阅读说明：本技术 一种焊接点位温度监测系统 (Welding point position temperature monitoring system ) 是由 陈多 于 2021-10-22 设计创作，主要内容包括：本发明公开了一种焊接点位温度监测系统,包括外壳,外壳内开设处理腔,处理腔内壁上开设有两个左右对称的进料腔,处理腔后壁上开设有滑动腔,滑动腔内滑动设有调整块,调整块内转动设有转动轴,转动轴上滑动设有焊条,外壳顶面上开设有第一光滑腔,第一光滑腔底壁上滑动设有滑动块,滑动块上滑动设有滑动杆,滑动杆底面上开设有火花腔,火花腔内壁上转动设有转动球,滑动杆底面上固定设有两个左右对称的扇形板,左侧的扇形板底面上固定设有测温器,本发明能够根据焊接点位温度变化,自动迅速调整加工温度,自动对工件进行冷却处理,避免加工时对工件造成巨大的损坏,本发明将焊接与切割组合使用,能够提升工件的加工效率。(The invention discloses a welding point position temperature monitoring system, which comprises a shell, wherein a processing cavity is formed in the shell, two bilaterally symmetrical feeding cavities are formed in the inner wall of the processing cavity, a sliding cavity is formed in the rear wall of the processing cavity, an adjusting block is arranged in the sliding cavity in a sliding manner, a rotating shaft is rotatably arranged in the adjusting block, a welding rod is arranged on the rotating shaft in a sliding manner, a first smooth cavity is formed in the top surface of the shell, a sliding block is arranged on the bottom wall of the first smooth cavity in a sliding manner, a sliding rod is arranged on the sliding block in a sliding manner, a spark cavity is formed in the bottom surface of the sliding rod, a rotating ball is rotatably arranged on the inner wall of the spark cavity, two bilaterally symmetrical sector plates are fixedly arranged on the bottom surface of the sliding rod, and a temperature measurer is fixedly arranged on the bottom surface of the sector plate on the left side of the shell. The invention combines welding and cutting, and can improve the processing efficiency of workpieces.)

1. A welding point location temperature monitoring system, includes shell (10), its characterized in that: the top surface of the shell (10) is fixedly provided with a controller (54), a treatment cavity (11) is formed in the shell (10), the inner wall of the treatment cavity (11) is provided with two bilaterally symmetrical feeding cavities (12), the rear wall of the treatment cavity (11) is provided with a sliding cavity (32), an adjusting block (36) is arranged in the sliding cavity (32) in a sliding manner, a rotating shaft (40) is rotatably arranged in the adjusting block (36), and a welding rod (39) is slidably arranged on the rotating shaft (40);

a first smooth cavity (15) is formed in the top surface of the shell (10), a sliding block (16) is arranged on the bottom wall of the first smooth cavity (15) in a sliding mode, a sliding rod (19) is arranged on the sliding block (16) in a sliding mode, a spark cavity (26) is formed in the bottom surface of the sliding rod (19), a rotating ball (25) is rotatably arranged on the inner wall of the spark cavity (26), a spark nozzle (27) is fixedly arranged on the bottom surface of the rotating ball (25), two fan-shaped plates (22) which are symmetrical left and right are fixedly arranged on the bottom surface of the sliding rod (19), a temperature detector (24) is fixedly arranged on the bottom surface of the fan-shaped plate (22) on the left side, and a dry ice nozzle (23) is formed in the bottom surface of the fan-shaped plate (22) on the right side;

a workbench (33) is fixedly arranged on the bottom wall of the treatment cavity (11), two second smooth cavities (43) which are symmetrical front and back are formed in the top surface of the workbench (33), smooth plates (44) are arranged in the two second smooth cavities (43) in a sliding mode, lifting cavities (45) are formed in the top surfaces of the two smooth plates (44), a fixing plate (34) is arranged in the treatment cavity (11) in a sliding mode, and the bottom end of the fixing plate (34) is inserted into the two lifting cavities (45);

the laser cutting machine is characterized in that a sliding plate (28) is arranged on the left wall of the treatment cavity (11) in a sliding mode, the sliding plate (28) penetrates through the left wall of the treatment cavity (11) from left to right, a cutting cavity (29) is formed in the right side face of the sliding plate (28), a cutting shaft (30) is arranged on the rear wall of the cutting cavity (29) in a rotating mode, and a laser nozzle (31) is fixedly arranged on the periphery of the cutting shaft (30).

2. The weld site location temperature monitoring system of claim 1, wherein: fixed spring (17) that are equipped with four rotational symmetry on sliding block (16) top surface, fixed spring board (18) that are equipped with in slide bar (19) top, spring board (18) bottom surface and four spring (17) top is fixed, the internal rotation of sliding block (16) is equipped with slip axle (20), fixed sliding gear (21) that are equipped with on slip axle (20) periphery, slip gear (21) with slide bar (19) meshing.

3. The weld site location temperature monitoring system of claim 1, wherein: two it is equipped with first gear shaft (47) all to rotate in the one side that smooth plate (44) are close to each other, two all fixed first gear (46) that are equipped with in first gear shaft (47) periphery, two first gear (46) respectively with the homonymy second smooth chamber (43) inner wall meshing.

4. The weld site location temperature monitoring system of claim 1, wherein: two bilaterally symmetrical second gear shafts (48) are rotatably arranged on the fixing plate (34), second gears (49) are fixedly arranged on the peripheries of the two second gear shafts (48), and the two second gears (49) are respectively meshed with the inner walls of the lifting cavities (45) on the same side.

5. The weld site location temperature monitoring system of claim 1, wherein: the axis of rotation (40) internal rotation is equipped with two bilateral symmetry's welding rod axle (41), two all fixed welding rod wheel (42) that are equipped with in welding rod axle (41) periphery, welding rod (39) are located two between welding rod wheel (42), and two the one side that welding rod wheel (42) are close to each other all with welding rod (39) butt.

6. The weld site location temperature monitoring system of claim 5, wherein: the welding rod (39) can swing through the rotating shaft (40), the adjusting shaft (37) is arranged in the bottom surface of the adjusting block (36) in a rotating mode, an adjusting wheel (38) is fixedly arranged on the periphery of the adjusting shaft (37), and the adjusting wheel (38) is abutted to the bottom wall of the sliding cavity (32).

7. The weld site location temperature monitoring system of claim 1, wherein: seted up on fixed plate (34) top surface welding mouth (35), welding rod (39) front end can be swung into in welding mouth (35), two all rotate on feeding chamber (12) inner wall and be equipped with two longitudinal symmetry's feeding axle (13), four all fixed feed wheel (14) that are equipped with in feeding axle (13) periphery.

8. The weld site location temperature monitoring system of claim 1, wherein: a sliding plate shaft (52) is rotatably arranged in the left side face of the shell (10), a sliding plate gear (53) is fixedly arranged on the periphery of the sliding plate shaft (52), a rack is fixedly arranged on the top face of the sliding plate (28), and the sliding plate gear (53) is meshed with the top face of the sliding plate (28).

9. The weld site location temperature monitoring system of claim 1, wherein: the sliding block (16) is provided with two symmetrical roller shafts (50) in the front and back in a rotating mode, rollers (51) are fixedly arranged on the peripheries of the roller shafts (50), and the rollers (51) are abutted to the bottom wall of the first smooth cavity (15).

Technical Field

The invention relates to the technical field of temperature monitoring, in particular to a welding point position temperature monitoring system.

Background

Welding is a manufacturing process and technique for joining metals or other thermoplastic materials in a heated, high temperature or high pressure manner, and therefore, when workpieces are welded, the temperature of the welding point is generally monitored;

however, the conventional welding temperature monitoring system is not provided with a temperature adjusting device, so that the temperature cannot be automatically adjusted according to the change of the welding temperature, and the workpiece cannot be cooled in time under the condition that the welding temperature exceeds the preset processing temperature, so that the workpiece is seriously damaged;

the existing welding machine can only carry out metal welding, has single function and low workpiece machining efficiency, and the existing welding device is not provided with a workpiece fixing device, so that the workpiece is easy to slide, the welding point position is deviated, and even the workpiece is directly damaged.

Disclosure of Invention

The invention aims to provide a welding point position temperature monitoring system which is used for overcoming the defects in the prior art.

The welding point position temperature monitoring system comprises a shell, wherein a processing cavity is formed in the shell, two bilaterally symmetrical feeding cavities are formed in the inner wall of the processing cavity, a workpiece can enter the processing cavity through the feeding cavities, a sliding cavity is formed in the rear wall of the processing cavity, an adjusting block is arranged in the sliding cavity in a sliding mode, a rotating shaft is arranged in the adjusting block in a rotating mode, a welding rod is arranged on the rotating shaft in a sliding mode and penetrates through the rotating shaft in a front-back mode, and the welding rod is used as a material to be consumed during workpiece welding;

the top surface of the shell is provided with a first smooth cavity, the bottom wall of the first smooth cavity is provided with a sliding block in a sliding manner, the sliding block is provided with a sliding rod in a sliding manner, the sliding rod vertically penetrates through the sliding block and the bottom wall of the first smooth cavity, the bottom end of the sliding rod is inserted into the treatment cavity, the bottom surface of the sliding rod is provided with a spark cavity, the inner wall of the spark cavity is rotatably provided with a rotating ball, the bottom surface of the rotating ball is fixedly provided with a spark nozzle used for welding a workpiece, the bottom surface of the sliding rod is fixedly provided with two bilaterally symmetrical sector plates, the bottom surface of the left sector plate is fixedly provided with a temperature detector used for monitoring the temperature of a welding point, the bottom surface of the right sector plate is provided with a dry ice nozzle, and the dry ice nozzle can spray dry ice, so that the workpiece can be cooled and put out a fire;

a workbench is fixedly arranged on the bottom wall of the processing cavity, two second smooth cavities which are symmetrical front and back are formed in the top surface of the workbench, smooth plates are arranged in the two second smooth cavities in a sliding mode, lifting cavities are formed in the top surfaces of the two smooth plates, a fixed plate is arranged in the processing cavity in a sliding mode and used for fixing workpieces, the bottom end of the fixed plate is inserted into the two lifting cavities, and the fixed plate can slide left and right in the processing cavity through the two smooth plates;

the cutting device comprises a processing cavity, and is characterized in that a sliding plate is arranged on the left wall of the processing cavity in a sliding mode, the sliding plate penetrates through the left wall of the processing cavity from left to right, a cutting cavity is formed in the right side face of the sliding plate, a cutting shaft is arranged on the rear wall of the cutting cavity in a rotating mode, a laser nozzle is fixedly arranged on the periphery of the cutting shaft, and the laser nozzle is used for cutting a workpiece.

Beneficially, four rotationally symmetrical springs are fixedly arranged on the top surface of the sliding block, a spring plate is fixedly arranged at the top end of the sliding rod, the bottom surface of the spring plate is fixed with the top ends of the four springs, and the sliding rod can be manually controlled to slide up and down through the springs and the spring plate.

Advantageously, a sliding shaft is rotatably arranged in the sliding block, a sliding gear is fixedly arranged on the periphery of the sliding shaft, the sliding gear is meshed with the sliding rod, and the sliding rod can slide up and down through the sliding gear.

Beneficially, the two smooth plates are rotatably provided with first gear shafts in the surfaces close to each other, the peripheries of the two first gear shafts are fixedly provided with first gears, the two first gears are respectively meshed with the inner walls of the second smooth cavities on the same side, and the two smooth plates can slide left and right through the first gears on the same side.

Beneficially, two bilaterally symmetrical second gear shafts are rotatably arranged on the fixing plate, second gears are fixedly arranged on the peripheries of the two second gear shafts, the two second gears are respectively meshed with the inner wall of the lifting cavity on the same side, and the fixing plate can slide up and down in the treatment cavity through the two second gears.

Beneficially, the rotating shaft is internally provided with two bilaterally symmetrical welding rod shafts, two welding rod wheels are fixedly arranged on the peripheries of the two welding rod shafts, the welding rods are located between the two welding rod wheels, one surfaces, close to each other, of the two welding rod wheels are abutted to the welding rods, and the welding rods can slide forwards into the treatment cavity through the two welding rod wheels.

Beneficially, the welding rod can be swung through the rotating shaft, an adjusting shaft is arranged in the bottom surface of the adjusting block in a rotating mode, an adjusting wheel is fixedly arranged on the periphery of the adjusting shaft and is abutted against the bottom wall of the sliding cavity, and the adjusting block can slide left and right in the sliding cavity through the adjusting wheel.

Beneficially, a welding port is formed in the top face of the fixing plate, the front end of the welding rod can swing into the welding port, two feeding shafts which are symmetrical up and down are rotatably arranged on the inner walls of the two feeding cavities, and feeding wheels are fixedly arranged on the peripheries of the four feeding shafts.

Advantageously, a sliding plate shaft is rotatably arranged in the left side face of the shell, a sliding plate gear is fixedly arranged on the periphery of the sliding plate shaft, a rack is fixedly arranged on the top face of the sliding plate, the sliding plate gear is meshed with the top face of the sliding plate, and the sliding plate can slide left and right through the sliding plate gear.

Advantageously, two roller shafts which are symmetrical back and forth are arranged in the sliding block in a rotating mode, rollers are fixedly arranged on the peripheries of the two roller shafts, the two rollers are abutted against the bottom wall of the first smooth cavity, and the sliding block can slide left and right in the first smooth cavity through the rollers.

Beneficially, a controller is fixedly arranged on the top surface of the shell and used for controlling the welding temperature, and the temperature detector can transmit temperature information to the controller.

The invention has the beneficial effects that: the welding point position temperature monitoring system can automatically and rapidly adjust the processing temperature according to the temperature change of the welding point position, can automatically cool the workpiece under the condition that the temperature of the welding point position far exceeds the set temperature, and avoids huge damage to the workpiece during processing.

Drawings

FIG. 1 is a schematic view of a weld site location temperature monitoring system of the present invention;

FIG. 2 is a schematic cross-sectional view of a weld site location temperature monitoring system of the present invention;

FIG. 3 is a schematic side view in cross section of a weld site temperature monitoring system of the present invention;

FIG. 4 is an enlarged schematic view of the conditioning block of FIG. 2 in accordance with the present invention;

FIG. 5 is an enlarged, fragmentary, schematic view at A of FIG. 3 of the present invention;

fig. 6 is a partial schematic view of the slide bar of fig. 2 of the present invention.

In the figure:

10. a housing; 11. a treatment chamber; 12. a feed cavity; 13. a feed shaft; 14. a feed wheel; 15. a first smooth cavity; 16. a slider; 17. a spring; 18. a spring plate; 19. a slide bar; 20. a sliding shaft; 21. a sliding gear; 22. a sector plate; 23. a dry ice nozzle; 24. a temperature detector; 25. rotating the ball; 26. a spark chamber; 27. a spark nozzle; 28. a sliding plate; 29. cutting the cavity; 30. cutting the shaft; 31. a laser nozzle; 34. a fixing plate; 32. a sliding cavity; 33. a work table; 35. welding the opening; 36. an adjusting block; 37. an adjustment shaft; 38. an adjustment wheel; 39. welding rods; 40. a rotating shaft; 41. a weld bar shaft; 42. a welding rod wheel; 43. a second smooth cavity; 44. a smooth plate; 45. a lifting cavity; 46. a first gear; 47. a first gear shaft; 48. a second gear shaft; 49. a second gear; 50. a roller shaft; 51. a roller; 52. a slide plate shaft; 53. a sled gear; 54. and a controller.

Detailed Description

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

Referring to fig. 1-6, a welding point location temperature monitoring system according to an embodiment of the present invention includes a housing 10, a processing cavity 11 is formed in the housing 10, two feeding cavities 12 are formed on an inner wall of the processing cavity 11, a workpiece can enter the processing cavity 11 through the feeding cavities 12, a sliding cavity 32 is formed on a rear wall of the processing cavity 11, an adjusting block 36 is slidably disposed in the sliding cavity 32, a rotating shaft 40 is rotatably disposed in the adjusting block 36, a welding rod 39 is slidably disposed on the rotating shaft 40, the welding rod 39 penetrates the rotating shaft 40 in a front-back direction, and the welding rod 39 is used as a material to be consumed during welding the workpiece;

a first smooth cavity 15 is formed in the top surface of the shell 10, a sliding block 16 is slidably arranged on the bottom wall of the first smooth cavity 15, a sliding rod 19 is slidably arranged on the sliding block 16, the sliding rod 19 vertically penetrates through the sliding block 16 and the bottom wall of the first smooth cavity 15, the bottom end of the sliding rod 19 is inserted into the processing cavity 11, a spark cavity 26 is formed in the bottom surface of the sliding rod 19, a rotating ball 25 is rotatably arranged on the inner wall of the spark cavity 26, a spark nozzle 27 is fixedly arranged on the bottom surface of the rotating ball 25, the spark nozzle 27 is used for welding a workpiece, two bilaterally symmetrical sector plates 22 are fixedly arranged on the bottom surface of the sliding rod 19, a temperature measurer 24 is fixedly arranged on the bottom surface of the sector plate 22 on the left side, the temperature measurer 24 is used for monitoring the temperature of a welding point, a dry ice nozzle 23 is formed in the bottom surface of the sector plate 22 on the right side, and the dry ice nozzle 23 can spray dry ice, thereby cooling and extinguishing the fire of the workpiece;

a workbench 33 is fixedly arranged on the bottom wall of the processing cavity 11, two second smooth cavities 43 which are symmetrical front and back are formed in the top surface of the workbench 33, smooth plates 44 are arranged in the two second smooth cavities 43 in a sliding mode, lifting cavities 45 are formed in the top surfaces of the two smooth plates 44, a fixing plate 34 is arranged in the processing cavity 11 in a sliding mode, the fixing plate 34 is used for fixing a workpiece, the bottom end of the fixing plate 34 is inserted into the two lifting cavities 45, and the fixing plate 34 can slide left and right in the processing cavity 11 through the two smooth plates 44;

the processing chamber 11 is characterized in that a sliding plate 28 is arranged on the left wall of the processing chamber 11 in a sliding mode, the sliding plate 28 penetrates through the left wall of the processing chamber 11 from left to right, a cutting chamber 29 is formed in the right side face of the sliding plate 28, a cutting shaft 30 is arranged on the rear wall of the cutting chamber 29 in a rotating mode, a laser nozzle 31 is fixedly arranged on the periphery of the cutting shaft 30, and the laser nozzle 31 is used for cutting workpieces.

Preferably, fixed four rotational symmetry's of being equipped with spring 17 on the sliding block 16 top surface, the fixed spring board 18 that is equipped with in slide bar 19 top, spring board 18 bottom surface and four spring 17 top is fixed, through spring 17 with spring board 18 can manual control slide bar 19 slides from top to bottom, spark chamber 26 left side wall internal fixation is equipped with adjusting motor, adjusting motor with rolling ball 25 power is connected, opens adjusting motor, makes rolling ball 25 with spark mouth 27 rotates.

Preferably, a sliding shaft 20 is rotatably arranged in the sliding block 16, a sliding gear 21 is fixedly arranged on the periphery of the sliding shaft 20, the sliding gear 21 is engaged with the sliding rod 19, the sliding rod 19 can slide up and down through the sliding gear 21, a sliding motor is fixedly arranged in the sliding block 16, and the sliding motor is in power connection with the sliding shaft 20 and is turned on to rotate the sliding gear 21.

Preferably, two smooth plates 44 all rotate in the face that is close to each other and are equipped with first gear shaft 47, two first gear shaft 47 all is fixed on the periphery and is equipped with first gear 46, two first gear 46 respectively with the homonymy second smooth chamber 43 inner wall meshing, two smooth plates 44 respectively through with it homonymy first gear 46 can the horizontal slip, two smooth plates 44 all are fixed in the face that is close to each other and are equipped with first motor, two first motor respectively with homonymy first gear shaft 47 power connection, open first motor, make first gear 46 rotates.

Preferably, the fixing plate 34 is rotatably provided with two bilaterally symmetrical second gear shafts 48, the peripheries of the two second gear shafts 48 are respectively and fixedly provided with second gears 49, the two second gears 49 are respectively engaged with the inner walls of the lifting cavities 45 at the same side, the fixing plate 34 can slide up and down in the treatment cavity 11 through the two second gears 49, two bilaterally symmetrical second motors are fixedly arranged in the fixing plate 34, the two second motors are respectively in power connection with the second gear shafts 48 at the same side, and the second motors are started to rotate the second gears 49.

Preferably, the rotation is equipped with two bilateral symmetry's welding rod axle 41 in the 40 internal rotations of axis of rotation, two all the fixed welding rod wheel 42 that is equipped with in the welding rod axle 41 periphery, welding rod 39 is located two between the welding rod wheel 42, and two the one side that welding rod wheel 42 is close to each other all with welding rod 39 butt, welding rod 39 is through two welding rod wheel 42 can slide forward in the treatment chamber 11, the rotation is equipped with two bilateral symmetry's solder motor, two the solder motor respectively with the homonymy the welding rod axle 41 power is connected, opens the solder motor, makes welding rod wheel 42 rotates.

Preferably, adjusting block 36 internal fixation is equipped with swing motor, swing motor with axis of rotation 40 power connection, through axis of rotation 40 can make welding rod 39 swings, adjusting block 36 bottom surface internal rotation is equipped with adjusting spindle 37, the fixed adjusting wheel 38 that is equipped with in the adjusting spindle 37 periphery, adjusting wheel 38 with slide chamber 32 diapire butt, adjusting block 36 passes through adjusting wheel 38 can the horizontal slip in the slide chamber 32, adjusting block 36 internal fixation is equipped with the third motor, the third motor with adjusting spindle 37 power connection opens swing motor, makes axis of rotation 40 rotates, opens the third motor, makes adjusting wheel 38 rotates.

Preferably, a welding port 35 is formed in the top surface of the fixing plate 34, the front end of the welding rod 39 can be placed into the welding port 35, the feeding shaft 13 is arranged on the inner wall of the feeding cavity 12 in a rotating mode and is in up-down symmetry, the feeding wheel 14 is arranged on the periphery of the feeding shaft 13 in a fixed mode, the feeding motor is arranged on the inner wall of the feeding cavity 12 in a fixed mode and is in up-down symmetry, the feeding motor is in power connection with the feeding shaft 13 and is in the same side with the feeding motor, the feeding motor is started, and the feeding wheel 14 rotates.

Preferably, a sliding plate shaft 52 is rotatably disposed in the left side surface of the housing 10, a sliding plate gear 53 is fixedly disposed on the outer periphery of the sliding plate shaft 52, a rack is fixedly disposed on the top surface of the sliding plate 28, the sliding plate gear 53 is engaged with the top surface of the sliding plate 28, the sliding plate 28 can slide left and right through the sliding plate gear 53, a fourth motor is fixedly disposed in the left side surface of the housing 10, and the fourth motor is in power connection with the sliding plate shaft 52 and is turned on to rotate the sliding plate gear 53.

Preferably, the sliding block 16 internal rotation is equipped with the roller shaft 50 of two longitudinal symmetries, two all fixed gyro wheels 51 that are equipped with in the roller shaft 50 periphery, two gyro wheels 51 all with first smooth chamber 15 diapire butt, sliding block 16 passes through gyro wheel 51 can the horizontal slip in the first smooth chamber 15, the sliding block 16 internal fixation is equipped with the fifth motor of two longitudinal symmetries, two the fifth motor respectively with the homonymy the roller shaft 50 power is connected, opens the fifth motor, makes gyro wheel 51 rotates.

Preferably, the rolling ball 25 internal fixation is equipped with welding source, welding source with spark mouth 27 electricity is connected, cutting chamber 29 back wall internal fixation is equipped with the sixth motor, the sixth motor with cutting axle 30 power connection, cutting axle 30 internal fixation is equipped with laser power, laser power with laser mouth 31 electricity is connected, opens laser power, makes laser mouth 31 takes place laser, opens the sixth motor makes cutting axle 30 with laser mouth 31 rotates, opens welding source makes spark mouth 27 transmission electric spark.

Preferably, a controller 54 is fixedly disposed on the top surface of the housing 10, the controller 54 is used for controlling the welding temperature, the temperature detector 24 is capable of transmitting temperature information to the controller 54, the controller 54 is capable of transmitting an adjustment command to the welding power supply so as to adjust the power of the welding power supply and adjust the spraying temperature of the torch nozzle 27, and the controller 54 is capable of transmitting a cooling command to the dry ice nozzle 23 so as to enable the dry ice nozzle 23 to spray dry ice.

The invention discloses a welding point position temperature monitoring system, which comprises the following working procedures:

and (3) welding function: the main workpiece is fed into the processing cavity 11 leftwards through the feeding cavity 12 on the right side and is placed on the top surface of the workbench 33, and the auxiliary workpiece is fed into the processing cavity 11 rightwards through the feeding cavity 12 on the left side and is also positioned on the top surface of the workbench 33;

then turning on the first motor to rotate the first gear 46, thereby sliding the smoothing plate 44 and the fixing plate 34 until the welding port 35 is aligned with the welding point position up and down, and then turning on the second motor to rotate the second gear 49, thereby sliding the fixing plate 34 down until the fixing plate 34 abuts against the workpiece on the top surface of the worktable 33, thereby fixing the workpiece on the top surface of the worktable 33;

then turning on the third motor to rotate the adjustment wheel 38, thereby sliding the adjustment block 36 and the rotating shaft 40 to the left until the welding rod 39 is aligned with the welding opening 35 up and down, and then turning on the fifth motor to rotate the roller 51, thereby sliding the slide block 16 and the slide rod 19 until the spark tip 27 is aligned with the welding rod 39 up and down;

then, the slide motor is turned on to rotate the slide gear 21, thereby sliding the slide rod 19 downward, the swing motor is turned on to rotate the rotary shaft 40 until the tip of the welding rod 39 abuts against the welding point, and then the welding power source is turned on to cause the spark plug 27 to emit an electric spark, thereby welding the main workpiece and the sub-workpiece.

Cutting function: and starting the sixth motor to rotate the laser nozzle 31 until the right port of the laser nozzle 31 faces downwards, then starting the fourth motor to rotate the sliding plate gear 53 so as to slide the sliding plate 28 rightwards until the right port of the laser nozzle 31 is vertically aligned with a cutting point, and then starting the laser power supply to enable the laser nozzle 31 to generate laser so as to cut the workpiece on the top surface of the workbench 33.

Temperature control function: when welding operation is performed, the temperature detector 24 can monitor the temperature of the welding point location in real time, the temperature detector 24 transmits temperature information to the controller 54, when the temperature of the welding point location is too high, the controller 54 transmits an adjustment instruction to the welding power supply, so that the power of the welding power supply is reduced, the spraying temperature of the spark nozzle 27 is reduced, and the effect of real-time temperature control is achieved, and when the temperature of the welding point location far exceeds a set processing temperature, the controller 54 transmits a cooling instruction to the dry ice nozzle 23, so that the dry ice nozzle 23 sprays dry ice to cool a workpiece.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.