CN117071886A

CN117071886A - Cylindrical formwork reinforcing device and construction method

Info

Publication number: CN117071886A
Application number: CN202311086024.9A
Authority: CN
Inventors: 张国威; 王亚东; 汪浩; 廖云; 谭一夫; 邱俊; 樊绪德; 方涛
Original assignee: China Railway Shanghai Engineering Bureau Group South China Municipal Construction Co ltd; Shanghai Civil Engineering Co Ltd of CREC
Current assignee: China Railway Shanghai Engineering Bureau Group South China Municipal Construction Co ltd; Shanghai Civil Engineering Co Ltd of CREC
Priority date: 2023-08-28
Filing date: 2023-08-28
Publication date: 2023-11-17

Abstract

The invention relates to the technical field of building construction, in particular to a cylindrical formwork reinforcing device and a construction method.

Description

Cylindrical formwork reinforcing device and construction method

Technical Field

Background

The formwork engineering refers to a new concrete-poured forming formwork and a whole set of construction system for supporting the formwork, wherein the construction parts which contact the concrete and control the preset size, shape and position are called the formwork, the support system is formed by rods, trusses, connecting pieces, metal accessories, working temporary bridges and the like for supporting and fixing the formwork, and the self-elevating formwork is additionally formed by lifting power, lifting frames, platforms and the like for the sliding formwork, so that the formwork engineering is a temporary structure in concrete construction.

The arc-shaped template is used for assembling after the binding of the cylindrical steel bars is completed, the steel strips are adopted for reinforcing the arc-shaped template, the existing mode of manually winding the steel strips is adopted for reinforcing the arc-shaped template, the labor intensity is high, and the rapid construction is not facilitated.

Disclosure of Invention

The invention aims to provide a cylindrical template reinforcing device and a construction method, which are used for solving the problems that in the background technology, an arc-shaped template is reinforced by manually winding a steel belt, so that the labor intensity is high and the quick construction is not facilitated.

The technical scheme of the invention is as follows:

the utility model provides a cylinder template reinforcing apparatus, includes cylinder reinforcing bar body, cross frame, steel band winding subassembly, straightness that hangs down detection component, two arc templates and four walking components, two the outside at the cylinder reinforcing bar body is established to the arc template cover, the cross frame sets up in the top of the cylinder reinforcing bar body, four walking component is the rectangle and distributes in the bottom of cross frame, steel band winding subassembly is installed on the cross frame, straightness that hangs down detection component installs between two adjacent walking components.

Further, the steel belt winding assembly comprises a rotating shaft, a rotating disc, a rotating motor, a driving gear, a driven gear, a transverse plate and a steel belt winding part, wherein the rotating shaft is rotatably arranged at the center of the cross-shaped frame, the rotating disc is arranged at the bottom of the rotating shaft, the rotating motor is vertically arranged at the top of the cross-shaped frame, the driving gear is arranged on an output shaft of the rotating motor, the driven gear is arranged at the top end of the rotating shaft and is meshed with the driving gear, the transverse plate is horizontally arranged on the outer wall of the rotating disc, and the steel belt winding part is arranged at the bottom of the transverse plate.

Further, the steel strip winding part comprises a first screw rod sliding table, a connecting frame, a second screw rod sliding table, a lifting frame and a steel strip piece, wherein the first screw rod sliding table is horizontally arranged at the bottom of the transverse plate, the connecting frame is arranged at the moving end of the first screw rod sliding table, the second screw rod sliding table is vertically arranged at the bottom of the connecting frame, the lifting frame is arranged at the moving end of the second screw rod sliding table, and the steel strip piece is arranged on the outer wall of the lifting frame.

Further, the steel strip piece includes carrier, pivot, commentaries on classics roller, steel strip coil, removes frame, third lead screw slip table, linkage plate, hydraulic push rod, pushes away frame, cutter and two slide rails, the carrier is installed on the outer wall of crane, the pivot is rotated and is installed in the carrier, commentaries on classics roller installs in the pivot, the steel strip coil of strip suit is on commentaries on classics roller, two slide rail symmetry sets up the top at the carrier, remove the frame slidable mounting on two slide rails, third lead screw slip table level sets up the top at the carrier, the linkage plate is installed on the mobile terminal of third lead screw slip table to the linkage plate is connected with the bottom outer wall of removing the frame, the hydraulic push rod is vertical to be set up on the top of removing the frame, push away the frame and install on hydraulic push rod's output, the cutter is installed in the bottom of pushing away the frame.

Further, a rectangular groove for the cutter to pass through is arranged on the bearing frame.

Further, every walking subassembly all includes stiffening rod, walking board, walking seat and universal wheel, the vertical bottom edge that sets up at the cross frame of stiffening rod, the bottom at the stiffening rod is installed to the walking board, the bottom edge of walking board is installed to the walking seat, the universal wheel is installed in the walking seat.

Further, straightness detection subassembly includes chassis, mounting bracket, bracing piece, supporting shoe, detects seat, spirit level, connecting axle, adjusting gear and adjusting part, the both sides of chassis are installed on the outer wall of the walking board in two adjacent walking subassemblies, the mounting bracket is erect on the outer wall of chassis, the vertical top that sets up at the chassis of bracing piece, the supporting shoe is installed at the top of bracing piece, detect the seat and install at the top of supporting shoe, the spirit level passes through the connecting axle and rotates and install on detecting the seat, adjusting gear installs at the top of connecting axle, adjusting part installs the top at the mounting bracket to adjusting part is used for driving adjusting gear and rotates.

Further, the adjusting part comprises an adjusting rail, an adjusting block, an adjusting rack, a fourth screw sliding table and an L-shaped plate, wherein the adjusting rail is horizontally arranged at the top end of the mounting frame, the adjusting block is slidably mounted on the adjusting rail, the adjusting rack is horizontally arranged on the outer wall of the adjusting block and is meshed with the adjusting gear, the fourth screw sliding table is horizontally arranged at the top of the mounting frame, the L-shaped plate is mounted on the moving end of the fourth screw sliding table, and the L-shaped plate is connected with the top of the adjusting block.

A construction method of a cylindrical template reinforcing device comprises the following steps,

s1, pushing a cross frame to move to the upper side of a cylindrical steel bar body by using universal wheels, then driving gears are driven by a rotating motor to rotate, a rotating shaft and a rotating disc are driven by a driving gear to rotate, and a steel belt winding part is driven by the rotating disc to rotate;

s2, fixing one end of a steel strip coil on the outer walls of the two arc-shaped templates, and then driving the steel strip to wind the two arc-shaped templates to rotate by the rotating disc, wherein the steel strip in the steel strip coil is automatically wound on the outer walls of the two arc-shaped templates;

s3, the first screw rod sliding table and the second screw rod sliding table work cooperatively to enable the steel belt in the steel belt coil to wind all positions in the two arc-shaped templates;

s4, after winding is completed, the hydraulic push rod drives the pushing frame to move downwards, and the pushing frame drives the cutter to move downwards to cut the steel belt;

s5, the fourth screw rod sliding table drives the adjusting block to move on the adjusting rail by using the L-shaped plate, the adjusting block drives the adjusting gear to rotate by using the adjusting rack, the adjusting gear drives the level gauge to rotate to a proper angle, and then the level gauge detects the verticality of the two arc-shaped templates.

Compared with the prior art, the cylindrical template reinforcing device and the construction method provided by the invention have the following improvements and advantages:

the method comprises the following steps: the invention pushes the cross frame to move to the upper part of the cylindrical steel bar body by utilizing the four walking components, then the steel belt winding component works to automatically wind the steel belt on the outer walls of the two arc-shaped templates, and then the perpendicularity detection component works to detect the perpendicularity of the two arc-shaped templates, so that a mode of manually winding the steel belt is not needed, the labor intensity is reduced, and the rapid construction is facilitated.

And two,: according to the invention, the movable frame is driven to move on the two slide rails by the linkage plate through the work of the third screw rod sliding table, the movable frame drives the cutter to move to a proper position, then the hydraulic push rod works to drive the push frame and the cutter to move downwards, and the cutter moves downwards to cut the steel strip in the steel strip coil.

Drawings

The invention is further explained below with reference to the drawings and examples:

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of a second embodiment of the present invention;

FIG. 3 is a schematic perspective view of the steel strip winding assembly of the present invention;

fig. 4 is a schematic perspective view of a steel strip-wound part of the present invention;

FIG. 5 is a schematic perspective view of a verticality detection assembly according to the present invention;

fig. 6 is a schematic perspective view of a verticality detection assembly according to the second embodiment of the present invention.

Reference numerals illustrate:

cylindrical reinforcement 1, cross frame 2, steel strip winding assembly 3, rotation shaft 31, rotation disk 32, rotation motor 33, driving gear 34, driven gear 35, cross plate 36, steel strip winding part 37, first lead screw slide 371, connection frame 372, second lead screw slide 373, lifting frame 374, steel strip 375, carrying frame 3751, rectangular groove 37511, rotation shaft 3752, rotation roller 3753, steel strip coil 3754, moving frame 3755, third lead screw slide 3756, linkage plate 3757, hydraulic push rod 3758, push frame 3759, cutter 37591, slide rail 37592, verticality detection assembly 4, chassis 41, mounting frame 42, support rod 43, support block 44, detection seat 45, level 46, connection shaft 47, adjustment gear 48, adjustment part 49, adjustment rail 491, adjustment block 492, adjustment rack 493, fourth lead screw slide 494, l-shaped plate 495, arc-shaped template 5, walking assembly 6, reinforcement bar 61, walking plate 62, walking seat 63, universal wheel 64.

Detailed Description

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

The invention provides a cylindrical formwork reinforcing device through improvement, as shown in fig. 1-6, which comprises a cylindrical reinforcement body 1, a cross-shaped frame 2, a steel belt winding assembly 3, a verticality detection assembly 4, two arc-shaped formworks 5 and four traveling assemblies 6, wherein the two arc-shaped formworks 5 are sleeved outside the cylindrical reinforcement body 1, the cross-shaped frame 2 is arranged above the top of the cylindrical reinforcement body 1, the four traveling assemblies 6 are distributed at the bottom of the cross-shaped frame 2 in a rectangular shape, the steel belt winding assembly 3 is arranged on the cross-shaped frame 2, and the verticality detection assembly 4 is arranged between the two adjacent traveling assemblies 6; the cross-shaped frame 2 is pushed to move to the upper portion of the cylindrical steel bar body 1 by using the four traveling assemblies 6, then the steel belt winding assembly 3 works to automatically wind the steel belt on the outer walls of the two arc-shaped templates 5, then the perpendicularity detection assembly 4 works to detect the perpendicularity of the two arc-shaped templates 5, a mode of manually winding the steel belt is not needed, labor intensity is reduced, and quick construction is facilitated.

Specifically, the steel strip winding assembly 3 includes a rotation shaft 31, a rotation disc 32, a rotation motor 33, a driving gear 34, a driven gear 35, a cross plate 36 and a steel strip winding part 37, wherein the rotation shaft 31 is rotatably installed at the center of the cross frame 2, the rotation disc 32 is installed at the bottom of the rotation shaft 31, the rotation motor 33 is vertically arranged at the top of the cross frame 2, the driving gear 34 is installed on an output shaft of the rotation motor 33, the driven gear 35 is installed at the top end of the rotation shaft 31, the driven gear 35 is meshed with the driving gear 34, the cross plate 36 is horizontally arranged on the outer wall of the rotation disc 32, and the steel strip winding part 37 is installed at the bottom of the cross plate 36; the driving gear 34 is driven to rotate by the operation of the rotating motor 33, the driving gear 34 drives the rotating shaft 31 and the rotating disc 32 to rotate by the driven gear 35, the rotating disc 32 drives the steel belt winding part 37 to rotate by the transverse plate 36, and the steel belt winding part 37 automatically winds the steel belt on the outer walls of the two arc templates 5.

Specifically, the steel belt winding component 37 includes a first screw rod sliding table 371, a connecting frame 372, a second screw rod sliding table 373, a lifting frame 374 and a steel belt piece 375, wherein the first screw rod sliding table 371 is horizontally arranged at the bottom of the transverse plate 36, the connecting frame 372 is installed on the moving end of the first screw rod sliding table 371, the second screw rod sliding table 373 is vertically arranged at the bottom of the connecting frame 372, the lifting frame 374 is installed on the moving end of the second screw rod sliding table 373, and the steel belt piece 375 is installed on the outer wall of the lifting frame 374; the first screw rod sliding table 371 and the second screw rod sliding table 373 are matched to work, so that the steel strip piece 375 can be wound on all the two arc-shaped templates 5 conveniently.

Specifically, the steel strip piece 375 includes a carrying frame 3751, a rotating shaft 3752, a rotating roller 3753, a steel strip coil 3754, a moving frame 3755, a third screw rod sliding table 3756, a linkage plate 3757, a hydraulic push rod 3758, a pushing frame 3759, a cutter 37591 and two sliding rails 37592, wherein the carrying frame 3751 is installed on the outer wall of the lifting frame 374, the rotating shaft 3752 is rotatably installed in the carrying frame 3751, the rotating roller 3753 is installed on the rotating shaft 3752, the steel strip coil 3754 is sleeved on the rotating roller 3753, two sliding rails 37592 are symmetrically arranged at the top of the carrying frame 3751, the moving frame 3755 is slidably installed on the two sliding rails 37592, the third screw rod sliding table 3756 is horizontally arranged at the top of the carrying frame 3751, the linkage plate 3757 is installed at the moving end of the third screw rod sliding table 3756, the linkage plate 3757 is connected with the outer wall of the bottom end of the moving frame 3755, the hydraulic push rod 3758 is vertically arranged at the top of the moving frame 3755, the pushing frame 3758 is installed at the bottom of the pushing frame 37591, and the pushing frame 3759 is installed at the bottom of the pushing frame 3759; the third screw rod sliding table 3756 is operated to drive the movable frame 3755 to move on the two sliding rails 37592 by the linkage plate 3757, the movable frame 3755 drives the cutter 37591 to move to a proper position, then the hydraulic push rod 3758 is operated to drive the push frame 3759 and the cutter 37591 to move downwards, and the cutter 37591 moves downwards to cut the steel strip in the steel strip coil 3754.

Specifically, the carrier 3751 is provided with a rectangular slot 37511 for the cutter 37591 to pass through; the rectangular slot 37511 ensures that the cutter 37591 can move downwardly through the carrier 3751.

Specifically, each of the walking assemblies 6 includes a reinforcing rod 61, a walking plate 62, a walking seat 63 and a universal wheel 64, the reinforcing rod 61 is vertically disposed at the bottom edge of the cross frame 2, the walking plate 62 is mounted at the bottom of the reinforcing rod 61, the walking seat 63 is mounted at the bottom edge of the walking plate 62, and the universal wheel 64 is mounted in the walking seat 63; the cross frame 2 is moved by pushing it by means of the universal wheel 64.

Specifically, the verticality detection assembly 4 comprises a chassis 41, a mounting frame 42, a supporting rod 43, a supporting block 44, a detection seat 45, a level 46, a connecting shaft 47, an adjusting gear 48 and an adjusting component 49, wherein two sides of the chassis 41 are mounted on the outer walls of the walking plates 62 in two adjacent walking assemblies 6, the mounting frame 42 is erected on the outer walls of the chassis 41, the supporting rod 43 is vertically arranged at the top of the chassis 41, the supporting block 44 is mounted at the top of the supporting rod 43, the detection seat 45 is mounted at the top of the supporting block 44, the level 46 is rotatably mounted on the detection seat 45 through the connecting shaft 47, the adjusting gear 48 is mounted at the top of the connecting shaft 47, the adjusting component 49 is mounted at the top of the mounting frame 42, and the adjusting component 49 is used for driving the adjusting gear 48 to rotate; the adjusting gear 48 is driven to rotate by the operation of the adjusting component 49, and the connecting shaft 47 is utilized by the adjusting gear 48 to drive the level 46 to rotate to a proper angle.

Specifically, the adjusting part 49 includes an adjusting rail 491, an adjusting block 492, an adjusting rack 493, a fourth screw sliding table 494 and an L-shaped board 495, wherein the adjusting rail 491 is horizontally arranged at the top end of the mounting frame 42, the adjusting block 492 is slidably mounted on the adjusting rail 491, the adjusting rack 493 is horizontally arranged on the outer wall of the adjusting block 492, and the adjusting rack 493 is meshed with the adjusting gear 48, the fourth screw sliding table 494 is horizontally arranged at the top of the mounting frame 42, the L-shaped board 495 is mounted on the moving end of the fourth screw sliding table 494, and the L-shaped board 495 is connected with the top of the adjusting block 492; the adjusting block 492 is driven to move on the adjusting rail 491 by the L-shaped plate 495 through the fourth screw rod sliding table 494, and the adjusting block 492 drives the adjusting gear 48 to rotate by the adjusting rack 493.

s1, pushing the cross frame 2 to move to the upper side of the cylindrical reinforcement body 1 by using universal wheels 64, then driving gears 34 are driven by a rotating motor 33 to rotate, rotating shafts 31 and rotating discs 32 are driven by the driving gears 34 by using driven gears 35 to rotate, and steel belt winding parts 37 are driven by the rotating discs 32 to rotate;

s2, fixing one end of a steel strip coil 3754 on the outer walls of the two arc-shaped templates 5, and then driving the steel strip coil 3754 to rotate around the two arc-shaped templates 5 by the rotary disk 32, wherein the steel strip in the steel strip coil 3754 is automatically wound on the outer walls of the two arc-shaped templates 5;

s3, the first screw rod sliding table 371 and the second screw rod sliding table 373 work cooperatively to enable the steel strip in the steel strip coil 3754 to wind all positions in the two arc-shaped templates 5;

s4, after winding is completed, the hydraulic push rod 3758 drives the push frame 3759 to move downwards, and the push frame 3759 drives the cutter 37591 to move downwards to cut the steel belt;

s5, a fourth screw rod sliding table 494 drives an adjusting block 492 to move on an adjusting rail 491 by utilizing an L-shaped plate 495, the adjusting block 492 drives an adjusting gear 48 to rotate by utilizing an adjusting rack 493, the adjusting gear 48 drives a level gauge 46 to rotate to a proper angle, and then the level gauge 46 detects the verticality of the two arc-shaped templates 5.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A cylinder template reinforcing apparatus, its characterized in that: including cylinder reinforcing bar body (1), cross frame (2), steel band winding subassembly (3), straightness that hangs down detection assembly (4), two arc templates (5) and four walking subassembly (6), two arc template (5) cover is established in the outside of cylinder reinforcing bar body (1), cross frame (2) set up in the top of cylinder reinforcing bar body (1), four walking subassembly (6) are the rectangle and distribute in the bottom of cross frame (2), steel band winding subassembly (3) are installed on cross frame (2), straightness that hangs down detection assembly (4) are installed between two adjacent walking subassemblies (6).

2. A cylindrical form reinforcing apparatus according to claim 1, wherein: the steel belt winding assembly (3) comprises a rotating shaft (31), a rotating disc (32), a rotating motor (33), a driving gear (34), a driven gear (35), a transverse plate (36) and a steel belt winding part (37), wherein the rotating shaft (31) is rotatably arranged at the center of the cross-shaped frame (2), the rotating disc (32) is arranged at the bottom of the rotating shaft (31), the rotating motor (33) is vertically arranged at the top of the cross-shaped frame (2), the driving gear (34) is arranged on an output shaft of the rotating motor (33), the driven gear (35) is arranged at the top end of the rotating shaft (31), the driven gear (35) is meshed with the driving gear (34), the transverse plate (36) is horizontally arranged on the outer wall of the rotating disc (32), and the steel belt winding part (37) is arranged at the bottom of the transverse plate (36).

3. A cylindrical form reinforcing apparatus according to claim 2, wherein: the steel belt winding part (37) comprises a first screw rod sliding table (371), a connecting frame (372), a second screw rod sliding table (373), a lifting frame (374) and a steel belt piece (375), wherein the first screw rod sliding table (371) is horizontally arranged at the bottom of the transverse plate (36), the connecting frame (372) is arranged at the moving end of the first screw rod sliding table (371), the second screw rod sliding table (373) is vertically arranged at the bottom of the connecting frame (372), the lifting frame (374) is arranged at the moving end of the second screw rod sliding table (373), and the steel belt piece (375) is arranged on the outer wall of the lifting frame (374).

4. A cylindrical form reinforcing apparatus according to claim 3, wherein: the steel strip piece (375) comprises a bearing frame (3751), a rotating shaft (3752), a rotating roller (3753), a steel strip coil (3754), a moving frame (3755), a third screw rod sliding table (3756), a linkage plate (3757), a hydraulic push rod (3758), a pushing frame (3759), a cutter (37591) and two sliding rails (37592), wherein the bearing frame (3751) is installed on the outer wall of a lifting frame (374), the rotating shaft (3752) is rotatably installed in the bearing frame (3751), the rotating roller (3753) is installed on the rotating shaft (3752), the steel strip coil (3754) is sleeved on the rotating roller (3753), two sliding rails (37592) are symmetrically arranged at the top of the bearing frame (3751), the moving frame (3755) is slidably installed on two sliding rails (37592), the third screw rod sliding table (3756) is horizontally arranged at the top of the bearing frame (3751), the plate (3757) is installed on the third screw rod sliding table (3756) and is installed at the bottom of the sliding frame (3755), and the hydraulic push rod (3755) is installed at the bottom of the sliding frame (3755).

5. The cylindrical form reinforcing apparatus according to claim 4, wherein: the bearing frame (3751) is provided with a rectangular groove (37511) for a cutter (37591) to pass through.

6. The cylindrical form reinforcing apparatus according to claim 5, wherein: every walking subassembly (6) all includes stiffening rod (61), walking board (62), walking seat (63) and universal wheel (64), the vertical bottom edge that sets up in cross frame (2) of stiffening rod (61), the bottom at stiffening rod (61) is installed to walking board (62), the bottom edge at walking board (62) is installed to walking seat (63), universal wheel (64) are installed in walking seat (63).

7. The cylindrical form reinforcing apparatus as set forth in claim 6, wherein: the utility model provides a straightness detection subassembly (4) that hangs down, including chassis (41), mounting bracket (42), bracing piece (43), supporting shoe (44), detection seat (45), spirit level (46), connecting axle (47), adjusting gear (48) and adjusting part (49), the both sides of chassis (41) are installed on the outer wall of walking board (62) in two adjacent walking subassemblies (6), mounting bracket (42) erect on the outer wall of chassis (41), vertical setting in the top of chassis (41) bracing piece (43), the top at bracing piece (43) is installed in supporting shoe (44), detection seat (45) are installed at the top of supporting shoe (44), spirit level (46) are installed on detection seat (45) through connecting axle (47) rotation, the top at connecting axle (47) is installed in adjusting part (49) to adjusting part (49) are used for driving adjusting gear (48) rotation.

8. The cylindrical form reinforcing apparatus as set forth in claim 7, wherein: the adjusting part (49) comprises an adjusting rail (491), an adjusting block (492), an adjusting rack (493), a fourth screw sliding table (494) and an L-shaped plate (495), wherein the adjusting rail (491) is horizontally arranged at the top end of the mounting frame (42), the adjusting block (492) is slidably mounted on the adjusting rail (491), the adjusting rack (493) is horizontally arranged on the outer wall of the adjusting block (492), the adjusting rack (493) is meshed with the adjusting gear (48), the fourth screw sliding table (494) is horizontally arranged at the top of the mounting frame (42), the L-shaped plate (495) is mounted on the moving end of the fourth screw sliding table (494), and the L-shaped plate (495) is connected with the top of the adjusting block (492).

9. A method of constructing a cylindrical form reinforcing apparatus according to claim 9, wherein: comprises the steps of,

s1, pushing a cross-shaped frame (2) to move to the position above a cylindrical reinforcement body (1) by using a universal wheel (64), then driving a driving gear (34) to rotate by using a rotating motor (33), driving a rotating shaft (31) and a rotating disc (32) to rotate by using a driven gear (35) by using the driving gear (34), and driving a steel belt winding part (37) to rotate by using the rotating disc (32);

s2, fixing one end of a steel strip coil (3754) on the outer walls of the two arc-shaped templates (5), and then driving the steel strip coil (3754) to rotate around the two arc-shaped templates (5) by the rotary disc (32), wherein steel strips in the steel strip coil (3754) are automatically wound on the outer walls of the two arc-shaped templates (5);

s3, the first screw rod sliding table (371) and the second screw rod sliding table (373) work cooperatively to enable the steel belt in the steel belt coil (3754) to wind all positions in the two arc-shaped templates (5);

s4, after winding is completed, the hydraulic push rod (3758) drives the pushing frame (3759) to move downwards, and the pushing frame (3759) drives the cutter (37591) to move downwards to cut the steel belt;

s5, a fourth screw rod sliding table (494) drives an adjusting block (492) to move on an adjusting rail (491) by using an L-shaped plate (495), the adjusting block (492) drives an adjusting gear (48) to rotate by using an adjusting rack (493), the adjusting gear (48) drives a level meter (46) to rotate to a proper angle, and then the level meter (46) detects the verticality of two arc templates (5).