CN113086891A

CN113086891A - Conveyer for assembly type building structure

Info

Publication number: CN113086891A
Application number: CN202110337831.8A
Authority: CN
Inventors: 周楚荣; 姚子健; 李磊
Original assignee: Dongguan Guangyun Construction Engineering Co ltd
Current assignee: Dongguan Guangyun Construction Engineering Co ltd
Priority date: 2021-03-30
Filing date: 2021-03-30
Publication date: 2021-07-09
Anticipated expiration: 2041-03-30
Also published as: CN113086891B

Abstract

The application relates to the field of transportation devices, in particular to a transportation device for an assembly type building structure, which comprises a bearing platform, a sliding plate, a sliding mechanism and a lifting mechanism; the sliding plate is arranged on the bearing table in a sliding mode, the sliding mechanism is used for driving the sliding plate to slide in the horizontal direction, and the lifting mechanism comprises a lifting assembly, two guide assemblies, a second connecting assembly and a second driving assembly; the guide assembly comprises a guide rail and a sliding block, the guide rail is fixedly arranged on the side wall of the sliding plate, and the sliding block is in sliding fit with the guide rail; the lifting assembly comprises a connecting block, two lifting blocks and two second bearing blocks; two second carrier blocks are fixed on two sliders respectively, the both ends of connecting block and the lateral wall fixed connection of two elevator blocks, the one end of two second carrier blocks respectively with the bottom fixed connection of two elevator blocks, second coupling assembling and the second drive assembly that is used for driving the connecting block and slides. This application can carry a plurality of building elements simultaneously to the conveyer on.

Description

Conveyer for assembly type building structure

Technical Field

The application relates to the field of transportation devices, in particular to a transportation device for an assembly type building structure.

Background

With the continuous development of society, the living standard of people is continuously improved, and the high quality and the high efficiency become the life lines of the development of various industries. The building industry has grown to the modernization today and has made a great leap. Especially, the application of modern technology in the building industry, with the rapid development of assembly type buildings, the application of assembly type building structures is very common, various building components are increasing day by day, and the installation and transportation modes of the building components are also various.

In the related art, chinese patent with publication number CN209721419 discloses an assembly type transportation device for building structure, which can also be referred to as an assembly type transportation device for building structure, and includes a base, a sleeve is fixed on an outer wall of a top of the base by screws, a piston is slidably connected to an inner wall of the sleeve, a support rod is welded on an outer wall of a top of the piston, a damping spring is sleeved on an outer wall of the support rod, a transportation box is fixed on an outer wall of a top of the support rod by screws, a box cover is connected on an outer wall of a top of the transportation box by an ammonium chain, a handle is fixed on an outer wall of a top of the box cover by screws, a hydraulic cylinder is fixed on an inner wall of a bottom of the transportation box by screws, a sliding plate is fixed on one end of a piston rod of the hydraulic cylinder by screws, a foam pad is bonded on an outer wall of a top of the sliding plate, a push plate vertically arranged is, the outer wall of the push plate, which is positioned below the handle, is fixed with the storage battery through a screw, and one side of the outer wall of the top of the base is fixed with a hoisting mechanism through a screw.

In view of the above-mentioned related art, the inventors found the following drawbacks in the course of their work: in the process of transporting the building components, the hoisting mechanism can only hoist a single building component to the transporting device at each time, but cannot hoist a plurality of building components to the transporting device at the same time.

Disclosure of Invention

In order to be able to carry a plurality of building elements to a transport device simultaneously, the application provides a transport device for an assembly building structure.

The application provides a conveyer for assembly type structure adopts following technical scheme:

a transport device for an assembly type building structure comprises a bearing platform, a sliding plate, a sliding mechanism and a lifting mechanism;

the sliding plate is arranged on the bearing table in a sliding mode, and the sliding mechanism is used for driving the sliding plate to slide in the horizontal direction;

the lifting mechanism comprises a lifting assembly, two guide assemblies, a second connecting assembly and a second driving assembly;

the guide assembly comprises a guide rail and a sliding block, the guide rail is fixedly arranged on the side wall of the sliding plate, and the sliding block is in sliding fit with the guide rail;

the lifting assembly comprises a connecting block, two lifting blocks and two second bearing blocks; two the second carrier block is fixed in two respectively on the slider, the both ends of connecting block and two the lateral wall fixed connection of lifter, two the one end of second carrier block respectively with two the bottom fixed connection of lifter, second coupling assembling and second drive assembly are used for the drive the connecting block slides along vertical direction.

By adopting the technical scheme, when the building element needs to be carried, the second connecting assembly and the second driving assembly drive the second bearing block to slide downwards; the sliding mechanism drives the sliding plate to slide towards the direction close to the building components, and the sliding plate drives the second bearing blocks to slide so that the two second bearing blocks slide to the lower parts of the building components; the second connecting assembly and the second driving assembly drive the second bearing block to slide upwards, and the second bearing block simultaneously drives the plurality of building components to slide upwards; when a plurality of building components slide above the bearing table, the sliding mechanism drives the sliding plate to slide towards the direction close to the bearing table, and the sliding plate drives the second bearing block to slide towards the direction close to the bearing table, so that the plurality of building components are all positioned right above the bearing table; second coupling assembling and second drive assembly drive second carrier block slide downwards, and the second carrier block drives a plurality of building element simultaneously and slides downwards to on carrying a plurality of building element to the plummer simultaneously, compare in background art, improved staff's transport building element's efficiency.

Optionally, the sliding mechanism includes two sliding assemblies, a first connecting assembly and a first driving assembly, and the two sliding assemblies are respectively fixed to two opposite side walls of the plummer;

the sliding assembly comprises two first supporting blocks and a screw rod; the lower surface of the sliding plate is fixedly provided with two positioning blocks, and the side walls of the two positioning blocks are respectively abutted against two opposite side walls of the bearing table; the screw rod penetrates through the positioning block and is in threaded fit with the positioning block; the two first supporting blocks are fixedly arranged on the side wall of the bearing table, and two ends of the screw rod are respectively in rotating connection with the two first supporting blocks;

the first connecting assembly and the first driving assembly are fixedly arranged on the bearing table, and the first connecting assembly and the first driving assembly are used for driving the two screw rods to rotate, so that the two positioning blocks are driven to slide along the length direction of the screw rods.

Through adopting above-mentioned technical scheme, it is rotatory through two lead screws of first coupling assembling and first drive assembly drive, two lead screws drive two locating pieces respectively and slide along the length direction of lead screw, two locating pieces drive the slide plate simultaneously and slide along the length direction of lead screw, the slide plate drives two elevator blocks and slides along the length direction of lead screw, two elevator blocks drive two second carrier blocks respectively and slide along the length direction of lead screw, so that two second carrier blocks can not only slide along the horizontal direction, and can slide along vertical direction.

Optionally, the first connecting assembly includes a mounting bracket, a first reversing lever, two first bevel gears and two second bevel gears; the mounting frame is fixedly arranged on the side wall of the bearing table, the first reversing rod penetrates through the mounting frame and is rotatably connected with the mounting frame, two ends of the first reversing rod are respectively penetrated through the two first bevel gears, and two ends of the first reversing rod are respectively fixedly connected with the two first bevel gears; one end of each of the two screw rods is fixedly provided with a first driving rod, one end of each of the two first driving rods, which is far away from the screw rod, penetrates through the two second bevel gears respectively, the two first driving rods are fixedly connected with the two second bevel gears respectively, and the two first bevel gears are meshed with the two second bevel gears respectively; the first driving assembly is used for driving the first reversing rod to rotate.

Through adopting above-mentioned technical scheme, it is rotatory through first reversing bar of drive assembly drive, the both ends of first reversing bar drive two first bevel gears simultaneously and rotate, two first bevel gears drive two second bevel gears respectively and rotate, two second bevel gears drive two first actuating levers respectively and rotate, two first actuating levers drive two lead screws respectively and rotate, two lead screws drive two locating pieces respectively and slide along the length direction of lead screw, two locating pieces drive the slide plate simultaneously and slide along the length direction of lead screw, time saving and labor saving.

Optionally, the first driving assembly comprises a first driving piece, a second reversing rod, a third bevel gear and a fourth bevel gear, which are meshed with each other; the bottom end of the second reversing rod penetrates through the mounting frame, and the bottom end of the second reversing rod is rotatably connected with the mounting frame; the top end of the second reversing rod penetrates through the third bevel gear, and the top end of the second reversing rod is fixedly connected with the third bevel gear; the fourth bevel gear is sleeved on the first reversing rod and fixedly connected with the first reversing rod; the first driving piece is used for driving the second reversing rod to rotate.

By adopting the technical scheme, the second reversing rod is driven to rotate by the first driving piece, the second reversing rod drives the third bevel gear to rotate, the third bevel gear drives the fourth bevel gear to rotate, and the fourth bevel gear drives the first reversing rod to rotate, so that time and labor are saved.

Optionally, the second connecting assembly comprises a connecting rod and a rocker, the top end of the connecting rod is rotatably connected with the connecting block, the bottom end of the connecting rod is hinged with the top end of the rocker, a second driving rod is fixedly arranged on the side wall of the bottom end of the rocker, and one end, far away from the rocker, of the second driving rod is rotatably connected with the sliding plate; the second driving assembly is used for driving the second driving rod to rotate.

Through adopting above-mentioned technical scheme, it is rotatory through two actuating levers of second drive assembly drive, the second actuating lever drives the bottom of rocker and rotates around the second actuating lever, the top of rocker drives the bottom of connecting rod and the top relative rotation of rocker, the top of connecting rod drives the connecting block and slides along vertical direction, the both ends of connecting block drive two elevator blocks simultaneously and slide along vertical direction, two elevator blocks drive two second carrier blocks respectively and slide along vertical direction, labour saving and time saving.

Optionally, the second driving assembly includes a second driving member, a spur gear, and a rack engaged with the spur gear; the straight gear is sleeved on the second driving rod and is fixedly connected with the second driving rod; the sliding plate is fixedly provided with a first bearing block, the rack is arranged on the first bearing block in a sliding mode, and the second driving piece is used for driving the rack to slide.

Through adopting above-mentioned technical scheme, slide through the second driving piece drive rack, the rack drives the spur gear rotation, and the spur gear drives the rotation of second actuating lever, has laborsaving effect.

Optionally, an angle steel is arranged between the second bearing block and the lifting block, the angle steel includes a first angle side and a second angle side which are fixedly connected, and the first angle side and the second angle side are perpendicular to each other; the side wall of the first corner edge abuts against the side wall of the lifting block, and the lower surface of the second corner edge abuts against the upper surface of the second bearing block; a bolt penetrates through the first corner edge and is in threaded fit with the lifting block; and bolts are also arranged on the second corner edges in a penetrating manner and are in threaded fit with the second bearing blocks.

Through adopting above-mentioned technical scheme, fixed elevator and second carrier block together through the angle steel, increased the fastness of being connected between elevator and the second carrier block to the upper surface that makes the second carrier block can bear more building elements.

Optionally, a sliding groove is formed in the upper surface of the first bearing block, the lower surface of the rack abuts against the bottom of the sliding groove, the two opposite side walls of the rack abut against the two opposite side walls of the sliding groove respectively, and the rack is in sliding fit with the sliding groove.

Through adopting above-mentioned technical scheme, the groove of sliding has the guide effect to the rack, has increased the stability that the rack slided.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the building element needs to be carried, the second connecting assembly and the second driving assembly drive the second bearing block to slide downwards; the sliding mechanism drives the sliding plate to slide towards the direction close to the building components, and the sliding plate drives the second bearing blocks to slide so that the two second bearing blocks slide to the lower parts of the building components; the second connecting assembly and the second driving assembly drive the second bearing block to slide upwards, and the second bearing block simultaneously drives the plurality of building components to slide upwards; when a plurality of building components slide above the bearing table, the sliding mechanism drives the sliding plate to slide towards the direction close to the bearing table, and the sliding plate drives the second bearing block to slide towards the direction close to the bearing table, so that the plurality of building components are all positioned right above the bearing table; the second connecting assembly and the second driving assembly drive the second bearing block to slide downwards, and the second bearing block simultaneously drives the plurality of building components to slide downwards simultaneously, so that the plurality of building components are simultaneously conveyed to the bearing table, and compared with the background technology, the efficiency of conveying the building components by workers is improved;

2. the two screw rods are driven to rotate through the first connecting assembly and the first driving assembly, the two screw rods respectively drive the two positioning blocks to slide along the length direction of the screw rods, the two positioning blocks simultaneously drive the sliding plate to slide along the length direction of the screw rods, the sliding plate drives the two lifting blocks to slide along the length direction of the screw rods, and the two lifting blocks respectively drive the two second bearing blocks to slide along the length direction of the screw rods, so that the two second bearing blocks can slide along the horizontal direction and can slide along the vertical direction;

3. the lifting block and the second bearing block are fixed together through the angle steel, so that the firmness of connection between the lifting block and the second bearing block is increased, and more building components can be borne by the upper surface of the second bearing block.

Drawings

Fig. 1 is a schematic structural view of a first view of a transportation device for a prefabricated building structure according to an embodiment of the present application.

Fig. 2 is a schematic structural view of a second perspective view of a transportation device for prefabricated building structures in the embodiment of the present application.

Fig. 3 is a schematic structural view of a third perspective view of a transportation device for prefabricated building structures in the embodiment of the present application.

Description of reference numerals: 1. a bearing table; 11. a support plate; 2. a slide plate; 21. positioning blocks; 22. a first bearing block; 221. a sliding groove; 222. a lowering tank; 223. a limiting rod; 3. a sliding mechanism; 31. a slipping component; 311. a first support block; 3111. a first fixed part; 312. a screw rod; 3121. a first drive lever; 32. a first connection assembly; 321. a mounting frame; 3211. a first mounting block; 3212. a second mounting block; 322. a first reversing lever; 323. a first bevel gear; 324. a second bevel gear; 33. a first drive assembly; 331. a first motor; 332. a second reversing lever; 333. a third bevel gear; 334. a fourth bevel gear; 4. a lifting mechanism; 41. a lifting assembly; 411. connecting blocks; 4111. a first rotating section; 412. a lifting block; 413. a second bearing block; 4131. a bearing part; 414. angle steel; 4141. a first corner edge; 4142. a second corner edge; 42. a guide assembly; 421. a guide rail; 422. a slider; 4221. a chute; 43. a second connection assembly; 431. a connecting rod; 4311. a second rotating section; 432. a rocker; 4321. a second drive lever; 44. a second drive assembly; 441. a spur gear; 442. a rack; 443. a cylinder; 5. a rolling mechanism; 51. a rolling component; 511. a first rotating shaft; 512. a roller; 52. a third connection assembly; 521. a second support block; 5211. a second fixed part; 522. a second rotation shaft; 523. a fifth bevel gear; 524. a sixth bevel gear; 525. a seventh bevel gear; 53. a third drive assembly; 531. a third rotation axis; 532. an eighth bevel gear; 533. a second motor.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses conveyer for assembly type building structure. Referring to fig. 1 and 2, the transport device for the prefabricated building structure includes a bearing platform 1, a sliding plate 2, a sliding mechanism 3, a lifting mechanism 4 and a rolling mechanism 5. The sliding plate 2 is arranged on the bearing platform 1 in a sliding mode, the sliding mechanism 3 is used for driving the sliding plate 2 to slide on the bearing platform 1, the lifting mechanism 4 is arranged on the sliding plate 2, the lifting mechanism 4 is used for conveying building components to the bearing platform 1, and the rolling mechanism 5 is used for driving the bearing platform 1 to move forwards.

With continued reference to fig. 1 and 2, in the present embodiment, the shape of the carrier 1 is a rectangular parallelepiped, and the horizontal cross section of the carrier 1 is a rectangle. The slide plate 2 is also shaped like a rectangular parallelepiped. In order to increase the stability of the sliding plate 2 sliding on the bearing platform 1, two positioning blocks 21 are integrally formed on the lower surface of the sliding plate 2, the two positioning blocks 21 are also rectangular, and the inner side walls of the two positioning blocks 21 are respectively abutted to two opposite side walls of the bearing platform 1. In order to further increase the stability of the sliding plate 2 on the bearing table 1, the side wall of the sliding plate 2 is welded with a first bearing block 22, the first bearing block 22 is also cuboid in shape, the lower surface of the first bearing block 22 abuts against the upper surface of the bearing table 1, and the first bearing block 22 is in sliding fit with the bearing table 1. So set up, two locating pieces 21 and first carrier block 22 all have the positioning action to slide plate 2, have increased the stability that slide plate 2 slided on plummer 1.

Referring to fig. 2, in the present embodiment, the sliding mechanism 3 includes two sliding assemblies 31, a first connecting assembly 32, and a first driving assembly 33. Two slip assemblies 31 are respectively installed in two relative lateral walls of plummer 1, and first connecting assembly 32 is used for connecting two slip assemblies 31, and first drive assembly 33 is used for driving the board 2 that slides on plummer 1.

With continued reference to fig. 2, in particular, each sliding assembly 31 includes two first support blocks 311 and a lead screw 312. The two first supporting blocks 311 are both rectangular solids, and the two first supporting blocks 311 are parallel to each other. In order to increase the convenience of the worker for installing and detaching the first supporting block 311, the first fixing portions 3111 are integrally formed on two opposite side walls of the first supporting block 311, and each of the first fixing portions 3111 is shaped like a rectangular parallelepiped. All wear to be equipped with the bolt on every first fixed part 3111, every bolt all with plummer 1 screw-thread fit to be fixed in the lateral wall of plummer 1 with first fixed part 3111, and then be fixed in the lateral wall of plummer 1 with first supporting block 311. The length direction of the screw 312 is the horizontal direction, and both ends of the screw 312 are respectively rotatably connected with the two first supporting blocks 311. The positioning block 21 is located between the two first supporting blocks 311, the screw 312 passes through the positioning block 21, and the screw 312 is in threaded fit with the positioning block 21. So set up, first drive assembly 33 can drive the lead screw 312 in two slip subassemblies 31 rotatory simultaneously under the effect of first connecting element 32, it is worth mentioning that, in this embodiment, the spiral direction of two lead screws 312 is symmetrical about plummer 1 each other, and the direction of rotation of two lead screws 312 is opposite simultaneously to make two lead screws 312 can drive two locating pieces 21 and slide along the length direction of lead screw 312, and then drive the length direction of slide block 2 along lead screw 312 and slide.

With continued reference to fig. 2, in particular, the first linkage assembly 32 includes a mounting bracket 321, a first reversing lever 322, two first bevel gears 323, and two second bevel gears 324. The mounting frame 321 includes two first mounting blocks 3211 and a second mounting block 3212, the two first mounting blocks 3211 and the second mounting block 3212 are both welded to the side wall of the carrier platform 1, and the first mounting block 3211 and the second mounting block 3212 are rectangular parallelepiped in shape. The two first mounting blocks 3211 are parallel to each other, and the first mounting block 3211 and the second mounting block 3212 are perpendicular to each other. The length direction of the first direction changing rod 322 is a horizontal direction, two ends of the first direction changing rod 322 respectively penetrate through the two first mounting blocks 3211, and the first direction changing rod 322 is rotatably connected with the two first mounting blocks 3211. Two ends of the first reversing rod 322 penetrate through the centers of the two first bevel gears 323 respectively, and two ends of the first reversing rod 322 are fixedly connected with the two first bevel gears 323 respectively. The first driving rods 3121 are integrally formed at one end of each of the two lead screws 312, the ends of the two first driving rods 3121 far away from the lead screws 312 penetrate through the centers of the two second bevel gears 324, the two first driving rods 3121 are fixedly connected with the two second bevel gears 324, and the two first bevel gears 323 are engaged with the two second bevel gears 324. The first driving assembly 33 is used for driving the first reversing lever 322 to rotate.

With continued reference to fig. 2, in particular, the first drive assembly 33 includes a first drive member 331, a second reversing lever 332, a third bevel gear 333 and a fourth bevel gear 334 that mesh with each other. The length direction of the second reversing rod 332 is vertical, the bottom end of the second reversing rod 332 penetrates through the second mounting block 3212, and the bottom end of the second reversing rod 332 is rotatably connected with the second mounting block 3212. The top end of the second reversing lever 332 penetrates through the center of the third bevel gear 333, and the top end of the second reversing lever 332 is fixedly connected with the third bevel gear 333. The fourth bevel gear 334 is sleeved on the first reversing rod 322, the fourth bevel gear 334 is fixedly connected with the first reversing rod 322, and the fourth bevel gear 334 is located between the two first mounting blocks 3211. In this embodiment, the first driving member is a first motor 331, the first motor 331 is mounted on the lower surface of the second mounting block 3212, and an output shaft of the first motor 331 is fixedly connected to the bottom end of the second reversing lever 332.

With reference to fig. 2, the second reversing lever 332 is driven to rotate by the first motor 331, the second reversing lever 332 drives the third bevel gear 333 to rotate, the third bevel gear 333 drives the fourth bevel gear 334 to rotate, the fourth bevel gear 334 drives the first reversing lever 322 to rotate, two ends of the first reversing lever 322 simultaneously drive the two first bevel gears 323 to rotate, the two first bevel gears 323 respectively drive the two second bevel gears 324 to rotate, the two second bevel gears 324 respectively drive the two first driving levers 3121 to rotate, the two first driving levers 3121 respectively drive the two screw rods 312 to rotate, the two screw rods 312 respectively drive the two positioning blocks 21 to slide along the length direction of the screw rods 312, and the two positioning blocks 21 simultaneously drive the sliding plate 2 to slide along the length direction of the screw rods 312, which is time-saving and labor-saving.

Referring to fig. 1 and 2, in the present embodiment, the lifting mechanism 4 includes a lifting assembly 41, two guide assemblies 42, a connecting assembly, and a second driving assembly 44. The lifting assembly 41 is used to transport the building element to the upper surface of the load bearing platform 1. Two guide assemblies 42 are respectively installed on two sides of the sliding plate 2, and the two guide assemblies 42 are used for increasing the stability of the lifting assembly 41 in sliding along the vertical direction. The connecting assembly is used for connecting the lifting assembly 41 and the second driving assembly 44. The second driving assembly 44 is used for driving the lifting assembly 41 to slide along the vertical direction.

Referring to fig. 1, in particular, each guide assembly 42 comprises a guide rail 421 and two sliders 422. The length direction of guide rail 421 is vertical direction, and the lateral wall butt of guide rail 421 is in the lateral wall of slide plate 2, and the top of guide rail 421 flushes with the top of slide plate 2, and the bottom of guide rail 421 flushes with the upper surface of first carrier block 22. Wear to be equipped with a plurality of bolt on the guide rail 421, a plurality of bolt is arranged along the length direction of guide rail 421 equidistant, a plurality of bolt all with the 2 screw-thread fit of slide plate to be fixed in the lateral wall of slide plate 2 with guide rail 421. Two sliders 422 all offer the spout 4221 that supplies guide rail 421 to pass towards the lateral wall of guide rail 421, and the length direction of spout 4221 is vertical direction, and the both ends of spout 4221 all are the opening setting. The guide rail 421 sequentially passes through the sliding grooves 4221 on the two sliding blocks 422, and the two sliding blocks 422 are in sliding fit with the guide rail 421. So set up, guide rail 421 has the guide effect to two sliders 422 to make two sliders 422 in the stable slip of vertical direction.

Referring to fig. 2, in particular, the lifting assembly 41 includes a connection block 411, two lifting blocks 412 and two second bearing blocks 413. The connecting block 411, the lifting block 412 and the second bearing block 413 are all rectangular solids. The two lifting blocks 412 are respectively installed on the sliding blocks 422 on the two sides of the sliding plate 2, and the length directions of the two lifting blocks 412 are vertical directions. The connecting block 411 is fixed at the top ends of the two lifting blocks 412, and the two second bearing blocks 413 are respectively fixed at the bottom ends of the two lifting blocks 412.

With continued reference to fig. 2, specifically, eight bolts are disposed through the side wall of the top end of each connecting block 411, wherein four bolts are in threaded fit with one of the sliding blocks 422, and the other four bolts are in threaded fit with the other sliding block 422, so as to fix the connecting block 411 on the two sliding blocks 422.

Referring to fig. 1 and 2, in order to make the two lifting blocks 412 synchronously slide in the vertical direction, both ends of the connection block 411 are respectively welded to the sidewalls of the two lifting blocks 412, and the upper surface of the connection block 411 is flush with the top ends of the two lifting blocks 412. The length directions of the two second bearing blocks 413 are horizontal directions, and the length direction of the second bearing block 413 is the same as the length direction of the screw 312. One end of each second bearing block 413 facing the lifting block 412 is welded to the side wall of the bottom end of the lifting block 412, and the lower surface of the second bearing block 413 is flush with the lower surface of the lifting block 412.

Referring to fig. 1, in order to increase the firmness of the connection between the end of the second bearing block 413 and the bottom end of the lifting block 412, a bearing portion 4131 is integrally formed at one end of the second bearing block 413 facing the lifting block 412, the bearing portion 4131 is shaped as a rectangular parallelepiped, the lower surface of the bearing portion 4131 is flush with the lower surface of the second bearing block 413, and the upper surface of the bearing portion 4131 is located above the second bearing block 413. The side wall of the bearing part 4131 close to the lifting block 412 is welded with the side wall of the lifting block 412 away from the sliding plate 2. The bearing part 4131 increases a contact area between the second bearing block 413 and the lifting block 412, thereby increasing firmness of connection between the second bearing block 413 and the lifting block 412.

With continued reference to fig. 1, in order to further increase the firmness of the connection between the end of the second bearing block 413 and the bottom end of the lifting block 412, an angle iron 414 is disposed between the second bearing block 413 and the lifting block 412. In the present embodiment, the angle iron 414 includes a first corner 4141 and a second corner 4142 which are integrally formed, the first corner 4141 and the second corner 4142 are perpendicular to each other, and both the first corner 4141 and the second corner 4142 are rectangular. The sidewall of the first corner 4141 abuts against the sidewall of the lifting block 412, and the lower surface of the second corner 4142 abuts against the upper surface of the second bearing block 413. Three bolts are arranged on the first corner 4141 in a penetrating manner and are in threaded fit with the lifting block 412, so that the first corner 4141 is fixed on the side wall of the lifting block 412. The second corner 4142 is also provided with three bolts, and the three bolts are in threaded engagement with the second bearing block 413, so that the second corner 4142 is fixed on the upper surface of the second bearing block 413.

Referring to fig. 2, in particular, the second connecting assembly 43 includes a link 431 and a rocker 432. Specifically, connecting block 411 deviates from the welding of the lateral wall of slide plate 2 and has first rotating part 4111, and first rotating part 4111's shape is the cylinder. One end of the first rotating portion 4111, which is far away from the connecting block 411, passes through a top end of the connecting rod 431, and the top end of the connecting rod 431 is rotatably connected around the first rotating portion 4111. The bottom end of the connecting rod 431 is penetrated by a second rotating portion 4311, the second rotating portion 4311 is cylindrical, and the bottom end of the connecting rod 431 is rotatably connected with the second rotating portion 4311. The second rotating portion 4311 is simultaneously inserted into the top end of the rocker 432, and the top end of the rocker 432 is rotatably connected to the second rotating portion 4311. The bottom end of the rocker 432 is welded with a second driving rod 4321 towards the side wall of the sliding plate 2, and one end of the second driving rod 4321 far away from the rocker 432 is rotatably connected with the sliding plate 2.

With continued reference to fig. 2, in particular, second drive assembly 44 includes a second drive member, a spur gear 441, and a rack 442 intermeshed with spur gear 441. The straight gear 441 is sleeved on the second driving rod 4321, the straight gear 441 is fixedly connected with the second driving rod 4321, and the rack 442 is slidably disposed on the upper surface of the first bearing block 22. In this embodiment, the second driving member is a cylinder 443, the cylinder 443 is installed on the upper surface of the first bearing block 22, and an output shaft of the cylinder 443 is fixedly connected with one end of the rack 442.

With reference to fig. 2, in order to increase the sliding stability of the rack 442, the sliding groove 221 is formed in the upper surface of the first bearing block 22, the length direction of the sliding groove 221 is the same as the length direction of the first bearing block 22, the lower surface of the rack 442 abuts against the bottom of the sliding groove 221, two opposite side walls of the rack 442 abut against two opposite side walls of the sliding groove 221, and the rack 442 is in sliding fit with the sliding groove 221. With this arrangement, the two side walls of the sliding groove 221 guide the rack 442, so that the rack 442 slides stably along the length direction of the sliding groove 221.

With reference to fig. 2, in order to make the output shaft of the cylinder 443 and the rack 442 on the same horizontal plane, the upper surface of the first carrier block 22 is provided with a lowering groove 222, and the lower surface of the cylinder 443 abuts against the bottom of the lowering groove 222. So set up, it slides in groove 221 to slide to drive rack 442 through cylinder 443, rack 442 drives spur gear 441 rotatory, spur gear 441 drives second actuating lever 4321 rotatory, second actuating lever 4321 drives the bottom of rocker 432 and uses second actuating lever 4321 as the rotation of axes, the one end that second actuating lever 4321 was kept away from to rocker 432 drives the bottom of connecting rod 431 around second rotating part 4311 rotatory, connecting rod 431's top is rotatory around first rotating part 4111 simultaneously, thereby it slides along vertical direction to drive first rotating part 4111, first rotating part 4111 drives connecting block 411 and slides along vertical direction, the both ends of connecting block 411 drive two elevator blocks 412 simultaneously and slide along vertical direction, two elevator blocks 412 drive two second carrier blocks 413 respectively and slide along vertical direction, two second carrier blocks 413 drive building element and slide along vertical direction.

With continued reference to fig. 2, in order to limit the connecting block 411 from colliding with the spur gear 441 in the process of sliding in the vertical direction, two limiting rods 223 are fixedly arranged on the upper surface of the first bearing block 22, and the two limiting rods 223 are both rectangular solids. Specifically, the length directions of the two limiting rods 223 are vertical directions, the bottom ends of the two limiting rods 223 are flush with the upper surface of the first bearing block 22, and the top ends of the two limiting rods 223 are located above the spur gear 441. So set up, when connecting block 411 at the in-process that slides down, connecting block 411's lower surface butt when two gag lever post 223 tops, connecting block 411 can't continue to slide down, all has the guard action to connecting block 411 and spur gear 441.

Referring to fig. 3, in the present embodiment, the rolling mechanism 5 includes two rolling assemblies 51, two third connecting assemblies 52, and a third driving assembly 53. Specifically, the lower surface welding of plummer 1 has two backup pads 11, and two backup pads 11 are parallel to each other, and the shape of two backup pads 11 is the cuboid, and the length direction of two backup pads 11 all is the same with the length direction of plummer 1, and two rolling assemblies 51 all rotate and set up on two backup pads 11. Further, each rolling assembly 51 includes a first rotating shaft 511 and two rollers 512, a length direction of the first rotating shaft 511 is a horizontal direction, the length direction of the first rotating shaft 511 is perpendicular to a length direction of the supporting plate 11, two ends of the first rotating shaft 511 respectively penetrate through the two supporting plates 11, the first rotating shaft 511 is rotatably connected with the two supporting plates 11, and two ends of the first rotating shaft 511 are respectively fixedly connected with the two rollers 512. The third connecting assembly 52 and the third driving assembly 53 are used for driving the two first rotating shafts 511 to rotate.

With continued reference to fig. 3, two third connection assemblies 52 are each located between two support plates 11. Specifically, each of the third connecting members 52 includes a second supporting block 521, a second rotating shaft 522, a fifth bevel gear 523, a sixth bevel gear 524, and a seventh bevel gear 525. The fifth bevel gear 523 is sleeved on the first rotating shaft 511, the fifth bevel gear 523 is fixedly connected with the first rotating shaft 511, and the fifth bevel gear 523 is located between the two support plates 11. The second support block 521 is shaped like a rectangular parallelepiped, and the second support block 521 is fixed to the lower surface of the platform 1. The second rotating shaft 522 passes through the second support block 521, and the second rotating shaft 522 is rotatably connected to the second support block 521. The sixth bevel gear 524 is sleeved on one end of the second rotating shaft 522 close to the first rotating shaft 511, the sixth bevel gear 524 is fixedly connected with the second rotating shaft 522, and the fifth bevel gear 523 is engaged with the sixth bevel gear 524. The seventh bevel gear 525 is sleeved at one end of the third rotating shaft 531, which is far away from the fifth rotating shaft, the seventh bevel gear 525 is fixedly connected with the third rotating shaft 531, and the third driving assembly 53 is used for driving the two seventh bevel gears 525 to rotate at the same time.

With continued reference to fig. 3, in order to increase the convenience of the worker for installing and detaching the second support block 521, the second fixing portions 5211 are integrally formed on two opposite sidewalls of the second support block 521, and each of the second fixing portions 5211 is shaped like a rectangular parallelepiped. The upper surface of the second fixing portion 5211 is flush with the upper surface of the second supporting block 521, and the upper surface of the second supporting block 521 abuts against the lower surface of the platform 1. Bolts are arranged on each second fixing portion 5211 in a penetrating manner, and each bolt is in threaded fit with the bearing platform 1, so that the second fixing portion 5211 is fixed on the lower surface of the bearing platform 1, and the second support block 521 is fixed on the lower surface of the bearing platform 1.

With continued reference to FIG. 3, in particular, the third drive assembly 53 includes a third driver, a third rotational shaft 531 and an eighth bevel gear 532. Two ends of the third rotating shaft 531 penetrate through the two support plates 11, the third rotating shaft 531 is rotatably connected with the two support plates 11, the eighth bevel gear 532 is sleeved on the third rotating shaft 531, and the eighth bevel gear 532 is fixedly connected with the third rotating shaft 531. It is worth mentioning that two third connecting members 52 are symmetrically disposed at both sides of the third rotating shaft 531, and the eighth bevel gear 532 is simultaneously engaged with the two seventh bevel gears 525. In this embodiment, the third driving member is a second motor 533, the second motor 533 is mounted on one of the supporting plates 11, and an output shaft of the second motor 533 is fixedly connected to one end of the third rotating shaft 531.

With continued reference to fig. 3, the third rotating shaft 531 is driven by the second motor 533 to rotate, the third rotating shaft 531 drives the eighth bevel gear 532 to rotate, the eighth bevel gear 532 drives the two seventh bevel gears 525 to rotate simultaneously, the two seventh bevel gears 525 drive the two second rotating shafts 522 to rotate respectively, the two second rotating shafts 522 drive the two sixth bevel gears 524 to rotate respectively, the two sixth bevel gears 524 drive the two first rotating shafts 511 to rotate simultaneously, and each first rotating shaft 511 drives the two rollers 512 to roll on the ground simultaneously, so that the four rollers 512 drive the transportation device to advance, thereby transporting the building component to a designated place.

The implementation principle of the transport device for the assembly type building structure in the embodiment of the application is as follows:

the cylinder 443 drives the rack 442 to slide in the sliding groove 221 toward a direction close to the cylinder 443, the rack 442 drives the spur gear 441 to rotate, the spur gear 441 drives the second driving rod 4321 to rotate, the second driving rod 4321 drives the bottom end of the rocker 432 to rotate around the second driving rod 4321, one end of the rocker 432, which is far away from the second driving rod 4321, drives the bottom end of the connecting rod 431 to rotate around the second rotating portion 4311, and simultaneously the top end of the connecting rod 431 rotates around the first rotating portion 4111, so as to drive the first rotating portion 4111 to slide downwards, the first rotating portion 4111 drives the connecting block 411 to slide downwards, two ends of the connecting block 411 simultaneously drive the two lifting blocks 412 to slide downwards, and the two lifting blocks 412 respectively drive the two second bearing blocks 413 to slide downwards, so as to enable the two second bearing blocks 413 to slide to the;

the second reversing rod 332 is driven to rotate by the first motor 331, the second reversing rod 332 drives the third bevel gear 333 to rotate, the third bevel gear 333 drives the fourth bevel gear 334 to rotate, the fourth bevel gear 334 drives the first reversing rod 322 to rotate, two ends of the first reversing rod 322 simultaneously drive the two first bevel gears 323 to rotate, the two first bevel gears 323 respectively drive the two second bevel gears 324 to rotate, the two second bevel gears 324 respectively drive the two first driving rods 3121 to rotate, the two first driving rods 3121 respectively drive the two screw rods 312 to rotate, the two screw rods 312 respectively drive the two positioning blocks 21 to slide towards the direction far away from the first motor 331, the two positioning blocks 21 simultaneously drive the sliding plate 2 to slide towards the direction far away from the first motor 331, so that the two second bearing blocks 413 are simultaneously inserted into the lower surfaces of the plurality of building elements;

the rack 442 is driven to slide in the sliding groove 221 towards a direction far away from the cylinder 443 by the cylinder 443, the rack 442 drives the spur gear 441 to rotate, the spur gear 441 drives the second driving rod 4321 to rotate, the second driving rod 4321 drives the bottom end of the rocker 432 to rotate around the second driving rod 4321, one end of the rocker 432 far away from the second driving rod 4321 drives the bottom end of the connecting rod 431 to rotate around the second rotating part 4311, meanwhile, the top end of the connecting rod 431 rotates around the first rotating part 4111, so that the first rotating part 4111 is driven to slide upwards, the first rotating part 4111 drives the connecting block 411 to slide upwards, two ends of the connecting block 411 simultaneously drive the two lifting blocks 412 to slide upwards, the two lifting blocks 412 respectively drive the two second bearing blocks 413 to slide upwards, and the two second bearing blocks 413 simultaneously drive all the building components to slide upwards, so that all the building components are located above the bearing table 1;

then, the second reversing rod 332 is driven to rotate by the first motor 331, the second reversing rod 332 drives the third bevel gear 333 to rotate, the third bevel gear 333 drives the fourth bevel gear 334 to rotate, the fourth bevel gear 334 drives the first reversing rod 322 to rotate, two ends of the first reversing rod 322 simultaneously drive the two first bevel gears 323 to rotate, the two first bevel gears 323 respectively drive the two second bevel gears 324 to rotate, the two second bevel gears 324 respectively drive the two first driving rods 3121 to rotate, the two first driving rods 3121 respectively drive the two screw rods 312 to rotate, the two screw rods 312 respectively drive the two positioning blocks 21 to slide towards the direction close to the first motor 331, the two positioning blocks 21 simultaneously drive the sliding plate 2 to slide towards the direction close to the first motor 331, so that the plurality of building components are located above the bearing table 1;

the rack 442 is driven by the cylinder 443 to slide in the sliding groove 221 in a direction close to the cylinder 443, the rack 442 drives the spur gear 441 to rotate, the spur gear 441 drives the second driving rod 4321 to rotate, the second driving rod 4321 drives the bottom end of the rocker 432 to rotate around the second driving rod 4321, one end of the rocker 432, which is far away from the second driving rod 4321, drives the bottom end of the connecting rod 431 to rotate around the second rotating portion 4311, and simultaneously the top end of the connecting rod 431 rotates around the first rotating portion 4111, thereby driving the first rotating portion 4111 to slide downwards, the first rotating portion 4111 drives the connecting block 411 to slide downwards, both ends of the connecting block 411 simultaneously drive the two lifting blocks 412 to slide downwards, the two lifting blocks 412 respectively drive the two second bearing blocks 413 to slide downwards, so that the lower surface of the lowest building component abuts against the upper surface of the bearing platform 1, thereby all the building components are carried to the upper surface of the bearing platform 1 at one, compare in background art, the conveyer can be simultaneously with a plurality of building element transport to the conveyer on, improved the efficiency of conveyer transportation building element.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The utility model provides a conveyer for assembly type building structure which characterized in that: comprises a bearing table (1), a sliding plate (2), a sliding mechanism (3) and a lifting mechanism (4);

the sliding plate (2) is arranged on the bearing table (1) in a sliding mode, and the sliding mechanism (3) is used for driving the sliding plate (2) to slide in the horizontal direction;

the lifting mechanism (4) comprises a lifting component (41), two guide components (42), a second connecting component (43) and a second driving component (44);

the guide assembly (42) comprises a guide rail (421) and a sliding block (422), the guide rail (421) is fixedly arranged on the side wall of the sliding plate (2), and the sliding block (422) is in sliding fit with the guide rail (421);

the lifting assembly (41) comprises a connecting block (411), two lifting blocks (412) and two second bearing blocks (413); two second carrier block (413) are fixed in two respectively on slider (422), the both ends of connecting block (411) with two the lateral wall fixed connection of lifter (412), two the one end of second carrier block (413) respectively with two the bottom fixed connection of lifter (412), second coupling assembling (43) and second drive assembly (44) are used for the drive connecting block (411) slide along vertical direction.

2. The transport apparatus for a fabricated building structure according to claim 1, wherein: the sliding mechanism (3) comprises two sliding assemblies (31), a first connecting assembly (32) and a first driving assembly (33), wherein the two sliding assemblies (31) are respectively fixed on two opposite side walls of the bearing table (1);

the sliding assembly (31) comprises two first supporting blocks (311) and a screw rod (312); two positioning blocks (21) are fixedly arranged on the lower surface of the sliding plate (2), and the side walls of the two positioning blocks (21) are respectively abutted against two opposite side walls of the bearing table (1); the screw rod (312) penetrates through the positioning block (21), and the screw rod (312) is in threaded fit with the positioning block (21); the two first supporting blocks (311) are fixedly arranged on the side wall of the bearing table (1), and two ends of the screw rod (312) are respectively in rotating connection with the two first supporting blocks (311);

the first connecting assembly and the first driving assembly (33) are fixedly arranged on the bearing table (1), and the first connecting assembly (32) and the first driving assembly (33) are used for driving the two screw rods (312) to rotate, so that the two positioning blocks (21) are driven to slide along the length direction of the screw rods (312).

3. The transport apparatus for a fabricated building structure according to claim 2, wherein: the first connecting component (32) comprises a mounting frame (321), a first reversing rod (322), two first bevel gears (323) and two second bevel gears (324); the mounting frame (321) is fixedly arranged on the side wall of the bearing table (1), the first reversing rod (322) penetrates through the mounting frame (321), the first reversing rod (322) is rotatably connected with the mounting frame (321), two ends of the first reversing rod (322) are respectively penetrated through the two first bevel gears (323), and two ends of the first reversing rod (322) are respectively fixedly connected with the two first bevel gears (323); one end of each of the two screw rods (312) is fixedly provided with a first driving rod (3121), one end, far away from the screw rod (312), of each of the two first driving rods (3121) is respectively arranged on two second bevel gears (324) in a penetrating manner, the two first driving rods (3121) are respectively fixedly connected with the two second bevel gears (324), and the two first bevel gears (323) are respectively meshed with the two second bevel gears (324); the first driving assembly (33) is used for driving the first reversing rod (322) to rotate.

4. The transport apparatus for a fabricated building structure according to claim 3, wherein: the first driving assembly (33) comprises a first driving piece, a second reversing rod (332), a third bevel gear (333) and a fourth bevel gear (334) which are meshed with each other; the bottom end of the second reversing rod (332) penetrates through the mounting frame (321), and the bottom end of the second reversing rod (332) is rotatably connected with the mounting frame (321); the top end of the second reversing rod (332) penetrates through the third bevel gear (333), and the top end of the second reversing rod (332) is fixedly connected with the third bevel gear (333); the fourth bevel gear (334) is sleeved on the first reversing rod (322), and the fourth bevel gear (334) is fixedly connected with the first reversing rod (322); the first driving piece is used for driving the second reversing rod (332) to rotate.

5. The transport apparatus for a fabricated building structure according to claim 1, wherein: the second connecting assembly (43) comprises a connecting rod (431) and a rocker (432), the top end of the connecting rod (431) is rotatably connected with the connecting block (411), the bottom end of the connecting rod (431) is hinged with the top end of the rocker (432), a second driving rod (4321) is fixedly arranged on the side wall of the bottom end of the rocker (432), and one end, far away from the rocker (432), of the second driving rod (4321) is rotatably connected with the sliding plate (2); the second driving assembly (44) is used for driving the second driving rod (4321) to rotate.

6. The transport apparatus for a fabricated building structure according to claim 1, wherein: the second driving assembly (44) comprises a second driving piece, a straight gear (441) and a rack (442) meshed with the straight gear (441); the straight gear (441) is sleeved on the second driving rod (4321), and the straight gear (441) is fixedly connected with the second driving rod (4321); a first bearing block (22) is fixedly arranged on the sliding plate (2), the rack (442) is arranged on the first bearing block (22) in a sliding mode, and the second driving piece is used for driving the rack (442) to slide.

7. The transport apparatus for a fabricated building structure according to claim 1, wherein: an angle steel (414) is arranged between the second bearing block (413) and the lifting block (412), the angle steel (414) comprises a first angle edge (4141) and a second angle edge (4142) which are fixedly connected, and the first angle edge (4141) and the second angle edge (4142) are perpendicular to each other; the side wall of the first corner edge (4141) abuts against the side wall of the lifting block (412), and the lower surface of the second corner edge (4142) abuts against the upper surface of the second bearing block (413); a bolt penetrates through the first corner edge (4141) and is in threaded fit with the lifting block (412); the second corner edge (4142) is also provided with a bolt in a penetrating way, and the bolt is in threaded fit with the second bearing block (413).

8. The transport apparatus for a fabricated building structure according to claim 6, wherein: the upper surface of the first bearing block (22) is provided with a sliding groove (221), the lower surface of the rack (442) abuts against the groove bottom of the sliding groove (221), two opposite side walls of the rack (442) abut against the two opposite side walls of the sliding groove (221) respectively, and the rack (442) is matched with the sliding groove (221) in a sliding manner.