CN216680160U - Lead acid battery processing is with cast joint mould inner loop assembly - Google Patents

Abstract

The utility model relates to the technical field of lead-acid battery processing, in particular to a cast-weld mold internal circulation assembly for lead-acid battery processing, which comprises at least two groups of cast-weld molds, wherein one group of cast-weld molds are output from a lead boiling container for cooling cast-weld processing, the other group of cast-weld molds are input into the lead boiling container for heating and warming, and the cast-weld molds in the lead boiling container are heated and output after lead is taken through a circulation path arranged in a closed loop manner, and the other group of cast-weld molds participating in cast-weld cooling processing work are input into the lead boiling container for heating and warming, so that the heating and cooling time of the two groups of cast-weld molds are mutually superposed, the original processing time of a single group of lead-acid battery is shortened, and the processing efficiency is improved.

Description

Lead acid battery processing is with cast joint mould inner loop assembly

Technical Field

The utility model relates to the technical field of lead-acid battery processing, in particular to a cast-weld die internal circulation assembly for lead-acid battery processing.

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 die and the pole group clamp to the cast-weld and pole group preparation stations to enter the next production cycle.

The patent document with the patent application number of CN202010116407.6 discloses an intelligent full-automatic cast-weld production line and a process thereof for lead-acid batteries, wherein the production line transfers, conveys and brushes lead-acid batteries by utilizing the mutual matching of a cutting and brushing device, a second material grabbing mechanical arm, a conveying line and a transfer mechanical arm, and realizes the automatic feeding and discharging work of a plurality of groups of cast-weld machines alternately. .

However, the fully automatic cast-weld equipment disclosed by the technical scheme has the following problems in the cast-weld processing process of the lead-acid battery: during the cast-weld working process of the cast-weld mould in the cast-weld machine, the lead boiling container of the cast-weld machine idles, the lead boiling container still carries out the heating work of lead liquid, and after the cast-weld mould after the cast-weld work is finished enters the lead boiling container again, the temperature needs to be heated again, the cast-weld working time and the heating temperature rise time are added, so that the cast-weld working efficiency of the lead-acid battery is greatly reduced.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides an internal circulation assembly of a cast-weld mold for processing a lead-acid battery, which is characterized in that through a circulation path arranged in a closed loop, the cast-weld mold in a lead boiling container is heated, lead is taken out and output, and meanwhile, the other group of cast-weld molds participating in the cast-weld cooling processing work are input into the lead boiling container for heating and warming, so that the heating and cooling time of the two groups of cast-weld molds are mutually overlapped, the original processing time of a single group of lead-acid battery is shortened, and the processing efficiency is improved.

In order to achieve the purpose, the utility model provides the following technical scheme:

a cast-weld mould internal circulation assembly for processing lead-acid batteries comprises:

at least two sets of cast-weld molds;

and when one group of cast-weld molds are output from the lead boiling container to be cooled for cast-weld machining, the other group of cast-weld molds are input into the lead boiling container to be heated and heated.

A cast-weld mould internal circulation assembly for processing lead-acid batteries comprises:

the circulating path is used for continuously and circularly inputting and outputting the cast-weld mould to the lead boiling container and is arranged in a closed loop mode, and the circulating path is integrated on a cast-weld system of the lead-acid battery.

A cast-weld mould internal circulation assembly for processing lead-acid batteries comprises:

a closed loop circulation path consisting of a transfer path, a connection path, a rotation path and a connection path which are mutually connected end to end;

and the circulating path is used for outputting the cast-weld mould containing the lead liquid in the lead boiling container, and simultaneously inputting the other set of cast-weld mould subjected to cast-weld cooling into the lead boiling container for heating and temperature rise.

As an improvement, the transfer path is arranged at the top of the lead boiling container and is used for transferring the cast-weld mold which is heated and taken out of the lead boiling container and is output by the connecting path to a cast-weld cooling station;

the connecting path is arranged on the transfer path, is connected with the transfer path and the rotary path, and transfers the cast-weld mold output from the cast-weld cooling station to the rotary path;

the rotary path is connected with the connecting path, the cast welding mold is transferred to the upper part of the lead boiling container through the rotary path, and the lead is input back into the lead boiling container through the connecting path.

As a refinement, the transfer path is arranged in parallel with the turnaround path;

the connecting path and the connecting path are arranged in parallel.

As an improvement, a track is laid on the transfer path, and a moving rod for shifting the cast-weld mold to slide along the track is arranged beside the track.

As an improvement, the movable rod is arranged in a semi-square frame shape, and when the movable rod pushes the cast-weld mold, the movable rod semi-surrounds the cast-weld mold.

As an improvement, a movable rail arranged in a lifting manner is arranged on the connecting path, and when the movable rail descends in place, the movable rail is horizontally arranged at the fracture of the rail, and when the movable rail ascends in place, the movable rail is horizontally arranged on the rotating path.

As an improvement, a fixed rail is laid on the rotary path, and a deflector rod for pushing the cast-weld mold to slide along the fixed rail is arranged beside the fixed rail.

As an improvement, a heating bottom plate which is arranged in a lifting mode is arranged on the connecting path, bears the cast-weld mold, enters the lead boiling container to be heated, and after lead is taken out, the cast-weld mold is lifted and transferred to the transfer path.

As an improvement, the two side edges of the cast-weld mould are provided with clamping grooves used for clamping with the track, the movable track, the fixed track and the heating bottom plate.

The utility model has the beneficial effects that:

(1) according to the circulating path arranged in the closed loop, when the cast-weld molds in the lead boiling container are heated and output after lead is taken out, the other group of cast-weld molds participating in the cast-weld cooling processing work are input into the lead boiling container for heating and warming, so that the heating and cooling time of the two groups of cast-weld molds are mutually overlapped, the original processing time of a single group of lead-acid batteries is shortened, and the processing efficiency is improved;

(2) according to the utility model, the slide rail is disconnected, the movable slide rail is arranged at the disconnected part of the slide rail, the slide rail is fixed by lifting the slide rail, and another rotary path for driving the cast-weld mold to be used in a rotary manner is formed above the slide rail, so that the cast-weld mold can be used alternately, and the working efficiency is improved;

(3) the heating bottom plate is lifted in a staged manner, so that the lifting assembly drives the cast-weld mould to take lead and can be lifted to the highest position to bring the alternately recycled cast-weld mould back into the lead boiling container for recycling and heating;

(4) the movable rod is arranged in a semi-square frame shape, and the cast-weld mold can be transferred from the lead boiling container to the cast-weld cooling station and can also run reversely to drive the cast-weld mold to return to the movable rail from the cast-weld cooling station for circulating.

In conclusion, the automatic lead-acid battery processing device has the advantages of high automation degree, high working efficiency, compact structure and the like, and is particularly suitable for the technical field of lead-acid battery processing.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a first schematic cross-sectional view of the present invention;

FIG. 3 is a schematic perspective view of the track of the present invention;

FIG. 4 is a schematic cross-sectional view of the present invention;

FIG. 5 is a perspective view of the driving lever of the present invention;

FIG. 6 is a perspective view of the movable rod of the present invention;

fig. 7 is a schematic perspective view of the cast-weld mold according to the present invention.

Detailed Description

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

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Example 1:

as shown in fig. 1, an internal circulation assembly of a cast-weld mold for lead-acid battery processing includes:

a circulating path 3 arranged in a closed loop for continuously and circularly inputting and outputting the cast-welding mould 2 to and from the lead boiling container 1, wherein the circulating path 3 is integrated on a cast-welding system of the lead-acid battery.

It should be noted that, a set of cast-weld molds 2 heated and filled with lead liquid is transferred to the cast-weld cooling station through the circulation path 3, and meanwhile, another set of cast-weld molds 2 which have finished cast-weld cooling are transferred and input into the lead boiling container 1 through the circulation path 3 to be heated and warmed up, so that the time for cooling cast-weld and the time for heating and warming up the cast-weld molds are mutually superposed in the cast-weld process of a single lead-acid battery, and the technical problems of long processing time and low efficiency caused by production of one set of cast-weld molds are greatly reduced.

Further, according to the present invention, the circulation path 3 is provided, so that the output cast-weld mold 2 and the input cast-weld mold 2 in the lead boiling container 1 can be perfectly alternated without interference, and the circulation path 3 is integrally provided on the cast-weld equipment, so that the path is short and the time required for transferring the cast-weld mold 2 is short.

Example 2:

FIG. 2 is a schematic structural diagram of an embodiment 2 of a full-automatic internal circulation flow machining cast-weld system according to the present invention; as shown in fig. 2, in which the same or corresponding components as those in embodiment 1 are denoted by the same reference numerals as those in embodiment one, only the points of difference from embodiment 1 will be described below for the sake of convenience. This embodiment 2 differs from the embodiment 1 shown in fig. 1 in that:

as shown in fig. 2, an internal circulation assembly of a cast-weld mold for lead-acid battery processing includes:

a closed loop circulation path 3 composed of a transfer path 10, a connection path 20, a rotation path 30 and a connection path 40 which are connected end to end;

the circulation path 3 is used for outputting the cast-weld mold 2 containing the lead liquid in the lead boiling container 1, and simultaneously inputting the other set of cast-weld mold 2 which is cooled by cast welding into the lead boiling container 1 for heating and temperature rise.

Wherein the transfer path 10 is arranged at the top of the lead boiling container 1, and the transfer path 10 is used for transferring and conveying the cast-weld mold 2 which is heated by the lead boiling container 1 and takes lead and is output by the connecting path 40 to a cast-weld cooling station;

the connecting path 20 is provided on the transfer path 10, the connecting path 20 connects the transfer path 10 and the turning path 30, and the cast-weld mold 2 output from the cast-weld cooling station is transferred onto the turning path 30;

the turning path 30 is connected to the joining path 40, and the turning path 30 transfers the cast welding mold 2 to the upper part of the lead boiling container 1 and inputs the lead boiling mold into the lead boiling container 1 through the joining path 40.

Further, the transfer path 10 is disposed in parallel with the revolving path 30;

the connecting path 20 is arranged in parallel with the joining path 40.

It should be noted that, by arranging the transfer path 10 and the turning path 30 in parallel, and arranging the connection path 20 and the connection path 40 in parallel, the connection path 20 and the connection path 40 are respectively used for connecting the transfer path 10 and the turning path 30, so that the cast welding mold 2 can circularly circulate along the shortest path along the circulation path 3, and the time of the circular circulation is greatly shortened.

Example 3:

FIG. 3 is a schematic structural diagram of a full-automatic internal circulation flow machining cast-weld system according to embodiment 3 of the present invention; as shown in fig. 3, in which the same or corresponding components as those in embodiment 1 are denoted by the same reference numerals as in embodiment one, only the points of difference from embodiment 1 will be described below for the sake of convenience. This embodiment 3 differs from embodiment 1 shown in fig. 1 in that:

as shown in fig. 3 to 7, a rail 4 is laid on the transfer path 10, and a moving rod 41 for moving the cast-weld mold 2 to slide along the rail 4 is disposed beside the rail 4.

Further, the moving rod 41 is provided in a half-square frame shape, and when the moving rod 41 pushes the cast-weld mold 2, the moving rod 41 is provided to half surround the cast-weld mold 2.

Furthermore, a movable rail 5 which is arranged in a lifting manner is arranged on the connecting path 20, when the movable rail 5 descends to a proper position, the movable rail is horizontally arranged at the fracture 42 of the rail 4, and when the movable rail 5 ascends to a proper position, the movable rail is horizontally arranged on the revolving path 30.

Preferably, a fixed rail 6 is fixedly disposed on the revolving path 30, and a shift lever 61 for pushing the cast-weld mold 2 to slide along the fixed rail 6 is disposed beside the fixed rail 6.

More preferably, a heating bottom plate 7 arranged in a lifting manner is arranged on the connecting path 40, and after the cast-weld mold 2 is loaded on the heating bottom plate 7 and enters the lead boiling container 1 for heating and lead taking, the cast-weld mold 2 is lifted and transferred to the transfer path 10.

In addition, the two side edges of the cast welding mold 2 are provided with clamping grooves 21 for clamping with the rails 4, the movable rails 5, the fixed rails 6 and the heating bottom plate 7.

It should be noted that, the cast-weld mold 2 is moved on the transfer path 10 by the moving rod 41 cooperating with the rail 4 to move the cast-weld mold 2 from the lead boiling container 1 to the cast-weld cooling station, the rail 4 is provided with a movable rail 5 which is lifted along the connecting path 20, the movable rail 5 is lifted by a lifting cylinder, the movable rail 5 is flush with the rail 4 at the lowest position, after the cast-weld mold 2 after completing the cast-weld cooling operation is moved onto the movable rail 5, the movable rail 5 is lifted to lift the cast-weld mold 2 to be flush with the fixed rail 6 at the highest position, so that the cast-weld mold 2 moves on the connecting path 20, then the cast-weld mold 2 is pushed onto the fixed rail 6 from the movable rail 5 by the deflector rod 61, the movable rail 5 is reset to be flush with the rail 4, the fracture of the connecting rail 4, then, the cast-weld mold 2 is pushed to the heating bottom plate 7 from the fixed rail 6 by the deflector rod 61, so that the cast-weld mold 2 moves on the rotation path 30, finally, the lifting cylinder drives the heating bottom plate 7 to enter the lead boiling container 1 for heating and warming, so that the cast-weld mold 2 moves on the connection path 40, after the heating and warming, the cast-weld mold 2 containing lead liquid is lifted to be level with the rail 4 by the heating bottom plate 7, and the moving rod 41 is used for pushing the cast-weld mold 2 to the rail 4 from the heating bottom plate 7.

The working process is as follows:

the cast-weld mould 2 is driven to move on a transfer path 10 by a moving rod 41 matched with a rail 4, so that the cast-weld mould 2 can be transferred from a lead boiling container 1 to a cast-weld cooling station to work, a movable rail 5 which is lifted along a connecting path 20 is arranged on the rail 4, the movable rail 5 is driven by a lifting cylinder to be lifted, the movable rail 5 is leveled with the rail 4 at the lowest position, after the cast-weld mould 2 which finishes the cast-weld cooling work is moved onto the movable rail 5, the movable rail 5 is lifted, the cast-weld mould 2 is lifted to be leveled at the highest position on a fixed rail 6, so that the cast-weld mould 2 moves on the connecting path 20, then the cast-weld mould 2 is pushed onto the fixed rail 6 from the movable rail 5 through a deflector rod 61, the movable rail 5 is reset to be leveled with the rail 4, the fracture of the connecting rail 4 is connected, and then the cast-weld mould 2 is pushed onto a heating bottom plate 7 from the fixed rail 6 through the deflector rod 61, make cast joint mould 2 remove on gyration route 30, utilize lift cylinder to drive heating bottom plate 7 at last and enter into and boil plumbous container 1 in and heat the intensification for cast joint mould 2 removes on linking route 40, and heats the back that heaies up, and cast joint mould 2 who gets plumbous liquid is lifted to being equal with track 4 by heating bottom plate 7 again, utilizes carriage release lever 41 to follow heating bottom plate 7 with cast joint mould 2 on the propelling movement 4.

The above description is intended to be illustrative of the preferred embodiment of the present invention and should not be taken as limiting the utility model, but rather, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the utility model.

Claims (10)

1. The utility model provides a lead acid battery processing is with cast joint mould inner loop assembly which characterized in that includes:

at least two sets of cast welding dies (2);

when one set of the cast-weld molds (2) is output from the lead boiling container (1) through a closed loop type circulation path (3) to be cooled and cast-welded, the other set of the cast-weld molds (2) is input into the lead boiling container (1) through the circulation path (3) to be heated and heated, and the circulation path (3) is integrated with a cast-weld system of the lead-acid battery.

2. The cast-weld mold internal circulation assembly for processing lead-acid batteries according to claim 1, characterized by comprising:

a closed loop circulation path (3) consisting of a transfer path (10), a connection path (20), a rotation path (30) and a connection path (40) which are connected end to end;

the circulating path (3) is used for outputting the cast-weld mold (2) containing lead liquid in the lead boiling container (1), and simultaneously inputting the other set of cast-weld mold (2) which finishes cast-weld cooling into the lead boiling container (1) for heating and temperature rise.

3. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 2, characterized in that:

the transfer path (10) is arranged at the top of the lead boiling container (1), and the transfer path (10) is used for transferring and conveying the cast-weld mold (2) which is heated by the lead boiling container (1) and takes lead and is output through the connecting path (40) to a cast-weld cooling station;

the connecting path (20) is arranged on the transfer path (10), the connecting path (20) connects the transfer path (10) and the rotary path (30), and the cast-weld mold (2) output from the cast-weld cooling station is transferred onto the rotary path (30);

the rotary path (30) is connected with the joining path (40), the rotary path (30) transfers the cast welding mould (2) to the upper part of the lead boiling container (1), and the cast welding mould is conveyed back into the lead boiling container (1) through the joining path (40).

4. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 3, wherein:

the transfer path (10) is arranged in parallel with the turning path (30);

the connecting path (20) is arranged in parallel with the joining path (40).

5. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 3, wherein:

a track (4) is laid on the transfer path (10), and a moving rod (41) used for shifting the cast-weld mold (2) to slide along the track (4) is arranged beside the track (4).

6. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 5, wherein:

the movable rod (41) is arranged in a semi-square frame shape, and when the movable rod (41) pushes the cast-weld mold (2), the movable rod (41) is arranged in a manner of semi-surrounding the cast-weld mold (2).

7. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 6, wherein:

the connecting path (20) is provided with a movable rail (5) which is arranged in a lifting mode, when the movable rail (5) descends to the right position, the movable rail is horizontally arranged at a fracture (42) of the rail (4), and when the movable rail (5) ascends to the right position, the movable rail is horizontally arranged on the rotating path (30).

8. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 7, wherein:

a fixed rail (6) is fixedly arranged on the rotary path (30), and a shifting lever (61) for pushing the cast-weld mold (2) to slide along the fixed rail (6) is arranged beside the fixed rail (6).

9. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 8, wherein:

the heating bottom plate (7) is arranged on the connecting path (40) in a lifting mode, the heating bottom plate (7) bears the cast-weld mold (2), the cast-weld mold (2) enters the lead boiling container (1) to be heated and is lifted and transferred to the transfer path (10) after lead is taken out.

10. The cast-weld mold internal circulation assembly for processing the lead-acid battery according to claim 9, wherein:

and clamping grooves (21) used for clamping the track (4), the movable track (5), the fixed track (6) and the heating bottom plate (7) are formed in two side edges of the cast-weld mold (2).

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