CN117565952A - Device for space transportation of high-low span building outer vertical face large wallboard - Google Patents

Abstract

The application relates to the field of wallboard transportation, in particular to a device for transporting a large-scale wallboard space of a high-low span building outer facade. The device for space transportation of the large-scale wallboard of the outer facade of the high-low span building comprises a first trolley, a first sliding rail and a second sliding rail, wherein the wallboard is movably connected to the first sliding rail through a hanging assembly; the second trolley is provided with a second sliding rail, and the first sliding rail and the second sliding rail can be in butt joint. Through hanging the wallboard on hanging the subassembly, in the different positions of high low span, remove wherein one side with first dolly, the second dolly removes other one side, hangs the subassembly and removes the second slide rail on first slide rail, accomplishes the transportation of wallboard high low span.

Description

Device for space transportation of high-low span building outer vertical face large wallboard

Technical Field

The application relates to the field of wallboard transportation, in particular to a device for transporting a large-scale wallboard space of a high-low span building outer facade.

Background

Wallboard is an indispensable part in building structures, and an assembled building is a building formed by assembling, preparing and installing on site. In the process of assembly type building construction, the work of installing, dismantling and the like on template materials such as wallboards is needed, and the work of transporting wallboards is included.

In the prior art, the transportation of the wallboards is usually realized through the trolley, but most of transportation technologies are that the wallboards are directly stacked on the trolley board, the wallboard is extremely easy to collide, squeeze and deform in the transportation process of the wallboards, most of the existing wallboards are of structures integrating heat preservation and decoration, the transportation technologies have higher requirements, and once the wallboards deform, the whole building is influenced.

Although some technologies have improved the cart to make it possible to stably transport the wallboard horizontally, in the actual construction process, the problem of transferring the wallboard in the space between the high span and the low span is unavoidable, and at this time, the cart cannot be operated, which may affect the whole process of the construction process.

Disclosure of Invention

The application provides a device for large-scale wallboard space transportation of high low span building facade, can make to transport the wallboard fast and steadily under the environment of high low span.

Embodiments of the present application provide an apparatus for space transportation of high and low span building facades large wall panels, comprising:

the first trolley is provided with a first sliding rail, and the wallboard is movably connected to the first sliding rail through the hanging assembly;

the second trolley is provided with a second sliding rail, and the first sliding rail and the second sliding rail can be in butt joint.

In the device that is used for large-scale wallboard space transportation of high low building facade that is provided of this application embodiment, still including assisting wallboard business turn over device, it includes business turn over frame and connects to assist wallboard business turn over device the stopper of vertical setting on the business turn over frame, the stopper can carry out the centre gripping to the wallboard of putting.

In the device for large-scale wallboard space transportation of high-low span building facade provided by the embodiment of the application, the business turn over frame includes:

the four inlet and outlet connecting rods are connected with each other, and four tires with adjustable heights are arranged below the inlet and outlet connecting rods;

the two inlet and outlet cross beams are respectively connected with the inlet and outlet connecting rods, and three pairs of limiters are respectively and correspondingly arranged on the inlet and outlet cross beams.

In the device for transporting high-low span building facade large-scale wallboard space provided by the embodiment of the application, the bottom of the limiter is connected with the in-out frame through the hydraulic device, meanwhile, the contact surface of the limiter and the wallboard is provided with the pressure sensor, and the lossless fixation of the wallboard is realized through the cooperation of the hydraulic device and the pressure sensor in the process of fixing the wallboard through the limiter.

In the device for transporting high-low span building facade large-scale wallboard space provided by the embodiment of the application, the first trolley and the second trolley comprise a bottom frame, a hydraulic lifter and a top frame, the hydraulic lifter is connected to the bottom frame, the top frame is connected to the hydraulic lifter, the first sliding rail is arranged on the top frame of the first trolley, and the second sliding rail is arranged on the top frame of the second trolley.

In the device for space transportation of the high-low span building facade large wallboard provided by the embodiment of the application, the upper part of the front end of the first sliding rail is concave, and the lower part of the front end of the first sliding rail is slotted; the lower part of the front end of the second sliding rail is concave, and an outer convex part corresponding to the lower part of the first sliding rail is arranged in the concave.

In the device for space transportation of high-low span building facade large-scale wallboard that this application embodiment provided, the suspension assembly includes pulley and connecting rod, the pulley includes a plurality of, distributes on the both sides track of first slide rail, the connecting rod will both sides the pulley links together, the connecting rod is used for hanging the wallboard, when carrying out space transportation, first slide rail with the second slide rail dock the back of accomplishing, the pulley can slide out first slide rail gets into the second slide rail.

In the device for transporting high-low span building facade large-scale wallboard space provided by the embodiment of the application, the bottom frame is located the first dolly with the relative one side rotation of second dolly is connected with rotatable pole, rotatable pole can open and close the one side opening of bottom frame.

In the device for transporting high-low span building facade large-scale wallboard space that is provided by this application embodiment, hydraulic lifter includes four hydraulic stems and hydraulic booster, hydraulic booster with hydraulic stem is connected, four hydraulic stems are connected respectively to the corner of bottom frame, four the flexible end of pneumatic cylinder is connected respectively to on the top frame, hydraulic booster is connected to on the bottom frame.

In the device for space transportation of the high-low span building facade large wall plate provided by the embodiment of the application, the device further comprises a docking mechanism which is respectively arranged on the bottom frames of the first trolley and the second trolley;

wherein a first portion of the docking mechanism provided on the first dolly extends to the hydraulic stem side of the second dolly, a second portion of the docking mechanism extends below the bottom frame of the first dolly, the docking mechanism being configured to rotate in a predetermined direction such that the first portion abuts on the hydraulic stem of the second dolly, the second portion abutting on the ground;

a first portion of the docking mechanism disposed on the second cart extends to the hydraulic rod side of the first cart and a second portion of the docking mechanism extends below the bottom frame of the second cart.

The device for space transportation of the large-scale wallboard of the outer facade of the high-low span building is provided with the first trolley, the first trolley is provided with a first sliding rail, and the wallboard is movably connected to the first sliding rail through the hanging assembly; the second trolley is provided with a second sliding rail, and the first sliding rail and the second sliding rail can be in butt joint. Through hanging the wallboard on hanging the subassembly, in the different positions of high low span, remove wherein one side with first dolly, the second dolly removes other one side, hangs the subassembly and removes the second slide rail on first slide rail, accomplishes the transportation of wallboard high low span.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

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

FIG. 1 is a schematic diagram of the overall structure of a first cart for space transportation of high and low span building facades large wall panels provided in an embodiment of the present application;

FIG. 2 is a schematic view of a first cart for space transportation of high and low span building facades large wall panels provided in an embodiment of the present application;

FIG. 3 is a schematic view of a partial enlarged structure of A of FIG. 2;

FIG. 4 is a schematic diagram of the overall structure of a second cart for space transportation of high and low span building facades large wall panels provided in an embodiment of the present application;

fig. 5 is a schematic diagram of the overall structure of a device for assisting in the space transportation of large-scale wallboards on the outer vertical surface of a high-low span building according to the embodiment of the application.

Main elements and symbol description:

10. a first cart; 101. a first slide rail; 11. a bottom frame; 12. a hydraulic lifter; 121. a hydraulic rod; 122. a hydraulic booster; 13. a top frame;

20. a second cart; 201. a second slide rail; 21. a rotatable lever;

30. assisting the wallboard in entering and exiting the device; 301. a frame in and out; 3011. a connecting rod is arranged in and out; 3012. a beam is moved in and out; 302. a limiter; 303. a hydraulic device;

40. a hanging assembly; 401. a pulley;

50. a wallboard; 60. a docking mechanism; 601. a gear lever; 602. a rotating ring; 603. a driving motor; 604. an extension.

Description of the embodiments

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

Some embodiments of the present application are described in detail below with reference to the accompanying drawings. The following embodiments and features of the embodiments may be combined with each other without conflict.

It is to be understood that the terminology used in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be understood that, in order to clearly describe the technical solutions of the embodiments of the present application, in the embodiments of the present application, the words "first", "second", etc. are used to distinguish the same item or similar items having substantially the same function and effect. For example, the first groove and the second groove are merely for distinguishing between different grooves, and are not limited in order. It will be appreciated by those of skill in the art that the words "first," "second," and the like do not limit the amount and order of execution, and that the words "first," "second," and the like do not necessarily differ.

It should be further understood that the term "and/or" as used in this specification and the appended claims refers to any and all possible combinations of one or more of the associated listed items, and includes such combinations.

Wallboard is an indispensable part in building structures, and an assembled building is a building formed by assembling, preparing and installing on site. In the process of assembly type building construction, the work of installing, dismantling and the like on template materials such as wallboards is needed, and the work of transporting wallboards is included.

In the prior art, the transportation of the wallboards is usually realized through the trolley, but most of transportation technologies are that the wallboards are directly stacked on the trolley board, the wallboard is extremely easy to collide, squeeze and deform in the transportation process of the wallboards, most of the existing wallboards are of structures integrating heat preservation and decoration, the transportation technologies have higher requirements, and once the wallboards deform, the whole building is influenced.

Although some technologies have improved the cart to make it possible to stably transport the wallboard horizontally, in the actual construction process, the problem of transferring the wallboard in the space between the high span and the low span is unavoidable, and at this time, the cart cannot be operated, which may affect the whole process of the construction process.

In summary, the disadvantages of the prior art are:

wallboard is directly piled up on the device, easily leads to wallboard deformation and damage

Only support horizontal transportation, but can not solve the problem of high-low span transportation

The solution of this application is that the wallboard adopts the mode of hanging to place, can prevent the extrusion deformation problem of wallboard. The structure supports horizontal transportation, and high-low span space transportation is realized through synchronous adjustment of the supporting hydraulic rod

Referring to fig. 1-5, the present application provides an apparatus for space transportation of high and low span building facade large wall 50, comprising:

the first trolley 10 is provided with a first sliding rail 101, and the wallboard 50 is movably connected to the first sliding rail 101 through the hanging assembly 40;

the second trolley 20 is provided with a second slide rail 201, and the first slide rail 101 and the second slide rail 201 can be in butt joint.

By hanging the wall plate 50 on the hanging assembly 40, the first trolley 10 is moved to one side of the hanging assembly at different positions of the high span and the low span, the second trolley 20 is moved to the other side, and the hanging assembly 40 is moved to the second sliding rail 201 on the first sliding rail 101, so that the high span and the low span of the wall plate 50 are assembled.

In some embodiments, a help wall panel 50 access device 30 is also included, the help wall panel 50 access device 30 includes an access frame 301 and a vertically disposed stop 302 connected to the access frame 301, the stop 302 being capable of holding an opposing wall panel 50.

When the wallboard 50 is transported to the first trolley 10 and the second trolley 20, the wallboard 50 is clamped on the limiter 302 by assisting the wallboard 50 to enter and exit the device 30, and then is hung on the hanging assembly 40, or is detached from the hanging assembly 40 more conveniently.

The access frame 301 includes: the four in-out connecting rods 3011 are connected with each other, and four tires with adjustable heights are arranged below the in-out connecting rods 3011; the two in-out beams 3012 are respectively connected with the in-out connecting rods 3011, and three pairs of limiters 302 are respectively and correspondingly arranged on the in-out beams 3012.

The bottom of the limiter 302 is connected with the inlet and outlet frame 301 through a hydraulic device 303, meanwhile, a pressure sensor is arranged on the contact surface of the limiter 302 and the wallboard 50, and in the process of fixing the wallboard 50 through the limiter 302, the nondestructive fixing of the wallboard 50 is realized through the cooperation of the hydraulic device 303 and the pressure sensor.

The hydraulic device 303 includes a hydraulic telescopic rod, a hydraulic cylinder device, or the like. The pressure sensor is able to monitor the clamping pressure and avoid damage to the wall plate 50.

In some embodiments, the first cart 10 and the second cart 20 each comprise a bottom frame 11, a hydraulic lift 12, a top frame 13, the hydraulic lift 12 being connected to the bottom frame 11, the top frame 13 being connected to the hydraulic lift 12, the first rail 101 being disposed on the top frame 13 of the first cart 10, the second rail 201 being disposed on the top frame 13 of the second cart 20.

The upper part of the front end of the first sliding rail 101 is concave, and the lower part of the front end of the first sliding rail is grooved; the lower part of the front end of the second sliding rail 201 is concave, and an outer convex part corresponding to the lower part of the first sliding rail 101 is arranged in the concave.

The hanging assembly 40 comprises a plurality of pulleys 401 and connecting rods, the pulleys 401 are distributed on rails on two sides of the first sliding rail 101, the connecting rods are used for connecting the pulleys 401 on two sides together, the connecting rods are used for hanging the wallboard 50, and when space transportation is carried out, the pulleys 401 can slide out of the first sliding rail 101 and enter the second sliding rail 201 after the first sliding rail 101 and the second sliding rail 201 are in butt joint.

The bottom frame 11 is rotatably connected to a rotatable lever 21 on the opposite side of the first cart 10 and the second cart 20, and the rotatable lever 21 can open and close an opening on one side of the bottom frame 11.

The bottom frame 11 mainly comprises three connecting rods and two rotatable rods 21, and the bottommost part is four tires, wherein two lockable wheels far away from the rotatable rods 21 are used for fixing devices during space transportation, and two non-lockable universal wheels close to the rotatable rods 21 are used for changing directions during horizontal transportation;

the tire is last three connecting rod and two rotatable poles 21, and wherein three connecting rod bearing structure main part frame, two rotatable poles 21 are convenient for the business turn over of wallboard 50, namely: the rotatable rod 21 of the wallboard 50 is opened in the process of entering and exiting the first trolley 10 and the second trolley 20, so that the wallboard 50 can enter and exit conveniently; the rotatable rod 21 is closed in the process of transporting the first trolley 20 and the second trolley 20 after the wallboard 50 is fixed in and out, so that the integral stability of the structure is ensured.

The rotatable rod 21 is divided into two parts, wherein the upper part of one rotatable rod 21 is internally provided with a lower part hole, the other rotatable rod 21 is correspondingly provided with a lower part internally provided with an upper part hole, and the two rotatable rods 21 can be fixed through a bolt when the rotatable rod is closed.

The top frame 13 is a frame composed of four connecting rods, the first trolley 10 and the second trolley 20 have the same structure, the first sliding rail 101 and the second sliding rail 201 have different connecting structures, and other structures are the same;

the hydraulic rod 121 serves to support the entire top frame 13. The first sliding rail 101 and the second sliding rail 201 are provided with holes in front and back, and are connected and fixed with the top frame 13 through the holes.

In some embodiments, the hydraulic lifter 12 includes four hydraulic rods 121 and a hydraulic booster 122, the hydraulic booster 122 is connected to the hydraulic rods 121, four hydraulic rods 121 are respectively connected to corners of the bottom frame 11, telescopic ends of four hydraulic cylinders are respectively connected to the top frame 13, and the hydraulic booster 122 is connected to the bottom frame 11.

The height of the hydraulic rod 121 is synchronously adjusted through the work of the hydraulic booster 122, and then the transfer work of the first trolley 10 and the second trolley 20 between high and low spans is realized through the cooperation of the hydraulic rod 121 and the first sliding rail 101 and the second sliding rail 201.

In some embodiments, further comprising a docking mechanism 60 disposed on the bottom frame 11 of the first cart 10 and the second cart 20, respectively;

wherein a first portion of the docking mechanism 60 provided on the first cart 10 extends to the hydraulic rod 121 side of the second cart 20, a second portion of the docking mechanism 60 extends below the bottom frame 11 of the first cart 10, the docking mechanism 60 being configured to rotate in a predetermined direction such that the first portion abuts on the hydraulic rod 121 of the second cart 20, the second portion abutting on the ground;

a first portion of the docking mechanism 60 provided on the second cart 20 extends to the hydraulic rod 121 side of the first cart 10, and a second portion of the docking mechanism 60 extends below the bottom frame 11 of the second cart 20. The docking mechanism 60 is configured to rotate in a predetermined direction such that the first portion abuts against the hydraulic rod 121 of the first cart 10 and the second portion abuts against the ground.

With the above arrangement, when the first carriage 10 is docked with the second carriage 20, the docking mechanism 60 on the first carriage 10 is rotated in a predetermined direction such that the first portion of the docking mechanism 60 is abutted to the hydraulic rod 121 of the second carriage 20, the second portion is abutted to the ground, and the docking mechanism 60 on the second carriage 20 is rotated in a predetermined direction such that the first portion of the docking mechanism 60 is abutted to the hydraulic rod 121 of the first carriage 10, and the second portion is abutted to the ground. Thus, the first trolley 10 and the second trolley 20 are abutted against the ground, stability is achieved, when the first trolley 10 and the second trolley 20 are abutted, the wallboard 50 does not shake or generate a gap between the first trolley 10 and the second trolley 20, when the wallboard 50 moves, the pulley 401 generates a pushing force on the trolley when the pulley 401 moves to the joint of the first trolley 10 and the second trolley 20, the two trolleys cannot move, and the wallboard 50 is abutted against the ground more stably and simultaneously when moving, and a locking force is generated on the first trolley 10 and the second trolley 20.

The docking mechanism 60 comprises a gear lever 601, a rotating ring 602, a rotating shaft, a driving motor 603 and an extending piece 604, wherein the extending piece 604 and the gear lever 601 are connected to the rotating ring 602, the extending piece 604 is arranged corresponding to the gear lever 601, the rotating ring 602 is connected to the rotating shaft in a threaded manner, the rotating shaft is provided with threads, the driving motor 603 is connected to the bottom frame 11, the rotating shaft is connected to the driving motor 603, nuts are arranged on two sides of the rotating ring 602 after the rotating ring 602 is connected to the rotating shaft, and the nuts are connected with the rotating shaft in a threaded manner and lock the rotating ring 602. After the driving motor 603 rotates, the gear lever 601 rotates to be abutted to the hydraulic rod 121, and the extension piece 604 rotates to be abutted to the ground.

The lever 601 has an L-shaped structure.

The extension piece 604 is a telescopic driver, and can stretch out and draw back, so set up for first dolly 10 or second dolly 20 are when the inclined plane butt joint, and telescopic driver is according to inclined plane distance this department docking mechanism 60 length, extends corresponding distance, makes telescopic driver support to ground after, carries out the lifting to first dolly 10 and/or second dolly 20, makes two dollies in the plane and balanced, avoids the slope.

An infrared sensor, a level gauge and the like may be provided to test whether the carts thereof are balanced, for example, laser ranging sensors may be provided at four corners of the first cart 10 and the second cart 20.

While the invention has been described with reference to certain preferred embodiments, it will be understood by those skilled in the art that various changes and substitutions of equivalents may be made and equivalents will be apparent to those skilled in the art without departing from the scope of the invention. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (10)

1. A device for space transportation of high and low span building facades large wall panels, comprising:

the first trolley is provided with a first sliding rail, and the wallboard is movably connected to the first sliding rail through the hanging assembly;

the second trolley is provided with a second sliding rail, and the first sliding rail and the second sliding rail can be in butt joint.

2. The apparatus for space transportation of large high and low span building facades according to claim 1, further comprising a means for assisting in the ingress and egress of the wall panels, said means for assisting in the ingress and egress of the wall panels comprising an ingress and egress frame and vertically arranged stoppers connected to said ingress and egress frame, said stoppers being capable of holding the wall panels standing vertically.

3. The apparatus for space transportation of high and low span building facade large wall panels according to claim 2, wherein said access frame comprises:

the four inlet and outlet connecting rods are connected with each other, and four tires with adjustable heights are arranged below the inlet and outlet connecting rods;

the two inlet and outlet cross beams are respectively connected with the inlet and outlet connecting rods, and three pairs of limiters are respectively and correspondingly arranged on the inlet and outlet cross beams.

4. The device for space transportation of large-scale wallboards of high-low span building facades according to claim 2, wherein the bottom of the limiter is connected with the in-out frame through a hydraulic device, and meanwhile, the contact surface of the limiter and the wallboards is provided with a pressure sensor, and in the process of fixing the wallboards through the limiter, the lossless fixation of the wallboards is realized through the cooperation of the hydraulic device and the pressure sensor.

5. The apparatus for space transportation of high and low span building facade large wall panels according to claim 1, wherein the first trolley and the second trolley each comprise a bottom frame, a hydraulic lifter, a top frame, the hydraulic lifter being connected to the bottom frame, the top frame being connected to the hydraulic lifter, the first rail being arranged on the top frame of the first trolley, the second rail being arranged on the top frame of the second trolley.

6. The device for space transportation of high-low span building facade large wall boards according to claim 1, wherein the upper part of the front end of the first sliding rail is concave, and the lower part is slotted; the lower part of the front end of the second sliding rail is concave, and an outer convex part corresponding to the lower part of the first sliding rail is arranged in the concave.

7. The device for space transportation of large-scale wallboards of high-low span building facades according to claim 1, wherein the hanging component comprises a plurality of pulleys and connecting rods, the pulleys are distributed on two side rails of the first sliding rail, the connecting rods are used for connecting the pulleys on two sides together, the connecting rods are used for hanging wallboards, and when space transportation is carried out, after the first sliding rail and the second sliding rail are in butt joint, the pulleys can slide out of the first sliding rail and enter the second sliding rail.

8. The apparatus for space transportation of high and low span building facade large wall panels according to claim 5, wherein a rotatable lever is rotatably connected to the bottom frame on the opposite side of the first trolley and the second trolley, the rotatable lever being capable of opening and closing one side opening of the bottom frame.

9. The apparatus for space transportation of high and low span building facade large wall plates according to claim 5, characterized in that the hydraulic lifter comprises four hydraulic rods and hydraulic boosters, the hydraulic boosters being connected to the hydraulic rods, the four hydraulic rods being connected to the corners of the bottom frame, respectively, the telescopic ends of the four hydraulic cylinders being connected to the top frame, respectively, the hydraulic boosters being connected to the bottom frame.

10. The apparatus for space transportation of high and low span building facade large wall panels according to claim 9, further comprising docking means provided on the bottom frames of the first and second carts, respectively;

wherein a first portion of the docking mechanism provided on the first dolly extends to the hydraulic stem side of the second dolly, a second portion of the docking mechanism extends below the bottom frame of the first dolly, the docking mechanism being configured to rotate in a predetermined direction such that the first portion abuts on the hydraulic stem of the second dolly, the second portion abutting on the ground;

a first portion of the docking mechanism disposed on the second cart extends to the hydraulic rod side of the first cart and a second portion of the docking mechanism extends below the bottom frame of the second cart.