CN111408825A - Thick-section narrow-gap T-shaped welding method - Google Patents
Thick-section narrow-gap T-shaped welding method Download PDFInfo
- Publication number
- CN111408825A CN111408825A CN202010384516.6A CN202010384516A CN111408825A CN 111408825 A CN111408825 A CN 111408825A CN 202010384516 A CN202010384516 A CN 202010384516A CN 111408825 A CN111408825 A CN 111408825A
- Authority
- CN
- China
- Prior art keywords
- welding
- shaped
- groove
- narrow gap
- thick plate
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K9/00—Arc welding or cutting
- B23K9/16—Arc welding or cutting making use of shielding gas
- B23K9/173—Arc welding or cutting making use of shielding gas and of a consumable electrode
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K9/00—Arc welding or cutting
- B23K9/02—Seam welding; Backing means; Inserts
- B23K9/0213—Narrow gap welding
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K9/00—Arc welding or cutting
- B23K9/12—Automatic feeding or moving of electrodes or work for spot or seam welding or cutting
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K9/00—Arc welding or cutting
- B23K9/235—Preliminary treatment
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K9/00—Arc welding or cutting
- B23K9/24—Features related to electrodes
- B23K9/26—Accessories for electrodes, e.g. ignition tips
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K9/00—Arc welding or cutting
- B23K9/24—Features related to electrodes
- B23K9/28—Supporting devices for electrodes
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K9/00—Arc welding or cutting
- B23K9/32—Accessories
Landscapes
- Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Plasma & Fusion (AREA)
- Mechanical Engineering (AREA)
- Butt Welding And Welding Of Specific Article (AREA)
Abstract
The invention discloses a thick-section narrow-gap T-shaped welding method, and relates to the technical field of production and manufacturing of welding of thick plates and ultra-thick plates in the hydropower industry. According to the invention, the butt joint groove between the special-shaped structure thick plate and the plane thick plate is changed, namely a rectangular structure is processed within a range of 60mm above the welding end of the special-shaped thick plate, the arc welding bead is changed into a linear welding bead, the welding track of a robot can be simplified, the programming difficulty is reduced, an oblique welding surface with a certain inclination is arranged on the welding surface of the rectangular structure, the welding groove between the special-shaped thick plate and the plane thick plate is designed into an I-shaped narrow gap groove structure, the original multi-layer multi-pass welding is changed into one layer, the welding process is simplified, the probability of incomplete fusion between the welding beads and the times of cleaning the welding bead are reduced, and the welding.
Description
Technical Field
The invention relates to the technical field of production and manufacturing of welding of thick plates and ultra-thick plates in the hydropower industry, in particular to a T-shaped welding method with thick section and narrow gap.
Background
The thick plate and ultra-thick plate structure is widely applied to the hydropower manufacturing industry, the thick plate welding joint mainly comprises butt joint, T joint and the like, and the traditional welding method of the T joint generally adopts a workpiece K-shaped groove to carry out multilayer multi-path MAG welding. Along with the continuous increase of welding structure thickness, thick plate groove area sharply increases, leads to welding engineering volume to multiply, and production efficiency is low, and during multilayer multichannel welding, easily lead to fusing badly.
Because the stability of welding quality can be greatly improved by robot welding, the application of the arc welding robot is more and more extensive. However, for the welding of a thick plate special-shaped structure, the welding of an arc welding robot has many difficulties, mainly including:
(1) when a thick plate is T-connected, a K-shaped groove is opened to carry out multilayer and multi-pass welding, and programming is generally carried out in an online teaching or offline programming mode. The online teaching time is long, and the efficiency is low; during off-line programming, welding deformation is caused in the welding hot process, on-site deviation correction is often needed, a reliable tracking mode for automatic deviation correction is not available at present, and manual deviation correction is needed, so that the production efficiency is low;
(2) along with the increase of the thickness of the thick plate, the area of the groove is sharply increased, the number of welding tracks on each layer is increased, the cleaning between the tracks needs long time, and the non-fusion between the tracks is easy to form;
(3) the traditional K-shaped groove is adopted for multilayer and multi-pass welding, the welding quantity is huge, and due to the huge structure of hydroelectric equipment and limited welding space, the linkage of multiple robots cannot be realized, and the production output of one or two robots cannot be brought into a normal production flow;
(4) the welding of special-shaped structural parts has irregular welding bead and complex programming, and the accuracy of the track of the robot cannot be ensured, so that the welding bead is not formed well.
Therefore, the robot welding device cannot be widely used for robot welding of thick plates and ultra-thick plates with special-shaped structures all the time.
Disclosure of Invention
The invention aims to solve the problems that in the prior art, a T-shaped welding joint adopts a conventional K-shaped groove design, so that the welding bead is irregular, the planning difficulty of the welding bead is high, and the non-fusion between the welding beads is easy to form during multi-layer and multi-channel welding. According to the invention, the butt joint groove between the special-shaped structure thick plate and the plane thick plate is changed, namely a rectangular structure is processed within a range of 60mm above the welding end of the special-shaped thick plate, the arc welding bead is changed into a linear welding bead, the welding track of a robot can be simplified, the programming difficulty is reduced, an oblique welding surface with a certain inclination is arranged on the welding surface of the rectangular structure, the welding groove between the special-shaped thick plate and the plane thick plate is designed into an I-shaped narrow gap groove structure, the original multi-layer multi-pass welding is changed into one layer, the welding process is simplified, the probability of incomplete fusion between the welding beads and the times of cleaning the welding bead are reduced, and the welding.
In order to solve the problems in the prior art, the invention is realized by the following technical scheme:
the thick-section narrow-gap T-shaped welding method is characterized in that: the method comprises the following steps:
groove designing step: processing the special-shaped thick plate into a rectangular structure within the range of 60mm above the welding end of the special-shaped thick plate, wherein the width of the rectangular structure is not less than the maximum width of the special-shaped thick plate; the welding surface of the rectangular structure is an oblique welding surface with a certain inclination to form an I-shaped narrow gap groove structure, the gap between the root part of the I-shaped narrow gap groove and the plane thick plate is less than 16mm, and the gap between the upper end of the I-shaped narrow gap groove and the plane thick plate is less than 20 mm; a conventional K-shaped groove is formed in each of two ends of the special-shaped thick plate in a certain length, and a certain gap is reserved between the K-shaped groove and the I-shaped narrow gap groove;
assembling: assembling the special-shaped thick plate on the plane thick plate;
positioning welding and block lapping: assembling a plurality of blocks on the non-welding side of the special-shaped thick plate, welding and positioning welding the K-shaped groove part, and performing fillet welding on the blocks;
a welding track generation step of the welding robot, which is to plan the welding track of the welding robot in a computer control system according to the relation of the size, the assembly and the position of a workpiece and mount an L type narrow gap welding torch at an execution end of the welding robot;
preheating before welding: preheating a bottom welding bead of a welded workpiece by using a far infrared electric heating device or flame;
and a welding step, namely adjusting the position of an external moving platform of the robot and the posture of the robot body according to the relation of the size, the assembly and the position of a workpiece, so that the L type narrow gap welding torch body is positioned in the middle of the groove and is vertical to the plane of the narrow gap groove, and the posture of the welding gun is consistent with that of the welding track when planning, executing the automatic welding track of the robot planned in the welding track generation step of the welding robot, fusing the two side walls of the groove by utilizing the swinging of a L type welding torch conductive nozzle, and welding.
In the pre-welding preheating step, the preheating temperature is 80-150 ℃.
And an auxiliary support piece is machined at the root part of the type I narrow gap groove.
The L type narrow gap welding torch comprises a transmission mechanism and a welding torch main body, wherein the transmission mechanism is connected with one end of the welding torch main body, so that the overall appearance of the welding torch structure is L type, the welding torch main body is of a straight structure and comprises a rotary conducting mechanism, a nozzle cooling mechanism, a main conducting rotary rod, a nozzle, a conducting nozzle and a welding torch body, the main conducting rotary rod is arranged inside the welding torch body, the rotary conducting mechanism is arranged at the end part of the welding torch body and connected with the main conducting rotary rod to supply power to the main conducting rotary rod, the transmission mechanism is connected with the main conducting rotary rod to drive the main conducting rotary rod to rotate, the nozzle is arranged at the other end of the welding torch body, the end part of the main conducting rotary rod is connected with the conducting nozzle and located inside the nozzle, and the nozzle cooling mechanism is arranged inside.
The transmission mechanism comprises a servo motor, a speed reducer and a bevel gear set, the bevel gear set comprises two conical transmission gears, one conical transmission gear is arranged on the main conductive rotating rod, the other conical transmission gear is arranged on an output shaft of the speed reducer, and the servo motor is driven by the speed reducer to decelerate and drives the main conductive rotating rod to rotate by the transmission of the bevel gear set.
The conductive nozzle and the main conductive rotating rod form a certain angle, and the certain angle is 10-12 degrees.
The welding wire is arranged in the contact tube, and the length of the welding wire extending out of the contact tube is 17-20 mm.
The nozzle cooling mechanism is a water cooling channel arranged inside the welding torch body.
And the outer surface of the welding torch main body is sprayed with high-temperature-resistant insulating ceramic.
The nozzle is made of chromium-zirconium-copper materials, and high-temperature-resistant insulating ceramics are sprayed on the contact part of the end part of the welding torch body and the nozzle and are fixed by insulating screws.
Compared with the prior art, the beneficial technical effects brought by the invention are as follows:
1. the welding groove is processed into a rectangular structure within the range of 60mm above the welding end of the special-shaped thick plate, the arc welding bead is changed into the linear welding bead, the welding track of the robot can be simplified, the programming difficulty is reduced, the welding surface of the rectangular structure is set into an oblique welding surface with a certain inclination, the welding groove between the special-shaped thick plate and the planar thick plate is designed into an I-shaped narrow-gap groove structure, the original multilayer and multi-pass welding is changed into one layer, the welding process is simplified, the probability of incomplete fusion among the welding beads and the times of cleaning the welding bead are reduced, and the welding efficiency is improved.
2. The invention respectively arranges K-shaped grooves with certain length at two ends of the special-shaped thick plate for positioning welding, the length of the K-shaped grooves can be determined according to the actual working condition, a certain gap is reserved between the K-shaped grooves and the narrow-gap grooves, and the flat welding torch extends to the gap part during welding, so that the contact tip in the middle of the welding torch can reach the end part of the narrow-gap grooves.
3. The invention has the innovation point that the welding end of the thick plate with the special-shaped structure is changed into a linear type from a special shape, and the T-shaped joint of the thick plate is changed into an I-shaped groove from a K-shaped groove. The advantages after the change are that: the welding end of the thick plate with the special-shaped structure is changed into a linear type from special shape, so that the welding path track can be simplified. The thick plate T-shaped joint is changed from a K-shaped groove to an I-shaped groove, multilayer multi-pass welding is changed into single-pass one-pass welding, welding pass planning is simplified, the phenomenon that fusion does not occur between welding passes is avoided, welding pass cleaning is reduced, welding quantity is reduced by more than 60%, and welding efficiency is improved.
4. According to the invention, the auxiliary supporting piece is processed at the root part of the similar I-shaped narrow gap groove, so that the positioning of the special-shaped thick plate is convenient, and the welding is convenient.
5. The welding torch structure can effectively avoid the interference between the welding torch and the plane thick plate, the welding torch main body is of a straight structure and is parallel to the plane part in the T-shaped welding joint, and the problems of structural rigidity deterioration and unstable electric arc can be effectively solved. Torch cooling is mainly composed of contact tip cooling and nozzle cooling. The cooling of the contact nozzle is realized by a cooling water channel contained in the welding torch body, the welding torch body is of a solid aluminum alloy metal structure, two water channels are drilled in the welding torch body, the welding torch body is cooled through water cooling, and after the temperature of the contact nozzle is transferred to the main conductive rotary rod, the main conductive rotary rod conducts heat with the welding torch body in a contact heat transfer mode and is taken out by cooling water, so that the cooling of the contact nozzle is realized. The two nozzles of the welding torch are cooled by cooling water cooled by the two nozzles respectively.
6. The inner part of the welding torch body is additionally drilled with two paths of protective gas to lead the protective gas to the nozzle. The main conductive rotating rod is in arc contact with the rotary conductive mechanism, and the contact still exists when the main conductive rotating rod rotates. When the external power supply is connected to the rotary conductive mechanism, the power supply is transmitted to the main conductive rotary rod in rotation and is transmitted to the contact tip. The outer surface of the welding torch main body is sprayed with high-temperature-resistant insulating ceramic for electrical insulation, the welding torch main body can be used for a long time in a high-temperature environment, the hardness of the ceramic material is high, and the use is not affected after the ceramic material is slightly scratched on the side wall of a welding seam. The nozzle is made of chromium zirconium copper, and the contact part of the end part of the welding torch body and the nozzle is sprayed with high-temperature-resistant insulating ceramic and is fixed by adopting an insulating screw.
7. The welding wire is bent by a contact tube inclined by 10-12 degrees, the contact tube of the welding wire is always kept straight, the welding wire swings stably, and the electric arc is stable. The two 90-degree bevel gear transmission structures are connected, so that the power of the servo motor is transmitted to the main conductive rotating rod, and the conductive nozzle arranged on the main conductive rotating rod can rotate 360 degrees infinitely.
8. The welding torch is integrally L type, the main body of the welding torch is in a straight structure and is parallel to the plane part in the T-shaped joint, the welding torch is integrally cooled by water, the service lives of a nozzle, a contact tube and the welding torch body are prolonged, the welding torch adopts a special bevel gear transmission mechanism, a main rotating contact tube rod is infinitely rotated for 360 degrees, and the angle of the contact tube can be adjusted at will.
9. Aiming at the characteristics and difficulties of the T-shaped joint of the thick plate with the special-shaped structure, the L flat narrow-gap welding torch suitable for the T-shaped joint is developed through innovatively changing the groove structure and is carried on an arc welding robot, so that the intelligent narrow-gap welding of the T-shaped joint of the thick plate with the special-shaped structure is realized, the welding path track and the welding path planning are simplified, the difficulty in programming the welding program of the robot is reduced, the welding quantity is greatly reduced, the welding efficiency of the robot is improved, meanwhile, the intelligent welding of the robot is adopted, the welding quality is stabilized, and the dependence on manual welding is reduced.
10. The invention aims at the welding difficulty of the T-shaped joint of the thick plate and the ultra-thick plate with the special-shaped structure, develops from a welding structure, changes the multi-layer and multi-pass welding of the conventional K-shaped large groove into the single-layer and one-pass welding of the I-shaped groove, greatly reduces the welding deposition amount, improves the welding efficiency, shortens the welding period and improves the welding quality.
11. The invention changes a thick plate T-shaped joint from a K-shaped large groove to an approximate I-shaped narrow gap groove, changes multilayer multi-pass welding to single-layer one-pass welding, simplifies welding bead planning, avoids the occurrence of incomplete fusion between welding beads, reduces welding bead cleaning, reduces more than 60 percent of welding amount, improves welding efficiency, changes the welding end of a thick plate with a special-shaped structure from a special shape to a linear shape, simplifies welding bead track planning, realizes the welding of the T-shaped joint narrow groove through the design of L type flat narrow gap welding torches, and carries a L type flat narrow gap welding torch on an arc welding robot, thereby realizing the intelligent narrow gap welding of the robot with the super-thick section of the special-shaped structural part, improving welding quality, improving manual work environment and greatly shortening welding period.
Drawings
FIG. 1 is a schematic structural view of the assembly of a special-shaped thick plate and a plane thick plate;
FIG. 2 is a schematic structural diagram of a welding end of a specially-shaped thick plate;
FIG. 3 is a schematic structural view of a conventional K-groove in the prior art;
FIG. 4 is a schematic structural view of a type I narrow gap groove of the present invention;
FIG. 5 is a schematic view of a narrow gap groove structure after the special-shaped thick plate and the planar thick plate are assembled according to the present invention;
FIG. 6 is a schematic structural view of a narrow gap T-joint of the present invention;
FIG. 7 is a schematic top view of a torch in accordance with the present invention;
FIG. 8 is a schematic side view of a torch of the present invention;
FIG. 9 is a schematic structural view of a torch drive mechanism according to the present invention;
FIG. 10 is a schematic view of the torch of the present invention rotated;
FIG. 11 is a schematic diagram of a narrow gap MAG welding method of the present invention;
FIG. 12 is a view of a turbine shroud assembly configuration;
FIG. 13 is a view of a turbine seat ring robot narrow gap welding position 1;
FIG. 14 is a view of a turbine seat ring robot narrow gap welding position 2;
FIG. 15 is a schematic view of the present invention performing thick section narrow gap welding;
11. the welding torch comprises a transmission mechanism, 12, a welding torch main body, 13, a rotary conducting mechanism, 14, a nozzle cooling mechanism, 15, a main conducting rotary rod, 16, a nozzle, 17, a contact tip, 18, a welding torch body, 19, a servo motor, 110, a speed reducer, 111, a bevel gear set, 112, a welding wire, 113 and a robot, wherein c represents an angle between the contact tip and the main conducting rotary rod, d represents a swinging angle of the contact tip, and L represents the length of the welding wire extending out of the contact tip.
Detailed Description
The technical scheme of the invention is further elaborated in the following by combining the drawings in the specification.
Example 1
As a preferred embodiment of the present invention, the present embodiment discloses:
the thick-section narrow-gap T-shaped welding method is characterized in that: the method comprises the following steps:
groove designing step: processing the special-shaped thick plate into a rectangular structure within the range of 60mm above the welding end of the special-shaped thick plate, wherein the width of the rectangular structure is not less than the maximum width of the special-shaped thick plate 1; the welding surface of the rectangular structure is an oblique welding surface 4 with a certain inclination to form an I-shaped narrow gap groove structure, the gap between the root part of the I-shaped narrow gap groove and the plane thick plate 2 is less than 16mm, and the gap between the upper end of the I-shaped narrow gap groove and the plane thick plate 2 is less than 20 mm; a conventional K-shaped groove is formed in each of two ends of the special-shaped thick plate 1 in a certain length, and a certain gap is reserved between the K-shaped groove and the I-shaped narrow gap groove;
assembling: assembling the special-shaped thick plate 1 on the plane thick plate 2;
positioning welding and block lapping: assembling a plurality of overlapping blocks 7 on the non-welding side of the special-shaped thick plate 1, welding and positioning welding on the K-shaped groove part, and performing fillet welding on the overlapping blocks 7;
a step of generating a welding track of the welding robot 113, which is to plan the welding track of the welding robot 113 in a computer control system according to the relation of the size, the assembly and the position of a workpiece, and mount an L type narrow gap welding torch at an execution end of the welding robot 113;
preheating before welding: preheating a bottom welding bead of a welded workpiece by using a far infrared electric heating device or flame;
and a welding step, namely adjusting the position of a moving platform outside the robot 113 and the posture of the robot 113 body according to the size, assembly and position relation of a workpiece, enabling the L-type narrow gap welding torch body 18 to be positioned in the middle of the groove and be vertical to the plane of the narrow gap groove, keeping the posture of a welding gun consistent with that of a welding track when planning, executing the automatic welding track of the robot 113 planned in the welding track generation step of the welding robot 113, and fusing two side walls of the groove by utilizing the swinging of the L-type welding torch contact tip 17 to weld.
Example 2
Referring to fig. 1-6 of the specification, this embodiment discloses as another preferred embodiment of the present invention:
the thick-section narrow-gap T-shaped welding method is characterized in that: the method comprises the following steps:
groove designing step: processing the special-shaped thick plate into a rectangular structure within the range of 60mm above the welding end of the special-shaped thick plate, wherein the width of the rectangular structure is not less than the maximum width of the special-shaped thick plate 1; the welding surface of the rectangular structure is an oblique welding surface 4 with a certain inclination to form an I-shaped narrow gap groove structure, the gap between the root part of the I-shaped narrow gap groove and the plane thick plate 2 is less than 16mm, and the gap between the upper end of the I-shaped narrow gap groove and the plane thick plate 2 is less than 20 mm; a conventional K-shaped groove is formed in each of two ends of the special-shaped thick plate 1 in a certain length, and a certain gap is reserved between the K-shaped groove and the I-shaped narrow gap groove;
assembling: assembling the special-shaped thick plate 1 on the plane thick plate 2;
positioning welding and block lapping: assembling a plurality of overlapping blocks 7 on the non-welding side of the special-shaped thick plate 1, welding and positioning welding on the K-shaped groove part, and performing fillet welding on the overlapping blocks 7;
a step of generating a welding track of the welding robot 113, which is to plan the welding track of the welding robot 113 in a computer control system according to the relation of the size, the assembly and the position of a workpiece, and mount an L type narrow gap welding torch at an execution end of the welding robot 113;
preheating before welding: preheating a bottom welding bead of a welded workpiece by using a far infrared electric heating device or flame; the preheating temperature is 80-150 ℃;
and a welding step, namely adjusting the position of a moving platform outside the robot 113 and the posture of the robot 113 body according to the size, assembly and position relation of a workpiece, enabling an L-type narrow gap welding torch body 18 to be positioned in the middle of the groove and be vertical to the plane of the narrow gap groove, keeping the posture of a welding gun consistent with that of a welding track when planning, executing the automatic welding track of the robot 113 planned in the welding track generation step of the welding robot 113, fusing two side walls of the groove by utilizing the swinging of a L-type welding torch contact tip 17, and welding, wherein an auxiliary support 3 is machined at the root part of the groove with the similar I-type narrow gap.
Example 3
Referring to fig. 1-11 of the specification, this embodiment discloses:
the use of robots 113 is the direction of future manufacturing. Aiming at the welding of the robot 113 for welding thick plates and ultra-thick plates with special-shaped structures, the welding quality and efficiency of the arc welding robot 113 need to be improved. Therefore, the welding groove of the thick plate and the ultra-thick plate is changed by changing the welding structure of the product, the novel welding technology is carried on the arc welding robot 113, the welding amount of the ultra-thick section structural member is reduced, the welding efficiency of the arc welding robot 113 is increased, and a new intelligent welding field of the arc welding robot 113 in the hydropower industry of power generation equipment is developed.
The narrow gap gas shielded welding technology is a novel welding technology and mainly has the following advantages:
(1) the deposition efficiency is high, and the clearance is small (mostly 10-16 mm), so the production efficiency is higher;
(2) the heat input is moderate, the adjusting range is large, and the welding device is suitable for welding various metals; the preheating temperature can be reduced, and preheating and post-heating can be omitted for medium-strength steel;
(3) the welding device is suitable for flat welding, transverse welding and all-position welding, and the limit thickness of the welding is larger and is generally 300 mm.
(4) And the slag removal between welding beads is simple.
The narrow-gap gas shielded welding technology is connected with the arc welding robot 113, so that the welding efficiency of the arc welding robot 113 can be greatly improved, one or two high-quality and high-efficiency welding of a deep narrow groove single layer is realized, and the risk of poor fusion during multi-layer and multi-channel welding of an ultra-thick section is avoided.
The technical scheme adopted by the invention is that the groove structure of the welding end of the special-shaped structural member is changed, the arc groove is changed into a linear groove, the K-shaped groove of the T-shaped joint is changed into an I-shaped groove, and the special L-shaped flat narrow gap welding torch is loaded at the tail end of the arc welding robot 113 to carry out robot 113 narrow gap welding.
1. Groove design: the T-shaped joint of the thick plate with the special-shaped structure generally comprises two structural parts, as shown in an attached figure 1 of the specification, wherein 1 is a special-shaped thick plate with an ultra-thick section, 2 is a plane thick plate 2, and a welding groove of the joint is formed in a special-shaped thick plate 11, so that groove design is mainly performed on the special-shaped thick plate 11. The sectional shape of the special-shaped thick plate 11 is shown as d1 in fig. 2, the conventional groove is a K-shaped groove, and a T-shaped joint is formed with the plane thick plate 22, as shown in fig. 3, the structural groove is huge, and the weld bead profile is irregular. Generally adopt artifical welding or the welding of robot 113 in the conventional welding, carry out multilayer multi-pass welding, artifical welding amount of labour is big, when adopting the welding of robot 113, because the welding bead is irregular, the welding bead planning degree of difficulty is big, and during multilayer multi-pass welding, the extremely easy formation between the way does not fuse.
The technical scheme includes that a rectangular structure is machined within a range of 60mm above a welding end of a special-shaped thick plate 1, an arc welding bead is changed into a linear welding bead, the welding track of a robot 113 is simplified, programming difficulty is reduced, if d2 is shown in fig. 2, a certain inclined plane is arranged on a rectangular L1 part to form a groove structure similar to an I-shaped narrow gap, if d 4 is shown in fig. 5, a root a of the narrow gap groove is smaller than 16mm, and an upper end b of the narrow gap groove is smaller than 20mm, one-layer narrow gap welding is carried out, the original multi-layer multi-channel welding is changed into one-layer narrow gap welding, the welding process is simplified, the probability of incomplete fusion between welding beads and the times of cleaning of the welding beads are reduced, welding efficiency is improved, conventional K-type grooves are formed in certain lengths at two ends of a fixed guide vane 5 respectively for positioning welding, a certain gap is reserved between the K-type groove and the narrow gap groove, and a.
The technical scheme of the invention is innovatively changed by two points: (1) changing the welding end of the thick plate with the special-shaped structure from special shape to linear shape; (2) the T-shaped joint of the thick plate is changed from a K-shaped groove to an approximate I-shaped groove. The advantages after the change are: (1) the welding end of the thick plate with the special-shaped structure is changed into a linear type from a special shape, so that the welding path track is simplified. (2) The thick plate T-shaped joint is changed from a K-shaped groove to an approximate I-shaped groove, multilayer multi-pass welding is changed into single-layer one-pass welding, welding bead planning is simplified, the occurrence of incomplete fusion between welding beads is avoided, welding bead cleaning is reduced, welding quantity is reduced by more than 60%, and welding efficiency is improved.
2. L type flat narrow gap welding torch design, the narrow gap consumable electrode gas shielded welding technology is a new welding technology, has certain application in the nuclear power structural field at present, mainly apply to the butt joint groove, the welding torch structure is generally T-type, the common maximum welding depth is 300mm, but when the flat thick plate 21 welding end L size in the T-type connects is greater than 500mm, the structural rigidity of the T-type welding torch worsens, while welding, the electric arc is unstable, therefore, the narrow gap welding torch of this structure becomes extremely maladaptable to the narrow groove welding of the T-type connects, in order to realize the narrow gap groove welding of the T-type connects, need redesign the welding torch.
2.1 torch structure to realize the narrow gap welding of T-shaped structure, it needs to arrange the other parts except the main body 12 of the torch on the side of item 2 in FIG. 6, and avoid the interference between the torch and item 1, therefore the external form of the torch is designed to L type, which is composed of two parts of item 11 and item 12 in FIG. 8, wherein item 12 is the main body 12 of the torch, which extends into the narrow gap groove during welding, item 11 is the control part of the contact tip 17, which is located on the side of item 2 in FIG. 6 during welding, item 12 mainly contains the rotary conducting mechanism 13, the nozzle cooling mechanism 14, the main wire rotating rod, the nozzle 16, the contact tip 17 and the torch body 18.
Cooling the welding torch: mainly consists of contact tip 17 cooling and nozzle 16 cooling. The cooling of the contact tip 17 is realized by a cooling water channel contained in the welding torch body 18, the welding torch body 18 is of a solid aluminum alloy metal structure, two water channels are drilled in the welding torch body, the welding torch body 18 is cooled through water cooling, and after the temperature of the contact tip 17 is transmitted to the main conductive rotating rod 15, the main conductive rotating rod 15 and the welding torch body 18 conduct heat in a contact heat transfer mode and are taken out by cooling water, so that the cooling of the contact tip 17 is realized. The two nozzles 16 of the welding torch are cooled by the cooling water of the two nozzle cooling mechanisms 14.
Gas protection: the torch body 18 is further bored with two shield gas passages to guide the shield gas to the nozzle 16.
Conducting electricity: the main conductive rotating rod 15 is in arc contact with the rotating conductive mechanism 13, and the contact still exists when the main conductive rotating rod 15 rotates. When an external power source is connected to the rotary conductive mechanism 13, the power source is transmitted to the main conductive rotary rod 15 in rotation and the power source is transmitted to the contact tip 17.
Insulation: the outer surface of the welding torch main body 12 is sprayed with high-temperature-resistant insulating ceramic for electrical insulation, the welding torch can be used for a long time in a high-temperature environment, the hardness of the ceramic material is high, and the use is not affected after the ceramic material is slightly scratched on the side wall of a welding seam. The nozzle 16 is made of chromium zirconium copper, and the contact part of the end part of the welding torch body 18 and the nozzle 16 is sprayed with high-temperature resistant insulating ceramic and fixed by using an insulating screw.
And (2) swinging the contact tip 17, namely bending the welding wire 112 by the contact tip 17 inclined by 10-12 degrees, keeping the contact tip 17 out of the welding wire 112 in a straight state all the time, enabling the welding wire 112 to swing stably and enabling an electric arc to be stable, wherein an item 11 is a swinging control part of the contact tip 17, and comprises a servo motor 19, a precision star reducer 110 and a bevel gear group 111 as shown in figure 9, and the item 11 and the item 12 in figure 8 are connected through two 90-degree bevel gear transmission structures, so that the power of the servo motor 19 is transmitted to a main guide wire rotating rod, the contact tip 17 arranged on the main guide wire rotating rod is enabled to rotate infinitely for 360 degrees, the thickness direction of the item 12 is a plane structure, and the item 11 and the item 12 form.
The welding torch is structurally characterized in that the whole welding torch is L-shaped, the main body 12 of the welding torch is of a straight structure and is parallel to the plane part in the T-shaped joint, the whole welding torch is cooled by water, the service lives of the nozzle 16, the contact tip 17 and the welding torch body 18 are prolonged, the welding torch adopts a special bevel gear transmission mechanism 11, the main rotating contact tip 17 rod rotates 360 degrees infinitely, and the angle of the contact tip 17 can be adjusted randomly.
2.2 welding torch swinging principle: the servo motor 19 is controlled to rotate, the main conductive rotating rod 15 is driven to rotate through two 90-degree bevel gears (one is arranged on the motor, and the other is arranged on the main conductive rotating rod 15), the conductive nozzle 17 and the main conductive rotating rod 15 are eccentric by 10-12 degrees, and the rotation of the main conductive rotating rod 15 drives the conductive nozzle 17 to swing.
As shown in FIG. 10, the contact tip 17 and the main conductive rotating rod 15 form an angle c, wherein c is 10-12 degrees, the length L of the welding wire 112 extending out of the contact tip 17 is 17-20mm, and after the main conductive rotating rod 15 rotates, the contact tip 17 swings, wherein the swing angle d can be any angle of 360 degrees.
2.3 principle of narrow gap MAG welding method: as shown in FIG. 11, the tip 17 is angled with respect to the main conductive rotating rod 15 and the welding wire 112 is threaded obliquely out of the front end of the torch. The rotation of the main conductive rotating rod 15 drives the welding wire 112 to swing left and right, so that the purpose of swinging left and right of the electric arc is realized in the welding process, and the left and right side walls of the narrow groove are effectively fused.
3. Welding the T-shaped joint robot 113 of the thick plate with the special-shaped structure in a narrow gap manner:
when the special-shaped structure thick plate adopts conventional K-shaped groove to carry out robot 113 welding, because the welding bead orbit is the arc, need set up sufficient track point and come to fit the orbit to the degree of difficulty of programming has been increased. And because the groove size is different when K type groove is at the different degree of depth, need plan multilayer multichannel welding bead, in case the deviation appears in the actual welding process in the well planned welding bead, need modify at any time, this greatly reduced the efficiency that robot 113 welded.
After the welding end of the thick plate with the special-shaped structure is changed into a linear type from the special shape, the welding path track is simplified, the walking track of the arc welding robot 113 is changed into the linear type from the arc shape, and the welding procedure programming of the robot 113 is greatly simplified. The K-shaped groove is changed into an approximate I-shaped groove, multilayer multi-pass welding is changed into single-layer one-pass welding, the welding path planning does not need to be changed according to the difference of the forming and welding quantity of each welding line of each layer, and the welding path planning is extremely simple.
Therefore, the invention has the technical proposal that after the groove of the thick plate with the special-shaped structure is changed from the groove design of the item 1, the L type flat narrow gap welding torch in the design of the L type flat narrow gap welding torch of the item 2 is arranged on an arc welding robot 113 to carry out the intelligent narrow gap welding of the robot 113, and the concrete steps are as follows:
(1) processing the thick plate with the special-shaped structure according to the step 1;
(2) assembling the special-shaped structure thick plate 1 and the plane thick plate 22;
(3) positioning welding and block lapping 7 are carried out after assembly;
(4) robot 113 automatic welding trajectory generation: and planning the welding track of the robot 113 in a computer control system by utilizing the solid modeling function of three-dimensional CAD software according to the size, assembly and position relation of each part of the seat ring. And (3) taking the three-dimensional model to two points at the arc starting position and the arc extinguishing position of each welding seam track, then respectively taking a gun inlet point and a gun outlet point, and completing the whole narrow-gap groove welding seam by the welding seam program through a circulating command.
(5) An L type narrow gap torch was mounted on the tip of the arc welding robot 113, and a torch tip contact tip 17 oscillation control system was connected.
(6) Preheating before welding: the bottom weld bead of the workpiece to be welded is preheated by a far infrared electric heating device or flame, and the preheating temperature is determined according to the material and the plate thickness of the workpiece and is usually 80-150 ℃.
(7) And (3) adjusting the position of a moving platform outside the robot 113 and the posture of the robot 113 body according to the size, assembly and position relation of the workpiece, so that the L type narrow gap welding torch body 18 is positioned in the middle of the groove and is vertical to the plane of the narrow gap groove, and the posture of the welding torch is consistent with that of the welding track when planning, executing the automatic welding track of the robot 113 planned in the step 4, fusing two side walls of the groove by utilizing the swinging of the L type flat welding torch contact nozzle 17, and carrying out one-layer high-efficiency and high-quality welding.
Aiming at the characteristics and difficulties of the T-shaped joint of the thick plate with the special-shaped structure, the L-type flat narrow-gap welding torch suitable for the T-shaped joint is developed through innovatively changing the groove structure and is carried on the arc welding robot 113, the intelligent narrow-gap welding of the T-shaped joint of the thick plate with the special-shaped structure is realized, the welding path track and the welding path planning are simplified, the difficulty in programming the welding program of the robot 113 is reduced, the welding quantity is greatly reduced, the welding efficiency of the robot 113 is improved, meanwhile, the intelligent welding of the robot 113 is adopted, the welding quality is stabilized, and the dependence on manual welding is reduced.
Example 4
As another preferred embodiment of the present invention, referring to fig. 12-14 of the specification, the present embodiment discloses:
the application of the thick plate T-shaped joint robot 113 narrow gap welding technology in the water turbine seat ring is as follows: the seat ring mainly comprises a fixed guide vane 5 and a ring plate 6, the thickness of the fixed guide vane 5 can reach 270mm at most, and the thickness of the ring plate 6 can reach 250mm at most.
1. Groove machining: the welding bevel of the seat ring fixed guide vane 5 and the ring plate 6 is arranged at the end part of the fixed guide vane 5, so the bevel design is mainly carried out on the fixed guide vane 5. The section of the fixed guide vane 5 is of a special-shaped structure, the fixed guide vane is processed to a rectangular structure within the range of 60mm above a welding end, a certain inclined plane is arranged on the rectangular part to form an approximate I-shaped narrow gap groove structure, the root part a of the narrow gap groove is smaller than 16mm, the upper end b of the narrow gap groove is smaller than 20mm, conventional K-shaped grooves are respectively formed in two ends of the fixed guide vane 5 by certain lengths, and a certain gap is reserved between the K-shaped grooves and the narrow gap grooves.
2. Assembling a seat ring: when the conventional seat ring is welded, the two petal seat rings are assembled together in a way that the back surfaces and the opposite surfaces of the two petal seat rings are assembled together by adopting a butt strap so as to control the welding deformation. Compared with the conventional K-shaped groove, the groove size is reduced by 60% when narrow gap welding is adopted, and the welding amount and the welding deformation are correspondingly reduced, so that the method is different from the conventional seat ring assembly.
(1) Marking on the ring plate 6 according to the drawing of the product;
(2) assembling the fixed guide vane 5 according to the marking and the simulation result of the welding of the robot 113;
(3) two blocks 7 are respectively assembled on the upper side and the lower side of the non-welding side of the fixed guide vane 5 to control welding deformation;
(4) and (6) positioning and welding. Welding and positioning welding on the K-shaped groove part, wherein the welding quantity is 20 mm;
(5) and the block 7 is welded. Fillet welding is carried out on the lapping block 7, and the welding leg is 20 mm.
(6) The robot 113 automatically simulates the welding track: and planning the welding position of each guide vane and the welding track of the robot 113 in a computer control system by using the solid modeling function of three-dimensional CAD software according to the size, assembly and position relation of each part of the seat ring.
(7) And placing the seat ring on the welding platform according to the computer simulation result.
3. Seat ring welding:
(1) preheating before welding: the bottom weld bead of the workpiece to be welded is preheated by a far infrared electric heating device or flame, and the preheating temperature is determined according to the material and the plate thickness of the seat ring part and is usually 80-150 ℃.
(2) Robot 113 welding programming: and calibrating the base of the workpiece according to the position of the workpiece, and compiling the actual welding track of the robot 113.
(3) As shown in fig. 15, a flat welding torch is inserted into the I-shaped narrow gap groove to perform one-layer or two-layer high-efficiency and high-quality welding, after each welding pass is completed, the welding pass is cleaned by a steel wire brush, and after each two-layer welding pass is completed, the welding pass is cleaned by a pneumatic shovel to remove slag.
(4) And (3) welding sequence: when the welding filling amount of the groove of the single fixed guide vane 5 reaches a certain thickness, the welding position of the welding robot 113 is adjusted, another fixed guide vane 5 is welded, and the fixed guide vanes 5 at the position are welded to a certain thickness in sequence. Turning over, welding the fixed guide vane 5 at the other position, and completing welding of the welding seam of the fixed guide vane 5 at the position. Turning over, putting the guide vane to the original position, and welding all welding seams of the lower fixed guide vane 5 at the position.
Claims (10)
1. The thick-section narrow-gap T-shaped welding method is characterized in that: the method comprises the following steps:
groove designing step: processing the special-shaped thick plate into a rectangular structure within the range of 60mm above the welding end of the special-shaped thick plate, wherein the width of the rectangular structure is not less than the maximum width of the special-shaped thick plate (1); the welding surface of the rectangular structure is an oblique welding surface (4) with a certain inclination to form an I-shaped narrow gap groove structure, the gap between the root of the I-shaped narrow gap groove and the plane thick plate (2) is less than 16mm, and the gap between the upper end of the I-shaped narrow gap groove and the plane thick plate (2) is less than 20 mm; a conventional K-shaped groove is formed in each of two ends of the special-shaped thick plate (1) in a certain length, and a certain gap is reserved between the K-shaped groove and the I-shaped narrow gap groove;
assembling: assembling the special-shaped thick plate (1) on the plane thick plate (2);
positioning welding and block lapping: assembling a plurality of blocks on the non-welding side of the special-shaped thick plate (1), welding and positioning welding on the K-shaped groove part, and performing fillet welding on the blocks;
a step of generating a welding track of the welding robot (113), which is to plan the welding track of the welding robot (113) in a computer control system according to the relation of the size, the assembly and the position of a workpiece, and mount an L type narrow gap welding torch at an execution end of the welding robot (113);
preheating before welding: preheating a bottom welding bead of a welded workpiece by using a far infrared electric heating device or flame;
and a welding step, namely adjusting the position of an external moving platform of the robot (113) and the posture of the robot (113) body according to the relation of the size, assembly and position of a workpiece, enabling an L type narrow gap welding torch body (18) to be positioned in the middle of the groove and perpendicular to the plane of the narrow gap groove, keeping the posture of a welding gun consistent with that of a welding track when planning, executing the automatic welding track of the robot (113) planned in the welding track generation step of the welding robot (113), and fusing two side walls of the groove by utilizing the swinging of a L type welding torch contact nozzle (17) to weld.
2. A thick section narrow gap T-shaped welding method as claimed in claim 1, characterized in that: in the pre-welding preheating step, the preheating temperature is 80-150 ℃.
3. A thick section narrow gap T-shaped welding method as claimed in claim 1, characterized in that: and an auxiliary support piece (3) is machined at the root part of the type I narrow gap groove.
4. A thick section narrow gap T-shaped welding method as defined in claim 1, characterized in that the L type narrow gap welding torch comprises a transmission mechanism (11) and a main torch body (12), the transmission mechanism (11) is connected with one end of the main torch body (12) to make the overall appearance of the welding torch structure be L type, the main torch body (12) is a straight structure, the main torch body (12) comprises a rotary conducting mechanism (13), a nozzle cooling mechanism (14), a main conductive rotary rod (15), a nozzle (16), a contact tip (17) and a main torch body (18), the main conductive rotary rod (15) is arranged inside the main torch body (18), the rotary conducting mechanism (13) is arranged at the end of the main torch body (18) and connected with the main conductive rotary rod (15) to supply power to the main conductive rotary rod (15), the transmission mechanism (11) is connected with the main conductive rotary rod (15) to drive the main conductive rotary rod (15) to rotate, the nozzle (16) is arranged at the other end of the main torch body (18), the end of the main conductive rotary rod (15) is connected with the contact tip (17), and is positioned inside the nozzle (16) for cooling the nozzle (18).
5. A thick section narrow gap T-shaped welding method as claimed in claim 4, characterized in that: the transmission mechanism (11) comprises a servo motor (19), a speed reducer (110) and a bevel gear set (111), the bevel gear set (111) comprises two conical transmission gears, one conical transmission gear is arranged on the main conductive rotating rod (15), the other conical transmission gear is arranged on an output shaft of the speed reducer (110), and the servo motor (19) is driven by the speed reducer (110) in a speed reducing mode and drives the main conductive rotating rod (15) to rotate through the transmission of the bevel gear set (111).
6. A thick section narrow gap T-shaped welding method as claimed in claim 4, characterized in that: the contact nozzle (17) and the main conductive rotating rod (15) form a certain angle, and the certain angle is 10-12 degrees.
7. A thick section narrow gap T-shaped welding method as claimed in claim 4, characterized in that: a welding wire (112) is arranged in the contact tip (17), and the length of the welding wire (112) extending out of the contact tip (17) is 17-20 mm.
8. A thick section narrow gap T-shaped welding method as claimed in claim 4, characterized in that: the nozzle cooling mechanism (14) is a water cooling channel disposed inside the torch body (18).
9. A thick section narrow gap T-shaped welding method as claimed in claim 4, characterized in that: the outer surface of the welding torch main body (12) is sprayed with high-temperature-resistant insulating ceramic.
10. A thick section narrow gap T-shaped welding method as claimed in claim 4, characterized in that: the nozzle (16) is made of chromium zirconium copper, and the contact part of the end part of the welding torch body (18) and the nozzle (16) is sprayed with high-temperature-resistant insulating ceramic and fixed by adopting an insulating screw.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202010384516.6A CN111408825B (en) | 2020-05-09 | 2020-05-09 | Thick-section narrow-gap T-shaped welding method |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202010384516.6A CN111408825B (en) | 2020-05-09 | 2020-05-09 | Thick-section narrow-gap T-shaped welding method |
Publications (2)
Publication Number | Publication Date |
---|---|
CN111408825A true CN111408825A (en) | 2020-07-14 |
CN111408825B CN111408825B (en) | 2021-06-18 |
Family
ID=71487160
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202010384516.6A Active CN111408825B (en) | 2020-05-09 | 2020-05-09 | Thick-section narrow-gap T-shaped welding method |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN111408825B (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113458674A (en) * | 2021-08-06 | 2021-10-01 | 中国二十冶集团有限公司 | Construction method for assisting welding of high-altitude wall plate |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2001030091A (en) * | 1999-07-21 | 2001-02-06 | Hitachi Constr Mach Co Ltd | Structure of t-shaped joint with narrow groove, its welding method, and welded structure |
JP2006130510A (en) * | 2004-11-02 | 2006-05-25 | Aiko Engineering Kk | Butt welding method for thick plate metal |
CN203380484U (en) * | 2013-06-28 | 2014-01-08 | 四川蓝星机械有限公司 | Welding equipment for welding seam between pressure vessel shell and connecting tube |
CN105127595A (en) * | 2015-10-15 | 2015-12-09 | 上海临仕激光科技有限公司 | Laser-double side arc compound welding method for thick plate |
CN107598340A (en) * | 2017-10-26 | 2018-01-19 | 上海振华重工(集团)股份有限公司 | Big thick plate T-joint welding method |
CN109483009A (en) * | 2018-10-31 | 2019-03-19 | 中国石油天然气集团有限公司 | A kind of manufacturing method of composite bimetal pipe end portion treatment structure |
CN109982802A (en) * | 2016-11-21 | 2019-07-05 | 株式会社神户制钢所 | Exempt from back chipping complete penetration welding method and welding point |
-
2020
- 2020-05-09 CN CN202010384516.6A patent/CN111408825B/en active Active
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2001030091A (en) * | 1999-07-21 | 2001-02-06 | Hitachi Constr Mach Co Ltd | Structure of t-shaped joint with narrow groove, its welding method, and welded structure |
JP2006130510A (en) * | 2004-11-02 | 2006-05-25 | Aiko Engineering Kk | Butt welding method for thick plate metal |
CN203380484U (en) * | 2013-06-28 | 2014-01-08 | 四川蓝星机械有限公司 | Welding equipment for welding seam between pressure vessel shell and connecting tube |
CN105127595A (en) * | 2015-10-15 | 2015-12-09 | 上海临仕激光科技有限公司 | Laser-double side arc compound welding method for thick plate |
CN109982802A (en) * | 2016-11-21 | 2019-07-05 | 株式会社神户制钢所 | Exempt from back chipping complete penetration welding method and welding point |
CN107598340A (en) * | 2017-10-26 | 2018-01-19 | 上海振华重工(集团)股份有限公司 | Big thick plate T-joint welding method |
CN109483009A (en) * | 2018-10-31 | 2019-03-19 | 中国石油天然气集团有限公司 | A kind of manufacturing method of composite bimetal pipe end portion treatment structure |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113458674A (en) * | 2021-08-06 | 2021-10-01 | 中国二十冶集团有限公司 | Construction method for assisting welding of high-altitude wall plate |
Also Published As
Publication number | Publication date |
---|---|
CN111408825B (en) | 2021-06-18 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN113385822B (en) | Narrow-gap laser-TIG (tungsten inert gas) arc composite welding device and welding method | |
CN104400226B (en) | A kind of double-sided laser-TIG arc hybrid welding method | |
CN104651832B (en) | Surface remediation process for large-size metallic component | |
CN103180084B (en) | Vertical laser cladding system | |
JP5602458B2 (en) | Method for joining two metal parts by a tungsten-inert gas welding method and apparatus for carrying out the method | |
CN206415882U (en) | A kind of increase and decrease material composite manufacture device of large format parts | |
CN105081595A (en) | Fillet weld welding structure for K-type grooves of moderately-thick plate without back chipping and welding technology of fillet weld welding structure | |
CN106166645A (en) | A kind of electric arc combined welder of robotic laser and method | |
CN101890560B (en) | Narrow-clearance heating wire TIG welding gun | |
CN111408825B (en) | Thick-section narrow-gap T-shaped welding method | |
CN107999934A (en) | Saddle-shaped joint pipe groove narrow-clearance submerged arc welding connects method and apparatus | |
MX2011006121A (en) | Robotically applied hardfacing with pre-heat. | |
CN108994459B (en) | Gear oil pump laser-electric arc composite heterogeneous additive manufacturing system and method | |
CN106563870A (en) | Twin-tungsten-electrode electronic swing arc (ESA) argon arc welding | |
CN212371483U (en) | Connecting structure for reactor vessel | |
CN113664222A (en) | Composite laser device and method for directional energy deposition equipment | |
CN1298486C (en) | Rotary double focus laser-MIG electric arc composite welding head | |
CN104014933A (en) | Laser-TOPTIG hybrid welding method | |
CN110899974B (en) | Laser swing welding method for medium plate armored steel | |
CN212264826U (en) | Welding torch structure for narrow gap welding | |
CN100436021C (en) | An Automatic built up welding method and equipment | |
CN108213966A (en) | The processing machine and its laser splitting device of Compound Machining | |
CN216126556U (en) | Composite laser device for directional energy deposition equipment | |
CN212217496U (en) | Thick-section narrow-gap T-shaped welding joint structure | |
CN202356770U (en) | All-digital automatic welding machine of T-shaped pipe |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PB01 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
GR01 | Patent grant | ||
GR01 | Patent grant |