CN111230375B - Multi-groove tailor-welding tool - Google Patents

Abstract

The invention relates to a multi-groove tailor-welding tool, which is characterized in that: comprises a platform; the sliding frame is driven by the propulsion driving structure to slide back and forth; the top surface of the placing frame is provided with a plurality of openings for placing the sink buckets, the top surface is used for placing the flange surfaces of the sink buckets, and the placing frame is driven by the lifting driving structure to slide up and down; the fixing frame is arranged on the platform, and an accommodating space is formed between the bedplate of the fixing frame and the platform; the front and rear inner supporting structures and the side inner supporting structures; the elastic jacking control structure is arranged on the platform of the fixing frame, the lifting driving structure drives the placing frame to ascend for the first time to be in contact with the elastic jacking control structure, so that a control gap is formed between the pressing surface and the flange surface of the sink bucket, and the height of the control gap is smaller than the thickness of the plate forming the flange surface. The tool can realize automatic welding of the stainless steel water tank formed by welding the multiple water tank hoppers together, can ensure that the flange surfaces of the two adjacent water tank hoppers are tightly attached, and avoids the flange surfaces from being overlapped in a dislocation way, thereby providing guarantee for manufacturing the high-quality stainless steel water tank.

Description

Multi-groove tailor-welding tool

Technical Field

The invention relates to a large high-precision full-automatic welding tool, in particular to a multi-groove tailor-welding tool which is particularly suitable for welding a plurality of water groove buckets together.

Background

In modern industry, frock clamp appears in each link of product manufacturing in a large number, along with the improvement of industry level, and is more and more high to the precision and the degree of automation of frock clamp, and traditional frock clamp has hardly satisfied the production demand of modernization. When the precision welding, the requirement on the gap between the welded parts is very high, if the gap exceeds the required value, two workpieces cannot be welded firmly, and the welding reject ratio is high and the production efficiency is low when the traditional clamp is used for clamping.

Take the stainless steel basin of many basins fill as an example, constitute by a plurality of basins fill, each basin fill open-ended has the flange face of turning up all around, and the flange face welding of two adjacent basins is in the same place, for guaranteeing welding quality, and the basin is fought when the welding, and the flange face that needs to guarantee two adjacent basins to fight is in the same place, and the flange face that will guarantee two adjacent basins simultaneously fights can not misplace and lead to the part to overlap together.

At present, the stainless steel water tank is welded by adopting a traditional welding mode, so that the welding precision is low, and the welding consumes time and labor. In order to improve the quality of the stainless steel water tank, how to ensure that the flange surfaces of two adjacent water tank hoppers are tightly attached during welding and prevent the flange surfaces from being overlapped in a dislocation way is a technical problem to be solved by technical personnel in the field, and how to realize automatic welding and reduce labor cost is a technical problem to be solved by the technical personnel in the field urgently.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a multi-groove tailor-welding tool aiming at the current situation of the prior art, the tool can realize automatic welding of a stainless steel water groove formed by tailor-welding a plurality of water groove buckets, can ensure that the flange surfaces of two adjacent water groove buckets are tightly attached, and prevent the flange surfaces from being overlapped in a dislocation way, thereby providing guarantee for manufacturing a high-quality stainless steel water groove.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides a welding frock of multislot tailor-welding which characterized in that: comprises a platform; the bottom of the sliding frame is constrained on the platform through a horizontal sliding rail structure and can slide back and forth, and the sliding frame is driven by the propulsion driving structure and can slide back and forth relative to the platform; the top surface of the placing frame is provided with a plurality of openings for placing the sink buckets, the top surface is used for placing flange surfaces of the sink buckets, the placing frame is constrained in the placing frame through a vertical sliding rail structure and can slide up and down, and the placing frame is driven by a lifting driving structure arranged on the sliding frame and can slide up and down; the fixing frame is arranged on the platform, an accommodating space for placing the placing frame in is formed between the bedplate of the fixing frame and the platform, the bottom surface of the bedplate forms a pressing surface, and the bedplate is provided with strip-shaped holes for exposing the tailor-welded seams of the flange surfaces of the two adjacent water channel hoppers; the front and rear inner supporting structures and the side inner supporting structures are arranged below the bedplate and can extend into each water tank bucket of the placing frame and press the inner surface of the corresponding water tank bucket; the elastic jacking control structure is installed on a platen of the fixing frame and moves backwards to the accommodating space, the lifting driving structure drives the placing frame to ascend for the first time to be in contact with the elastic jacking control structure, so that a control gap is formed between the pressing surface and the flange surface of the sink bucket, the height of the control gap is smaller than the thickness of the plate of the flange surface, after the lifting driving structure drives the placing frame to ascend for the second time, the placing frame overcomes the elastic force of the elastic jacking control structure to further move upwards, and the pressing surface presses the flange surface of the sink bucket in the placing frame onto the top surface of the placing frame.

The elastic jacking control structure comprises a plurality of limiting bolts, the rod parts of the limiting bolts penetrate through a bedplate of the fixing frame from bottom to top and then are connected with limiting nuts to be hung below the bedplate, the limiting bolts can move up and down relative to the bedplate, limiting springs enabling the limiting bolts to keep moving down trend are sleeved on the rod parts of the limiting bolts, and the heads of the limiting bolts are used for being in gear contact with the placing frame. This elasticity jacking control structure relates to the part few, moreover, the steam generator is simple in structure, and the equipment is convenient, because of spacing spring to spacing bolt decurrent pressure, rise to the head with spacing bolt after the contact for the first time when lift drive structure drive rack, the power of ascending drive power and spring is balanced basically, thereby let form the control clearance between the flange face that compresses tightly face and basin were fought, drive power when lift drive structure further strengthens, overcome spacing spring's elasticity, the rack further shifts up, make the flange face that the basin that the face will arrange in the rack was fought compress tightly on the top surface of rack, the completion compresses tightly.

Preferably, the four limit bolts are distributed at four corner positions of the bedplate of the fixing frame, so that the pressure applied to the placing frame is more balanced, and the four corner positions of the placing frame are provided with limit bosses which are laterally convex and are used for being in stop contact with the heads of the limit bolts. Spacing bolt and the spacing boss cooperation that is located four corner positions of rack department can not produce the work plane of rack and interfere, rationally distributed.

Preferably, the front and rear inner support structure includes a front compression block that is driven by a front cylinder and can slide forward and backward, and a rear compression block that is driven by a rear cylinder and can slide forward and backward, the side inner support structure includes a side compression block that is driven by a side cylinder and can slide left and right, and the front cylinder, the rear cylinder and the side cylinder are all fixed below the bedplate. The front and rear inner supporting structures and the side inner supporting structures are powered by cylinders, and control is facilitated.

Under the breach that satisfies the condition, the quantity of compact heap is the better less, and as preferred overall arrangement, the top surface of above-mentioned rack is opened has three about the interval set up the trompil, can stretch into preceding compact heap, back compact heap and the side compact heap in the trompil in the middle respectively have two, can stretch into preceding compact heap, back compact heap and the side compact heap in the trompil of both sides respectively have one.

In order to ensure that the sliding frame does not easily slide in the processes of pressing and welding, the left side and the right side of the rear part of the platform are respectively provided with a limiting pin which is driven by a limiting cylinder and can move up and down, the bottom of the sliding frame is provided with two limiting holes matched with the limiting pins, the placing frame is moved backwards to the accommodating space, the limiting pins are matched with the limiting holes, and the limiting pins can be inserted into the corresponding limiting holes in the upward movement mode. After the placing frame moves backwards to the right position, the limiting pin is driven by the limiting cylinder to ascend and is inserted into the limiting hole, so that the sliding frame cannot slide forwards and backwards, and the position accuracy in the pressing and welding process is guaranteed.

Preferably, the lifting driving structure is a grading pressurization hydraulic cylinder fixed at the bottom of the sliding frame, and a piston rod of the grading pressurization hydraulic cylinder penetrates through the sliding frame and then is connected with the bottom of the placing frame. The staged pressurizing hydraulic cylinder can provide staged driving force, the first stage driving force (pneumatic forming part) is matched with the elastic force of the elastic jacking control structure, just under the balance state of the first stage driving force and the elastic jacking control structure, the control gap is located in the design range, when the elastic jacking control structure is further compressed, the placing frame can be driven to overcome the elastic force of the elastic jacking control structure by increasing the pressure (hydraulic pressurizing stroke part) only through the staged pressurizing hydraulic cylinder, and the staged pressurizing control is facilitated.

In order to firmly and stably position the two adjacent water tank hoppers, the outer side surfaces of the two adjacent water tank hoppers need to be connected by adopting a connecting support, the connecting support also needs to be welded on the water tank hoppers, in order to complete the welding of the connecting support in the tool, the lower part of the placing rack is provided with a plurality of clamping components which are driven by a pressing cylinder to slide back and forth, the inner end surfaces of the clamping components are provided with positioning structures for positioning the connecting supports, and after the clamping components move towards the direction of the water tank hoppers, the connecting supports positioned on the clamping components can press the outer end surfaces of the two adjacent water tank hoppers; the top surface of the placing frame is provided with a notch for the connecting support to penetrate out upwards, so that the placing frame is convenient to take out the water tank welded with the connecting support.

Preferably, the clamping assembly comprises three clamping blocks arranged at left and right intervals, the positioning structure is arranged on the clamping block at the middle part and comprises a concave part which is arranged on the inner end face of the clamping block at the middle part and used for placing the connecting support, the middle part of the concave part is provided with a positioning shaft which is used for being inserted into a through hole of the connecting support, and two sides of the connecting support are attached to the inner end faces of the clamping blocks at two sides. The middle clamping block mainly plays a role in positioning the left side and the right side of the connecting support, and the clamping blocks on the left side and the right side are used for pressing the welding surface of the connecting support onto the outer end surface of the water tank bucket.

Preferably, the top surface of the placing frame is further provided with a plurality of positioning pins which are movably inserted into the through holes on the flange surface of the sink bucket. The positioning pin and the through hole on the flange surface of the water tank hopper are in clearance fit, and the positioning pin and the through hole can realize coarse positioning of the water tank hopper.

Compared with the prior art, the invention has the advantages that: at the initial position, the pushing driving structure pulls the placing frame out of the containing space along with the sliding frame, so that a water tank hopper can be placed conveniently; after the sink buckets are placed, the placing frame is pushed into the containing space along with the sliding frame by the pushing driving structure, the lifting driving structure drives the placing frame to move upwards relative to the sliding frame for the first time, namely the placing frame moves towards the direction close to the pressing surface, after the placing frame is contacted with the elastic jacking control structure, a control gap is formed between the pressing surface and the flange surface of the sink buckets, then each internal supporting structure acts to press the inner end of the sink bucket towards the periphery, due to the existence of the control gap, a trough body is not completely pressed, the sink buckets are enabled to be driven to move by the internal supporting structure to realize accurate positioning, the end faces of the adjacent flange surfaces needing to be welded together are enabled to be tightly attached, and due to the fact that the height of the control gap is smaller than the thickness of a plate forming the flange surfaces, the flange surfaces of the two adjacent sink buckets cannot be overlapped; the lifting driving structure drives the placing frame to move upwards relative to the sliding frame for the second time, the placing frame overcomes the elasticity of the elastic jacking control structure to further move upwards, the pressing surface presses the flange surfaces of the water tank buckets in the placing frame onto the top surface of the placing frame, and the splicing welding seams of the flange surfaces of two adjacent water tank buckets are linear and are suitable for laser welding; after welding, each cylinder resets, and moves the sliding frame out of the accommodating space, so that the workpiece is conveniently taken out. The tool can realize the automatic operation of multi-groove tailor-welding, and reduce the comprehensive cost of welding while ensuring the welding precision.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present invention (a sliding frame in a position of outward movement);

FIG. 2 is a schematic perspective view of a second embodiment of the present invention (the sliding frame is in a position of outward movement);

FIG. 3 is a schematic perspective view of an embodiment of the present invention (with the sliding frame moved outward, and the water tank and the connecting bracket placed in position);

FIG. 4 is a schematic perspective view of an embodiment of the present invention (with the sliding frame moved inward, the water tank and the connecting bracket placed in position);

FIG. 5 is a schematic perspective view (compression welded state) of an embodiment of the present invention;

FIG. 6 is a schematic perspective view (first compression state) of an embodiment of the present invention;

FIG. 7 is a schematic perspective view (second compression state) of an embodiment of the present invention;

FIG. 8 is an exploded perspective view of the carriage in accordance with an embodiment of the present invention;

FIG. 9 is a partially exploded perspective view of the fixing frame according to an embodiment of the present invention;

FIG. 10 is a partially exploded perspective view of the fixing frame according to an embodiment of the present invention;

FIG. 11 is a schematic perspective view of a fixing frame according to an embodiment of the present invention;

FIG. 12 is a schematic perspective view of a clamping assembly according to an embodiment of the present invention;

fig. 13 is a schematic perspective view of a welded stainless steel water tank according to an embodiment of the present invention.

Detailed Description

The invention is described in further detail below with reference to the accompanying examples.

As shown in FIGS. 1 to 13, a preferred embodiment of the present invention is shown.

A multi-groove tailor-welding tool is used for welding three water tank hoppers 6 together and comprises

The platform 1 is in a frame structure.

The bottom of the sliding frame 2 is constrained on the platform 1 through a horizontal sliding rail structure 3a and can slide back and forth, and the sliding frame 2 is driven by a propulsion driving structure 4a and can slide back and forth relative to the platform 1; the propulsion driving structure 4a can be a driving cylinder, and can also be realized by a motor through a transmission structure, the left side and the right side of the rear part of the platform 1 are both provided with limit pins 12 which are driven by the limit cylinders 11 and can move up and down, the bottom of the sliding frame 2 is provided with two limit holes 21 matched with the limit pins 12, the placing frame 5 moves backwards to the state in the accommodating space S, the limit pins 12 are matched with the limit holes 21, and the upward movement of the limit pins 12 can be inserted into the corresponding limit holes 21.

The top surface 51 of the placing frame 5 is provided with a plurality of openings 52 for placing the sink buckets 6, the top surface 51 is used for placing the flange surfaces 61 of the sink buckets 6, the placing frame 5 is constrained in the placing frame 5 through a vertical sliding rail structure 3b and can slide up and down, and the placing frame 5 is driven by a lifting driving structure 4b arranged on the sliding frame 2 and can slide up and down; the lifting driving structure 4b is a grading pressurization hydraulic cylinder fixed at the bottom of the sliding frame 2, and a piston rod of the grading pressurization hydraulic cylinder penetrates through the sliding frame 2 and then is connected with the bottom of the placing frame 5. The top surface of the placing frame 5 is also provided with a plurality of positioning pins 16 which are movably inserted into the through holes on the flange surface 61 of the sink bucket.

The fixing frame 7 is arranged at the rear part of the platform 1, an accommodating space S for placing the placing frame 5 in is formed between a bedplate 71 of the fixing frame 7 and the platform 1, a pressing surface 72 is formed on the bottom surface of the bedplate 71, and strip-shaped holes 73 for exposing the tailor-welded seams 62 of the flange surfaces 61 of the two adjacent water channel hoppers are formed in the bedplate 71;

the front and rear inner supporting structures and the side inner supporting structures are both arranged below the bedplate 71, and both the front and rear inner supporting structures and the side inner supporting structures can extend into each water tank bucket 6 of the placing frame 5 and press the inner surfaces of the corresponding water tank buckets 6; the front and rear inner support structure comprises a front pressing block 9a driven by a front cylinder 10a to slide back and forth and a rear pressing block 9b driven by a rear cylinder 10b to slide back and forth, the side inner support structure comprises a side pressing block 9c driven by a side cylinder 10c to slide left and right, and the front cylinder 10a, the rear cylinder 10b and the side cylinder 10c are all fixed below the bedplate 71. The top surface 51 of the placing rack 5 is provided with three openings 52 arranged at left and right intervals, two front pressing blocks 9a, two rear pressing blocks 9b and two side pressing blocks 9c which can extend into the openings 52 in the middle are respectively arranged, and one front pressing block 9a, one rear pressing block 9b and one side pressing block 9c which can extend into the openings 52 on the two sides are respectively arranged.

The elastic jacking control structure 8 is installed on a platen 71 of the fixing frame 7, the placing frame 5 is moved to the accommodating space S after the placing frame 5 is moved, the lifting driving structure 4b drives the placing frame 5 to rise for the first time to be in contact with the elastic jacking control structure 8, a control gap X is formed between the pressing surface 72 and the flange surface 61 of the water tank bucket 6, the height of the control gap X is smaller than the thickness of a plate forming the flange surface 61, after the lifting driving structure 4b drives the placing frame 5 to rise for the second time, the placing frame 5 overcomes the elastic force of the elastic jacking control structure 8 to further move upwards, and the pressing surface 72 presses the flange surface 61 of the water tank bucket 6 placed in the placing frame 5 onto the top surface of the placing frame 5.

The elastic jacking control structure 8 in this embodiment includes a plurality of limiting bolts 81, the rod portions of the limiting bolts 81 pass through the platen 71 of the fixing frame 7 from bottom to top and then are connected with the limiting nuts 82 to be hung below the platen 71, the limiting bolts 81 can move up and down relative to the platen 71, the rod portions of the limiting bolts 81 are sleeved with limiting springs 83 for enabling the limiting bolts 81 to keep moving down, and the head portions of the limiting bolts 81 are used for contacting with the gears of the placing frame 5. Four limiting bolts 81 are distributed at four corner positions of the bedplate 71 of the fixed frame 7, and the four corner positions of the placing frame 5 are provided with laterally convex limiting bosses 53 which are used for contacting with the head of the limiting bolts 81 in a blocking way.

The lower part of the placing rack 5 is provided with a plurality of clamping components which are driven by a pressing cylinder 14 to slide back and forth, the inner end surfaces of the clamping components are provided with positioning structures for positioning the connecting supports 13, and after the clamping components move towards the water tank buckets 6, the connecting supports 13 positioned on the clamping components can press the outer end surfaces of two adjacent water tank buckets 6; the top surface 51 of the placing frame 5 is provided with a notch 511 for the connecting bracket 13 to pass through upwards.

The clamping assembly comprises three clamping blocks 15 arranged at left and right intervals, the positioning structure is arranged on the clamping block 15 in the middle, the positioning structure comprises a concave portion 151 which is arranged on the inner end face of the clamping block 15 in the middle and used for placing the connecting support 13, a positioning shaft 152 which is used for being inserted into a through hole 131 of the connecting support 13 is arranged in the middle of the concave portion 151, and two sides of the connecting support 13 are attached to the inner end faces of the clamping blocks 15 on two sides.

The working principle and the process of the embodiment of the invention are as follows:

as shown in fig. 1 and 2, in the initial position, the pushing and driving structure 4a pulls the rack 5 out of the accommodating space S along with the carriage 2, so as to place the sink bucket 6 and the connecting brackets 13.

And (3) positioning: placing the three water channel hoppers 6 into the open holes 52, wherein the flange surface 61 of each water channel hopper 6 is placed on the top surface 51 of the placing frame 5, and each connecting bracket 13 is placed on the clamping assembly, as shown in fig. 3; then the driving structure 4a is pushed forward to convey the placing rack 5 into the accommodating space S along with the sliding rack 2, as shown in fig. 4; the lifting driving structure 4b drives the placing frame 5 to move upwards relative to the sliding frame 2 for the first time, as shown in fig. 5, that is, the placing frame 5 moves towards the direction close to the pressing surface 72, when the placing frame 5 contacts with the head of the limit bolt 81, the driving force provided by the lifting driving structure 4b is balanced with the elastic force of the spring 83, so as to ensure that a control gap X is formed between the pressing surface 72 and the flange surface 61 of the sink bucket 6, as shown in fig. 6, then each inner supporting structure acts to press the inner end of the sink bucket 6 towards the periphery, generally, the inner supporting structure at the side in the middle sink bucket acts first, then the inner supporting structures at the sides act, and finally the inner supporting structures at the front and the back in each sink bucket act, because of the existence of the control gap X, the flange surface 61 of the sink bucket is not completely pressed, as shown in fig. 7, the sink bucket 6 can be driven by the inner supporting structures to move to realize accurate positioning, so as to ensure that the end surfaces of the adjacent flange surfaces 61 which need to be welded together are tightly attached, because the height of the control clearance X is smaller than the thickness of the plate forming the flange surface 61, the flange surfaces 61 of two adjacent water tank hoppers 6 cannot be overlapped in the tensioning and positioning process; the lifting driving structure 4b drives the placing frame 5 to move upwards relative to the sliding frame 2 for the second time, the placing frame 5 further moves upwards against the elastic force of the spring 83, the pressing surface 72 presses the flange surface 61 of the water tank bucket 6 placed in the placing frame 5 to the top surface 51 of the placing frame 5, the tailor-welded seams 62 of the flange surfaces 61 of the two adjacent water tank buckets 6 are in a straight line and are suitable for laser welding, and the tailor-welded seams 62 are exposed out of the strip-shaped holes 73; the pressing cylinder 14 drives the clamping block 15 to move towards the water tank bucket 6, and two sides of the connecting bracket 13 are pressed and attached to the outer end face of the water tank bucket 6 to be welded.

After the welding is completed, each cylinder is reset, and the sliding frame 2 is moved out of the accommodating space S, so that the welded stainless steel water tank can be conveniently taken out, as shown in fig. 13.

It should be noted that in the description of the present embodiment, the terms "front, back", "left, right", "up, down", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, which is only for convenience of describing the present invention and simplifying the description, but does not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

Claims (10)

1. The utility model provides a welding frock of multislot tailor-welding which characterized in that: comprises that

A platform (1);

the bottom of the sliding frame (2) is constrained on the platform (1) through a horizontal sliding rail structure (3a) and can slide back and forth, and the sliding frame (2) is driven by a propulsion driving structure (4a) and can slide back and forth relative to the platform (1);

the rack (5) is provided with a plurality of holes (52) for placing the sink buckets (6) on the top surface (51), the top surface (51) is used for placing flange surfaces (61) of the sink buckets (6), the rack (5) is constrained in the rack (5) through a vertical sliding rail structure (3b) and can slide up and down, and the rack (5) is driven by a lifting driving structure (4b) arranged on the sliding frame (2) and can slide up and down;

the fixing frame (7) is installed at the rear part of the platform (1), an accommodating space (S) for placing the placing frame (5) in is formed between a bedplate (71) of the fixing frame (7) and the platform (1), a pressing surface (72) is formed by the bottom surface of the bedplate (71), and a strip-shaped hole (73) for exposing a splice welding seam (62) of two adjacent water tank bucket flange surfaces (61) is formed in the bedplate (71);

the front and rear inner supporting structures and the side inner supporting structures are both arranged below the bedplate (71), and both the front and rear inner supporting structures and the side inner supporting structures can extend into each water tank bucket (6) of the placing rack (5) and press the inner surfaces of the corresponding water tank buckets (6);

an elastic jacking control structure (8) is arranged on a bedplate (71) of the fixed frame (7), under the state that the placing rack (5) moves backwards into the accommodating space (S), the lifting driving structure (4b) drives the placing rack (5) to ascend for the first time to be contacted with the elastic jacking control structure (8), so that a control gap (X) is formed between the pressing surface (72) and the flange surface (61) of the water tank bucket (6), the height of the control gap (X) is smaller than the thickness of the plate material forming the flange surface (61), after the lifting driving structure (4b) drives the placing rack (5) to ascend for the second time, the placing rack (5) overcomes the elasticity of the elastic jacking control structure (8) to further move upwards, and the pressing surface (72) presses the flange surface (61) of the sink bucket (6) arranged in the placing rack (5) on the top surface of the placing rack (5).

2. The multi-groove tailor-welded welding tool according to claim 1, wherein: elasticity jacking control structure (8) include a plurality of spacing bolts (81), and the pole portion of spacing bolt (81) is connected and is hung and establish in platen (71) below with stop nut (82) after platen (71) of mount (7) are passed from bottom to top, and spacing bolt (81) can reciprocate relatively platen (71), the cover is equipped with spacing spring (83) that make spacing bolt (81) keep moving down the trend on the pole portion of spacing bolt (81), and the head of spacing bolt (81) is used for keeping off the position contact with rack (5).

3. The multi-groove tailor-welded welding tool according to claim 2, wherein: the four limit bolts (81) are distributed at four corner positions of the bedplate (71) of the fixed frame (7), and the four corner positions of the placing frame (5) are provided with limit bosses (53) which are laterally convex and used for being in gear contact with the head of the limit bolts (81).

4. The multi-groove tailor-welded welding tool according to claim 1, wherein: the front and rear inner support structure comprises a front pressing block (9a) driven by a front cylinder (10a) to slide back and forth and a rear pressing block (9b) driven by a rear cylinder (10b) to slide back and forth, the side inner support structure comprises a side pressing block (9c) driven by a side cylinder (10c) to slide left and right, and the front cylinder (10a), the rear cylinder (10b) and the side cylinder (10c) are all fixed below the bedplate (71).

5. The multi-groove tailor-welded welding tool according to claim 4, wherein: the top surface (51) of rack (5) is opened has three left and right sides interval setting trompil (52), can stretch into preceding compact heap (9a), back compact heap (9b) and side compact heap (9c) in trompil (52) in the middle of the stretching into respectively have two, can stretch into preceding compact heap (9a), back compact heap (9b) and side compact heap (9c) in trompil (52) of both sides and respectively have one.

6. The multi-groove tailor-welded welding tool according to claim 1, wherein: the left and right sides at the rear portion of platform (1) all is equipped with and can reciprocate spacer pin (12) by spacing cylinder (11) drive, open the bottom of carriage (2) has two spacing holes (21) that match with spacer pin (12), moves to behind rack (5) under the state in accommodation space (S), spacer pin (12) match with spacing hole (21), and the corresponding spacing hole (21) can be inserted in shifting up of spacer pin (12).

7. The multi-groove tailor-welded welding tool according to claim 1, wherein: the lifting driving structure (4b) is a grading pressurizing hydraulic cylinder fixed at the bottom of the sliding frame (2), and a piston rod of the grading pressurizing hydraulic cylinder penetrates through the sliding frame (2) and then is connected with the bottom of the placing frame (5).

8. The multi-groove tailor-welded welding tool according to claim 1, wherein: the lower part of the placing rack (5) is provided with a plurality of clamping components which are driven by a pressing cylinder (14) to slide back and forth, the inner end surfaces of the clamping components are provided with positioning structures for positioning connecting supports (13), and after the clamping components move towards the water tank buckets (6), the connecting supports (13) positioned on the clamping components can press the outer end surfaces of two adjacent water tank buckets (6); and a notch (511) for the connecting support (13) to penetrate out upwards is formed in the top surface (51) of the placing frame (5).

9. The multi-groove tailor-welded welding tool according to claim 8, wherein: the clamping assembly comprises three clamping blocks (15) arranged at left and right intervals, the positioning structure is arranged on the clamping blocks (15) at the middle part and comprises concave parts (151) arranged on the inner end faces of the clamping blocks (15) at the middle part and used for placing the connecting supports (13), the middle parts of the concave parts (151) are provided with positioning shafts (152) used for being inserted into through holes (131) of the connecting supports (13), and the two sides of the connecting supports (13) are attached to the inner end faces of the clamping blocks (15) at the two sides.

10. The multi-groove tailor-welded welding tool according to claim 1, wherein: and the top surface of the placing rack (5) is also provided with a plurality of positioning pins (16) which are movably inserted into through holes on the flange surface (61) of the sink bucket.

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