavities,

Preferably, the tightening mechanism comprises a tightening shaft penetrating through the tightening mechanism cavity and the tightening gear cavity, a tightening gear fixed on the outer surface of the tightening mechanism cavity part and meshed with the tightening rack, a tightening mechanism fixed on the outer surface of the tightening mechanism cavity part, a nut cavity far away from the tightening mechanism end and aligned with the guide rail bracket connecting hole when the tightening shaft is closed, a double-shaft motor fixed between the two nut cavities and an output shaft extending into the nut cavity, a worm fixed at the tail end of the output shaft of the double-shaft motor and penetrating through the nut cavity, and a nut sleeve located in the nut cavity and rotating and connected with the worm and worm gear.

The utility model has the advantages that 1, through the upper buckle and the lower buckle, the clamping of the guide rail frame is realized, meanwhile, the guide rail frame is lifted along with the construction lifter, and finally, the guide rail frame is higher than the construction lifter through the sliding of the sliding plate on the construction lifter, thereby solving the problem of shaking in the lifting process of the guide rail frame; 2. utilize the electromagnetism to adsorb the bolt and promote along with the guide rail frame to after the guide rail frame is placed successfully, directly carry out the screw rod to the guide rail frame and screw up, reduce constructor and lean out the possibility of upper part of the body, avoid constructor to appear dangerously.

Drawings

FIG. 1 is a schematic structural view of the self-mounting advanced device of the construction elevator guide rail frame for engineering construction of the present invention;

FIG. 2 isbase:Sub>A schematic view of the structure A-A in FIG. 1;

FIG. 3 is a schematic view of B-B in FIG. 1;

FIG. 4 is a schematic view of the structure of C-C in FIG. 1;

FIG. 5 is a schematic view of D-D of FIG. 1;

FIG. 6 is an enlarged view of E in FIG. 1;

FIG. 7 is an enlarged view of F in FIG. 3;

FIG. 8 is an enlarged view of G in FIG. 6;

FIG. 9 is an enlarged view of H in FIG. 6;

FIG. 10 is an isometric view of a stationary gantry and a mobile gantry;

FIG. 11 is an isometric view of the nut sleeve;

wherein, 1, a lifting mechanism, 2, a clamping mechanism, 3, a bolt mechanism, 4, a tightening mechanism, 101, a fixed frame, 102, an F sliding groove, 103, a cylindrical pin, 104, a moving frame, 105, an inclined sliding groove, 106, an electric guide rail, 107, a first-order lifting block, 108, a first-order sliding groove, 109, a first-order sliding block, 110, a second-order lifting block, 111, a lifting motor, 112, a wire wheel cavity, 113, a wire wheel, 114, a driving wire, 115, a driven wire, 116, a reversing cavity, 117, a reversing wheel, 118, a second-order sliding groove, 119, a second-order sliding block, 120, a third-order lifting block, 201, a built-in cavity, 202, a clamping hook, 203, a clamping shaft, 204, a clamping gear, 205, a clamping rack, 206, a clamping motor, 207 and a clamping nut, 208, a clamping screw 209, a clamping screw cavity 210, a clamping cavity 301, a rack cavity 302, an electromagnet 303, a pressure spring 304, a rack 305, a gear cavity 306, a gear 307, a shaft 308, a manipulator 309, a positioning block 310, a damping channel 311, a manipulator cavity 312, a feeding electromagnet 313, a feeding pressure spring 314, a swivel 315, a bolt grasping sleeve 401, a tightening manipulator cavity 402, a tightening manipulator 403, a nut sleeve 404, a worm 405, a double-shaft motor 406, a nut cavity 407, a tightening gear cavity 408, a tightening gear 409, a tightening shaft 410, a tightening electromagnet 411, a tightening rack cavity 412, a tightening pressure spring 413, a tightening rack.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

As shown in fig. 1-11, an advanced self-installation device for a construction elevator guide rail frame for engineering construction comprises a fixed frame 101 installed on a wall of a construction elevator connected with the guide rail frame, wherein the fixed frame 101 is provided with an F-shaped sliding chute 102 penetrating through the wall of the construction elevator and in an "F" shape, a lifting mechanism 1 driving the guide rail frame to ascend and descend is arranged in the F-shaped sliding chute 102, a clamping lead screw cavity 209 is arranged in the lifting mechanism 1, a clamping mechanism 2 for clamping the guide rail frame is arranged in the clamping lead screw cavity 209, a manipulator cavity 311 is arranged in the lifting mechanism 1, a bolt mechanism 3 for driving a bolt to reach above a connecting hole is arranged in the manipulator cavity 311, a tightening gear cavity 407 is arranged in the lifting mechanism 1, and a tightening mechanism 4 for driving a nut to reach below the connecting hole and to be tightened on the bolt is arranged in the tightening gear cavity 407; 2 centre gripping guide rail frame lower extremes of fixture, construction elevator rise to the top, afterwards elevating system 1 drives fixture 2 bolt mechanism 3 screw up mechanism 4 and guide rail frame to construction elevator top, existing guide rail frame top, afterwards elevating system 1 descends one section distance, causes the guide rail frame to place in existing guide rail frame top, afterwards bolt mechanism 3 with screw up mechanism 4 and rotate and fold, the bolt stretches into in the guide rail frame connecting hole and butt on screw up 4 internal nut of mechanism, afterwards, screw up mechanism 4 and drive the nut and rotate, fixes the guide rail frame, afterwards bolt mechanism 3 with screw up mechanism 4 and reset, elevating system 1 resets, and construction elevator descends, accomplishes guide rail frame installation once.

The lifting mechanism 1 comprises two cylindrical pins 103 which are positioned in the F sliding groove 102 to slide, a first-order lifting block 107 which is simultaneously fixed on the two cylindrical pins 103, a moving frame 104 which is positioned at the end, far away from the first-order lifting block 107, of the fixed frame 101 to move transversely, an inclined sliding groove 105 which is positioned on the moving frame 104 and is penetrated by the wall of the vertical construction lifter and is inserted by the cylindrical pins 103, an electric guide rail 106 which is fixed on the upper wall and the lower wall of the moving frame 104 and the fixed frame 101, a first-order sliding groove 108 which is positioned on the wall, far away from the cylindrical pins 103, of the first-order lifting block 107, a first-order sliding block 109 which is positioned in the first-order sliding groove 108, a second-order lifting block 110 which is fixed on the wall, far away from the first-order lifting block 107, of the second-order sliding groove 118 which is positioned on the wall, far away from the first-order lifting block 107, of the second-order lifting block 110 and is opened far away from the first-order lifting block 107, a second-order slide block 119 positioned in the second-order slide groove 118 to slide, a third-order lifting block 120 fixed on the wall of the second-order slide block 119 far away from the second-order lifting block 110, a reversing cavity 116 communicated with the top wall of the second-order slide groove 118, a reversing wheel 117 positioned in the reversing cavity 116 to rotate, a driven pull wire 115 with one end fixed on the second-order slide block 119 and the other end fixed on the bottom wall of the first-order lifting block 107 after bypassing the reversing wheel 117, a wire wheel cavity 112 communicated with the top wall of the first-order slide groove 108, a lifting motor 111 positioned in the wall of the wire wheel cavity 112 and with an output shaft horizontally parallel to the construction lifter wall direction and penetrating through the wire wheel cavity 112, a wire wheel 113 fixed on the outer surface of the lifting motor 111, and a driving pull wire 114 wound and fixed on the outer surface of the wire wheel 113 and the other end fixed on the first-order slide block 109; when the construction elevator ascends to the top end, the electric guide rail 106 drives the movable frame 104 to move, the first-order lifting block 107 finishes '7' type movement under the action of the movable frame 104 and the F chute 102, when the first-order lifting block 107 ascends to the top end of the F chute 102 to be traversed, the lifting motor 111 rotates to drive the wire wheel 113 to rotate and wind the driving pull wire 114, so that the first-order slider 109 moves upwards, the second-order lifting block 110 moves upwards, the distance between the reversing wheel 117 and the bottom wall of the first-order lifting block 107 is increased, the second-order slider 119 is further driven to move upwards, the second-order slider 119 drives the third-order lifting block 120 to move upwards, the clamping mechanism 2, the bolt mechanism 3, the screwing mechanism 4 and the guide rail frame are further driven to move upwards, and then the first-order lifting block 107 continues to move, the guide rail frame is positioned above the existing guide rail frame, then the lifting motor 111 rotates reversely to drive the wire wheel 113 to rotate reversely to release the active stay wire 114, further to drive the first-order slide block 109 to move downwards, the second-order lifting block 110 moves downwards, the distance between the bottom wall of the second-order lifting block 110 and the reversing wheel 117 becomes shorter, the second-order slide block 119 and the third-order lifting block 120 descend under the self-weight, the guide rail frame is placed on the existing guide rail frame, after the bolt mechanism 3 and the tightening mechanism 4 are fixed, the clamping mechanism 2 is released, the lifting motor 111 rotates to drive the wire wheel 113 to rotate to wind the active stay wire 114, so that the first-order slide block 109 moves upwards, thereby driving the second-order lifting block 110 to move upwards, further causing the distance between the reversing wheel 117 and the bottom wall of the first-order lifting block 107 to become longer, further to drive the second-order slide block 119 to move upwards, the second-order slide block 119 drives the third-order lifting block 120 to move upwards, so as to drive the clamping mechanism 2, the bolt mechanism 3 and the tightening mechanism 4 to move upwards to the limit, the electric guide rail 106 drives the moving frame 104 to move reversely, the inclined chute 105 is matched with the F chute 102 to cause the first-order lifting block 107 to finish transverse movement, then the lifting motor 111 rotates reversely to drive the wire wheel 113 to rotate reversely to release the active wire 114, so as to drive the first-order slide block 109 to move downwards, the second-order lifting block 110 moves downwards, the distance between the bottom wall of the second-order lifting block 110 and the reversing wheel 117 becomes short, the second-order slide block 119 and the third-order lifting block 120 descend and reset under the self-weight, the electric guide rail 106 continues to drive the moving frame 104 to move reversely, and the inclined chute 105 is matched with the F chute 102 to cause the first-order lifting block 107 to finish descending, and then the construction elevator descends.

The inclined sliding groove 105 is an inclined long strip-shaped through groove and is matched with the F-shaped sliding groove 102, so that the first-order lifting block 107 completes a 7-shaped path.

The side walls of the first-order sliding block 109 and the second-order sliding block 119 are provided with protruding blocks which are used for being clamped in the first-order sliding groove 108 and the second-order sliding groove 118 and preventing the second-order lifting block 110 and the third-order lifting block 120 from falling, the cylindrical pins 103 are provided with protruding circular rings which are clamped in the F sliding groove 102 and used for preventing the first-order lifting block 107 from falling, and the two cylindrical pins 103 are arranged up and down to prevent the first-order lifting block 107 from rotating.

The clamping mechanism 2 comprises two clamping lead screw cavities 209 which are symmetrically distributed on the upper wall and the lower wall of the three-order lifting block 120, a clamping motor 206 which is positioned in the wall of the clamping lead screw cavity 209 and an output shaft of which extends into the clamping lead screw cavity 209 in a direction far away from the construction hoist, a clamping lead screw 208 which is fixed at the tail end of the output shaft of the clamping motor 206 and penetrates through the clamping lead screw cavity 209, a clamping nut 207 which is in threaded connection with the outer surface of the clamping lead screw 208, two clamping cavities 210 which are positioned in the wall of the clamping lead screw cavity 209 in a manner of symmetrical front-back communication and are opened far away from the construction hoist, an internal hidden cavity 201 which is communicated between the clamping cavities 210, a clamping shaft 203 which is rotatably connected with the clamping nut 207 at the corresponding position of the clamping cavity 210 and extends into the clamping cavity 210, a clamping rack 205 which is fixed on the side wall of the clamping cavity 210, a clamping gear 204 which is fixed on the outer surface of the clamping shaft 203 and can be meshed with the clamping rack 205, and a clamping hook 202 which is fixed on the outer surface of the clamping shaft 203; when the guide rail frame is attached to the third-order lifting block 120, the clamping motor 206 rotates to drive the clamping screw 208 to rotate, the clamping screw 208 rotates to drive the clamping nut 207 to be close to the construction lifter, the clamping nut 207 drives the clamping shaft 203 to slide in the clamping cavity 210 to be close to the construction lifter, the clamping gear 204 rotates under the action of the clamping rack 205 to cause the clamping hook 202 to extend out of the inner hidden cavity 201 and buckle on the guide rail frame, then the clamping nut 207 continues to be close to the construction lifter to cause the clamping hook 202 to compress the guide rail frame on the third-order lifting block 120 to complete clamping, when the guide rail frame needs to be loosened, the clamping motor 206 reversely rotates to drive the clamping screw 208 to reversely rotate, the clamping screw 208 reversely rotates to drive the clamping nut 207 to be far away from the construction lifter, the clamping nut 207 drives the clamping shaft 203 to slide in the clamping cavity 210 to be far away from the construction lifter, the clamping gear 204 reversely rotates under the action of the clamping rack 205 to cause the clamping hook 203 to reversely rotate, so that the clamping hook 202 retracts in the inner hidden cavity 201, thereby avoiding the lifting block 1 and resetting mechanism 202.

The clamping hooks 202 on the front side and the rear side are designed according to the shape of the vertical rod of the guide rail bracket.

The bolt mechanism 3 comprises a manipulator cavity 311 which is positioned at the top wall of the three-step lifting block 120 and is symmetrical back and forth and is far away from openings in two directions of a central line and a construction lifter, a gear cavity 305 which is positioned in a vertical direction wall of the manipulator cavity 311 and is far away from openings in two directions of the central line and the construction lifter, a rack cavity 301 communicated with the gear cavity 305 and close to the central line wall, a rack 304 positioned in the rack cavity 301 to slide, an electromagnet 302 which is positioned between the two rack cavities 301 and extends into the rack cavity 301, a pressure spring 303 fixed between the rack 304 and the rack cavity 301, a shaft 307 penetrating through the gear cavity 305 and the manipulator cavity 311, a gear 306 fixed on the outer surface of the part of the gear cavity 305 and meshed with the rack 304 a mechanical hand 308 which is connected with the shaft 307 in a spline mode and is positioned on the outer surface of the part, located in the mechanical hand cavity 311, of the shaft 307, a bolt grabbing sleeve 315 which is fixed at the end, away from the shaft 307, of the mechanical hand 308 and is aligned with a guide rail frame connecting hole when the mechanical hand 308 is folded, a damping channel 310 which is communicated with the end, close to a construction hoist, of the mechanical hand cavity 311, a positioning block 309 which is fixed at the end, close to the shaft 307, of the mechanical hand 308, a rotary ring 314 which is connected with the wall of the mechanical hand 308 in a rotating mode, a feeding compression spring 313 which is fixed between the rotary ring 314 and the mechanical hand cavity 311, and a feeding electromagnet 312 which is fixed on the wall, where the feeding compression spring 313 is fixed, of the mechanical hand cavity 311; the bolt is placed in the bolt grabbing sleeve 315, the guide rail frame is placed on an existing guide rail frame, the electromagnet 302 loses electromagnetism to release the rack 304, the pressure spring 303 rebounds to drive the rack 304 to move, the rack 304 drives the gear 306 to rotate, the gear 306 drives the shaft 307 to rotate, the shaft 307 drives the manipulator 308 to rotate, the bolt grabbing sleeve 315 is driven to reach the position above a connecting hole of the guide rail frame, the positioning block 309 is aligned with the damping channel 310, when the tightening mechanism 4 is in place, the feeding electromagnet 312 loses electromagnetism to release the rotating ring 314, the feeding pressure spring 313 rebounds to drive the rotating ring 314 to move downwards, the rotating ring 314 drives the manipulator 308 to move downwards, the manipulator 308 drives the bolt grabbing sleeve 315 to move downwards, the bolt grabbing sleeve 315 drives the bolt to move downwards, the bolt grabbing sleeve 315 fixes the guide rail frame under the action of the tightening mechanism 4, after fixing is completed, the bolt grabbing sleeve 315 releases the bolt, the feeding electromagnet 312 moves upwards to adsorb the rotating ring 314, the feeding pressure spring 313 is pressed, the rotating ring 314 moves upwards, the bolt 308 drives the bolt 308 to drive the rack 307, the gear 307, the manipulator 304 to move upwards, and the pressure spring 306 is adsorbed by the resetting electromagnet 306, the pressure spring 306, the manipulator 304 and the pressure spring 306.

The bolt grabbing sleeve 315 is downward opened and provided with an electromagnet for adsorbing a bolt, a damping component is arranged in the damping channel 310 to prevent the bolt from being damaged due to too fast descending, and the positioning block 309 can prevent the manipulator 308 from deflecting in the descending process.

Tightening mechanism 4 is including being located second order elevator block 110 diapire department front and back symmetry just keeps away from the central line and two direction openings of construction elevator tightening gear chamber 407, being located in the vertical direction wall of manipulator chamber 311 and keeping away from central line and two direction openings of construction elevator tightening manipulator chamber 401, the intercommunication is in tightening rack chamber 411 on the wall that tightening manipulator chamber 401 is close to the central line, being located tightening rack 413 that slides in tightening rack chamber 411, fixed two tightening electromagnet 410 between the tightening rack chamber 411 and stretching into in tightening rack chamber 411, fix tightening rack 413 with tightening pressure spring 412 between the tightening rack chamber 411.

A tightening shaft 409 penetrating through the tightening hand cavity 401 and the tightening gear cavity 407, a tightening gear 408 fixed to the tightening shaft 409 on a part of the outer surface of the tightening hand cavity 401 and engaged with the tightening rack 413, a tightening hand 402 fixed to the tightening shaft 409 on a part of the outer surface of the tightening hand cavity 401, a nut cavity 406 aligned with the rail bracket coupling hole when the tightening shaft 409 is closed at the end of the tightening hand 402 away from the tightening shaft 409, a two-axis motor 405 fixed between the two nut cavities 406 with an output shaft extending into the nut cavity 406, a worm 404 fixed to the end of the output shaft of the two-axis motor 405 and penetrating through the nut cavity 406, a nut sleeve 403 rotating in the nut cavity 406 and coupled with the worm 404 and the worm gear; when the bolt mechanism 3 is closed, the tightening electromagnet 410 electromagnetically releases the tightening rack 413, the tightening compression spring 412 rebounds to drive the tightening rack 413 to move, the tightening rack 413 drives the tightening gear 408 to rotate, the tightening gear 408 drives the tightening shaft 409 to rotate, the tightening shaft 409 rotates to drive the tightening manipulator 402 to rotate, the tightening manipulator 402 rotates to cause the nut sleeve 403 to be positioned right below the guide frame connecting hole and to abut against the guide frame, when the bolt mechanism 3 abuts a bolt against a nut in the nut sleeve 403, the double-shaft motor 405 rotates to drive the worm 404 to rotate, the worm 404 rotates to drive the nut sleeve to rotate, the nut sleeve 403 rotates to tighten the nut onto the bolt to complete the guide frame specification, at this time, the lifting mechanism 1 can be lowered by an end distance to cause the nut sleeve 403 to be separated from the nut, then the tightening electromagnet 410 adsorbs the tightening rack 413, the tightening compression spring 412 is compressed, the tightening rack 413 drives the tightening gear 408 to reversely rotate, the tightening gear 408 reversely rotates, the tightening shaft 408 to drive the tightening shaft 409 to drive the tightening manipulator 402 to reset.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and are not intended to limit the spirit and scope of the present invention. Without departing from the design concept of the present invention, various modifications and improvements made by the technical solution of the present invention by those skilled in the art should fall into the protection scope of the present invention, and the technical contents claimed by the present invention have been fully recorded in the claims.

Claims (10)

1. The utility model provides an engineering construction is with construction elevator guide rail frame is from installing advanced device which characterized in that: including installing mount (101) on construction elevator is connected with the wall of guide rail frame, mount (101) are provided with perpendicular construction elevator wall and run through and are F spout (102) of "F" type, be provided with elevating system (1) that drive guide rail frame lift in F spout (102), be provided with centre gripping lead screw chamber (209) in elevating system (1), be provided with fixture (2) that are used for centre gripping guide rail frame in centre gripping lead screw chamber (209), be provided with manipulator chamber (311) in elevating system (1), be provided with bolt mechanism (3) that are used for driving the bolt to reach the connecting hole top in manipulator chamber (311), be provided with in elevating system (1) and screw up gear chamber (407), it reaches connecting hole below and screws up screw up mechanism (4) on the bolt to be provided with in screw up gear chamber (407) and be used for driving the nut.

2. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 1, wherein: the lifting mechanism (1) comprises two cylindrical pins (103) which are positioned in the F sliding groove (102) to slide, a first-order lifting block (107) which is fixed on the two cylindrical pins (103) simultaneously, a moving frame (104) which is positioned at the end, far away from the first-order lifting block (107), of the fixed frame (101) and moves transversely, an inclined sliding groove (105) which is positioned on the moving frame (104) and penetrates through the wall of a construction lifter and is inserted by the cylindrical pins (103), an electric guide rail (106) which is fixed on the upper lower wall of the moving frame (104) and the fixed frame (101), a first-order sliding groove (108) which is positioned on the wall, far away from the cylindrical pins (103), of the first-order lifting block (107) and is opened far away from the cylindrical pins (103), a first-order sliding block (109) which is positioned in the first-order sliding groove (108), a second-order lifting block (110) which is fixed on the wall, far away from the first-order lifting block (107), a second-order lifting block (118) which is positioned on the wall, far away from the first-order lifting block (107), a second-order lifting block (118), and a second-order lifting block (118) which is positioned on the wall (118) and is positioned on the second-order lifting block (118), and is communicated with the top wall (116), and is positioned on the second-order lifting block (118), the wire wheel lifting mechanism comprises a reversing wheel (117) located in the reversing cavity (116) and rotating, a driven pull wire (115) with one end fixed on the second-order sliding block (119) and the other end bypassing the reversing wheel (117) and then fixed on the bottom wall of the first-order lifting block (107), a wire wheel cavity (112) communicated with the top wall of the first-order sliding groove (108), a lifting motor (111) located in the wire wheel cavity (112) and with an output shaft horizontally parallel to the construction lifter wall direction and penetrating through the wire wheel cavity (112), a wire wheel (113) fixed on the outer surface of the lifting motor (111), and a driving pull wire (114) wound and fixed on the outer surface of the wire wheel (113) and with the other end fixed on the first-order sliding block (109).

3. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 2, wherein: the inclined sliding groove (105) is an inclined long strip-shaped through groove and is matched with the F-shaped sliding groove (102), so that the first-order lifting block (107) completes a 7-shaped path.

4. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 3, wherein: the side walls of the first-order sliding block (109) and the second-order sliding block (119) are provided with protruding blocks which are used for being clamped in the first-order sliding groove (108) and the second-order sliding groove (118) to prevent the second-order lifting block (110) and the third-order lifting block (120) from falling, the cylindrical pin (103) is provided with a protruding circular ring which is clamped in the F sliding groove (102) to prevent the first-order lifting block (107) from falling, and the two cylindrical pins (103) are arranged up and down to prevent the first-order lifting block (107) from rotating.

5. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 2, wherein: the clamping mechanism (2) comprises two clamping screw cavities (209), two clamping nuts (207), two clamping cavities (210), two clamping racks (205) and clamping hooks (205), wherein the two clamping screw cavities (209) are symmetrically distributed on the upper wall and the lower wall of the three-order lifting block (120), the two clamping motors (206) are located in the clamping screw cavities (209) and the output shafts of the three-order lifting block extend into the clamping screw cavities (209) away from the direction of the construction lifter, the clamping screws (208) are fixed at the tail ends of the output shafts of the clamping motors (206) and penetrate through the clamping screw cavities (209), the clamping nuts (207) are in threaded connection on the outer surfaces of the clamping screws (208), the two clamping cavities (210) are located in the walls, far away from the center line, the clamping screws (209) are symmetrically communicated front and back, the openings of the two clamping cavities (210) are far away from the construction lifter, the clamping cavities (201) are communicated between the clamping cavities (210), the clamping nuts (207) are rotatably connected, the clamping nuts (207) are located at the corresponding positions of the clamping cavities (210) and extend into the clamping shafts (203) of the clamping cavities (210), the clamping racks (205) are fixed on the side walls of the clamping cavities (210), and the clamping hooks (202) are fixed on the outer surfaces of the clamping shafts (202).

6. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 5, wherein: the clamping hooks (202) on the front side and the rear side are designed according to the shape of the vertical rod of the guide rail bracket.

7. The construction elevator guide rail frame self-installing advanced device for engineering construction according to claim 2, characterized in that: the bolt mechanism (3) comprises a manipulator cavity (311) which is positioned at the top wall of the three-order lifting block (120) and is in front-back symmetry and is far away from openings in the middle line and the construction lifter in two directions, a gear cavity (305) which is positioned in the vertical direction wall of the manipulator cavity (311) and is far away from openings in the middle line and the construction lifter in two directions, a rack cavity (301) communicated with the gear cavity (305) and is close to the middle line wall, a rack (304) positioned in the rack cavity (301) to slide, an electromagnet (302) fixed between the two rack cavities (301) and extending into the rack cavity (301), a pressure spring (303) fixed between the rack (304) and the rack cavity (301), a shaft (307) penetrating through the gear cavity (305) and the manipulator cavity (311), a manipulator (308) fixed on the outer surface of the gear cavity (305) and meshed with the rack (304), a spline (306) connected with the shaft (307) and positioned on the outer surface of the manipulator cavity (311) and is close to the manipulator cavity (308), and a damping bolt (310) is connected with the manipulator cavity (308) and is close to the construction lifter and is communicated with the lifting frame (310), and the lifting block (311), and the lifting block (310) is positioned on the manipulator cavity (308), and is connected with the lifting block (310), the feeding mechanism comprises a positioning block (309) fixed on the end, close to the shaft (307), of the manipulator (308), a rotating ring (314) rotatably connected to the wall of the manipulator (308), a feeding compression spring (313) fixed between the rotating ring (314) and the manipulator cavity (311), and a feeding electromagnet (312) fixed on the wall, fixed with the feeding compression spring (313), of the manipulator cavity (311).

8. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 7, wherein: the bolt grabbing sleeve (315) is downward in opening and provided with electromagnetism and used for adsorbing bolts, a damping component is arranged in the damping channel (310), damage caused by too fast descending of the bolts is avoided, and the positioning block (309) can prevent the manipulator (308) from deflecting in the descending process.

9. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 2, wherein: screw up mechanism (4) including being located second order elevator block (110) diapire department front and back symmetry just keeps away from central line and construction elevator two direction open-ended screw up gear chamber (407), be located in the manipulator chamber (311) vertical direction wall and keep away from central line and construction elevator two direction open-ended screw up manipulator chamber (401), intercommunication are in screw up manipulator chamber (401) and be close to screw up rack chamber (411) on the wall of central line, be located screw up rack (413), fixed two sliding in screw up rack chamber (411) screw up between rack chamber (411) and stretch into screw up electro-magnet (410) in screwing up rack chamber (411), fix screw up rack (413) with screw up pressure spring (412) between rack chamber (411).

10. The construction elevator guide rail frame self-installation advanced device for engineering construction as claimed in claim 9, wherein: a tightening shaft (409) penetrating through the tightening manipulator cavity (401) and the tightening gear cavity (407), a tightening gear (408) fixed to the tightening shaft (409) on a part of the outer surface of the tightening manipulator cavity (401) and engaged with the tightening rack (413), a tightening robot (402) fixed to the tightening shaft (409) on a part of the outer surface of the tightening manipulator cavity (401), a nut cavity (406) aligned with the guide rail bracket connection hole when the tightening robot (402) is away from the tightening shaft (409) end and the tightening shaft (409) is closed, a double-shaft motor (405) fixed between the two nut cavities (406) and having an output shaft extending into the nut cavity (406), a worm (404) fixed to the end of the output shaft of the double-shaft motor (405) and penetrating through the nut cavity (406), and a worm wheel sleeve (403) rotating in the nut cavity (406) and connected with the worm (404).

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