CN116900614A - Scaffold plate buckle welding device - Google Patents

Abstract

The application relates to the technical field of scaffold processing equipment, and particularly discloses a scaffold plate buckle welding device which comprises a frame and a welding unit, wherein the welding unit is fixedly arranged at the upper end of the frame, a rotary switching mechanism is arranged right below the welding unit, a pre-welding positioning mechanism is arranged at the lower end of the welding unit, and the pre-welding positioning mechanism clamps and positions scaffold plate buckles on the rotary switching mechanism before welding; the scaffold plate buckle welding device disclosed by the application has the advantages that the welding efficiency of the whole scaffold is effectively improved in the automatic feeding and automatic discharging processes in the welding process, simultaneously, the plurality of plate buckles on the scaffold steel pipe before welding are synchronously clamped and positioned through the arranged pre-welding positioning mechanism, the deviation of the plate buckles in the feeding process of the scaffold is effectively eliminated, the rotary welding is performed after the plate buckles are positioned, the position accuracy of the plate buckle welding is effectively improved, and the welding quality of the whole scaffold is effectively ensured.

Description

Scaffold plate buckle welding device

Technical Field

The application relates to the technical field of scaffold machining equipment, and particularly discloses a scaffold plate buckle welding device.

Background

The disc-buckle type scaffold is also called a disc-type scaffold, and is a common scaffold structural form. The existing disc buckles in the disc buckle type scaffold mainly adopt manual welding, an operator sleeves a plurality of disc buckles on a steel pipe in the welding process, then the disc buckles are moved to set positions to be welded one by one, the whole welding process is high in labor intensity and low in operation efficiency, and welding quality is unstable.

The application patent with the application number of 2019106383912 discloses a full-automatic welding machine for scaffold upright rod disc buckles, which comprises a main body frame, and an air storage tank, a welding power supply, an operation box and a power supply control box which are arranged on the main body frame, wherein a feeding pipe penetrating device is arranged on one side of the main body frame; the welding machine disclosed by the application realizes automatic pipe feeding and pipe penetrating, automatic plate feeding, spot welding and ring welding, and has high whole processing efficiency, but after pipe penetrating is performed at fixed points by plate buckles, the pipe penetrating machine is required to be conveyed to the position right below a welding mechanism by a feeding pipe penetrating device, and the plate buckles which are positioned originally in the conveying process are easy to generate position deviation, so that the position deviation of the plate buckles after final welding exists. In addition, after the welding machine is used for welding the coiled scaffold, manual blanking is needed, and the local temperature of the welded scaffold is too high due to the welding process, so that the situation of false touch and scald can often occur in the manual blanking process. Therefore, on the premise of overcoming the defects of the existing full-automatic welding machine for the scaffold upright pole plate buckle, the application provides the welding device for the scaffold plate buckle, which can effectively solve the technical problems.

Disclosure of Invention

The application aims to provide a scaffold plate buckle welding device which aims to solve the defects of the existing scaffold upright rod plate buckle full-automatic welding machine in the background technology.

The application is realized by the following technical scheme:

the welding device for the scaffold plate buckle comprises a frame and a welding unit, wherein the welding unit is fixedly arranged at the upper end of the frame, a rotary switching mechanism is arranged right below the welding unit, a pre-welding positioning mechanism is arranged at the lower end of the welding unit, and the pre-welding positioning mechanism clamps and positions the scaffold plate buckle on the rotary switching mechanism before welding;

the rotary switching mechanism comprises two material carrying discs which are arranged left and right, a first driving device for realizing synchronous rotation of the two material carrying discs, a plurality of pipe body clamping grooves are uniformly formed in the circumferential surface of the material carrying discs, and the rotary switching mechanism further comprises a jacking rotary assembly for rotationally driving scaffold steel pipes in the uppermost pipe body clamping grooves;

the welding front positioning mechanism comprises a movable arm which is arranged in a direction of the rotary switching mechanism, a first movable bar and a second movable bar are respectively arranged at the upper end and the lower end of the movable arm in a sliding mode, a plurality of first clamping plates and second clamping plates are respectively connected to the side faces of the first movable bar and the second movable bar, the first clamping plates and the second clamping plates are arranged in a staggered mode, and a second driving device for achieving the opposite movement of the first movable bar and the second movable bar is arranged on the movable arm.

As the specific setting of above-mentioned scheme, the welding unit is including fixing the quick-witted case on frame top, the leading flank of machine case is provided with the welder mount pad through first telescoping device reciprocates, the interval is provided with multiunit welder head on the welder mount pad.

As a further arrangement of the scheme, the front side surface of the welding gun mounting seat is provided with a protective cover for placing all welding gun heads inside.

As the concrete setting of above-mentioned scheme, two carry the lifter between the charging tray, the both ends of lifter all are provided with the rotation seat, a drive arrangement is including setting up the first motor on the rotation seat, the motor shaft of first motor is connected with the lifter.

As the concrete setting of above-mentioned scheme, the rotation subassembly is gone into in the top including setting up second motor, the second telescoping device of two rotation seats top, second motor, second telescoping device's output all is connected with the toper kicking block, two the toper kicking block is in setting on same straight line, and the toper kicking block all carries the body draw-in groove alignment setting of charging tray uppermost.

As a further arrangement of the scheme, the pre-welding positioning mechanism further comprises a seat plate, and a third telescopic device connected with the movable arm is arranged on the seat plate.

As the specific setting of above-mentioned scheme, second drive arrangement is including setting up the third motor at the removal arm back, be connected with the drive gear who is located between first removal strip and the second removal strip on the output shaft of third motor, all seted up on first removal strip and the second removal strip with drive gear engaged with tooth's socket face.

As a further arrangement of the scheme, a feeding frame connected with the rotary switching mechanism is arranged right below the frame.

As a further setting of above-mentioned scheme, rotary switching mechanism's leading flank is provided with the unloading frame, the unloading frame is including controlling two support frames, and the upper end of two support frames all is connected with the guide block that laminates mutually with carrying the charging tray, and the front end of guide block is connected with the buffer block through the elastic component.

In the operation process of the scaffold steel pipe buckle welding device disclosed by the application, an operator puts the scaffold steel pipe sleeved with the buckle on a loading frame, rolls the scaffold steel pipe to a position propped against a material carrying disc in a rotary switching mechanism under the action of gravity, then clamps the scaffold steel pipe through a pipe body clamping groove on the material carrying disc in the rotation process of the rotary switching mechanism, and enables the scaffold steel pipe to rotate to a position of a pre-welding positioning mechanism along with the material carrying disc.

And then before the scaffold steel pipe and the disc buckles are welded, starting the pre-welding positioning mechanism to move the movable arm towards the direction of the movable arm, and enabling each disc buckle to be positioned between the adjacent two dislocated first clamping plates and the adjacent two dislocated second clamping plates. Then, the third motor is started to enable the driving gear to rotate, then the first moving strip and the second moving strip are enabled to move in opposite directions through the meshing action of tooth groove surfaces on the first moving strip and the second moving strip in the process of rotating the driving gear, all the dislocated first clamping plates and the dislocated second clamping plates are enabled to be close to each other, and the offset disc buckle is moved to the adjusted position along the direction of the scaffold steel tube to carry out positioning clamping.

Before the scaffold steel pipe and the disc buckle are rotationally switched to a station under the welding gun head, the third motor is reversely started to enable the first clamping plate and the second clamping plate to withdraw from the clamping effect of the disc buckle, and then the scaffold steel pipe and the disc buckle are conveyed to a welding station under the rotation effect of the material carrying disc. And in the welding process, the scaffold steel pipe is fixed by using the jacking rotating assembly, and is rotated in the welding process, and then the annular welding of the scaffold is completed in the rotating process, so that the welding quality of all the disc buckles is ensured to be consistent.

Finally, after the scaffold steel pipe and the disc buckle are welded, continuously enabling the material carrying disc to rotate, discharging the welded workpiece into a discharging frame for cooling, and taking down the workpiece after cooling for a period of time.

Compared with the prior art, the application has the following beneficial effects:

the scaffold steel pipe buckle welding device disclosed by the application realizes the switching of the stations of scaffold steel pipes before and after welding by utilizing the action of the material loading disc in the rotary switching mechanism, and realizes the automatic feeding and automatic discharging processes in the welding process by utilizing the action of the pipe orifice clamping groove on the material loading disc, thereby effectively improving the welding efficiency of the whole scaffold.

The application also carries out synchronous clamping and positioning on a plurality of disc buckles on the scaffold steel pipe before welding through the positioning mechanism before welding, effectively eliminates the deviation of the disc buckles in the feeding process of the scaffold, carries out rotary welding after the disc buckles are positioned, effectively improves the position accuracy of the disc buckle welding, and simultaneously effectively ensures the welding quality of the whole scaffold.

According to the pre-welding positioning mechanism, the clamping and positioning of the plurality of disc buckles can be realized only by arranging one motor, excessive clamping driving parts such as air cylinders are not required to be arranged for the plurality of disc buckles, the height optimization of the whole pre-welding positioning mechanism is realized, the structural design is novel, and the positioning effect of the pre-welding disc buckles is excellent.

Drawings

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

Fig. 1 is a schematic view of a first angle perspective structure of embodiment 1 of the present application;

FIG. 2 is a schematic view of a second angle perspective structure of embodiment 1 of the present application;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1A according to the present application;

FIG. 4 is a schematic view of a first angular perspective of a pre-weld positioning mechanism according to the present application;

FIG. 5 is a schematic view of a second angular perspective of the pre-weld positioning mechanism of the present application;

fig. 6 is a schematic perspective view of embodiment 2 of the present application;

fig. 7 is an enlarged schematic view of the structure of fig. 6B according to the present application.

Detailed Description

In order that those skilled in the art will better understand the present application, a technical solution in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present application without making any inventive effort, shall fall within the scope of the present application.

It should be noted that, without conflict, the embodiments of the present application and features of the embodiments may be combined with each other. The present application will be described in detail with reference to fig. 1 to 7, and examples.

Example 1

Embodiment 1 discloses a scaffold button welding device, referring to fig. 1 and 2, comprising a frame 100, a welding unit 200, a rotary switching mechanism 300, a pre-welding positioning mechanism 400, and a loading frame 500. The rack 100 includes a bottom plate 101 and two uprights 102, and the two uprights 102 are fixed to left and right ends of the bottom plate 101, respectively.

The welding unit 200 comprises a case 201 fixedly arranged between the top ends of two uprights 102, welding gun installation seats 202 are arranged on the front side face of the case 201 in a vertically moving mode, a plurality of groups of welding gun heads 203 which are downwards arranged are arranged on the welding gun installation seats 202 at intervals, the specific welding gun heads 203 are generally arranged between 4-8 groups, the welding gun heads are determined by the number of disc buckles which are required to be welded on a scaffold steel pipe 600, each group of welding gun heads 203 is provided with two welding gun heads, and the two welding gun heads 203 are arranged in a mirror symmetry mode and are close to the middle of the lower end. A first telescopic device 204 is fixedly installed on the case 201, and the first telescopic device 204 can be an air cylinder or a hydraulic cylinder, and is connected with the welding gun mounting seat 202. In addition, in order to ensure the stable up-and-down movement of the welding gun mounting seat 202, a vertical sliding rail 205 is further provided on the front side surface of the chassis 201, and a sliding slot opening matching with the welding gun mounting seat 202 is provided on the back surface thereof.

Referring to fig. 1 and 3, the rotation switching mechanism 300 includes two rotation seats 301 provided at both left and right ends of the base plate 101, a rotation lever 302 is provided between the two rotation seats 301, and the rotation lever 302 is located directly under the row of torch heads 203. A loading tray 303 is welded at each of the left and right ends of the rotating rod 302, and a plurality of pipe body clamping grooves 3031 are uniformly formed in the outer circumferential surface of the loading tray 303. A first motor 304 is arranged on the rotating seat 301, the first motor 304 is connected with the rotating rod 302, a servo motor or a stepping motor is preferably selected for the first motor 304, and the rotation number of the first motor 304 can be controlled by a control pulse signal, so that the station switching of scaffold steel pipes on the material carrying disc 303 is realized.

In addition, a second motor 305 is disposed at the top end of the rotating seat 301 mounted with the first motor 304, a conical top block 306 is connected to the end of the output shaft of the second motor 305, a seat block 307 is disposed at the position of the other rotating seat 301, a second telescopic device 308 is disposed at the top end of the seat block 307, one of an air cylinder or a hydraulic cylinder may be used as the second telescopic device 309, the conical top block 306 is rotatably connected to the telescopic end of the second telescopic device 308, and the two conical top blocks 306 are disposed on the same straight line and aligned with the pipe body clamping groove 3031 at the uppermost end of the material carrying disc 303. When the scaffold steel pipe sleeved with the plate buckle rotates to the uppermost end of the material carrying plate 303, the second telescopic device 308 is started to slightly push the scaffold steel pipe to a small distance in the direction of the second motor 305, at the moment, the two conical jacking blocks 306 are respectively jacked into pipe orifices at two ends of the scaffold, and then the second motor 305 is started to realize the rotation function of the scaffold steel pipe.

Referring to fig. 2, 4 and 5, the pre-welding positioning mechanism 400 is fixedly disposed on the lower surface of the chassis 201 in the welding unit 200, and includes a seat plate 401, a moving arm 402 is disposed on one side of the seat plate 401 near the rotary switching mechanism 300, a third telescopic device 403 connected to the moving arm 402 is mounted on the seat plate 401, the moving arm 402 moves in a direction approaching or moving away from the rotary switching mechanism 300 by the action of the third telescopic device 403, and in order to ensure stability during movement, a longitudinal sliding rail 404 is disposed on the seat plate 401, and a sliding slot matched with the moving arm 402 is disposed on the moving arm 402.

The upper and lower inner walls of the moving arm 402 are respectively provided with a transverse sliding rail 405, the upper and lower transverse sliding rails 405 are respectively provided with a first moving strip 406 and a second moving strip 407 in a sliding manner, a plurality of first clamping plates 408 are welded on the first moving strip 406 at intervals, and a plurality of second clamping plates 409 are welded on the first moving strip 406 at intervals. The specific number of the first clamping plates 408 and the second clamping plates 409 is the same as the number of the welding gun head 203 groups, and the first clamping plates 408 and the second clamping plates 409 are arranged in a staggered manner. A tooth slot surface 410 is provided on opposite sides of the middle section of the first moving bar 406 and the second moving bar 407, and a driving gear 411 is provided between the two tooth slot surfaces 411, and then a third motor 412 is mounted on the back surface of the moving arm 402, and a motor shaft of the third motor 412 is connected with the driving gear 411. When the third motor 412 is started to rotate the driving gear 411, the first moving bar 406 and the second moving bar 407 move synchronously and oppositely due to the meshing action of the gears, at this time, each corresponding first clamping plate 408 and second clamping plate 409 are close to each other, so as to clamp and position the disc buckle sleeved on the scaffold steel tube 600, and after the positioning is completed, the motor is driven reversely to enable the first clamping plate 408 and the second clamping plate 409 to be far away from each other, so that the disc buckle is not clamped.

Finally, the feeding frame 500 is disposed directly below the pre-welding positioning mechanism 400, and includes a left first supporting frame 501 and a right first supporting frame 501, and a first guide block 502 that is inclined downward toward the direction of the rotary switching mechanism 300 is disposed at the upper end of each first supporting frame 501, and the front end of the first guide block 502 is attached to the circumferential surface of the corresponding loading tray 303. To ensure stability of the entire loading ledges 500, a transverse connecting rod 503 is also connected between the two first support frames 501. In the feeding process, two ends of the scaffold steel tube sleeved with the coil buckle are placed on the first guide block 502, then the scaffold steel tube is rolled to a position propped against the material carrying disc 303 by utilizing the action of gravity, then in the subsequent rotation process of the material carrying disc 303, two ends of the scaffold steel tube 600 can enter the tube clamping groove 3031 and rotate to a pre-welding positioning station along with the rotation of the material carrying disc 303, and the scaffold steel tube is positioned by rotating the coil buckle to the position right below the welding gun head 203 and then is subjected to annular full welding.

Example 2

Embodiment 2 discloses a scaffold button welding device which is improved based on the technical scheme of embodiment 1, and the same points as those of embodiment 1 are not explained again, and the differences are referred to in fig. 6 and fig. 7.

The welding unit 200 of this embodiment 2 includes a shield 206 attached to the gun mount 202, the shield 206 having all of the gun tips 203 disposed therein and extending a length down the shield 206. In the operation process of the welding unit 200, the welding gun mounting seat 202 is pushed downwards through the first telescopic device 204, so that each group of welding gun heads 203 are aligned to two sides of the upper disc buckle of the scaffold steel tube 600, meanwhile, the welding position is effectively shielded by the protective cover 206, and then in the process of driving the scaffold steel tube 600 to rotationally weld through the second motor 305, sparks generated in the welding process can be shielded through the protective cover 206, and the influence caused by sparks four shots is avoided.

In addition, in embodiment 2, a blanking frame 700 is further disposed on the front side of the welding unit 200, the blanking frame 700 includes two left and right second supporting frames 701, and second guide blocks 702 attached to the circumferential surface of the loading tray 303 are disposed at the upper ends of the two second supporting frames 701, so that the welded scaffold can fall on the second guide blocks 702 and automatically roll forward. In addition, a buffer block 704 is connected to the front end of each second guide block 702 through a spring 703, and an arc-shaped groove adapted to the scaffold steel tube 600 is formed in the buffer block 704. The buffer block 704 can prevent the falling scaffold steel tube 600 from colliding with the front end of the second guide block 702, and avoid the surface quality influence caused by collision.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the application.

Claims (9)

1. The welding device for the scaffold plate buckle comprises a frame and a welding unit, wherein the welding unit is fixedly arranged at the upper end of the frame;

the rotary switching mechanism comprises two material carrying discs which are arranged left and right, a first driving device for realizing synchronous rotation of the two material carrying discs, a plurality of pipe body clamping grooves are uniformly formed in the circumferential surface of the material carrying discs, and the rotary switching mechanism further comprises a jacking rotary assembly for rotationally driving scaffold steel pipes in the uppermost pipe body clamping grooves;

the welding front positioning mechanism comprises a movable arm which is arranged in a direction of the rotary switching mechanism, a first movable bar and a second movable bar are respectively arranged at the upper end and the lower end of the movable arm in a sliding mode, a plurality of first clamping plates and second clamping plates are respectively connected to the side faces of the first movable bar and the second movable bar, the first clamping plates and the second clamping plates are arranged in a staggered mode, and a second driving device for achieving the opposite movement of the first movable bar and the second movable bar is arranged on the movable arm.

2. The scaffold plate button welding device according to claim 1, wherein the welding unit comprises a case fixed at the top end of the frame, a welding gun mounting seat is arranged on the front side surface of the case in a vertically moving manner through a first telescopic device, and a plurality of groups of welding gun heads are arranged on the welding gun mounting seat at intervals.

3. The scaffold button welding device of claim 2, wherein a front side of the welding gun mount is provided with a shield that houses all gun heads inside.

4. The scaffold plate button welding device according to claim 1, wherein a rotating rod is connected between the two material carrying plates, two ends of the rotating rod are provided with rotating seats, the first driving device comprises a first motor arranged on the rotating seats, and a motor shaft of the first motor is connected with the rotating rod.

5. The welding device for scaffold disc buckles according to claim 4, wherein the jacking rotating assembly comprises a second motor and a second telescopic device which are arranged above two rotating seats, the output ends of the second motor and the second telescopic device are connected with conical jacking blocks, the two conical jacking blocks are arranged on the same straight line, and the conical jacking blocks are aligned with the pipe clamping grooves at the uppermost end of the loading disc.

6. The scaffold button welding device according to claim 1, wherein the pre-welding positioning mechanism further comprises a seat plate, and a third telescopic device connected with the movable arm is arranged on the seat plate.

7. The welding device for scaffold buttons of claim 1 or 6, wherein the second driving device comprises a third motor arranged on the back of the movable arm, a driving gear arranged between the first movable bar and the second movable bar is connected to an output shaft of the third motor, and tooth socket surfaces meshed with the driving gear are formed on the first movable bar and the second movable bar.

8. The scaffold button welding device according to claim 1, wherein a loading frame engaged with a rotary switching mechanism is provided directly under the frame.

9. The scaffold plate button welding device according to claim 1 or 8, wherein a discharging frame is arranged on the front side surface of the rotary switching mechanism, the discharging frame comprises a left supporting frame and a right supporting frame, the upper ends of the two supporting frames are connected with guide blocks attached to the material carrying tray, and the front ends of the guide blocks are connected with buffer blocks through elastic pieces.