CN212191190U - Intelligent full-automatic cast welding equipment for bus bar of lead-acid storage battery - Google Patents

Abstract

The utility model relates to a full-automatic cast joint equipment of lead acid battery busbar intelligence, include: the transmission mechanism comprises a traction assembly and a reciprocating assembly, and the cast-weld mold slides on the reciprocating assembly and is driven by the traction assembly to synchronously reciprocate; the lead dipping mechanism is positioned at the input end of the conveying mechanism and comprises a lead furnace, a lifting assembly arranged on the lead furnace and a scraping assembly arranged on the lifting assembly; the cooling mechanism is arranged at the output end of the transmission mechanism and is positioned below the reciprocating assembly; the demoulding mechanism is arranged right above the cooling mechanism; the groove entering mechanism is arranged above the transmission mechanism and below the demolding mechanism; the welding-assistant mechanism comprises a driving cylinder, a welding-assistant liquid box and a conduction assembly; the utility model provides a need artifical transport battery, degree of automation is low, and cooling work and lead dipping work are in a space simultaneously, the serious technical problem of energy loss.

Description

Intelligent full-automatic cast welding equipment for bus bar of lead-acid storage battery

Technical Field

The utility model relates to a lead acid battery technical field especially relates to a full-automatic cast joint equipment of lead acid battery busbar intelligence.

Background

The production process of cast-weld is characterized by that after the battery electrode group is placed in a specially-made electrode group clamp, firstly the lugs of every electrode group are positioned and aligned, then the electrode group is tightly pressed, and the lead paste and oxide attached to the lugs are brushed off, and the lugs are dipped with cast-weld agent, and after the welding preparation works, the following several technological processes are implemented: 1) heating the cast-weld mould; 2) casting and welding a plurality of polar plate polar lug busbars and polar columns; 3) cooling the cast-welded mould and the busbar pole; 4) demolding between the busbar pole and the cast-weld mold; 5) inserting the demoulded pole group into a battery shell groove (called pole group groove for short); 6) and respectively returning the cast-weld mold and the pole group clamp to the cast-weld and pole group preparation stations to enter the next production period.

Patent document No. CN2015104077581 discloses a continuous cast-weld device of a bus bar and a pole of a lead-acid storage battery, which comprises a frame, wherein a cast-weld device, a cooling device of a cast-weld mold, a demoulding device of the cast-weld mold and a pole group clamp, a cast-weld mold heating device, a pole group groove feeding device and a clamp returning roller way are arranged on the frame; the outlet of the cast-weld device is connected with the inlet of the cooling device, and the outlet of the cooling device is connected with the inlet of the demoulding device; the invention can meet the requirements of cast-weld of tractors such as automobile starting, valve-controlled sealed and tubular positive plates and lead-acid storage batteries of various types.

However, in the actual use process, the inventor finds that the storage battery needs to be manually transported, the automation degree is low, and the cooling work and the lead dipping work are in one space, so that the energy loss is serious.

SUMMERY OF THE UTILITY MODEL

The utility model aims at prior art's weak point, through setting up demoulding mechanism, it can be directly integrative with the production line linking to realize the battery, and then replace artifical transport storage battery to accomplish and end automatic facial make-up and ejection of compact work, degree of automation is high, in addition, demoulding mechanism sets up outside lead soaking mechanism, make cooling operation can not influence the scattering and disappearing of heat in the lead furnace of high temperature, thereby solved and needed artifical transport battery, degree of automation is low, cooling operation and lead soaking work are in a space simultaneously, the serious technical problem of energy loss.

Aiming at the technical problems, the technical scheme is as follows: the utility model provides a full-automatic cast joint equipment of lead acid battery busbar intelligence, includes:

the transmission mechanism comprises a traction assembly arranged on the rack and a reciprocating assembly matched with the traction assembly, and the cast-weld mold slides on the reciprocating assembly and is driven by the traction assembly to synchronously reciprocate;

the lead dipping mechanism is positioned at the input end of the conveying mechanism and comprises a lead furnace, a lifting assembly arranged on the lead furnace and a scraping assembly arranged on the lifting assembly;

the cooling mechanism is arranged at the output end of the conveying mechanism and is positioned below the reciprocating assembly;

the demolding mechanism is arranged right above the cooling mechanism;

the groove feeding mechanism is positioned above the transmission mechanism and below the demolding mechanism; and

the welding flux soaking and assisting mechanism comprises a driving cylinder arranged on the rack, a welding flux assisting box arranged at the output end of the driving cylinder and a conducting assembly arranged on the rack and positioned above the welding flux assisting box.

Preferably, the pulling assembly comprises:

a first guide rail mounted on the frame;

the connecting rod is arranged on the first guide rail in a sliding mode through a sliding seat; and

grab the ear, grab the ear install on the connecting rod and its location end sets up vertically downwards.

Preferably, the reciprocating assembly comprises:

a second guide rail mounted on the frame; and

and the cast-weld mold is arranged on the second guide rail in a sliding manner and is positioned below the connecting rod, and a buckle block matched with the grabbing lug is arranged on the cast-weld mold.

Preferably, the lifting assembly comprises a first lifting assembly arranged at the upper end of the lead furnace and a second lifting assembly arranged on the first lifting assembly.

Preferably, the first lifting assembly comprises a first pushing cylinder with a telescopic end vertically arranged downwards and a telescopic rod fixedly arranged in the lead furnace, and the telescopic rod is provided with a plurality of groups and arranged around the outer side of the first pushing cylinder.

Preferably, the second lifting assembly includes:

the second pushing cylinder is fixedly connected with the output end of the first pushing cylinder;

the supporting plate is connected with the second pushing cylinder, and the upper surface of the supporting plate is connected with the lower end of the telescopic rod;

the connecting rods are arranged below the supporting plate and are provided with a plurality of groups, two groups of clamping plates and limiting plates connected with the two groups of clamping plates are connected and arranged below the connecting rods, one surfaces of the limiting plates, which are arranged in rows, are arranged in a zigzag structure, one surfaces, which are arranged inwards, of the clamping plates are provided with concave grooves, and the cast-weld mold slides in the concave grooves in a matched manner; and

and the pressing plate is fixedly connected with the telescopic end of the second horizontal pushing cylinder, and the lower surface of the pressing plate is provided with a notch groove matched with the upper end of the clamping plate.

Preferably, the scraping assembly comprises:

the third horizontal pushing cylinder is arranged on the supporting plate, and the telescopic end of the third horizontal pushing cylinder is vertically arranged downwards; and

the scraper blade, the scraper blade with the flexible end fixed connection of third translation cylinder and its lower surface are horizontal structure.

Preferably, the cooling mechanism includes:

the fourth horizontal pushing cylinder is arranged on the rack, and the telescopic end of the fourth horizontal pushing cylinder is vertically arranged upwards; and

and the water tank is fixedly connected with the telescopic end of the fourth horizontal pushing cylinder.

Preferably, the mold-releasing mechanism includes:

the fifth horizontal pushing cylinder is arranged on the rack, and the telescopic end of the fifth horizontal pushing cylinder is vertically arranged downwards; and

the support frame, the support frame with the flexible end fixed connection of fifth horizontal push cylinder, storage battery settles on the support frame.

Preferably, the groove entering mechanism comprises:

the two groups of card seats are arranged on the frame respectively; and

the fixing seat is arranged on the clamping seat in a sliding mode and provided with a jacking block matched with the storage battery pack, and the sixth horizontal pushing cylinder drives the fixing seat to slide through the connecting seat.

Preferably, the conduction assembly comprises a mounting frame, a third guide rail mounted on the mounting frame, a bearing plate matched and sliding in the third guide rail, and a linear motor mounted on the mounting frame and located on one side of the third guide rail, wherein the linear motor drives the bearing plate to reciprocate through a transfer rod; the bearing plate is matched and arranged on the support frame in a sliding manner and is used for mounting a storage battery pack;

the fastening piece includes with drive the perpendicular horizontal cylinder that sets up of the flexible direction of actuating cylinder, with the flexible end fixed connection's of horizontal cylinder stock and setting are in two sets of card posts on the stock, the card post matches the setting with the card hole of accepting on the board.

The utility model has the advantages that:

(1) the utility model realizes that the storage battery can be directly connected with the production line into a whole by arranging the demoulding mechanism, thereby replacing the manual handling of the storage battery to finish the automatic loading and discharging work, and the automation degree is high; in addition, the demoulding mechanism is arranged outside the lead dipping mechanism, so that the heat loss in the high-temperature lead furnace can not be influenced during cooling work, and the energy utilization rate is high;

(2) in the utility model, the traction component is matched with the reciprocating component to complete the output and input work of the cast-weld mould, and meanwhile, the grabbing lugs and the hasp blocks are fixed in an overlapping manner, so that the stable transmission of the cast-weld mould is realized, and the traction effect is firm;

(3) the utility model discloses in order to make the lower extreme of utmost point ear fully expose outside and the busbar fully contact, polar plate in the battery case is in non-contact state along the inner wall of vertical direction with the casing, through setting up and going into groove mechanism, will attach to the busbar on utmost point ear and together push into the casing together with the polar plate.

In conclusion, the device has the advantages of simple structure and full automation, and is particularly suitable for the technical field of lead-acid storage batteries.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings described below are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an intelligent full-automatic cast-weld device for a bus bar of a lead-acid storage battery.

Fig. 2 is a schematic structural diagram of the lead dipping mechanism.

Fig. 3 is a first schematic structural diagram of the lifting assembly.

Fig. 4 is a schematic structural diagram of a second lifting assembly.

Fig. 5 is a third schematic structural view of the lifting assembly.

Fig. 6 is a schematic structural view of the transfer mechanism.

Fig. 7 is a schematic top view of the transfer mechanism.

Fig. 8 is a schematic structural view of the mold-releasing mechanism.

Fig. 9 is a schematic structural diagram of the groove entering mechanism.

Fig. 10 is a schematic top view of the in-slot mechanism.

Fig. 11 is a schematic front view of the cooling mechanism.

Fig. 12 is a schematic structural diagram of the lead dipping mechanism.

Fig. 13 is a schematic cross-sectional view of the lead dipping mechanism.

Fig. 14 is an enlarged partial schematic view at a of fig. 13.

Detailed Description

The technical solution in the embodiment of the present invention is clearly and completely described below with reference to the accompanying drawings.

Example one

As shown in FIG. 1, an intelligent full-automatic cast-weld device for a bus bar of a lead-acid storage battery comprises:

the conveying mechanism 1 comprises a traction assembly 12 installed on a frame 11 and a reciprocating assembly 13 matched with the traction assembly 12;

the lead dipping mechanism 2 is positioned at the input end of the conveying mechanism 1, and comprises a lead furnace 21, a lifting assembly 22 arranged on the lead furnace 21 and a scraping assembly 23 arranged on the lifting assembly 22;

the cooling mechanism 3 is installed at the output end of the conveying mechanism 1 and is positioned below the reciprocating assembly 13;

the demolding mechanism 4 is arranged right above the cooling mechanism 3; and

the groove feeding mechanism 5 is positioned above the transmission mechanism 1 and below the demolding mechanism 4;

the welding flux soaking and assisting mechanism 6 comprises a driving cylinder 61 mounted on the frame 11, a welding flux box 62 arranged at the output end of the driving cylinder 61, and a conducting assembly 63 mounted on the frame 11 and located above the welding flux box 62.

In the embodiment, the storage battery can be directly connected with a production line into a whole by arranging the demoulding mechanism 4, so that the storage battery can be carried by a worker to finish automatic loading and discharging, and the automation degree is high; in addition, the demoulding mechanism 4 is arranged outside the lead soaking mechanism 2, so that the heat loss in the high-temperature lead furnace 21 cannot be influenced during cooling operation, and the energy utilization rate is high.

It should be noted that, the driving cylinder 61 is arranged to drive the soldering flux assisting box 62 to ascend and descend, so as to complete the operation of applying the soldering flux to the tabs of the battery pack 43 on the receiving plate 633, and at the same time, the battery pack 43 on which the operation of applying the soldering flux is completed is automatically conveyed to the supporting frame 42 to wait for the demolding operation.

Further, as shown in fig. 6 and 7, the traction assembly 12 includes:

a first guide rail 121, the first guide rail 121 being mounted on the frame 11;

a connecting rod 122, wherein the connecting rod 122 is slidably arranged on the first guide rail 121 through a sliding seat 123; and

a grasping ear 124, wherein the grasping ear 124 is installed on the connecting rod 122 and the positioning end of the grasping ear is vertically arranged downwards.

In this embodiment, through setting up drawing subassembly 12 and the reciprocal subassembly 13 of cooperation, accomplish cast joint mould's output and input work, it is fixed with hasp piece 134 overlap joint through grabbing ear 124 simultaneously, and then realizes the stable transmission of cast joint mould, and it is firm to draw the effect.

Further, as shown in fig. 6 and 7, the reciprocating assembly 13 includes:

a second guide rail 131, the second guide rail 131 being mounted on the frame 11; and

and a cast-weld mold 132, wherein the cast-weld mold 132 is slidably disposed on the second guide rail 131 and located below the connecting rod 122, and a buckle block 134 disposed on the cast-weld mold 132 and matched with the catch 124 is provided.

Further, as shown in fig. 2, 3, 4 and 5, the lifting assembly 22 includes a first lifting assembly 22a disposed at an upper end of the lead furnace 21, and a second lifting assembly 22b disposed on the first lifting assembly 22 a.

In this embodiment, through setting up second lifting unit 22b, will descend and suppress to the cast joint mould top in the lead furnace, avoid the upper surface of cast joint mould and the interior upper surface of lead furnace floating slag charge contact for there is not slag charge on the cast joint mould surface, improves the lead dipping effect.

In addition, the first lifting assembly 22a is arranged to drive the second lifting assembly 22b to lift, so that the descending lead dipping work of the cast welding mould and the reset discharging work after lead dipping are achieved.

Further, as shown in fig. 3, the first lifting assembly 22a includes a first pushing cylinder 221 with a telescopic end vertically arranged downward and a telescopic rod 222 fixedly arranged in the lead furnace 21, and the telescopic rod 222 is provided with a plurality of groups and arranged around the outer side of the first pushing cylinder 221.

Further, as shown in fig. 4, the second lifting assembly 22b includes:

the second pushing cylinder 223 is fixedly connected with the output end of the first pushing cylinder 221;

a supporting plate 224, wherein the supporting plate 224 is connected to the second pushing cylinder 223, and the upper surface of the supporting plate is connected to the lower end of the telescopic rod 222;

the connecting rods 225 are arranged below the supporting plate 224 and are provided with a plurality of groups, two groups of clamping plates 226 and limiting plates 227 connected with the two groups of clamping plates 226 are connected and arranged below the connecting rods 225, one side of each limiting plate 227 facing to the row is provided with a zigzag structure, one side of each clamping plate 226 facing to the inside is provided with a concave groove 228, and the cast-weld mold 132 slides in the concave groove 228 in a matching manner; and

and the pressing plate 229 is fixedly connected with the telescopic end of the second pushing cylinder 223, and the lower surface of the pressing plate 229 is provided with a notch groove 220 matched with the upper end of the clamping plate 226.

In this embodiment, the inward surface of the limiting plate 227 is a zigzag structure, so that the surface of the cast-weld mold facing the limiting plate 227 can also complete the lead dipping work; on the other hand, the limiting plate 227 has a limiting effect on the cast-weld mold during conveying; in addition, the positioning work of the cast-weld mold is performed by providing the concave groove 228 on the inward surface of the engaging plate 226.

Further, as shown in fig. 5, the scraper assembly 23 includes:

a third push cylinder 231, wherein the third push cylinder 231 is mounted on the support plate 224 and the telescopic end thereof is vertically arranged downwards; and

and the scraping plate 232 is fixedly connected with the telescopic end of the third pushing cylinder 231, and the lower surface of the scraping plate 232 is of a horizontal structure.

In this embodiment, scrape material subassembly 23 through the setting for the cast joint mould that accomplishes the lead dipping work is when exporting, and the hanging material work of cast joint mould upper surface is accomplished to the tip of cooperation scraper blade 232, guarantees the roughness of cast joint mould upper surface, improves the effect of the final quality of product.

Further, as shown in fig. 11, the cooling mechanism 3 includes:

the fourth horizontal pushing cylinder 31 is installed on the rack 11, and the telescopic end of the fourth horizontal pushing cylinder 31 is vertically arranged upwards; and

and the water tank 32 is fixedly connected with the telescopic end of the fourth horizontal pushing cylinder 31.

In this embodiment, the cooling mechanism 3 performs the cooling operation of the cast-on-mold, and the lead on the cast-on-mold is cooled to form the bus bar.

Further, as shown in fig. 8, the ejector mechanism 4 includes:

the fifth horizontal pushing cylinder 41 is arranged on the rack 11, and the telescopic end of the fifth horizontal pushing cylinder 41 is vertically arranged downwards; and

and the support frame 42 is fixedly connected with the telescopic end of the fifth horizontal pushing cylinder 41, and the storage battery pack 43 is arranged on the support frame 42.

It should be noted that the fifth horizontal pushing cylinder 41 is lifted for the first time to combine the tab in the battery pack 43 with the bus bar, and lifted for the second time to insert the plate into the inner wall of the casing in cooperation with the slot entering mechanism 5.

Further, as shown in fig. 12 and 13, the conducting assembly 63 includes a mounting frame 631, a third guiding rail 632 mounted on the mounting frame 631, a receiving plate 633 matched and sliding in the third guiding rail 632, a linear motor 634 mounted on the mounting frame 633 and located at one side of the third guiding rail 632, and a fastening member 635 mounted on the mounting frame 631, wherein the linear motor 634 drives the receiving plate 633 to reciprocate through a transmission rod;

the bearing plate 633 is matched and slidably arranged on the support frame 42 for mounting the storage battery pack 43;

the fastening member 635 comprises a transverse cylinder 636 perpendicular to the expansion direction of the driving cylinder 61, an elongated rod 637 fixedly connected with the expansion end of the transverse cylinder 636, and two sets of clamping columns 638 arranged on the elongated rod 637, wherein the clamping columns 638 are matched with clamping holes 639 on the bearing plate 633.

In this embodiment, by providing the fastening member 635, when the battery pack 43 on the receiving plate 633 is used for tab lead dipping, the transverse cylinder 636 drives the long rod 637 to extend and clamp into the clamping hole 639, so as to position the receiving plate 633, thereby facilitating the stable and comprehensive operation of the upper fluxing medium.

Example two

As shown in fig. 9, in which the same or corresponding components as those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, only the points of difference from the first embodiment will be described below for the sake of convenience. The second embodiment is different from the first embodiment in that:

further, as shown in fig. 9, the groove entering mechanism 5 includes:

two sets of card holders 51 are arranged on the card holder 51 and are respectively installed on the rack 11; and

the fixing seat 52 is slidably disposed on the card seat 51, a jacking block 53 matched with the battery pack 43 is disposed on the fixing seat 52, and the sixth horizontal pushing cylinder 54 drives the fixing seat 52 to slide through a connecting seat 55.

In order to fully expose the lower ends of the tabs to the outside and fully contact the bus bars, the electrode plates in the battery case are in a non-contact state with the inner wall of the case along the vertical direction.

In the present embodiment, the bus bar attached to the tab is pushed into the case together with the pole plate by providing the slot-entering mechanism 5.

The working process is as follows:

firstly, the cast-weld mould is pushed by the gripping lug 124 to be sent into the concave groove 228, then the first pushing cylinder 221 is started to push downwards to send the cast-weld mould into the lead furnace 21, meanwhile, the second pushing cylinder 223 is started to drive the pressing plate 229, and the pressing plate 229 is pushed to the upper surface of the cast-weld mould; the cast-weld mould after the lead dipping work is completed is lifted along with the reset of the first horizontal pushing cylinder 221, meanwhile, the second horizontal pushing cylinder 223 is reset, then the third horizontal pushing cylinder 231 is started, the scraper 232 moves downwards to the position above the cast-weld mould, the cast-weld mould is output, and the scraper 232 completes the scraping work of the upper surface of the cast-weld mould;

the cast-weld mold is conveyed to the upper part of the cooling mechanism under the reset drive of the grabbing lug 124, the fifth horizontal pushing cylinder 41 is started, the lower surface of the storage battery pack 43 is contacted with the cast-weld mold, then the fourth horizontal pushing cylinder 31 is started, the water tank 32 is lifted upwards, the cast-weld mold finishes the cooling work, the bus bar and the grabbing lug are integrated, and the fifth horizontal pushing cylinder 41 is reset to finish the demolding;

and finally, starting the sixth horizontal pushing cylinder 54, moving the fixed seat 52 to be right below the storage battery pack 43, starting the fifth horizontal pushing cylinder 41 again, mutually extruding the lower surface of the storage battery pack 43 and the jacking block 53, and pushing the polar plate to the inner wall of the storage battery shell.

In the description of the present invention, it is to be understood that the terms "front and back", "left and right", and the like indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplification of description, and do not indicate or imply that the equipment or parts referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

Of course, in this disclosure, those skilled in the art will understand that the terms "a" and "an" should be interpreted as "at least one" or "one or more," i.e., in one embodiment, a number of an element may be one, and in another embodiment, a number of the element may be plural, and the terms "a" and "an" should not be interpreted as limiting the number.

The above description is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art in the technical suggestion of the present invention should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides a full-automatic cast joint equipment of lead acid battery busbar intelligence which characterized in that includes:

the conveying mechanism (1) comprises a traction assembly (12) arranged on a rack (11) and a reciprocating assembly (13) matched with the traction assembly (12);

the lead dipping mechanism (2), the lead dipping mechanism (2) is positioned at the input end of the conveying mechanism (1) and comprises a lead furnace (21), a lifting assembly (22) arranged on the lead furnace (21) and a scraping assembly (23) arranged on the lifting assembly (22);

the cooling mechanism (3), the cooling mechanism (3) is installed at the output end of the transmission mechanism (1) and is positioned below the reciprocating assembly (13);

the demolding mechanism (4) is arranged right above the cooling mechanism (3);

the groove feeding mechanism (5) is positioned above the transmission mechanism (1) and below the demolding mechanism (4); and

the welding flux soaking and assisting mechanism (6) comprises a driving cylinder (61) arranged on the rack (11), a welding flux assisting box (62) arranged at the output end of the driving cylinder (61), and a conducting assembly (63) arranged on the rack (11) and positioned above the welding flux assisting box (62).

2. The intelligent, fully-automatic cast-on-weld equipment for lead-acid battery busbars according to claim 1, characterised in that the drawing assembly (12) comprises:

a first guide rail (121), the first guide rail (121) being mounted on the frame (11);

the connecting rod (122) is arranged on the first guide rail (121) in a sliding mode through a sliding seat (123); and

the grabbing lug (124) is installed on the connecting rod (122) and the positioning end of the grabbing lug (124) is vertically arranged downwards.

3. The intelligent full-automatic cast-on-weld equipment for lead-acid battery busbars according to claim 2, characterised in that the reciprocating assembly (13) comprises:

a second guide rail (131), the second guide rail (131) being mounted on the frame (11); and

and the cast-weld mold (132), the cast-weld mold (132) is arranged on the second guide rail (131) in a sliding manner and is positioned below the connecting rod (122), and a buckle block (134) matched with the grabbing lug (124) is arranged on the cast-weld mold (132).

4. The intelligent full-automatic cast-welding equipment for the lead-acid storage battery bus bars according to claim 1, characterized in that the lifting assembly (22) comprises a first lifting assembly (22a) arranged at the upper end of the lead furnace (21) and a second lifting assembly (22b) arranged on the first lifting assembly (22 a).

5. The intelligent full-automatic cast-welding equipment for the lead-acid storage battery bus bars according to claim 4 is characterized in that the first lifting assembly (22a) comprises a first pushing cylinder (221) with a telescopic end arranged vertically downwards and a telescopic rod (222) fixedly arranged in the lead furnace (21), wherein the telescopic rod (222) is provided with a plurality of groups and is arranged around the outer side of the first pushing cylinder (221);

the second lifting assembly (22b) comprises:

the second pushing cylinder (223), the second pushing cylinder (223) is fixedly connected with the output end of the first pushing cylinder (221);

the supporting plate (224) is connected with the second pushing cylinder (223), and the upper surface of the supporting plate (224) is connected with the lower end of the telescopic rod (222);

the connecting rods (225), the connecting rods (225) are arranged below the supporting plate (224) and are provided with a plurality of groups, two groups of clamping plates (226) and limiting plates (227) connected with the two groups of clamping plates (226) are connected and arranged below the connecting rods (225), one side of each limiting plate (227) arranged in a row is arranged in a zigzag structure, one side of each clamping plate (226) arranged inwards is provided with a concave groove (228), and the cast welding mold (132) slides in the concave grooves (228) in a matching mode; and

and the pressing plate (229) is fixedly connected with the telescopic end of the second pushing cylinder (223), and the lower surface of the pressing plate (229) is provided with a notch groove (220) matched with the upper end of the clamping plate (226).

6. The intelligent full-automatic cast-on-site welding equipment for lead-acid storage battery busbars according to claim 5, characterized in that the scraping component (23) comprises:

a third pushing cylinder (231), wherein the third pushing cylinder (231) is arranged on the supporting plate (224) and the telescopic end of the third pushing cylinder is vertically arranged downwards; and

and the scraping plate (232) is fixedly connected with the telescopic end of the third pushing cylinder (231), and the lower surface of the scraping plate (232) is of a horizontal structure.

7. The intelligent full-automatic cast-on-weld equipment for lead-acid battery busbars according to claim 1, characterised in that the cooling mechanism (3) comprises:

the fourth horizontal pushing cylinder (31), the fourth horizontal pushing cylinder (31) is installed on the rack (11), and the telescopic end of the fourth horizontal pushing cylinder is vertically arranged upwards; and

and the water tank (32) is fixedly connected with the telescopic end of the fourth horizontal pushing cylinder (31).

8. The intelligent full-automatic cast-weld equipment for the bus bars of lead-acid storage batteries according to claim 1, characterized in that the demolding mechanism (4) comprises:

the fifth horizontal pushing cylinder (41), the fifth horizontal pushing cylinder (41) is arranged on the rack (11) and the telescopic end of the fifth horizontal pushing cylinder is vertically arranged downwards; and

the support frame (42), the support frame (42) with the flexible end fixed connection of fifth horizontal push cylinder (41), storage battery (43) are settled on the support frame (42).

9. The intelligent full-automatic cast-weld equipment for the bus bars of the lead-acid storage batteries according to claim 1, characterized in that the in-groove mechanism (5) comprises:

two groups of clamping seats (51) are arranged on the clamping seats (51) and are respectively installed on the rack (11); and

the fixing seat (52) is arranged on the clamping seat (51) in a sliding mode, a jacking block (53) matched with the storage battery pack (43) is arranged on the fixing seat (52), and the sixth horizontal pushing cylinder (54) drives the fixing seat (52) to slide through a connecting seat (55).

10. The intelligent full-automatic cast-welding equipment for the lead-acid storage battery bus bar is characterized in that the conducting assembly (63) comprises a mounting frame (631), a third guide rail (632) installed on the mounting frame (631), a receiving plate (633) matched and sliding in the third guide rail (632), a linear motor (634) installed on the mounting frame (631) and located on one side of the third guide rail (632), and a fastener (635) installed on the mounting frame (631), wherein the linear motor (634) drives the receiving plate (633) to reciprocate through a transmission rod; the bearing plate (633) is arranged on the support frame (42) in a matching sliding mode and used for mounting a storage battery pack (43);

the fastening piece (635) comprises a transverse cylinder (636) vertically arranged in the telescopic direction of a driving cylinder (61), a long rod (637) fixedly connected with the telescopic end of the transverse cylinder (636) and two groups of clamping columns (638) arranged on the long rod (637), wherein the clamping columns (638) are matched with clamping holes (639) in a bearing plate (633) and a third guide rail (632).

Images