CN112302206A

CN112302206A - Alignment angle splicing device for assembling assembled wallboard

Info

Publication number: CN112302206A
Application number: CN202011333054.1A
Authority: CN
Inventors: 曹艳艳; 刘奇; 徐华; 施清瀚; 姚薇; 孔艳; 钟学轩
Original assignee: Jinan First Construction Group Co Ltd
Current assignee: Jinan First Construction Group Co Ltd
Priority date: 2020-11-24
Filing date: 2020-11-24
Publication date: 2021-02-02
Anticipated expiration: 2040-11-24
Also published as: CN112302206B

Abstract

The invention discloses an alignment angle splicing device for assembling an assembled wallboard, which comprises a base, a motor and a transmission belt, wherein the motor is fixedly installed inside the base, a first driving mechanism and a second driving mechanism are respectively sleeved on the surface of one extending end of a driving shaft in the motor, the transmission belt is arranged inside the first driving mechanism, the other end of the transmission belt is meshed with a driven belt pulley, and a reciprocating screw rod is connected with the internal thread of the driven belt pulley. This assembled wallboard assembly is with counterpoint angle splicing apparatus, it is rotatory to drive first actuating mechanism when the motor corotation, it is rotatory to make the drive belt drive driven pulley, pass through the intermeshing of rack and roller gear this moment, make the rack unable rotatory, thereby make driven pulley drive threaded connection's reciprocal lead screw slide, and then make the rack drive between the roller gear of symmetric distribution in opposite directions or the rotation dorsad, the work of adjusting the angle of concatenation has been made things convenient for, holistic suitability has been improved.

Description

Alignment angle splicing device for assembling assembled wallboard

Technical Field

The invention relates to the technical field of building construction, in particular to an alignment angle splicing device for assembling an assembled wallboard.

Background

Along with the development and progress of modern technology, the requirement of human beings on the living environment is higher and higher, so that the building construction can be generally carried out only in the daytime of working days, the requirement on the efficiency of the building construction is higher and higher, and the assembly type building is developed greatly, the assembly type building comprises a plurality of types, wherein the assembly type wallboard is formed by directly carrying out a large amount of field operation in the traditional construction mode in a factory, firstly, the wallboard is processed and manufactured in the factory, then, the wallboard is transported to a construction site for splicing and assembling, the efficiency of wallboard installation is greatly improved, a splicing device is required when the assembly type wallboard is assembled, but the existing splicing device generally has the following problems when in use;

1. the angle alignment work is not facilitated, so that the assembled wallboard is not matched with the field after being spliced due to negligence, the splicing is failed, and the assembled wallboard needs to be spliced again after being disassembled, so that the labor intensity of workers is increased, and the splicing efficiency is reduced;

2. be unfavorable for carrying on the regulation work of angle for can not counterpoint concatenation work to multiple angle, thereby reduced holistic suitability, inconvenient simultaneously splices the wallboard of multiple specification, further reduction holistic suitability.

We have therefore proposed an alignment angle splicing apparatus for assembly of assembled panels to solve the problems set forth above.

Disclosure of Invention

The invention aims to provide an alignment angle splicing device for assembling an assembled wallboard, which aims to solve the problems that the alignment work which is not beneficial to angles is carried out, so that the assembled wallboard is not matched with the field after being spliced once negligence occurs, the splicing fails, the assembled wallboard needs to be spliced again after being disassembled, the labor intensity of workers is increased, the splicing efficiency is reduced, the angle adjusting work is not facilitated, the alignment splicing work can not be carried out on various angles, the overall applicability is reduced, the wallboards of various specifications are not convenient to splice, and the overall applicability is further reduced.

In order to achieve the purpose, the invention provides the following technical scheme: an alignment angle splicing device for assembling an assembled wallboard comprises a base, a motor and a transmission belt, wherein the motor is fixedly arranged in the base, a first driving mechanism and a second driving mechanism are respectively sleeved on the surface of one end, extending out of a driving shaft, of the motor, the transmission belt is arranged in the first driving mechanism, the other end of the transmission belt is meshed with a driven belt pulley, a reciprocating lead screw is connected to the inner thread of the driven belt pulley, a rack is fixedly arranged at one end of the reciprocating lead screw, the surface of the rack is meshed with a cylindrical gear, a supporting shaft is arranged at the center of the cylindrical gear, a movable support is arranged at one end, extending out of the base, of the supporting shaft, a nut fixing piece is fixedly arranged on the surface of one end of the movable support, a first movable block and a second movable block are respectively arranged at the other end of the nut fixing piece, a first movable plate, and coil spring is installed to the one end of first fly leaf, coil spring's the other end is connected with the backup pad, and the one end center of backup pad is provided with spacing axle to the second fly leaf has been cup jointed on the surface of spacing axle, the inside of base is provided with the second bevel gear, and the center of second bevel gear is provided with the transmission shaft, the surface of transmission shaft has been cup jointed automatic line axle, and the transmission shaft stretches into the inside one end of fixed axle and has cup jointed volute spiral spring to fixed axle fixed mounting is in the inner wall of base.

Preferably, the first driving mechanism comprises a first ratchet wheel, a first ratchet and a driving belt pulley, the first ratchet wheel is fixedly sleeved on the surface of the driving shaft of the motor, the surface of the first ratchet wheel is connected with the first ratchet in a meshed mode, one end, far away from the first ratchet wheel, of the first ratchet wheel is connected with the driving belt pulley in a rotating mode, and the first driving mechanism and the second driving mechanism are consistent in internal structure.

Preferably, the second driving mechanism comprises a second ratchet wheel, a second ratchet and a first bevel gear, the second ratchet wheel is fixedly sleeved on the surface of the motor driving shaft, the surface of the second ratchet wheel is connected with the second ratchet in a meshed mode, one end, far away from the second ratchet wheel, of the second ratchet wheel is rotatably connected with the first bevel gear, the second ratchet wheel and the second ratchet wheel are reversely distributed and opposite to the first ratchet wheel and the first ratchet wheel, and the first bevel gear is an incompletely meshed bevel gear.

Preferably, the rack and the base form a sliding structure through a reciprocating screw rod, tooth blocks are distributed on two sides of the rack at equal intervals, and cylindrical gears are symmetrically meshed on two sides of the rack.

Preferably, the movable supports are symmetrically distributed about the longitudinal central line of the base, and the movable supports are distributed in a V shape when viewed from top.

Preferably, connect through the mutual rotation of metallic axle between first movable block and the second movable block, and the inside of first movable block and second movable block all is provided with the connecting rod to the magnet piece is installed to the one end of connecting rod, and the equal interval in surface of first movable block and second movable block simultaneously sets up threaded hole.

Preferably, the end of the connecting rod extending out of the first movable block and the second movable block is in threaded connection with the nut fixing piece, and the end of the connecting rod located inside the first movable block and the second movable block is viewed as a cross-shaped structure in plan.

Preferably, the inner wall of the magnet block is curved in plan view, the outer wall of the magnet block is half a regular hexagon in plan view, and the inner wall of the magnet block fits the surface of the metal shaft.

Preferably, one end of the first movable plate forms a sliding structure with the movable support through a connecting line, the other end of the first movable plate is provided with a return spring, and the first movable plate forms a telescopic structure with the movable support through the return spring.

Preferably, an extension spring and a clamping block are respectively arranged in the first movable plate, the clamping block and the first movable plate form an extension structure through the extension spring, and the first movable plate and the clamping block are vertically distributed in a overlook mode.

Compared with the prior art, the invention has the beneficial effects that: the assembly of the assembled wallboard uses the alignment angle splicing device;

1. when the motor rotates forwards, the first driving mechanism is driven to rotate, the driving belt drives the driven belt pulley to rotate, and at the moment, the rack cannot rotate through mutual meshing of the rack and the cylindrical gears, so that the driven belt pulley drives the reciprocating screw rod in threaded connection to slide, and further the rack drives the cylindrical gears which are symmetrically distributed to rotate oppositely or reversely, the work of adjusting the splicing angle is facilitated, and the overall applicability is improved;

2. when the motor rotates reversely, the automatic wiring shaft is driven to rotate through the second driving mechanism, so that the automatic wiring shaft drives the first movable plate to slide through the connecting wire, the first movable plate drives the assembled wallboards to slide oppositely to perform splicing work conveniently, the splicing efficiency is improved, and the whole energy consumption is reduced by driving through one motor;

3. under coil spring's elastic action, be favorable to adjusting the interval between first fly leaf and the backup pad, made things convenient for and carried out the centre gripping location to the assembled wallboard of multiple width, simultaneously through expanding spring's elastic action down, made things convenient for the grip block to carry out the centre gripping location to the assembled wallboard of multiple thickness, further improvement the suitability of integrated device.

Drawings

FIG. 1 is a schematic view of the overall front cross-sectional structure of the present invention;

FIG. 2 is a schematic view of the overall top cross-sectional structure of the present invention;

FIG. 3 is a schematic side view of the connection structure between the base and the motor according to the present invention;

FIG. 4 is a schematic view of a top-view connection structure of a rack and a spur gear according to the present invention;

FIG. 5 is a schematic view of the internal front cross-section of the first driving mechanism according to the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 7 is an enlarged view of the structure at B in FIG. 2 according to the present invention;

FIG. 8 is a schematic side view of the connecting structure of the extension spring and the return spring according to the present invention;

FIG. 9 is a schematic diagram of a cross-sectional view of the second driving mechanism according to the present invention;

FIG. 10 is a schematic top view of the base of the present invention;

FIG. 11 is a side view of the transmission shaft and the spiral spring of the present invention.

In the figure: 1. a base; 2. a motor; 3. a first drive mechanism; 301. a first ratchet wheel; 302. a first ratchet; 303. a drive pulley; 4. a second drive mechanism; 401. a second ratchet wheel; 402. a second ratchet; 403. a first bevel gear; 5. a transmission belt; 6. a driven pulley; 7. a reciprocating screw rod; 8. a rack; 9. a cylindrical gear; 10. a support shaft; 11. a movable support; 12. a nut fixing member; 13. a first movable block; 1301. a connecting rod; 1302. a magnet block; 1303. a metal shaft; 1304. a threaded hole; 14. a second movable block; 15. a first movable plate; 16. a coil spring; 17. a support plate; 18. a limiting shaft; 19. a second movable plate; 20. a second bevel gear; 21. a drive shaft; 22. automatically connecting a bobbin; 23. a fixed shaft; 24. a volute spiral spring; 25. a connecting wire; 26. a tension spring; 27. a return spring; 28. and (4) clamping the block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-11, the present invention provides a technical solution: an alignment angle splicing device for assembling an assembled wallboard comprises a base 1, a motor 2, a first driving mechanism 3, a first ratchet wheel 301, a first ratchet 302, a driving belt pulley 303, a second driving mechanism 4, a second ratchet wheel 401, a second ratchet 402, a first bevel gear 403, a transmission belt 5, a driven belt pulley 6, a reciprocating screw 7, a rack 8, a cylindrical gear 9, a supporting shaft 10, a movable support 11, a nut fixing member 12, a first movable block 13, a connecting rod 1301, a magnet block 1302, a metal shaft 1303, a threaded hole 1304, a second movable block 14, a first movable plate 15, a spiral spring 16, a supporting plate 17, a limiting shaft 18, a second movable plate 19, a second bevel gear 20, a transmission shaft 21, an automatic wire connecting shaft 22, a fixed shaft 23, a spiral spring 24, a connecting wire 25, a telescopic spring 26, a return spring 27 and a clamping block 28, wherein the motor 2 is fixedly arranged in the base 1, and the surface of one end of the motor 2, from which the driving shaft extends, is respectively sleeved with a first driving mechanism 3 and a second driving mechanism 4, a driving belt 5 is arranged inside the first driving mechanism 3, the other end of the driving belt 5 is mutually engaged with a driven belt pulley 6, the interior of the driven belt pulley 6 is in threaded connection with a reciprocating screw rod 7, one end of the reciprocating screw rod 7 is fixedly provided with a rack 8, the surface of the rack 8 is engaged with a cylindrical gear 9, the center of the cylindrical gear 9 is provided with a supporting shaft 10, one end of the supporting shaft 10, from which the exterior of the base 1 extends, is provided with a movable bracket 11, one end of the movable bracket 11 is fixedly provided with a nut fixing member 12, the other end of the nut fixing member 12 is respectively provided with a first movable block 13 and a second movable block 14, a first movable plate 15 is arranged inside the other end of the, the other end of the spiral spring 16 is connected with a supporting plate 17, a limiting shaft 18 is arranged at the center of one end of the supporting plate 17, a second movable plate 19 is sleeved on the surface of the limiting shaft 18, a second bevel gear 20 is arranged inside the base 1, a transmission shaft 21 is arranged at the center of the second bevel gear 20, an automatic wire connecting shaft 22 is sleeved on the surface of the transmission shaft 21, a volute spiral spring 24 is sleeved at one end of the transmission shaft 21 extending into a fixed shaft 23, and the fixed shaft 23 is fixedly installed on the inner wall of the base 1;

the first driving mechanism 3 comprises a first ratchet wheel 301, a first ratchet 302 and a driving belt pulley 303, the first ratchet wheel 301 is fixedly sleeved on the surface of a driving shaft of the motor 2, the surface of the first ratchet wheel 301 is meshed and connected with the first ratchet 302, one end, far away from the first ratchet wheel 301, of the first ratchet 302 is rotatably connected with the driving belt pulley 303, and the first driving mechanism 3 and the second driving mechanism 4 are consistent in internal structure, so that the first driving mechanism 3 is driven to rotate when the motor 2 rotates forwards conveniently;

the second driving mechanism 4 comprises a second ratchet wheel 401, a second ratchet 402 and a first bevel gear 403, the second ratchet 401 is fixedly sleeved on the surface of a driving shaft of the motor 2, the surface of the second ratchet wheel 401 is connected with the second ratchet 402 in a meshed mode, one end, far away from the second ratchet wheel 401, of the second ratchet 402 is rotatably connected with the first bevel gear 403, the second ratchet wheel 401 and the second ratchet 402 are reversely distributed in the direction opposite to the distribution direction of the first ratchet wheel 301 and the first ratchet 302, and the first bevel gear 403 is an incompletely meshed bevel gear, so that idling inside the first driving mechanism 3 is facilitated when the motor 2 rotates reversely, and the second driving mechanism 4 is driven to rotate independently when the motor 2 rotates reversely;

the rack 8 and the base 1 form a sliding structure through the reciprocating screw rod 7, tooth blocks are distributed on two sides of the rack 8 at equal intervals, and cylindrical gears 9 are symmetrically meshed on two sides of the rack 8, so that the rack 8 can conveniently drive the symmetrically distributed cylindrical gears 9 to rotate oppositely or reversely when sliding;

the movable supports 11 are symmetrically distributed about the longitudinal central line of the base 1, and the movable supports 11 are distributed in a V shape when being overlooked, so that the movable supports 11 can conveniently perform alignment splicing work of various angles after angle adjustment;

the first movable block 13 and the second movable block 14 are rotatably connected with each other through a metal shaft 1303, connecting rods 1301 are arranged inside the first movable block 13 and the second movable block 14, a magnet block 1302 is arranged at one end of each connecting rod 1301, and threaded holes 1304 are formed in the surfaces of the first movable block 13 and the second movable block 14 at equal intervals, so that the assembled wallboard can be conveniently fastened after being spliced through bolts and the threaded holes 1304;

one end of the connecting rod 1301, which extends out of the first movable block 13 and the second movable block 14, is in threaded connection with the nut fixing piece 12, and the other end of the connecting rod 1301, which is positioned inside the first movable block 13 and the second movable block 14, is in a cross-shaped structure, so that the connecting rod 1301 is prevented from falling off, and the nut fixing piece 12 is convenient to drive the first movable block 13 and the second movable block 14 to keep reverse-angle rotation with the movable support 11 through the connecting rod 1301;

the inner wall of the magnet block 1302 is in an arc shape in a depression mode, the outer wall of the magnet block 1302 is in a half-hexagon structure in a depression mode, the inner wall of the magnet block 1302 is matched with the surface of the metal shaft 1303, the magnet block 1302 is convenient to position the metal shaft 1303, and therefore the phenomenon that the first movable block 13 and the second movable block 14 accidentally rotate after the bolts are fastened subsequently is avoided;

one end of the first movable plate 15 forms a sliding structure with the movable support 11 through a connecting line 25, the other end of the first movable plate 15 is provided with a return spring 27, and the first movable plate 15 forms a telescopic structure with the movable support 11 through the return spring 27, so that the return spring 27 can conveniently drive the first movable plate 15 to perform return sliding;

the inside of the first movable plate 15 is provided with a retractable spring 26 and a clamping block 28, and the clamping block 28 forms a retractable structure with the first movable plate 15 through the retractable spring 26, and the first movable plate 15 and the clamping block 28 are vertically distributed in a plan view, which is beneficial for the clamping block 28 to clamp and position assembled wallboards with various thicknesses.

The working principle of the embodiment is as follows: according to the figures 1-6, firstly, the base 1 is placed at a proper position, then the motor 2 is started after being connected with an external power supply, the motor 2 drives the internal shaft to rotate, when the angle needs to be adjusted, a worker controls the motor 2 to rotate in the forward direction, so that the motor 2 drives the first ratchet wheel 301 to rotate through the driving shaft, the first ratchet wheel 301 is meshed with the first ratchet wheel 302, the first ratchet wheel 301 drives the driving pulley 303 to rotate through the first ratchet wheel 302, meanwhile, the motor 2 drives the second ratchet wheel 401 to rotate in the forward direction, the second ratchet wheel 401 is disengaged from the second ratchet wheel 402, the second ratchet wheel 401 idles in the first bevel gear, the driving pulley 303 drives the transmission belt 5 to rotate when rotating, the transmission belt 5 drives the driven pulley 6 to rotate, and at the moment, the rack 8 and the cylindrical gear 9 are meshed with each other, so that the rack 8 and the reciprocating screw rod 7 cannot rotate, therefore, the driven belt pulley 6 drives the reciprocating screw rod 7 in threaded connection to slide in a reciprocating mode when rotating, then the reciprocating screw rod 7 drives the rack 8 to slide in a reciprocating mode, the rack 8 is favorable for driving the cylindrical gears 9 which are symmetrically distributed to rotate in an opposite direction or in a reverse direction, the cylindrical gears 9 drive the movable support 11 to perform angle adjustment through the supporting shafts 10, the movable support 11 drives the connecting rod 1301 to rotate through the nut fixing piece 12 when rotating, the connecting rod 1301 is favorable for driving the first movable block 13 and the second movable block 14 to rotate respectively, the first movable block 13 and the second movable block 14 are favorable for keeping reverse angle rotation with the movable support 11, multi-angle alignment splicing work of the assembled wallboard is facilitated, and the overall applicability is improved;

according to fig. 1-2 and 6-8, after the angle adjustment is completed, the worker pulls the supporting plate 17 to make the supporting plate 17 drive the coil spring 16 to stretch and deform, then abuts one end of the assembled wallboard to the surface of the supporting plate 17, after the supporting plate 17 is released, the coil spring 16 contracts and returns to the original position, so that the coil spring 16 drives the supporting plate 17 to abut one end of the assembled wallboard, the assembled wallboards with various widths are positioned conveniently under the elastic action of the coil spring 16, then the clamping block 28 is pulled to make the clamping block 28 extrude the expansion spring 26 to contract and deform, then the other end of the assembled wallboard abuts to the surface of the first movable plate 15, the clamping block 28 is released to make the expansion spring 26 stretch and return, so that the clamping block 28 clamps and positions the other end of the assembled wallboard, under the elastic action of the telescopic spring 26, the fixing work of the assembled wallboards with various thicknesses is facilitated, and the applicability of the whole device is further improved;

according to fig. 1-3 and 6-11, after the prefabricated wall panel is fixed, the worker controls the motor 2 to rotate reversely, so that the motor 2 drives the first ratchet wheel 301 to rotate reversely, so that the first ratchet wheel 301 is disengaged from the first ratchet 302, and then the first ratchet wheel 301 idles in the driving pulley 303, and simultaneously, when the motor 2 rotates reversely, the motor 2 drives the second ratchet wheel 401 to rotate reversely through the driving shaft, so that the second ratchet wheel 401 is engaged with the second ratchet 402, so that the second ratchet wheel 401 drives the first bevel gear 403 to rotate through the second ratchet 402, and through the arrangement of the first bevel gear 403 as an incompletely-engaged bevel gear, the first bevel gear 20 is driven to rotate when being engaged with the second bevel gear 20, so that the second bevel gear 20 drives the automatic take-up spool 22 to rotate through the transmission shaft 21, and then the automatic take-up spool 22 drives the connecting wire 25 to take up, meanwhile, the transmission shaft 21 rotates to drive the volute spiral spring 24 to deform, so that when the subsequent first bevel gear 403 is disengaged from the second bevel gear 20, the volute spiral spring 24 drives the transmission shaft 21 to rotate reversely, the automatic wire receiving shaft 22 is convenient to unreel the connecting wire 25, the connecting wire 25 is reeled to drive the first movable plate 15 to slide, so that the first movable plate 15 pushes the assembled wallboard to slide, the assembled wallboard slides to extrude the second movable plate 19, the second movable plate 19 rotates through the fixed shaft 23, the second movable plate 19 is free of limiting of the assembled wallboard, when the assembled wallboard slides to be attached to the surface of the first movable block 13, the motor 2 is stopped to operate, the assembled wallboard is fastened in the threaded hole 1304 through bolt insertion, and then the nut fixing member 12 is shifted to separate the connecting rod 1301 from the nut fixing member 12, at this time, under the magnetic attraction effect of the magnet block 1302 and the metal shaft 1303, the magnet block 1302 slides to the surface of the metal shaft 1303 to be attached, so that the magnet block 1302 positions the metal shaft 1303, and the accidental rotation phenomenon between the first movable block 13 and the second movable block 14 is avoided, thereby completing the whole splicing work.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. The utility model provides an assembled wallboard assembly is with counterpoint angle splicing apparatus, includes base (1), motor (2) and drive belt (5), its characterized in that: the automatic transmission mechanism is characterized in that a motor (2) is fixedly mounted inside the base (1), a first driving mechanism (3) and a second driving mechanism (4) are respectively sleeved on the surface of one end, extending out of a driving shaft, of the motor (2), a driving belt (5) is arranged inside the first driving mechanism (3), the other end of the driving belt (5) is meshed with the driven belt pulley (6), a reciprocating screw rod (7) is connected to the inner thread of the driven belt pulley (6), a rack (8) is fixedly mounted at one end of the reciprocating screw rod (7), a cylindrical gear (9) is meshed with the surface of the rack (8), a supporting shaft (10) is arranged at the center of the cylindrical gear (9), a movable support (11) is mounted at one end, extending out of the base (1), of the supporting shaft (10), and a nut fixing piece (12) is fixedly mounted at the surface of one end, and the other end of the nut fixing piece (12) is respectively provided with a first movable block (13) and a second movable block (14), a first movable plate (15) is arranged inside the other end of the movable bracket (11), and one end of the first movable plate (15) is provided with a spiral spring (16), the other end of the spiral spring (16) is connected with a supporting plate (17), a limiting shaft (18) is arranged at the center of one end of the supporting plate (17), a second movable plate (19) is sleeved on the surface of the limiting shaft (18), a second bevel gear (20) is arranged inside the base (1), a transmission shaft (21) is arranged in the center of the second bevel gear (20), an automatic wire connecting shaft (22) is sleeved on the surface of the transmission shaft (21), and one end of the transmission shaft (21) extending into the fixed shaft (23) is sleeved with a volute spiral spring (24), and the fixed shaft (23) is fixedly arranged on the inner wall of the base (1).

2. The aligning angle splicing apparatus for assembling an assembled wallboard according to claim 1, wherein: the first driving mechanism (3) comprises a first ratchet wheel (301), a first ratchet tooth (302) and a driving belt pulley (303), the first ratchet wheel (301) is fixedly sleeved on the surface of a driving shaft of the motor (2), the surface of the first ratchet wheel (301) is meshed with the first ratchet tooth (302), one end, far away from the first ratchet wheel (301), of the first ratchet tooth (302) is rotatably connected with the driving belt pulley (303), and the internal structures of the first driving mechanism (3) and the second driving mechanism (4) are consistent.

3. The aligning angle splicing device for assembling the assembled wallboard according to claim 2, wherein: the second driving mechanism (4) comprises a second ratchet wheel (401), a second ratchet wheel (402) and a first bevel gear (403), the second ratchet wheel (401) is fixedly sleeved on the surface of a driving shaft of the motor (2), the surface of the second ratchet wheel (401) is connected with the second ratchet wheel (402) in a meshed mode, one end, far away from the second ratchet wheel (401), of the second ratchet wheel (402) is connected with the first bevel gear (403) in a rotating mode, the distribution directions of the second ratchet wheel (401) and the second ratchet wheel (402) are opposite to the distribution directions of the first ratchet wheel (301) and the first ratchet wheel (302), and the first bevel gear (403) is an incomplete meshing bevel gear.

4. The aligning angle splicing apparatus for assembling an assembled wallboard according to claim 1, wherein: the rack (8) and the base (1) form a sliding structure through the reciprocating screw rod (7), tooth blocks are distributed on two sides of the rack (8) at equal intervals, and cylindrical gears (9) are symmetrically meshed on two sides of the rack (8).

5. The aligning angle splicing apparatus for assembling an assembled wallboard according to claim 1, wherein: the movable supports (11) are symmetrically distributed about the longitudinal central line of the base (1), and the movable supports (11) are distributed in a V shape in a overlooking mode.

6. The aligning angle splicing apparatus for assembling an assembled wallboard according to claim 1, wherein: the first movable block (13) and the second movable block (14) are connected in a rotating mode through metal shafts (1303), connecting rods (1301) are arranged inside the first movable block (13) and the second movable block (14), magnet blocks (1302) are installed at one ends of the connecting rods (1301), and threaded holes (1304) are formed in the surfaces of the first movable block (13) and the second movable block (14) at equal intervals.

7. The aligning angle splicing device for assembling an assembled wallboard according to claim 6, wherein: one end of the connecting rod (1301) extending out of the first movable block (13) and the second movable block (14) is in threaded connection with the nut fixing piece (12), and one end of the connecting rod (1301) located inside the first movable block (13) and the second movable block (14) is in a cross-shaped structure in a plan view.

8. The aligning angle splicing device for assembling an assembled wallboard according to claim 6, wherein: the magnet block (1302) has an arc-shaped inner wall as viewed from above, the outer wall of the magnet block (1302) has a half-hexagonal shape as viewed from above, and the inner wall of the magnet block (1302) is fitted to the surface of the metal shaft (1303).

9. The aligning angle splicing apparatus for assembling an assembled wallboard according to claim 1, wherein: one end of the first movable plate (15) forms a sliding structure with the movable support (11) through a connecting wire (25), the other end of the first movable plate (15) is provided with a return spring (27), and the first movable plate (15) forms a telescopic structure with the movable support (11) through the return spring (27).

10. The aligning angle splicing apparatus for assembling an assembled wallboard according to claim 1, wherein: the first movable plate (15) is internally provided with a telescopic spring (26) and a clamping block (28) respectively, the clamping block (28) and the first movable plate (15) form a telescopic structure through the telescopic spring (26), and the first movable plate (15) and the clamping block (28) are vertically distributed in a overlooking mode.