CN220372487U - Aluminum template welding assembly line - Google Patents

Abstract

The utility model discloses an aluminum template welding assembly line which comprises a feeding conveyor line, a discharging conveyor line, at least one welding tool and at least one welding device. The feeding conveying line is provided with a first side and a second side opposite to the first side in a second direction, the second direction is perpendicular to the first direction, the welding fixture comprises a frame, a turnover table top positioning mechanism and a turnover driving device, the turnover table top is pivoted with the frame, and the turnover driving device is in power connection with the turnover table top so that the turnover table top has a horizontal position and an inclined position; in horizontal position, upset mesa cooperates with the material loading transfer chain in order to receive the aluminium template that shifts out from the second side to make welding set can weld the aluminium template on the welding frock, simultaneously, the material loading transfer chain need not to stop carrying, and the material loading transfer chain continues to carry other aluminium templates to next welding station forward, has improved efficiency. In the inclined position, the overturning table top is matched with the blanking conveying line so that the aluminum templates on the overturning table top slide onto the blanking conveying line.

Description

Aluminum template welding assembly line

Technical Field

The utility model relates to the technical field of welding equipment, in particular to an aluminum template welding assembly line.

Background

The aluminum template generally refers to an aluminum alloy template for building, and the aluminum template system has the advantages of light dead weight, good pressure bearing condition, recycling and the like, so that the aluminum template system is widely applied to building construction. Aluminum mould board among the prior art, including mainboard and the connecting plate of integrative setting, connecting plate perpendicular to mainboard, the mainboard includes working face and holding surface, is provided with the strengthening rib along aluminum mould board length direction on the holding surface. When the aluminum template is welded and produced, the main board, the reinforcing ribs and other components are required to be welded into a whole.

The current aluminum mould board welding assembly line includes pan feeding cylinder transfer chain, ejection of compact cylinder transfer chain and welding robot etc. welding robot locates one side of pan feeding cylinder transfer chain, and ejection of compact cylinder transfer chain is connected the pan feeding cylinder transfer chain. The working mode is as follows: place the aluminium mould bottom plate on pan feeding cylinder conveying line, pan feeding cylinder conveying line is used for carrying aluminium mould bottom plate to aluminium mould bottom plate feeding mechanism on, aluminium mould servo positioning mechanism carries out spacing fixedly to aluminium mould bottom plate, store up the muscle pipe conveying line and carry the muscle pipe, the manipulator is transplanted to the muscle pipe is used for pressing the muscle pipe clamp out on aluminium mould bottom plate, welding robot is used for welding aluminium mould bottom plate and muscle pipe, after the welding is accomplished, aluminium mould bottom plate feeding mechanism carries aluminium mould bottom plate to ejection of compact cylinder conveying line on, ejection of compact cylinder conveying line is used for carrying welded aluminium mould bottom plate.

When the aluminum template welding assembly line is welded, the feeding roller conveying line needs to stop conveying, and only after the welding of the previous aluminum template is completed, the next aluminum template can be conveyed to the position of the welding robot forward for welding, so that the welding efficiency is low. In addition, pan feeding cylinder transfer chain and ejection of compact cylinder transfer chain adopt the mode of arranging side by side, have led to equipment whole occupation space great, and space utilization is low.

Disclosure of Invention

The embodiment of the utility model provides an aluminum template welding assembly line for solving the technical problems of low welding efficiency and low space utilization rate of the aluminum template welding assembly line in the prior art.

In order to solve the technical problems, in one aspect, an embodiment of the present utility model provides an aluminum template welding assembly line, including:

the feeding conveying line is configured to convey the aluminum templates along a first direction; the feeding conveying line is provided with a first side and a second side opposite to the first side in a second direction, and the second direction is perpendicular to the first direction;

a blanking conveying line overlapped below the feeding conveying line, wherein the blanking conveying line is configured to convey the aluminum templates along the first direction or the direction opposite to the first direction;

the welding tool is positioned at the second side and comprises a frame, a turnover table top positioning mechanism and a turnover driving device, the turnover table top is pivoted with the frame, and the turnover driving device is in power connection with the turnover table top so that the turnover table top has a horizontal position and an inclined position; in the horizontal position, the overturning table top is matched with the feeding conveying line to receive the aluminum template moved out of the second side; in the inclined position, the overturning table top is matched with the blanking conveying line so that the aluminum templates on the overturning table top slide onto the blanking conveying line; the positioning mechanism is configured to position the aluminum template on the turning table top; and

and the welding device is arranged on one side of the welding tool and used for welding the aluminum template on the overturning table top.

In some embodiments, the positioning mechanism comprises a clamping device, a side pressure device, a limit stop, and a hold-down device;

the flip top has a third side adjacent to the second side and a fourth side opposite the third side; the clamping device and the limit baffle are arranged on the fourth side, the side pressing device is arranged on the third side, and the pressing device is arranged on the frame and is positioned above the third side;

the side pressure device is configured to laterally press the aluminum template on the overturning table so as to enable the aluminum template to cling to the limit baffle;

the clamping device is configured to press down one side of the aluminum template on the flip top;

the hold down device is configured to hold down the other side of the aluminum form on the flip top.

In some embodiments, the clamping device comprises a plurality of first lever cylinders arranged at intervals, the first lever cylinders having first press blocks which press down the aluminum templates on the flip table;

and/or the side pressure device comprises a plurality of second lever cylinders which are arranged at intervals, wherein the second lever cylinders are provided with second pressing blocks; the second lever cylinder is arranged on the lower side of the overturning table top; the second pressing block is provided with a release position and a side pressure position; in the release position, the second press block is lower than the surface of the overturning table top; the second pressing block laterally presses the aluminum template on the overturning table top at the side pressing position;

and/or the pressing device comprises a plurality of lower pressing cylinders which are arranged at intervals, wherein the lower pressing cylinders are provided with third pressing blocks, the lower pressing cylinders and the third pressing blocks are positioned above the overturning table top, and the third pressing blocks press down the aluminum templates on the overturning table top.

In some embodiments, the welding fixture further comprises a pin cylinder, wherein the pin cylinder is fixed on the frame, and at least one pin cylinder is arranged at each of two ends of the overturning table top; the two ends of the turnover table top are respectively provided with a clamping hole, the pin cylinder is provided with a pin shaft, and the pin shaft is opposite to the clamping holes in the horizontal position so that the pin shaft can be clamped into the clamping holes;

and/or, welding frock still includes to press from both sides the mechanism, it includes first pair clamp push pedal, first lead screw nut mechanism, second pair clamp push pedal and second lead screw nut mechanism to press from both sides the mechanism, first pair clamp push pedal with the second pair clamp push pedal sets up relatively and is located upset mesa upside, be equipped with linear guide way on the upset mesa, first pair clamp push pedal with the second pair clamp push pedal is connected to respectively through linear guide way is located upset mesa downside first lead screw nut mechanism with second lead screw nut mechanism.

In some embodiments, the aluminum die plate welding line further comprises:

the at least one jacking side pushing mechanism comprises a first jacking device, a side pushing driving mechanism and a side pushing force application piece; the first jacking device is positioned at the lower side of the feeding conveying line and jacks the aluminum templates on the feeding conveying line so as to separate the aluminum templates from the feeding conveying line; the side pushing driving mechanism is connected with the side pushing force application member, and the side pushing force application member is configured to be driven by the side pushing driving mechanism to move along the second direction so as to push the aluminum mould plate on the first jacking device out of the second side.

In some embodiments, the side-pushing driving mechanism comprises a primary side-pushing cylinder and a secondary side-pushing cylinder, wherein the primary side-pushing cylinder is in power connection with the secondary side-pushing cylinder to drive the secondary side-pushing cylinder to move along the second direction;

the side pushing force application piece is in power connection with the secondary side pushing cylinder.

In some embodiments, the first jacking device comprises a mounting bracket, a first jacking cylinder, a lifting bracket and a plurality of guide posts;

the mounting bracket is fixed on the feeding conveying line, the first jacking air cylinder is arranged on the mounting bracket, the lifting bracket is in power connection with the first jacking air cylinder, the lifting bracket is connected with the mounting bracket through the guide post, and the side pushing driving mechanism is arranged on the lifting bracket;

the feeding conveying line is a first roller conveying line and is provided with a plurality of first rollers, and the lifting support is provided with a hollowed-out avoidance portion for avoiding the first rollers.

In some embodiments, the aluminum die plate welding line further comprises:

the lower side pushing mechanism comprises a linear motion mechanism and a plurality of second jacking devices, wherein the linear motion mechanism is in power connection with the second jacking devices so as to drive the second jacking devices to move along the second direction, and the second jacking devices are positioned on the lower side of the blanking conveying line so as to jack up the aluminum templates on the blanking conveying line.

In some embodiments, the linear motion mechanism comprises a rodless cylinder, a plurality of guide rods and a connecting plate, wherein the rodless cylinder is in power connection with the connecting plate, the guide rods are arranged on the lower side of the blanking conveying line, the connecting plate is in sliding connection with the guide rods, the second jacking device comprises a second jacking cylinder and a jacking motion piece, the second jacking cylinder is arranged on the connecting plate, and the jacking motion piece is in power connection with the second jacking cylinder.

In some embodiments, an oblique guide plate is arranged on one side, close to the welding tool, of the blanking conveying line, and in the oblique position, the overturning table top is in butt joint with the oblique guide plate, so that the aluminum template on the overturning table top slides to the blanking conveying line through the oblique guide plate;

and/or the overturning driving device comprises an overturning air cylinder, wherein the overturning air cylinder is obliquely arranged, and a piston rod of the overturning air cylinder is connected with the overturning table top.

The embodiment of the utility model has the following beneficial effects: when the aluminum template welding assembly line works, the welding tool receives the aluminum templates which are moved out from the second side, so that the welding device can weld the aluminum templates on the welding tool, meanwhile, the feeding conveying line does not need to stop conveying, and the feeding conveying line continuously conveys the rest aluminum templates to the next welding station, so that the production efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of a first embodiment of an aluminum die plate welding assembly line according to the present utility model;

FIG. 2 is a schematic view of the hidden welding apparatus of FIG. 1;

FIG. 3 is a schematic view of the structure of FIG. 2 after concealing the feed conveyor line and the discharge conveyor line;

FIG. 4 is another operational schematic of FIG. 3;

FIG. 5 is a further operational schematic of FIG. 3;

FIG. 6 is a schematic structural view of a first embodiment of a welding tool according to the present utility model;

FIG. 7 is a top view of a first embodiment of a welding tool of the present utility model;

FIG. 8 is a cross-sectional view taken along line A-A shown in FIG. 7;

FIG. 9 is a cross-sectional view taken along B-B shown in FIG. 7;

FIG. 10 is an enlarged partial view of region C shown in FIG. 9;

FIG. 11 is a bottom view of the flip top in the present utility model;

FIG. 12 is a schematic view of the construction of a first embodiment of the jacking side pushing mechanism of the present utility model;

fig. 13 is a schematic structural view of a first embodiment of the lower-layer side pushing mechanism in the present utility model.

Reference numerals illustrate:

100. a feeding conveying line; 110. a first side; 120. a second side; 200. a blanking conveying line; 210. an inclined guide plate; 300. a jacking side pushing mechanism; 310. a first jacking device; 311. a mounting bracket; 312. a first jacking cylinder; 313. a lifting bracket; 314. a guide post; 320. a side pushing driving mechanism; 321. a first-stage side pushing cylinder; 322. a secondary side pushing cylinder; 330. a side-pushing force application member; 400. welding a tool; 410. a frame; 420. turning over the table top; 421. a third side; 422. a fourth side; 423. a clamping hole; 424. a linear guide groove; 425. a rotating shaft; 430. a flip driving device; 440. a clamping device; 441. a first lever cylinder; 442. a first briquette; 450. a side pressure device; 451. a second lever cylinder; 452. a second briquetting; 460. a limit baffle; 470. a compacting device; 471. a pressing cylinder; 472. a third briquetting; 480. a pin cylinder; 481. a pin shaft; 490. a butt-clamping mechanism; 491. a first pair of pinch push plates; 492. a first lead screw nut mechanism; 493. a second pair of pinch push plates; 494. a second feed screw nut mechanism; 500. a welding device; 600. a lower layer side pushing mechanism; 610. a second jacking device; 611. a second jacking cylinder; 612. jacking the moving part; 620. a rodless cylinder; 630. a guide rod; 640. a connecting plate; 700. an aluminum template.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings, for the purpose of making the objects, technical solutions and advantages of the present utility model more apparent. It is only stated that the terms of orientation such as up, down, left, right, front, back, inner, outer, etc. used in this document or the imminent present utility model, are used only with reference to the drawings of the present utility model, and are not meant to be limiting in any way.

In the present utility model, unless specifically stated and limited otherwise, the terms "connected," "affixed," and the like are to be construed broadly, and for example, "affixed" may be a fixed connection, a removable connection, or an integral body; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The description as it relates to "first", "second", etc. in the present utility model is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

As shown in fig. 1 to 5, an embodiment of the present utility model provides an aluminum die plate welding line, which includes a feeding conveyor line 100, a discharging conveyor line 200, at least one welding tool 400, and at least one welding device 500. In order to improve the welding efficiency, the number of the welding devices 500 is generally more than one, and accordingly, the number of the welding tools 400 and the jacking side pushing mechanisms 300 is equal to the number of the welding devices 500.

The loading conveyor line 100 is configured to convey the aluminum form 700 in a first direction. The feeding conveyor line 100 has a first side 110 and a second side 120 opposite to the first side 110 in a second direction, which is perpendicular to the first direction.

The discharging conveyor line 200 is stacked under the feeding conveyor line 100, and the discharging conveyor line 200 is configured to convey the aluminum form 700 in the first direction or the opposite direction of the first direction. Because the feeding conveyor line 100 and the discharging conveyor line 200 are arranged in a stacked manner, the overall structure is more compact, so that the space is further saved. Alternatively, the loading conveyor line 100 and the unloading conveyor line 200 are an upper layer conveyor line and a lower layer conveyor line of the double-layer roller conveyor line, respectively.

The welding fixture 400 is located on the second side 120, and the welding fixture 400 includes a frame 410, a positioning mechanism for the turning table 420, and a turning driving device 430, where the turning table 420 is pivoted to the frame 410, and the turning driving device 430 is dynamically connected to the turning table 420 so that the turning table 420 has a horizontal position and an inclined position. In the horizontal position, the flip top 420 cooperates with the loading conveyor line 100 to receive the aluminum form 700 removed from the second side 120. In the inclined position, the overturning platform 420 is matched with the blanking conveying line 200 so that the aluminum template 700 on the overturning platform 420 slides onto the blanking conveying line 200. By turning the table 420, transfer of the aluminum form 700 from the loading conveyor line 100 (upper layer) to the unloading conveyor line 200 (lower layer) is achieved. The positioning mechanism is configured to position the aluminum form 700 on the flip top 420 for welding.

The welding device 500 is provided at one side of the welding tool 400 to weld the aluminum form 700 on the turn table 420. Alternatively, the welding apparatus 500 is a welding station or welding robot.

When the aluminum template welding assembly line works, the welding tool 400 receives the aluminum templates 700 moved out from the second side 120, so that the welding device 500 can weld the aluminum templates 700 on the welding tool 400, and meanwhile, since the aluminum templates 700 being welded are moved out of the feeding conveyor line 100, the feeding conveyor line 100 does not need to stop conveying, and the feeding conveyor line 100 continues to convey the next aluminum templates 700 to the next welding station, so that the production efficiency is improved.

Optionally, as shown in fig. 3, the aluminum die plate welding line further includes at least one jacking side pushing mechanism 300, and the jacking side pushing mechanism 300 includes a first jacking device 310, a side pushing driving mechanism 320, and a side pushing force application member 330. The first jacking device 310 is located at the lower side of the feeding conveyor line 100 to jack the aluminum pattern plate 700 on the feeding conveyor line 100 to separate the aluminum pattern plate 700 from the feeding conveyor line 100. The side pushing driving mechanism 320 is connected to the side pushing force applying member 330, and the side pushing force applying member 330 is configured to be driven by the side pushing driving mechanism 320 to move along the second direction so as to push the aluminum form 700 on the first jacking device 310 out of the second side 120. The aluminum pattern plate 700 on the feeding conveyor line 100 is lifted up by the first lifting device 310, and then the aluminum pattern plate 700 on the first lifting device 310 is pushed out of the feeding conveyor line 100 from the second side 120 by the side pushing force application member 330. It should be noted that the aluminum form 700 may be removed from the second side 120 by other means, such as a robot.

Alternatively, as shown in fig. 5, the flipping driving means 430 comprises a flipping cylinder which is arranged obliquely and whose piston rod is connected to the flipping table 420. In more detail, both ends of the fourth side 422 of the flip top 420 are pivotally connected to the frame 410 via the pivot 425, respectively. And the rod end of the inversion cylinder is connected to the third side 421 of the inversion tabletop 420. Thus, when the piston rod of the inversion cylinder is in an extended state, the inversion table 420 is in a horizontal position. When the piston rod of the flip cylinder is contracted, the flip table 420 is in an inclined position.

In some embodiments, as shown in fig. 6-8, to secure the aluminum form 700 on the welding tool 400, the positioning mechanism includes a clamping device 440, a side pressure device 450, a limit stop 460, and a hold down device 470.

The flip top 420 has a third side 421 and a fourth side 422 opposite the third side 421, the third side 421 being adjacent to the second side 120, i.e., the aluminum form 700 removed from the second side 120 first passes the third side 421. Generally, the aluminum form 700 is square, and when the square aluminum form 700 is placed on the flip top 420, one pair of opposite sides are located on the third side 421 and the fourth side 422, respectively. The clamping device 440 and the limit baffle 460 are disposed on the fourth side 422, the side pressing device 450 is disposed on the third side 421, and the pressing device 470 is disposed on the frame 410 and above the third side 421.

The side press 450 is configured to laterally press the aluminum form 700 on the flip top 420 to place the aluminum form 700 against the stop plate 460, positioning the aluminum form 700 from both sides through the interaction of the side press 450 and the stop plate 460. The clamping device 440 is configured to press down one side of the aluminum form 700 on the flip top 420. The hold down 470 is configured to press down on the other side of the aluminum form 700 on the flip top 420 to hold the aluminum form 700 fixed to the flip top 420 by pressing down on both sides of the aluminum form 700.

Further, the clamping device 440 includes a plurality of first lever cylinders 441 arranged at intervals, the first lever cylinders 441 have first pressing blocks 442, and the first pressing blocks 442 press the aluminum die plates 700 on the turnover table 420.

Further, the side pressing device 450 includes a plurality of second lever cylinders 451 arranged at intervals, and the second lever cylinders 451 have second pressing blocks 452. The second lever cylinder 451 is provided at the lower side of the flipping table 420. The second presser piece 452 has a release position and a side pressure position. In the release position, the second press 452 is below the surface of the flip top 420. In the side pressure position, the second press block 452 laterally presses against the aluminum die plate 700 on the flip top 420. When the aluminum form 700 is transferred from the loading conveyor line 100 to the turn table 420, or when the aluminum form 700 is transferred from the turn table 420 to the unloading conveyor line 200, the second press block 452 needs to be located at a release position to avoid. When the aluminum form 700 is welded, or the turning table 420 is turned over, the second press 452 needs to be positioned at the side pressure position, thereby clamping the aluminum form 700.

Further, the pressing device 470 includes a plurality of pressing cylinders 471 arranged at intervals, the pressing cylinders 471 have a third pressing block 472, and the pressing cylinders 471 and the third pressing blocks 472 are located above the turning table 420 to avoid the aluminum form 700 or the side pushing force application member 330. The third press block 472 presses down the aluminum die plate 700 on the turn table 420.

In some embodiments, as shown in fig. 9 to 10, the welding tool 400 further includes a pin cylinder 480, the pin cylinder 480 is fixed on the frame 410, and at least one pin cylinder 480 is disposed at each of two ends of the flip top 420. The two ends of the turnover table 420 are respectively provided with a clamping hole 423, the pin cylinder 480 is provided with a pin shaft 481, and in the horizontal position, the pin shaft 481 is opposite to the clamping holes 423, so that the pin shaft 481 can be clamped into the clamping holes 423 to fix the turnover table 420, thereby keeping the turnover table 420 horizontal and being beneficial to the welding work. Conversely, when the flip top 420 is reversed, the pin shaft 481 exits the clamping hole 423.

As shown in fig. 6 and 11, in order to further fix the remaining two sides of the aluminum die plate 700, the welding fixture 400 further includes a butt clamp mechanism 490, where the butt clamp mechanism 490 includes a first butt clamp push plate 491, a first lead screw nut mechanism 492, a second butt clamp push plate 493, and a second lead screw nut mechanism 494, the first butt clamp push plate 491 and the second butt clamp push plate 493 are disposed opposite to each other and are located on the upper side of the turnover table 420, a linear guide groove 424 is provided on the turnover table 420, and the first butt clamp push plate 491 and the second butt clamp push plate 493 are connected to the first lead screw nut mechanism 492 and the second lead screw nut mechanism 494 located on the lower side of the turnover table 420 through the linear guide groove 424, respectively. The first and second pair of clamp pushing plates 491, 493 move toward or away from each other and are respectively attached to one side of the aluminum form 700 to secure the aluminum form 700 and position the aluminum form 700. Specifically, the first lead screw nut mechanism 492 and the second lead screw nut mechanism 494 each include a drive motor, a lead screw, and a nut, the lead screw being in power connection with the drive motor, the nut being in threaded engagement with the lead screw. The first and second pair of clamp pusher plates 491, 493 are each connected to two nuts.

In some embodiments, as shown in fig. 12, to avoid the difficulty of pushing the aluminum form 700 from the feed conveyor line 100 to the welding fixture 400 by a single cylinder, the side pushing driving mechanism 320 includes a primary side pushing cylinder 321 and a secondary side pushing cylinder 322, and the primary side pushing cylinder 321 is in power connection with the secondary side pushing cylinder 322 to drive the secondary side pushing cylinder 322 to move in the second direction. The side pushing force applying member 330 is in power connection with the secondary side pushing cylinder 322. The side push aluminum form 700 process is as follows: the primary side pushing cylinder 321 drives the secondary side pushing cylinder 322 and the side pushing force applying member 330 on the secondary side pushing cylinder 322 to move to the second side 120, and the side pushing force applying member 330 pushes the aluminum die plate 700 to the edge of the second side 120 at this time, but the aluminum die plate 700 is not transferred to the welding fixture 400 entirely. Then, the secondary side pushing cylinder 322 drives the side pushing force applying member 330 to continue side pushing, so that the aluminum template 700 is integrally transferred to the welding fixture 400. In addition, in order to transfer the aluminum form 700 from the first jacking device 310 to the side-pushing force applying member 330, the side-pushing force applying member 330 is a long strip.

In some embodiments, as shown in fig. 12, the first jacking device 310 includes a mounting bracket 311, a first jacking cylinder 312, a lifting bracket 313, and a plurality of guide posts 314. The mounting bracket 311 is fixed on the feeding conveyor line 100, the first lifting cylinder 312 is arranged on the mounting bracket 311, the lifting bracket 313 is in power connection with the first lifting cylinder 312, and the lifting bracket 313 is specifically a bracket. And the lifting support 313 is connected with the mounting support 311 through the guide post 314. The side pushing driving mechanism 320 is provided on the lifting bracket 313.

The material loading transfer chain 100 is first cylinder transfer chain and has a plurality of first cylinders, and lifting support 313 has the fretwork that is used for dodging a plurality of first cylinders and keeps away a position portion, and lifting support 313 removes the in-process promptly and can not cause the interference to first cylinder, and first cylinder work is not influenced, can not stop and carry out the jacking.

In some embodiments, as shown in fig. 13, in order to integrally move the aluminum form 700 to the blanking conveying line 200 and convey the aluminum form 700 after the blanking conveying line 200 receives the aluminum form 700, the aluminum form welding line further includes a lower side pushing mechanism 600, and the lower side pushing mechanism 600 includes a linear motion mechanism and a plurality of second jacking devices 610, wherein the linear motion mechanism is dynamically connected to the second jacking devices 610 to drive the second jacking devices 610 to move in a second direction, and the second jacking devices 610 are positioned at the lower side of the blanking conveying line 200 to jack the aluminum form 700 on the blanking conveying line 200.

Further, as shown in fig. 13, the linear motion mechanism includes a rodless cylinder 620, a plurality of guide rods 630, and a connecting plate 640, the rodless cylinder 620 is dynamically connected to the connecting plate 640, the plurality of guide rods 630 are disposed on the lower side of the blanking conveying line 200, the connecting plate 640 is slidably connected to the plurality of guide rods 630, the second jacking device 610 includes a second jacking cylinder 611 and a jacking moving member 612, the second jacking cylinder 611 is disposed on the connecting plate 640, and the jacking moving member 612 is dynamically connected to the second jacking cylinder 611. When one side of the aluminum form 700 contacts the lifting moving member 612, the second lifting cylinder 611 drives the lifting moving member 612 to lift the aluminum form 700. The rodless cylinder 620 drives the second jacking cylinder 611 away from the turn table 420, thereby dragging the aluminum form 700 until the aluminum form 700 is entirely dragged into the blanking transfer line 200. The second jacking cylinder 611 drives the jacking moving member 612 to descend, and the aluminum die plate 700 is conveyed forward in contact with the second roller of the blanking conveying line 200.

In some embodiments, in order to enable the aluminum form 700 to slide smoothly from the turning table 420 to the blanking conveying line 200, the side of the blanking conveying line 200 close to the welding tool 400 is provided with the inclined guide plate 210, and in the inclined position, the turning table 420 is in butt joint with the inclined guide plate 210, so that the aluminum form 700 on the turning table 420 slides to the blanking conveying line 200 through the inclined guide plate 210. And when the aluminum mould plate 700 does not integrally slide to the blanking conveying line 200, a part of the aluminum mould plate 700 is also positioned on the inclined guide plate 210 so as to cooperate with the lower-layer side pushing mechanism 600 to integrally transfer the aluminum mould plate 700 to the blanking conveying line 200.

While the foregoing is directed to the preferred embodiments of the present utility model, it will be appreciated by those skilled in the art that changes and modifications may be made without departing from the principles of the utility model, such changes and modifications are also intended to be within the scope of the utility model.

Claims (10)

1. An aluminum die plate welding assembly line, characterized by comprising:

the feeding conveying line is configured to convey the aluminum templates along a first direction; the feeding conveying line is provided with a first side and a second side opposite to the first side in a second direction, and the second direction is perpendicular to the first direction;

a blanking conveying line overlapped below the feeding conveying line, wherein the blanking conveying line is configured to convey the aluminum templates along the first direction or the direction opposite to the first direction;

the welding tool is positioned at the second side and comprises a frame, a turnover table top positioning mechanism and a turnover driving device, the turnover table top is pivoted with the frame, and the turnover driving device is in power connection with the turnover table top so that the turnover table top has a horizontal position and an inclined position; in the horizontal position, the overturning table top is matched with the feeding conveying line to receive the aluminum template moved out of the second side; in the inclined position, the overturning table top is matched with the blanking conveying line so that the aluminum templates on the overturning table top slide onto the blanking conveying line; the positioning mechanism is configured to position the aluminum template on the turning table top; and

and the welding device is arranged on one side of the welding tool and used for welding the aluminum template on the overturning table top.

2. The aluminum die plate welding assembly line according to claim 1, wherein the positioning mechanism comprises a clamping device, a side pressure device, a limit baffle and a pressing device;

the flip top has a third side adjacent to the second side and a fourth side opposite the third side; the clamping device and the limit baffle are arranged on the fourth side, the side pressing device is arranged on the third side, and the pressing device is arranged on the frame and is positioned above the third side;

the side pressure device is configured to laterally press the aluminum template on the overturning table so as to enable the aluminum template to cling to the limit baffle;

the clamping device is configured to press down one side of the aluminum template on the flip top;

the hold down device is configured to hold down the other side of the aluminum form on the flip top.

3. The aluminum die plate welding line of claim 2, wherein the clamping means comprises a plurality of first lever cylinders arranged at intervals, the first lever cylinders having a first press block which presses down the aluminum die plate on the turn table;

and/or the side pressure device comprises a plurality of second lever cylinders which are arranged at intervals, wherein the second lever cylinders are provided with second pressing blocks; the second lever cylinder is arranged on the lower side of the overturning table top; the second pressing block is provided with a release position and a side pressure position; in the release position, the second press block is lower than the surface of the overturning table top; the second pressing block laterally presses the aluminum template on the overturning table top at the side pressing position;

and/or the pressing device comprises a plurality of lower pressing cylinders which are arranged at intervals, wherein the lower pressing cylinders are provided with third pressing blocks, the lower pressing cylinders and the third pressing blocks are positioned above the overturning table top, and the third pressing blocks press down the aluminum templates on the overturning table top.

4. The aluminum die plate welding assembly line according to claim 1, wherein the welding tool further comprises pin cylinders, wherein the pin cylinders are fixed on the frame, and at least one pin cylinder is arranged at each of two ends of the overturning table top; the two ends of the turnover table top are respectively provided with a clamping hole, the pin cylinder is provided with a pin shaft, and the pin shaft is opposite to the clamping holes in the horizontal position so that the pin shaft can be clamped into the clamping holes;

and/or, welding frock still includes to press from both sides the mechanism, it includes first pair clamp push pedal, first lead screw nut mechanism, second pair clamp push pedal and second lead screw nut mechanism to press from both sides the mechanism, first pair clamp push pedal with the second pair clamp push pedal sets up relatively and is located upset mesa upside, be equipped with linear guide way on the upset mesa, first pair clamp push pedal with the second pair clamp push pedal is connected to respectively through linear guide way is located upset mesa downside first lead screw nut mechanism with second lead screw nut mechanism.

5. The aluminum die plate welding line of claim 2, further comprising:

the at least one jacking side pushing mechanism comprises a first jacking device, a side pushing driving mechanism and a side pushing force application piece; the first jacking device is positioned at the lower side of the feeding conveying line and jacks the aluminum templates on the feeding conveying line so as to separate the aluminum templates from the feeding conveying line; the side pushing driving mechanism is connected with the side pushing force application member, and the side pushing force application member is configured to be driven by the side pushing driving mechanism to move along the second direction so as to push the aluminum mould plate on the first jacking device out of the second side.

6. The aluminum die plate welding line of claim 5, wherein the side-pushing drive mechanism comprises a primary side-pushing cylinder and a secondary side-pushing cylinder, the primary side-pushing cylinder being in dynamic connection with the secondary side-pushing cylinder to drive the secondary side-pushing cylinder to move in the second direction;

the side pushing force application piece is in power connection with the secondary side pushing cylinder.

7. The aluminum die plate welding assembly line of claim 5, wherein the first jacking device comprises a mounting bracket, a first jacking cylinder, a lifting bracket and a plurality of guide posts;

the mounting bracket is fixed on the feeding conveying line, the first jacking air cylinder is arranged on the mounting bracket, the lifting bracket is in power connection with the first jacking air cylinder, the lifting bracket is connected with the mounting bracket through the guide post, and the side pushing driving mechanism is arranged on the lifting bracket;

the feeding conveying line is a first roller conveying line and is provided with a plurality of first rollers, and the lifting support is provided with a hollowed-out avoidance portion for avoiding the first rollers.

8. The aluminum die plate welding line of claim 1, further comprising:

the lower side pushing mechanism comprises a linear motion mechanism and a plurality of second jacking devices, wherein the linear motion mechanism is in power connection with the second jacking devices so as to drive the second jacking devices to move along the second direction, and the second jacking devices are positioned on the lower side of the blanking conveying line so as to jack up the aluminum templates on the blanking conveying line.

9. The aluminum die plate welding assembly line of claim 8, wherein the linear movement mechanism comprises a rodless cylinder, a plurality of guide rods and a connecting plate, the rodless cylinder is in power connection with the connecting plate, the plurality of guide rods are arranged on the lower side of the blanking conveying line, the connecting plate is in sliding connection with the plurality of guide rods, the second jacking device comprises a second jacking cylinder and a jacking movement piece, the second jacking cylinder is arranged on the connecting plate, and the jacking movement piece is in power connection with the second jacking cylinder.

10. The aluminum die plate welding assembly line according to any one of claims 1 to 9, wherein an inclined guide plate is arranged on one side of the blanking conveying line, which is close to the welding tool, and in the inclined position, the overturning table top is in butt joint with the inclined guide plate so that the aluminum die plate on the overturning table top slides to the blanking conveying line through the inclined guide plate;

and/or the overturning driving device comprises an overturning air cylinder, wherein the overturning air cylinder is obliquely arranged, and a piston rod of the overturning air cylinder is connected with the overturning table top.