CN218518003U - Novel industrial fan mesh enclosure automatic welding machine - Google Patents

Abstract

The utility model discloses a novel industrial fan screen panel automatic welding machine, the positioning die who is equipped with the screen panel through the rotary mechanism drive rotates to the position that needs the welding on the screen panel, then welding electrode is close to the screen panel under the drive of first drive assembly, welding electrode is close to the screen panel on the drive of second drive assembly, weld the screen panel through the two electric arcs that are close to the production, accomplish the welding back, welding electrode is kept away from the screen panel on the drive of second drive assembly, then welding electrode is followed the radial direction motion of screen panel on the drive of third drive assembly, it moves to next welding position and welds to drive welding electrode, after accomplishing the welding, welding electrode resets to the initial position under the drive of first drive assembly, welding electrode resets to the initial position on the drive of second drive assembly and third drive assembly, rotary mechanism adjusts positioning die position, in order to carry out next round of welding; by adopting the design, the automatic welding machine can complete the welding of the mesh enclosure only by arranging a group of upper welding electrodes.

Description

Novel industrial fan mesh enclosure automatic welding machine

Technical Field

The utility model relates to a welding equipment technical field, in particular to novel industrial fan screen panel automatic welding machine.

Background

Patent 2018203706227 discloses an automatic welding device for a fan mesh enclosure, wherein a winding die frame positioning device is mounted at the end part of one end, connected with a welding machine, of a winding workbench, and is positioned below a winding die frame; simultaneously when the welding, the piston rod action of accessible third lift cylinder pushes up the wire winding mould position sleeve to the wire winding mould pivot lower extreme of wire winding mould in the installation axle head, realizes fixing a position the wire winding mould, avoids the wire winding mould to rotate around its center pin, appears the dislocation deviation when leading to the welding, influences welding quality.

According to the technical scheme, the existing automatic welding equipment for the fan mesh enclosure can be generally provided with a plurality of groups of upper welding electrodes and at least one lower welding electrode in discharge fit so as to perform a welding process on the fan mesh enclosure on the positioning die, and due to the adoption of the design, the production cost of the welding equipment is too high, so that the production cost of products is increased.

The utility model discloses it is not enough to the prior art and research and propose.

SUMMERY OF THE UTILITY MODEL

The automatic welding equipment aims at the technical problem that the production cost of the welding equipment is too high because multiple groups of upper welding electrodes are usually arranged on the automatic welding equipment for the fan mesh enclosure in the prior art.

The utility model provides a technical scheme that its technical problem adopted is:

the utility model provides a novel industry fan screen panel automatic welding machine, includes the welding main part, be equipped with in the welding main part and be used for assembling the positioning die of fan screen panel, be used for carrying out welded structure to the fan screen panel and be used for driving the rotary mechanism of positioning die rotation in order to adjust fan screen panel welded position, welded structure is including the last welding electrode that is located the fan screen panel outside and being located the inboard lower welding electrode of fan screen panel, be equipped with in the welding main part and be used for driving down welding electrode and be close to or keep away from the first drive assembly of fan screen panel and be used for driving the second drive assembly that welding electrode is close to or keeps away from the fan screen panel, still be equipped with in the welding main part and be used for driving the motion of second drive assembly to drive the third drive assembly of welding electrode along the radial direction reciprocating motion of fan screen panel.

In order to ensure that the third drive assembly can normally operate, the third drive assembly is including locating the sliding guide in the welding main part, sliding connection has a sliding seat on the sliding guide, the second drive assembly is located on the sliding seat, be equipped with in the welding main part and be used for driving the gliding third driver of sliding seat on sliding guide.

In order to ensure that the third driver can stably drive the sliding seat to slide on the sliding guide rail, the output end of the third driver is provided with a screw rod, and the screw rod is in threaded connection with the sliding seat.

In order to ensure that the second driving assembly can normally operate, the second driving assembly is a second driver fixedly arranged on the sliding seat, and the upper welding electrode is arranged on the output end of the second driver.

In order to increase the welding scope of novel industry fan screen panel automatic welder to the fan screen panel, still be equipped with in the welding subject and be used for carrying out the welded cambered surface welding electrode on the lateral surface of fan screen panel and be used for driving the fourth drive subassembly that cambered surface welding electrode is close to or keeps away from the fan screen panel, lower welding electrode include with last welding electrode complex horizontal segment and with last cambered surface welding electrode complex segmental arc.

In order to ensure that the rotating mechanism can normally operate, the rotating mechanism comprises a rotating driver fixedly arranged on the welding main body and a rotating shaft arranged on the output end of the rotating driver, and an installation shaft end corresponding to the rotating shaft is arranged on the positioning die.

In order to ensure that first drive assembly can normal operating, first drive assembly is including locating the fixing base in the welding main part, be equipped with the fixed part that two intervals set up on the fixing base, two the fixed part between be equipped with the sliding block, each the fixed part on all be equipped with the spout, the equal sliding connection in the spout that corresponds in both sides of sliding block, be equipped with the assembly seat that is used for welding electrode under the assembly on the sliding block, be equipped with the first driver of being connected with the assembly seat in the welding main part, first driver is used for driving the motion of assembly seat to it slides on the spout to drive the sliding block.

In order to make the structure of the first driving assembly more compact, an avoiding hole for avoiding the first driver is arranged on the sliding block.

In order to improve the welding safety of the lower welding electrode, a telescopic fixing part for preventing the lower welding electrode from shaking in the welding process is further arranged on the welding main body, the telescopic fixing part comprises a telescopic driver arranged on the welding main body, and a fixing assembly is arranged on the output end of the telescopic driver.

In order to ensure that flexible fixed part can normal operating, fixed subassembly is including locating the fixed plate on the flexible driver output and locating the fixed shim on the fixed plate, the fixing base is close to one of flexible driver and serves and be equipped with the assembly piece corresponding with the fixed shim, be equipped with the pilot hole on the assembly piece, the one end of fixed shim is slided and is located in the pilot hole.

The utility model has the advantages that:

the utility model discloses a novel industrial fan screen automatic welding machine, which comprises a welding main body, wherein a positioning die, a welding structure and a rotating mechanism are arranged on the welding main body, the welding structure comprises upper welding electrodes in a group and lower welding electrodes in a group, when the automatic welding machine carries out welding process on the fan screen, firstly, the screen is assembled on the positioning die, then the rotating mechanism drives the positioning die to rotate to a position on the screen which needs to be welded, then the first driving component drives the lower welding electrodes to move to the top surface close to or offset against the inner side surface of the screen, then the second driving component drives the upper welding electrodes to move to the top surface close to or offset against the outer side surface of the screen, and the upper welding electrodes and the lower welding electrodes are close to each other, when the welding process is finished, the first driving assembly drives the lower welding electrode to be away from the net cover, the second driving assembly drives the upper welding electrode to be away from the net cover, the third driving assembly drives the upper welding electrode to be reset to an initial position, and then the rotating mechanism drives the positioning die to continuously rotate so as to adjust the net cover to rotate to a specified position to perform the next round of welding process; by adopting the design, the automatic welding machine can complete the welding process of the mesh enclosure by arranging the third driving assembly and then matching the third driving assembly with the second driving assembly and the welding electrode on the third driving assembly, and compared with the design of adopting the second driving assembly and the welding electrode on the third driving assembly, the production cost of the welding equipment can be effectively reduced, thereby reducing the production cost of products.

The present invention will be further described with reference to the accompanying drawings and the following detailed description.

Drawings

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

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

fig. 3 is one of the schematic structural diagrams of the third driving assembly, the second driving assembly and the upper welding electrode of the present invention after being assembled;

fig. 4 is a second schematic structural diagram of the third driving assembly, the second driving assembly and the upper welding electrode of the present invention after being assembled;

fig. 5 is a schematic structural view of the rotating mechanism and the positioning mold of the present invention after assembly;

fig. 6 is one of the structural diagrams of the first driving assembly, the lower welding electrode and the telescopic fixing component according to the present invention after being assembled;

fig. 7 is a second schematic structural view of the first driving assembly, the lower welding electrode and the telescopic fixing component of the present invention after assembly;

fig. 8 is one of the exploded views of the first driving assembly, the lower welding electrode and the telescopic fixing member according to the present invention after assembly;

fig. 9 is an exploded view of the first driving assembly, the lower welding electrode, and the telescopic fixing member according to the present invention.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1 to fig. 2, the novel industrial automatic welding machine for a fan mesh enclosure in this embodiment includes a welding main body 1, where the welding main body 1 is provided with a positioning mold 3 for assembling the fan mesh enclosure, a welding structure for welding the fan mesh enclosure, and a rotating mechanism 4 for driving the positioning mold 3 to rotate to adjust a welding position of the fan mesh enclosure, the welding structure includes an upper welding electrode 5 located outside the fan mesh enclosure and a lower welding electrode 2 located inside the fan mesh enclosure, the welding main body 1 is provided with a first driving component 11 for driving the lower welding electrode 2 to approach or be away from the fan mesh enclosure and a second driving component 12 for driving the upper welding electrode 5 to approach or be away from the fan mesh enclosure, and the welding main body 1 is further provided with a third driving component 13 for driving the second driving component 12 to move so as to drive the upper welding electrode 5 to reciprocate along a radial direction of the fan mesh enclosure;

the utility model discloses a novel industrial fan screen automatic welding machine, which comprises a welding main body, wherein a positioning die, a welding structure and a rotating mechanism are arranged on the welding main body, the welding structure comprises upper welding electrodes in a group and lower welding electrodes in a group, when the automatic welding machine carries out welding process on the fan screen, firstly, the screen is assembled on the positioning die, then the rotating mechanism drives the positioning die to rotate to a position on the screen which needs to be welded, then the first driving component drives the lower welding electrodes to move to the top surface close to or offset against the inner side surface of the screen, then the second driving component drives the upper welding electrodes to move to the top surface close to or offset against the outer side surface of the screen, and the upper welding electrodes and the lower welding electrodes are close to each other, when the welding process is finished, the first driving assembly drives the lower welding electrode to be away from the net cover, the second driving assembly drives the upper welding electrode to be away from the net cover, the third driving assembly drives the upper welding electrode to be reset to an initial position, and then the rotating mechanism drives the positioning die to continuously rotate so as to adjust the net cover to rotate to a specified position to perform the next round of welding process; by adopting the design, the automatic welding machine can complete the welding process of the mesh enclosure by arranging the third driving assembly and then matching the third driving assembly with the second driving assembly and the welding electrode on the third driving assembly, and compared with the design of adopting the second driving assembly and the welding electrode on the third driving assembly, the production cost of the welding equipment can be effectively reduced, thereby reducing the production cost of products.

As shown in fig. 3 to 4, the third driving assembly 13 of the present embodiment includes a sliding guide rail 131 disposed on the welding main body 1, the sliding guide rail 131 is slidably connected with a sliding seat 132, the second driving assembly 12 is fixedly disposed on the sliding seat 132, the welding main body 1 is provided with a third driver 133, an output end of the third driver 133 is connected with the sliding seat 132, and under the action of the third driver 133, the sliding seat 132 can be driven to slide on the sliding guide rail 131 in a reciprocating manner along the radial direction of the fan guard.

As shown in fig. 3, the output end of the third driver 133 of this embodiment is provided with a screw 134, the third driver 133 can drive the screw 134 to rotate circumferentially, the screw 134 is connected with the sliding seat 132 by a thread, specifically, when the third driver 133 drives the screw 134 to rotate circumferentially, the screw 134 can drive the sliding seat 132 to slide on the sliding guide rail 131, so as to drive the second driving assembly 12 to move along the radial direction of the fan mesh enclosure, and the transmission manner is simple and reliable; the screw rod transmission mode has the advantages of simple structure, easy processing, low cost, large transmission axial force, self-locking and high positioning precision.

As shown in fig. 1 to fig. 4, the second driving assembly 12 of this embodiment is a second driver fixedly disposed on the sliding seat 132, the second driver has an output end capable of extending and retracting, the upper welding electrode 5 is disposed on the output end of the second driver, and the second driver extends and retracts through the output end to drive the welding surface of the upper welding electrode to be close to or away from the outer side surface of the fan mesh enclosure, which has the advantages of simple structure and convenient operation.

As shown in fig. 1 to 2, the welding main body 1 of the present embodiment is further provided with an upper arc welding electrode 7 for welding an outer side surface of the fan mesh enclosure, and a fourth driving component 14 for driving the upper arc welding electrode 7 to be close to or far away from the fan mesh enclosure, preferably, the fourth driving component 14 is a fourth driver fixedly arranged on the welding main body 1, the upper arc welding electrode 7 is arranged at an output end of the fourth driver, the fourth driver drives a welding surface of the upper arc welding electrode 7 to be close to or far away from the outer side surface of the fan mesh enclosure through extension and retraction of the output end, and the upper welding electrode 5 and the upper arc welding electrode 7 are arranged in an arc shape along a welding outer arc surface of the fan mesh enclosure;

specifically, welding electrode 2 includes with last welding electrode 5 complex horizontal segment and with last cambered surface welding electrode 7 complex arc section, the face of weld of going up welding electrode 5 is close or the same with the radian of the top lateral surface of fan screen panel, the face of weld of welding electrode 2 horizontal segment is close or the same with the radian of the top medial surface of fan screen panel down, the face of weld of going up cambered surface welding electrode 7 is close or the same with the radian of the lateral surface of fan screen panel, the face of weld of welding electrode 2 arc section is close or the same with the radian of the side medial surface of fan screen panel down, adopts such design for last welding electrode 5, lower welding electrode 2 and last cambered surface welding electrode 7 can be close to the fan screen panel more, and can carry out the omnidirectional welding to whole fan screen panel, guarantees the welding effect.

As shown in fig. 1, fig. 2 and fig. 5, the rotating mechanism 4 of the present embodiment includes a rotating driver 41 fixedly disposed on the welding body 1 and a rotating shaft 42 disposed on an output end of the rotating driver 41, and the positioning mold 3 is provided with an installation shaft end 31 corresponding to the rotating shaft 42; rotatory driver 41 can drive rotatory pivot 42 circumference rotation, drives positioning die 3 through installation axle head 31 and rotates to the welding position of adjustment fan screen panel, it is preferred, installation axle head 31 is located positioning die 3's central point department, positioning die's outline is circular form, the length size of welding electrode 2 slightly is less than positioning die 3's radius size down to guarantee the welding range between welding electrode and the lower welding electrode, improve the welding effect.

As shown in fig. 1, fig. 2, and fig. 6 to fig. 9, the first driving assembly 11 of the present embodiment includes a fixing seat 111 disposed on the welding main body 1, two fixing portions 112 disposed at an interval are disposed on the fixing seat 111, a sliding block 113 is disposed between the two fixing portions 112, a sliding slot 1121 is disposed on each fixing portion 112, two sides of the sliding block 113 extend into the corresponding sliding slot 1121, and the sliding slots 1121 are slidably connected, so that the sliding block 113 can slide on the fixing seat 111 through the matching with the sliding slot 1121, an assembling seat 114 for assembling the lower welding electrode 2 is disposed on the sliding block 113, a first driver 115 is disposed on the welding main body 1, specifically, the first driver 115 has an output end capable of extending and retracting, an output end of the first driver 115 is connected with a side surface of the assembling seat 114 away from the lower welding electrode 2, and an output end of the first driver 115 can drive the sliding block 113 to slide on the fixing seat 111 through the assembling seat 114, so as to drive the lower welding electrode 2 to approach or leave the fan mesh cover.

As shown in fig. 1, 2, and 6 to 9, the sliding block 113 of the present embodiment is provided with an avoiding hole 1131 for avoiding the first driver 115, so as to reduce the volume of the first driving assembly, so that the structure of the automatic welding machine for the industrial fan mesh enclosure is more compact, the volume of the automatic welding machine is further reduced, and the space occupied by the assembly is reduced.

As shown in fig. 1, fig. 2, fig. 6 to fig. 9, the welding main body 1 of this embodiment is further provided with a telescopic fixing component for preventing the lower welding electrode 2 from shaking during the welding process, the telescopic fixing component includes a telescopic driver 8 disposed on the welding main body 1, the telescopic driver 8 has an output end capable of stretching, the output end of the telescopic driver 8 is provided with a fixing component 6, when the first driving component drives the outer side surface of the lower welding electrode 2 to abut against the inner side surface of the fan mesh enclosure, the telescopic driver 8 can drive the fixing component 6 to move to the lower side of the sliding block 113, so that the sliding block 113 is locked on the fixing component 6, thereby preventing the sliding block from moving in the direction away from the positioning mold due to the acting force generated when the upper welding electrode and the lower welding electrode are matched, avoiding the lower welding electrode from shaking up and down, and ensuring the welding effect on the fan mesh enclosure.

As shown in fig. 1, fig. 2, and fig. 6 to fig. 9, the fixing assembly 6 of this embodiment includes a fixing plate 61 disposed on the output end of the telescopic driver 8 and two fixing spacers 62 disposed on the fixing plate 61, preferably, the number of the fixing spacers 62 is two, and the two fixing spacers 62 are disposed on the fixing plate 61 at intervals and are respectively located at two sides of the first driver 115;

specifically, an assembly block 63 corresponding to the fixing pad 62 is disposed on one end of the fixing seat 111 close to the telescopic driver 8, an assembly hole 64 is disposed on each assembly block 63, one end of each fixing pad 62 is slidably disposed in the corresponding assembly hole 64, and in an initial state, one end of each fixing pad 62 is located in the assembly hole 64;

specifically, when the first driving assembly drives the outer side surface of the lower welding electrode 2 to abut against the inner side surface of the fan mesh enclosure, the telescopic driver 8 drives the fixing pad 62 on the fixing plate 61 to extend out of the assembly hole 64, so that the fixing pad 62 is located below the bottom of the sliding block 113, and the fixing pad 62 and the sliding block 113 abut against or abut against each other, and at this time, the fixing pad 62 can abut against the sliding block 113, so that the sliding block 113 is locked on the fixing seat 111;

when the fixing plate 61 moves in the direction away from the assembling block 63 under the action of the telescopic driver 8, the fixing gasket 62 retracts into the assembling hole 64, and the top surface of the fixing gasket 62 is no longer close to or abutted against the bottom of the sliding block 113, so that the sliding block 113 is in an unlocking state on the fixing seat 111, and the lower welding electrode 2 can move in the direction away from the fan mesh enclosure.

Preferably, the first driver, the second driver, the fourth driver and the telescopic driver may be air cylinders or servo motors, and the types of the drivers are selected according to actual requirements of users.

The utility model discloses a novel industrial fan screen panel automatic welding machine's theory of operation:

when the welding process is carried out, the rotary driver drives the positioning die to rotate to a position to be welded through the rotary rotating shaft, the first driver drives the sliding block to move on the fixed seat in the direction close to the fan mesh enclosure, so that the lower welding electrode on the assembling seat is driven to be close to the fan mesh enclosure, and the welding surface of the lower welding electrode is close to or abutted against the inner side surface of the fan mesh enclosure;

the telescopic driver drives the fixed gasket on the fixed plate to extend out of the assembly hole, so that the fixed gasket is positioned below the bottom of the sliding block and is close to or abutted against the fixed gasket, and specifically, the top surface of the fixed gasket is abutted against the bottom of the sliding block;

the second driver drives the upper welding electrode to be close to the fan mesh enclosure so that the welding surface of the upper welding electrode is close to or abutted against the outer side surface of the fan mesh enclosure, and the upper welding electrode and the horizontal section of the lower welding electrode are matched to discharge at the moment, so that the welding process is carried out on the fan mesh enclosure;

after welding is completed, the second driver drives the upper welding electrode to be far away from the fan mesh enclosure, then the third driver drives the screw rod to rotate circumferentially to drive the sliding seat to slide on the sliding guide rail along the radial direction of the fan mesh enclosure, so that the upper welding electrode on the second driver is driven to move to the next welding position, then the fan mesh enclosure is welded until the upper welding electrode on the second driver moves to the position closest to the upper cambered surface welding electrode, after the upper welding electrode is welded to the mesh enclosure, the fourth driver drives the upper cambered surface welding electrode to be close to the fan mesh enclosure, and at the moment, the upper cambered surface welding electrode and the cambered section of the lower welding electrode are matched to discharge, so that the welding process is performed on the cambered outer side surface of the fan mesh enclosure;

accomplish the welding back, cambered surface welding electrode keeps away from the fan screen panel on the fourth driver drive, resets to initial position, welding electrode keeps away from the fan screen panel on the second driver drive, and the reverse circumferential direction of third driver drive lead screw to welding electrode resets to initial position on the drive, flexible driver drive fixed plate is toward keeping away from the fixing base direction and is removed to make the fixed shim withdrawal assembly hole, first driver can drive the sliding block and remove at the fixing base toward the direction of keeping away from the fan screen panel to welding electrode keeps away from the fan screen panel under the drive, resets to initial position, then rotates to next welding position through rotatory driver drive positioning die utensil, thereby begins next round weldment work.

The technical contents of the present invention are further described by the above embodiments only, so that the reader can understand the embodiments more easily, but the embodiments of the present invention are not limited to the above embodiments, and any technical extension or re-creation according to the present invention is protected by the present invention. The protection scope of the present invention is subject to the claims.

Claims (10)

1. The utility model provides a novel industry fan screen panel automatic welder, includes welding main part (1), its characterized in that: be equipped with on welding main part (1) and be used for assembling fan screen panel positioning die (3), be used for carrying out welded structure to the fan screen panel and be used for driving rotary mechanism (4) of positioning die (3) rotation in order to adjust fan screen panel welded position, welded structure is including last welding electrode (5) that is located the fan screen panel outside and lower welding electrode (2) that is located the fan screen panel inboard, be equipped with on welding main part (1) and be used for driving down welding electrode (2) and be close to or keep away from fan screen panel's first drive assembly (11) and be used for driving second drive assembly (12) that welding electrode (5) are close to or keep away from the fan screen panel, still be equipped with on welding main part (1) and be used for driving second drive assembly (12) motion to welding electrode (5) third drive assembly (13) along the radial direction reciprocating motion of fan screen panel on the drive.

2. The novel automatic welder for the industrial fan mesh enclosure as claimed in claim 1, wherein: third drive assembly (13) is including locating sliding guide (131) on welding main part (1), sliding connection has a sliding seat (132) on sliding guide (131), second drive assembly (12) are located on sliding seat (132), be equipped with on welding main part (1) and be used for driving gliding third driver (133) of sliding seat (132) on sliding guide (131).

3. The novel automatic welder for the industrial fan mesh enclosure as claimed in claim 2, wherein: the output end of the third driver (133) is provided with a screw rod (134), the screw rod (134) is in threaded connection with the sliding seat (132), and when the third driver (133) drives the screw rod (134) to rotate circumferentially, the screw rod (134) can drive the sliding seat (132) to slide on the sliding guide rail (131).

4. The novel automatic welder for the industrial fan mesh enclosure as claimed in claim 2, wherein: the second driving component (12) is a second driver fixedly arranged on the sliding seat (132), and the upper welding electrode (5) is arranged on the output end of the second driver.

5. The novel automatic welder for the industrial fan mesh enclosure as claimed in claim 1, wherein: still be equipped with on welding main part (1) and be used for carrying out welded last cambered surface welding electrode (7) to the lateral surface of fan screen panel, and be used for driving fourth drive subassembly (14) that cambered surface welding electrode (7) are close to or keep away from the fan screen panel, lower welding electrode (2) include with last welding electrode (5) complex horizontal segment and with last cambered surface welding electrode (7) complex segmental arc.

6. The novel automatic welder for the industrial fan mesh enclosure as claimed in claim 1, wherein: the rotating mechanism (4) comprises a rotating driver (41) fixedly arranged on the welding main body (1) and a rotating shaft (42) arranged on the output end of the rotating driver (41), and an installation shaft end (31) corresponding to the rotating shaft (42) is arranged on the positioning die (3).

7. The novel automatic welding machine for the industrial fan mesh enclosure as claimed in claim 1, characterized in that: first drive assembly (11) is including locating fixing base (111) on welding main part (1), be equipped with fixed part (112) that two intervals set up on fixing base (111), two fixed part (112) between be equipped with sliding block (113), each fixed part (112) on all be equipped with spout (1121), the equal sliding connection in spout (1121) that corresponds in both sides of sliding block (113), be equipped with assembly seat (114) that are used for assembling welding electrode (2) down on sliding block (113), be equipped with first driver (115) of being connected with assembly seat (114) on welding main part (1), first driver (115) are used for driving assembly seat (114) and move to drive sliding block (113) and slide on spout (1121).

8. The novel industrial fan guard automatic welding machine as claimed in claim 7, wherein: and an avoiding hole (1131) for avoiding the first driver (115) is formed in the sliding block (113).

9. The novel industrial fan guard automatic welding machine as claimed in claim 7, wherein: still be equipped with the flexible fixed part that is used for preventing welding electrode (2) from taking place to rock when carrying out the welding process down on welding main part (1), flexible fixed part is including locating flexible driver (8) on welding main part (1), be equipped with fixed subassembly (6) on the output of flexible driver (8), work as when the lateral surface of welding electrode (2) offsets with the medial surface of fan screen panel down, flexible driver (8) can drive fixed subassembly (6) and remove the below to sliding block (113) to make sliding block (113) locking on fixed subassembly (6).

10. The novel automatic welding machine for the industrial fan mesh enclosure as claimed in claim 9, wherein: fixed subassembly (6) are including locating fixed plate (61) on flexible driver (8) output and locating fixed shim (62) on fixed plate (61), fixing base (111) are close to one of flexible driver (8) and serve and be equipped with assembly piece (63) corresponding with fixed shim (62), be equipped with pilot hole (64) on assembly piece (63), the one end of fixed shim (62) slides and locates in pilot hole (64), works as when fixed plate (61) down toward keeping away from assembly piece (63) direction motion under the effect of flexible driver (8), in fixed shim (62) withdrawal pilot hole (64), and the top surface of fixed shim (62) no longer presses close to or offsets with the bottom of sliding block (113).

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