CN115247486B - Safe operation platform for house construction - Google Patents

Abstract

The invention relates to the technical field of building construction work platforms, and discloses a safe work platform for building construction, which comprises a track and a supporting table slidingly connected with the track, wherein a supporting seat is arranged on the supporting table, a hydraulic cylinder is arranged on the supporting seat, a connecting cylinder is further connected on the supporting seat, a vacuum chuck for adsorbing building materials is arranged on the connecting cylinder, the hydraulic cylinder is used for driving the vacuum chuck to move, an adjusting part is further arranged in the supporting seat, the adjusting part is used for adjusting the position of the connecting cylinder, the adjusting part comprises a shaft rod rotatably connected on the supporting seat, and a disc is arranged on the shaft rod. According to the invention, the connecting cylinder and the vacuum chuck are pushed to shake through the short column, so that the vacuum chuck can quickly drive the connecting plate to be buckled on the connecting groove, further, a worker can quickly install the building material, the possibility of manual high-altitude operation is reduced, and the safety of the worker operation is greatly improved.

Description

Safe operation platform for house construction

Technical Field

The invention relates to the technical field of building operation platforms, in particular to a safe operation platform for building construction.

Background

With the rapid development of social economy, the development of global buildings and the pulling up of high-rise buildings, the maintenance and cleaning of indoor buildings and other works become difficult, the application of an aerial work platform is more necessary, the aerial work platform is special equipment for the aerial work of people, the aerial work platform is mainly used for the aerial work in the fields of building, equipment maintenance, equipment installation, building cleaning and the like, the aerial work platform can also be called an aerial work vehicle, a lifting machine, a lifting platform and the like, the production efficiency is greatly improved by using the aerial work platform, and the safety of aerial work personnel is guaranteed most importantly.

However, when the building is constructed on the outer elevation, the workers need to carry building materials to stand on the supporting table, the workers are transported to the designated position through the upward sliding of the supporting table, then a part of workers move the building materials to be aligned and attached to the floor, and then other workers are fixed by mounting screws, or the building materials are driven to be aligned and attached to the floor by the traction machine, but the traction machine drives the building materials to descend by using ropes, so that the descending precision of the traction machine is insufficient, and further, the workers are required to move the building to adjust the building materials to be attached to the floor.

Disclosure of Invention

The invention provides a safe operation platform for building construction, which has the beneficial effect that workers cannot be quickly assisted in installing building materials, and solves the problem that the safety of workers is low due to the fact that the safe operation platform for building construction cannot be quickly assisted in installing the building materials.

The invention provides the following technical scheme: the safe operation platform for building construction comprises a track and a supporting table which is connected with the track in a sliding manner, wherein a supporting seat is arranged on the supporting table, a hydraulic cylinder is arranged on the supporting seat, a connecting cylinder is further connected to the supporting seat, a vacuum chuck for adsorbing building materials is arranged on the connecting cylinder, and the hydraulic cylinder is used for driving the vacuum chuck to move;

still install adjusting part in the supporting seat, adjusting part is used for adjusting the position of connecting cylinder, adjusting part is including rotating the axostylus axostyle of connecting on the supporting seat, install the disc on the axostylus axostyle, adjusting part is including the short column, the axle center of disc is kept away from to the axle center of short column, be connected with the second connecting rod on the short column, the second connecting rod is used for adjusting the position of connecting cylinder.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the adjusting part comprises an adjusting groove arranged on a disc, a second telescopic rod is further arranged on the disc, an L-shaped plate is further arranged on the second telescopic rod, the L-shaped plate is slidably connected in the adjusting groove, and the short column is connected to one side of the L-shaped plate;

the outer surface sliding connection of axostylus axostyle has the pushing component, install the cone piece on the pushing component, the cone piece is used for contradicting L shaped plate slip.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the pushing component comprises an internal thread sleeve which is rotationally connected inside the rotating device, a threaded rod is connected with the internal thread of the internal thread sleeve, the threaded rod is connected with the conical block, and the threaded rod is used for pushing the conical block to slide.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the rotary device is also provided with a transmission part, the transmission part is used for driving the internal thread sleeve to rotate, the transmission part comprises a transmission shaft rotationally connected to the hydraulic cylinder, one end of the transmission shaft is rotationally connected with a first screw rod, the first screw rod is provided with a storage sleeve, the storage sleeve is provided with a limiting device, and the limiting device is used for assisting the connecting cylinder to slide;

the limiting device comprises an adjusting disc arranged on the storage sleeve, an annular groove is formed in the adjusting disc, a T-shaped sliding block is connected in the annular groove in a sliding mode, a third telescopic column is arranged on the T-shaped sliding block, and the third telescopic column is connected with the connecting cylinder.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the first telescopic rod is arranged on the second connecting rod, and is connected to the outer surface of the connecting cylinder in a sliding manner;

the third telescopic column is T-shaped, T-shaped sliding block and the adaptation of third telescopic column, the inside of regulating disk still is provided with the square groove, the internally mounted in square groove has first spring, install the block on the first spring, still be provided with the bleeder vent that is used for ventilation air on the T-shaped sliding block, be provided with the inclined plane on the block.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the inside of the connecting cylinder is also provided with a rotating device which is used for driving the vacuum sucker to swing, the rotating device comprises a sliding rod which is connected inside the connecting cylinder in a sliding way, the adjusting plate is also provided with a taper hole, the sliding rod penetrates through one side of the connecting cylinder and is used for being connected inside the taper hole in a sliding way, the inside of the connecting cylinder is also provided with a third spring, and the third spring is connected with the sliding rod;

the inside rotation of connecting cylinder is connected with the second hob, the inside of second hob is provided with the second helicla flute, install the second stopper on the slide bar, second stopper sliding connection is in the inside of second helicla flute, still install square board on the second hob, square board is connected with vacuum chuck.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the second spring is arranged in the storage sleeve and connected with the first spiral rod, a first spiral groove is formed in the first spiral rod, a first limiting block is further connected in the storage sleeve, and the first limiting block is slidably connected in the first spiral groove;

square bars are installed on two sides of the transmission shaft, a welding frame is further installed on the rotating device, a rotating wheel is connected to the welding frame in a rotating mode, a belt is sleeved on the rotating wheel, a transmission rod is connected to the rotating device in a rotating mode, a unidirectional rotating part is connected to the transmission rod, a shaft rod is installed on the unidirectional rotating part, and the belt is used for driving the transmission rod to rotate.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the storage sleeve is internally provided with a strip-shaped groove, and a first limiting block is connected in the strip-shaped groove in a sliding manner.

As an alternative scheme of the safe operation platform for building construction, the invention comprises the following steps: the unidirectional rotation part is including installing the minor axis on the transfer line, install the extension board on the minor axis, the inside of axostylus axostyle is provided with accomodates the groove, accomodate the inside rotation in groove and be connected with the rotor plate, the rotor plate is used for accomodating to accomodating the inside in groove, the welding piece is still installed to the inside of axostylus axostyle, the welding piece is used for contradicting the rotor plate, the shell fragment is still installed to the inside of axostylus axostyle, the shell fragment is connected with the rotor plate.

The invention has the following beneficial effects:

1. this construction is built with safe operation platform in room, promote connecting cylinder and vacuum chuck through the short column and rock, let the drive connecting plate buckle that vacuum chuck can be quick to the spread groove on, and then let the workman can be quick accomplish building material installation, reduce artifical high altitude construction's possibility, improved the security of workman's operation greatly.

2. This construction is built with safe operation platform in room drives the short column through the disc and rotates for the short column can constantly promote the connecting cylinder under the extrusion of circular cone piece and enlarge the scope that vacuum chuck rocked gradually, makes the device let the drive connecting plate buckle that vacuum chuck can be more quick on the mounting bracket.

3. This construction is built with safe operation platform in room is through T shape slider sliding connection in the inside of ring channel, when the second connecting rod promotes the connecting cylinder and rocks, because T shape slider sliding connection is in the inside of ring channel for the connecting cylinder can only have regular circumference rotation, and then realizes that the connecting cylinder regularly rocks, no longer is simple in disorder and rocks, with this further scope that increases the vacuum chuck and drive the connecting plate and rock.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a schematic structural view of the regulating member of the present invention.

Fig. 3 is a schematic structural view of the limiting device of the present invention.

Fig. 4 is a schematic view of a partial structure of the present invention at B of fig. 3.

FIG. 5 is a schematic view of the structure of the blocking piece and the T-shaped slider of the present invention.

Fig. 6 is a cross-sectional view of the conditioning disk of the present invention.

Fig. 7 is a schematic structural view of a transmission member of the present invention.

Fig. 8 is a schematic view of the partial structure of fig. 7 at a.

Fig. 9 is a schematic view of the structure of the shaft and the transmission rod of the present invention.

Fig. 10 is a schematic view of the structure of the rotating plate and the short shaft of the present invention.

In the figure: 1. a support table; 2. a track; 3. a rotating device; 4. a hydraulic cylinder; 5. a transmission member; 6. a vacuum chuck; 7. an adjusting member; 8. a connecting cylinder; 9. a limiting device; 10. a transmission rod; 11. an internal thread sleeve; 12. a threaded rod; 13. a first telescopic rod; 14. a first connecting rod; 15. a support base; 16. a short shaft; 17. a protruding plate; 18. a rotating plate; 19. a storage groove; 20. a spring plate; 21. a welding block; 22. a blocking piece; 23. an inclined plane; 24. a first spring; 25. a square groove; 26. a mounting frame; 27. a connecting groove; 28. a connecting plate; 29. cutting; 30. conical blocks; 71. a shaft lever; 72. a disc; 73. a short column; 74. a second connecting rod; 75. an adjustment tank; 76. an L-shaped plate; 77. a second telescopic rod; 51. a welding frame; 52. a transmission shaft; 53. square bars; 54. a rotating wheel; 55. a belt; 56. a first screw rod; 57. a first helical groove; 58. a storage sleeve; 59. a second spring; 50. a first limiting block; 60. a bar-shaped groove; 31. a second screw rod; 32. a square plate; 33. a second helical groove; 34. a second limiting block; 35. a slide bar; 36. a third spring; 37. taper holes; 91. an adjusting plate; 92. an annular groove; 93. a third telescoping column; 94. a T-shaped slider; 95. and (5) ventilation holes.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1-3, a safe operation platform for building construction comprises a track 2 and a supporting table 1 which is slidably connected with the track 2, wherein a supporting seat 15 is arranged on the supporting table 1, a hydraulic cylinder 4 is arranged on the supporting seat 15, a connecting cylinder 8 is further connected to the supporting seat 15, a vacuum chuck 6 for adsorbing building materials is arranged on the connecting cylinder 8, and the hydraulic cylinder 4 is used for driving the vacuum chuck 6 to move;

the supporting seat 15 is internally provided with an adjusting part 7, the adjusting part 7 is used for adjusting the position of the connecting cylinder 8, the adjusting part 7 comprises a shaft lever 71 rotatably connected to the supporting seat 15, the shaft lever 71 is provided with a disc 72, the adjusting part comprises a short column 73, the axis of the short column 73 is far away from the axis of the disc 72, the short column 73 is connected with a second connecting rod 74, and the second connecting rod 74 is used for adjusting the position of the connecting cylinder 8.

In this embodiment:

and (3) shaking adjustment: according to the illustration in fig. 2 and 3, the connecting plate 28 adsorbed by the vacuum chuck 6 is pushed onto the mounting frame 26 by the hydraulic cylinder 4, and then the disc 72 is rotated, so that the disc 72 drives the short column 73 far away from the axis of the disc 72 to eccentrically rotate, and then the short column 73 drives the second connecting rod 74 to push the connecting cylinder 8 to shake, and the connecting cylinder 8 drives the vacuum chuck 6 to shake, so that the vacuum chuck 6 drives the cutting 29 on the connecting plate 28 to be continuously aligned with the connecting groove 27, and the connecting plate 28 can be accurately mounted onto the mounting frame 26, so that the device pushes the connecting cylinder 8 and the vacuum chuck 6 to shake by the short column 73, and the vacuum chuck 6 can quickly drive the connecting plate 28 to be buckled onto the connecting groove 27, so that workers can quickly mount building materials, the possibility of manual high-altitude operation is reduced, and the safety of the workers is greatly improved.

Example 2

This embodiment is an improvement based on embodiment 1, and according to fig. 1-3, the adjusting component includes an adjusting groove 75 provided on a disc 72, a second telescopic rod 77 is further installed on the disc 72, an L-shaped plate 76 is further installed on the second telescopic rod 77, the L-shaped plate 76 is slidingly connected inside the adjusting groove 75, and the short column 73 is connected to one side of the L-shaped plate 76;

the outer surface of the shaft 71 is slidably connected with a pushing member, on which a conical block 30 is mounted, and the conical block 30 is used for abutting against the L-shaped plate 76 to slide.

In this embodiment:

the search range is enlarged: because the connecting cylinder 8 drives the shaking of the vacuum chuck 6 is completed by the disc 72 driving the eccentric short column 73 and the second connecting rod 74, and further the shaking range of the vacuum chuck 6 can be enlarged by adjusting the position of the short column 73, according to the embodiment shown in fig. 3, an adjusting groove 75 is arranged on the disc 72, the conical block 30 continuously slides leftwards, so that the conical block 30 continuously extrudes the L-shaped plate 76 upwards, the L-shaped plate 76 drives the short column 73 to be further far away from the axis of the disc 72, and along with the rotation of the disc 72, the disc 72 drives the short column 73 to rotate, so that the short column 73 can continuously push the connecting cylinder 8 to gradually enlarge the shaking range of the vacuum chuck 6 under the extrusion of the conical block 30, and the device can drive the connecting plate 28 to be buckled on the mounting frame 26 more rapidly.

Example 3

The embodiment is an improvement on the basis of the embodiment 1, and according to the embodiment shown in fig. 1-4, a transmission part 5 is further arranged on the rotating device 3, the transmission part 5 is used for driving the internal thread sleeve 11 to rotate, the transmission part 5 comprises a transmission shaft 52 rotatably connected with the hydraulic cylinder 4, one end of the transmission shaft 52 is rotatably connected with a first screw rod 56, a storage sleeve 58 is arranged on the first screw rod 56, a limiting device 9 is arranged on the storage sleeve 58, and the limiting device 9 is used for assisting the connecting cylinder 8 to slide;

the limiting device 9 comprises an adjusting disc 91 arranged on the storage sleeve 58, an annular groove 92 is arranged in the adjusting disc 91, a T-shaped sliding block 94 is slidably connected in the annular groove 92, a third telescopic column 93 is arranged on the T-shaped sliding block 94, and the third telescopic column 93 is connected with the connecting cylinder 8.

In this embodiment:

regular shaking: according to the illustration in fig. 4, an adjusting disk 91 is installed on one side of the storage sleeve 58, a third telescopic column 93 and a T-shaped slide block 94 are also installed on the connecting cylinder 8, the T-shaped slide block 94 is slidably connected in the annular groove 92, when the second connecting rod 74 pushes the connecting cylinder 8 to shake, the T-shaped slide block 94 is slidably connected in the annular groove 92, so that the connecting cylinder 8 can only rotate regularly and further the connecting cylinder 8 can shake regularly, and no longer is simply swaying, thereby further enlarging the range of the vacuum chuck 6 driving the connecting plate 28 to shake;

it should be noted that, according to fig. 3, since the conical block 30 can abut against the L-shaped plate 76 to adjust the position of the stub 73 to enlarge the shaking range of the connecting cylinder 8, the third telescopic column 93 is installed between the connecting cylinder 8 and the T-shaped slider 94, and the third telescopic column 93 is in the prior art, so that when the stub 73 pushes the second connecting rod 74 and the connecting cylinder 8 to slide upwards, the connecting cylinder 8 can compress the third telescopic column 93, and the adjusted stub 73 can still push the connecting cylinder 8 to rotate circumferentially through the second connecting rod 74, and the second connecting rod 74 is rotatably connected to the stub 73, so that the second connecting rod 74 will not be jammed when the stub 73 pulls the second connecting rod 74 to rotate.

Example 4

This embodiment is an improvement on the basis of embodiment 3, and according to fig. 1-5, a first telescopic rod 13 is mounted on a second connecting rod 74, a first connecting rod 14 is mounted on the first telescopic rod 13, and the first connecting rod 14 is slidably connected to the outer surface of the connecting cylinder 8;

the third telescopic column 93 is T shape, T shape slider 94 and the looks adaptation of third telescopic column 93, and the inside of regulating disk 91 still is provided with square groove 25, and the internally mounted of square groove 25 has first spring 24, installs on the first spring 24 and blocks the dog 22, still is provided with the bleeder vent 95 that is used for ventilation air on the T shape slider 94, is provided with inclined plane 23 on the dog 22.

In this embodiment: according to embodiment 3, the T-shaped slider 94 is slidingly connected to the inside of the annular groove 92, so that the connecting cylinder 8 can only move in a regular circle, and the second connecting rod 74 is guaranteed not to be blocked by the connecting cylinder 8, the first telescopic rod 13 is installed on the second connecting rod 74 for accumulating force, when the short column 73 rotates to the lower end of the disc 72, the T-shaped slider 94 is not driven to move the connecting cylinder 8, then when the disc 72 drives the short column 73 to rotate again, the second connecting rod 74 pulls the T-shaped slider 94 to move, so that the T-shaped slider 94 can slide suddenly downwards, the T-shaped slider 94 and the connecting cylinder 8 can move in a quick circle, so that the vacuum chuck 6 can drive the cutting 29 on the connecting plate 28 to miss the connecting groove 27, therefore, the device is used for reducing the fault tolerance and improving the efficiency of the installation of the connecting plate 28 on the mounting frame 26, and the blocking block 22 is arranged inside the annular groove 92;

sliding at a constant speed: according to the method shown in fig. 5, the interior of the annular groove 92 is divided into a plurality of equal parts of spaces by six blocking blocks 22, and the T-shaped sliding blocks 94 slide in the spaces, according to the method shown in fig. 5, when the T-shaped sliding blocks 94 slide in the spaces, the blocking blocks 22 seal the spaces, so that air in the spaces can only flow in the ventilation holes 95 on the T-shaped sliding blocks 94, and the aperture of the ventilation holes 95 can only circulate by a fixed amount at one time, so that the sliding speed of the T-shaped sliding blocks 94 in the annular groove 92 can be kept constant, the connecting cylinder 8 can drive the vacuum chuck 6 to move at a constant speed, the possibility that the vacuum chuck 6 drives the cutting 29 to miss the connecting groove 27 is reduced, the vacuum chuck 6 can further drive the connecting plate 28 to be buckled on the connecting groove 27, so that a worker can rapidly install building materials, the possibility of manual high-altitude operation is reduced, and the safety of the worker during operation is improved;

it should be noted that, when the T-shaped slider 94 abuts against the blocking piece 22, the inclined surface 23 is pressed by the T-shaped slider 94, so that the blocking piece 22 is retracted into the square groove 25, and the T-shaped slider 94 is rotated into the next space, thereby realizing uniform circumferential movement of the T-shaped slider 94 inside the annular groove 92.

Example 5

The embodiment is an improvement based on the embodiment 4, according to fig. 1-6, a rotating device 3 is further installed inside the connecting cylinder 8, the rotating device 3 is used for driving the vacuum chuck 6 to swing, the rotating device 3 comprises a sliding rod 35 which is slidingly connected inside the connecting cylinder 8, a taper hole 37 is further arranged on the adjusting disc 91, the sliding rod 35 penetrates through one side of the connecting cylinder 8 and is slidingly connected inside the taper hole 37, a third spring 36 is further installed inside the connecting cylinder 8, and the third spring 36 is connected with the sliding rod 35;

the inside rotation of connecting cylinder 8 is connected with second screw rod 31, and the inside of second screw rod 31 is provided with second helical groove 33, installs second stopper 34 on the slide bar 35, and second stopper 34 sliding connection is in the inside of second helical groove 33, still installs square plate 32 on the second screw rod 31, and square plate 32 is connected with vacuum chuck 6.

In this embodiment:

shaking in a small range: according to the illustration of fig. 6, there is slide bar 35 in the inside of connecting cylinder 8, when connecting cylinder 8 rotates at the inside circumference of ring channel 92, slide bar 35 in connecting cylinder 8 can follow the inside roll-off of taper hole 37, make adjustment dish 91 conflict slide bar 35 slide left, and then utilize slide bar 35 sliding connection in the inside of second screw rod 31, make the inside of second stopper 34 sliding connection in second screw groove 33 on slide bar 35, thereby it is rotatory to lead to second screw rod 31, according to the illustration of fig. 6, still install square plate 32 in the one end of second screw rod 31, and square plate 32 is connected with vacuum chuck 6, the axle center of vacuum chuck 6 is kept away from the axle center of second screw rod 31, and then lead to second screw rod 31 can drive square plate 32 and vacuum chuck 6 circular motion, thereby the device realizes under the whole large scale circular motion of connecting cylinder 8 drive vacuum chuck 6, second screw rod 31 is at the small circle motion of drive vacuum chuck 6, make the device can more accurate and quick let connecting plate 28 buckle on 26.

Example 6

The embodiment is an improvement based on embodiment 5, according to fig. 1-8, a second spring 59 is installed in the storage sleeve 58, the second spring 59 is connected with the first screw rod 56, the first screw rod 56 is provided with a first screw groove 57, the storage sleeve 58 is also connected with a first limiting block 50, and the first limiting block 50 is slidably connected in the first screw groove 57;

square bars 53 are arranged on two sides of the transmission shaft 52, a welding frame 51 is further arranged on the rotating device 3, a rotating wheel 54 is rotatably connected in the welding frame 51, a belt 55 is sleeved on the rotating wheel 54, a transmission rod 10 is rotatably connected to the rotating device 3, a unidirectional rotating part is connected to the transmission rod 10, a shaft lever 71 is arranged on the unidirectional rotating part, the belt 55 is used for driving the transmission rod 10 to rotate, a strip-shaped groove 60 is arranged in the accommodating sleeve 58, and a first limiting block 50 is slidably connected in the strip-shaped groove 60;

the pushing component comprises an internal thread sleeve 11 rotatably connected inside the rotating device 3, a threaded rod 12 is connected to the internal thread of the internal thread sleeve 11, the threaded rod 12 is connected with the conical block 30, and the threaded rod 12 is used for pushing the conical block 30 to slide.

In this embodiment:

automatic driving: according to the embodiment shown in fig. 7 and 8, the transmission shaft 52, the first screw rod 56, the accommodating sleeve 58, the adjusting disc 91, the connecting cylinder 8 and the vacuum chuck 6 are pushed by the hydraulic cylinder 4 to slide towards the mounting frame 26, so that the vacuum chuck 6 drives the cutting 29 on the connecting plate 28 to abut against the mounting frame 26, when the hydraulic cylinder 4 continues to slide towards the left mounting frame 26, the first screw rod 56 slides into the accommodating sleeve 58, so that the first limiting block 50 in the accommodating sleeve 58 is connected onto the first screw groove 57 in a sliding manner, the first screw rod 56 rotates, the belt 55 is driven by the first screw rod 56 to rotate, the transmission rod 10 is driven by the belt 55 to rotate, the disc 72 drives the short column 73 to eccentrically move, the second connecting rod 74, the first telescopic rod 13 and the first connecting rod 14 are driven by the short column 73 to pull the connecting cylinder 8, the device can automatically judge whether the cutting 29 on the connecting plate 28 is buckled inside the connecting groove 27, and if the cutting 29 abuts against the mounting frame 26, the belt 55 is driven by the first screw rod 56 to rotate, the belt 55 is driven by the disc 72, and the disc 72 is driven by the disc 72 to rotate;

according to fig. 7, the belt 55 is identical to the driving of the internal thread bush 11 for rotation, and when the belt 55 drives the internal thread bush 11 for rotation, the belt 55 drives the threaded rod 12 for rotation, but the threaded rod 12 is limited by the conical block 30, so that the threads in the internal thread bush 11 can only push the threaded rod 12 to slide leftwards, and the threaded rod 12 pushes the conical block 30 to slide leftwards, so that the device drives the threaded rod 12 through the internal thread bush 11 to automatically adjust the short column 73 gradually far away from the axle center of the disc 72.

Example 7

This embodiment is an improvement made on the basis of embodiment 6, according to the one-way rotation component shown in fig. 1-10, including the minor axis 16 of installing on the transfer line 10, install on the minor axis 16 and stretch out the board 17, the inside of axostylus axostyle 71 is provided with the storage groove 19, the inside rotation of storage groove 19 is connected with rotor plate 18, rotor plate 18 is used for accomodating to the inside of storage groove 19, welding piece 21 is still installed to the inside of axostylus axostyle 71, welding piece 21 is used for contradicting rotor plate 18, the inside of axostylus axostyle 71 still installs shell fragment 20, shell fragment 20 is connected with rotor plate 18.

In this embodiment:

avoid the card to die: when the vacuum chuck 6 drives the cutting 29 on the connecting plate 28 to be buckled in the connecting groove 27, the connecting cylinder 8, the adjusting disk 91 and the receiving sleeve 58 slide towards the mounting frame 26, so that the first limiting block 50 is reversely connected with the inside of the first screw rod 56 in a sliding manner, the first screw rod 56 can reversely drive the belt 55 to rotate, the transmission rod 10 can drive the shaft rod 71 and the disc 72 to reversely rotate, the short column 73 and the second connecting rod 74 can push the connecting cylinder 8 to shake again, the vacuum chuck 6 can be damaged when the vacuum chuck 6 cannot be timely separated from the connecting plate 28, the short shaft 16 is arranged at one end of the transmission rod 10 to avoid the situation, and according to the figures 9 and 10,

when the transmission rod 10 and the short shaft 16 rotate anticlockwise, the protruding plate 17 on the short shaft 16 is abutted against the rotating plate 18, the rotating plate 18 is abutted against the welding block 21, the rotating plate 18 is further enabled to drive the shaft lever 71 to rotate, when the transmission rod 10 and the short shaft 16 rotate clockwise, the protruding plate 17 on the short shaft 16 is abutted against the rotating plate 18, and the rotating plate 18 can rotate and shrink into the accommodating groove 19 due to the fact that the other side of the rotating plate 18 is not limited, and therefore the transmission rod 10 cannot drive the shaft lever 71 and the disc 72 to rotate reversely.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing is merely a preferred embodiment of the present invention, and it should be noted that it will be apparent to those skilled in the art that several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the scope of the invention.

Claims (8)

1. The utility model provides a safe operation platform for construction is built in room, includes supporting bench (1) of sliding connection on track (2) and track (2), its characterized in that: a supporting seat (15) is arranged on the supporting table (1), a hydraulic cylinder (4) is arranged on the supporting seat (15), a connecting cylinder (8) is further connected to the supporting seat (15), a vacuum chuck (6) for adsorbing building materials is arranged on the connecting cylinder (8), and the hydraulic cylinder (4) is used for driving the vacuum chuck (6) to move;

an adjusting part (7) is further arranged in the supporting seat (15), the adjusting part (7) is used for adjusting the position of the connecting cylinder (8), the adjusting part (7) comprises a shaft rod (71) rotatably connected to the supporting seat (15), a disc (72) is arranged on the shaft rod (71), the adjusting part comprises a short column (73), the axis of the short column (73) is far away from the axis of the disc (72), a second connecting rod (74) is connected to the short column (73), and the second connecting rod (74) is used for adjusting the position of the connecting cylinder (8);

the adjusting part comprises an adjusting groove (75) arranged on the disc (72), a second telescopic rod (77) is further arranged on the disc (72), an L-shaped plate (76) is further arranged on the second telescopic rod (77), the L-shaped plate (76) is slidably connected inside the adjusting groove (75), and the short column (73) is connected to one side of the L-shaped plate (76);

the outer surface sliding connection of axostylus axostyle (71) has pushing means, install cone piece (30) on the pushing means, cone piece (30) are used for contradicting L shaped plate (76) slip.

2. The safe operation platform for building construction according to claim 1, wherein: the pushing component comprises an internal thread sleeve (11) which is rotationally connected inside the rotating device (3), a threaded rod (12) is connected with the internal thread of the internal thread sleeve (11), the threaded rod (12) is connected with the conical block (30), and the threaded rod (12) is used for pushing the conical block (30) to slide.

3. The safe operation platform for building construction according to claim 2, wherein: the rotary device (3) is further provided with a transmission part (5), the transmission part (5) is used for driving the internal thread sleeve (11) to rotate, the transmission part (5) comprises a transmission shaft (52) rotationally connected to the hydraulic cylinder (4), one end of the transmission shaft (52) is rotationally connected with a first screw rod (56), the first screw rod (56) is provided with a storage sleeve (58), the storage sleeve (58) is provided with a limiting device (9), and the limiting device (9) is used for assisting the connecting cylinder (8) to slide;

the limiting device (9) comprises an adjusting disc (91) arranged on the storage sleeve (58), an annular groove (92) is formed in the adjusting disc (91), a T-shaped sliding block (94) is connected in the annular groove (92) in a sliding mode, a third telescopic column (93) is arranged on the T-shaped sliding block (94), and the third telescopic column (93) is connected with the connecting cylinder (8).

4. A safe operation platform for building construction according to claim 3, wherein: a first telescopic rod (13) is arranged on the second connecting rod (74), a first connecting rod (14) is arranged on the first telescopic rod (13), and the first connecting rod (14) is connected to the outer surface of the connecting cylinder (8) in a sliding manner;

the utility model discloses a flexible post of regulation dish, including flexible post, regulation dish, adjustable disk, T-shaped slider (94) are T-shaped, T-shaped slider (94) and flexible post (93) looks adaptation of third, the inside of adjustable disk (91) still is provided with square groove (25), internally mounted in square groove (25) has first spring (24), install on first spring (24) and block piece (22), still be provided with bleeder vent (95) that are used for ventilation air on T-shaped slider (94), be provided with inclined plane (23) on blocking piece (22).

5. The safe operation platform for building construction according to claim 4, wherein: the inside of the connecting cylinder (8) is also provided with a rotating device (3), the rotating device (3) is used for driving the vacuum chuck (6) to swing, the rotating device (3) comprises a sliding rod (35) which is connected inside the connecting cylinder (8) in a sliding way, the adjusting disc (91) is also provided with a taper hole (37), the sliding rod (35) penetrates through one side of the connecting cylinder (8) and is used for being connected inside the taper hole (37) in a sliding way, the inside of the connecting cylinder (8) is also provided with a third spring (36), and the third spring (36) is connected with the sliding rod (35);

the inside rotation of connecting cylinder (8) is connected with second screw rod (31), the inside of second screw rod (31) is provided with second helical groove (33), install second stopper (34) on slide bar (35), second stopper (34) sliding connection is in the inside of second helical groove (33), still install square board (32) on second screw rod (31), square board (32) are connected with vacuum chuck (6).

6. The safe operation platform for building construction according to claim 5, wherein: the inside of the storage sleeve (58) is provided with a second spring (59), the second spring (59) is connected with a first spiral rod (56), a first spiral groove (57) is formed in the first spiral rod (56), a first limiting block (50) is further connected to the inside of the storage sleeve (58), and the first limiting block (50) is slidably connected to the inside of the first spiral groove (57);

square bars (53) are all installed to both sides of transmission shaft (52), welding frame (51) are still installed on rotary device (3), the inside rotation of welding frame (51) is connected with swiveling wheel (54), the cover is equipped with belt (55) on swiveling wheel (54), it is connected with transfer line (10) to rotate on rotary device (3), be connected with unidirectional rotating part on transfer line (10), install axostylus axostyle (71) on the unidirectional rotating part, belt (55) are used for driving transfer line (10) rotatory.

7. A safe operation platform for building construction according to claim 3, wherein: a strip-shaped groove (60) is formed in the storage sleeve (58), and a first limiting block (50) is connected in the strip-shaped groove (60) in a sliding mode.

8. The safe operation platform for building construction according to claim 6, wherein: the unidirectional rotation part is including installing minor axis (16) on transfer line (10), install on minor axis (16) and stretch out board (17), the inside of axostylus axostyle (71) is provided with accomodates groove (19), the inside rotation of accomodating groove (19) is connected with rotor plate (18), rotor plate (18) are used for accomodating to the inside of accomodating groove (19), welding piece (21) are still installed to the inside of axostylus axostyle (71), welding piece (21) are used for contradicting rotor plate (18), shell fragment (20) are still installed to the inside of axostylus axostyle (71), shell fragment (20) are connected with rotor plate (18).