CN111251003A - Battery tray bottom plate welding mills transfer machine production system - Google Patents

Abstract

The invention discloses a welding and milling automatic line production system for a battery tray bottom plate, which comprises a reverse side production system and a front side production system, wherein the tail end of the reverse side production system is connected with the head end of the front side production system through a transfer overturning platform, the reverse side production system comprises a first conveying rail, the head end of the first conveying rail is provided with a feeding station, the first conveying rail is provided with a first carrying robot, the first conveying rail is taken as a symmetrical shaft, and the two ends of the first conveying rail are respectively provided with a reverse side stirring friction welding device and a reverse side deburring and milling CNC device; the front production system comprises a second conveying rail, wherein a second transfer robot is arranged on the second conveying rail, the second conveying rail is a symmetry axis, and the two ends of the second conveying rail are respectively provided with a front friction stir welding device, a front milling CNC device and a blanking station. The system improves the production efficiency of the product and ensures the stability and quality of the product; the production cost is reduced, and the production period is shortened.

Description

Battery tray bottom plate welding mills transfer machine production system

Technical Field

The invention relates to the technical field of production of battery tray bottom plates, in particular to a welding and milling automatic line production system for a battery tray bottom plate.

Background

In a welding and milling production system for a bottom plate of a battery tray, in the prior art, manual feeding and discharging, manual stirring and welding and manual CNC (Computer numerical control) equipment are generally adopted, so that unstable production exists, the production efficiency is low, the occupied area is large, and the labor cost and the site cost are high; moreover, the labor intensity of workers is very high, and the working environment is poor.

Therefore, the conventional welding and milling production system for the bottom plate of the battery tray obviously has inconvenience and defects in structure and use, and needs to be further improved. In order to solve the problems of the welding and milling production system for the bottom plate of the battery tray, the relevant manufacturers have tried to solve the problems without diligent attention, but there has been no suitable design developed and completed for a long time, and there is no suitable structure to solve the problems, which is obviously a problem to be solved by the relevant manufacturers.

In view of the above-mentioned defects of the existing welding and milling production system for the bottom plate of the battery tray, the inventor of the present invention has actively researched and innovated based on the practical experience and professional knowledge which are abundant for many years in the design and manufacture of such products and by using the theory, in order to create a new automatic production system for welding and milling the bottom plate of the battery tray, which can improve the existing welding and milling production system for the bottom plate of the battery tray, and make it more practical. After continuous research and design and repeated trial and improvement, the invention with practical value is finally created.

Disclosure of Invention

The invention mainly aims to overcome the defects of the existing welding and milling production system for the bottom plate of the battery tray, and provides a novel welding and milling automatic line production system for the bottom plate of the battery tray, aiming at solving the technical problems of ensuring high production efficiency and ensuring the quality and stability of products, thereby being more practical and having industrial utilization value.

The purpose of the invention and the technical problem to be solved are realized by adopting the following technical scheme.

According to one embodiment of the invention, the automatic line production system for welding and milling of the bottom plate of the battery tray is characterized in that: the automatic deburring and milling machine comprises a reverse side production system and a front side production system, wherein the tail end of the reverse side production system is connected with the head end of the front side production system through a transfer overturning platform, the reverse side production system comprises a first conveying rail, the head end of the first conveying rail is provided with a feeding station, the first conveying rail is provided with a first carrying robot, the first conveying rail is taken as a symmetry axis, and the two ends of the first conveying rail are respectively provided with a reverse side friction stir welding device and a reverse side deburring and milling CNC device; the front production system comprises a second conveying rail, wherein a second transfer robot is arranged on the second conveying rail, the second conveying rail is a symmetry axis, and the two ends of the second conveying rail are respectively provided with a front friction stir welding device, a front milling CNC device and a blanking station.

According to one embodiment of the invention, the welding and milling automatic line production system for the bottom plate of the battery tray is characterized in that: the back friction stir welding device comprises a first back friction stir welding machine and a second back friction stir welding machine, wherein the first back friction stir welding machine and the second back friction stir welding machine are symmetrically arranged on two sides of the first conveying rail and close to the feeding station by taking the first conveying rail as a symmetry axis.

According to one embodiment of the invention, the welding and milling automatic line production system for the bottom plate of the battery tray is characterized in that: the reverse side deburring milling CNC device comprises a reverse side deburring milling CNC first machine and a reverse side deburring milling CNC second machine, wherein the reverse side deburring milling CNC first machine and the reverse side deburring milling CNC second machine are arranged on two sides of the first conveying rail and close to the position of the middle turning table as symmetrical axisymmetric positions of the first conveying rail.

According to one embodiment of the invention, the welding and milling automatic line production system for the bottom plate of the battery tray is characterized in that: the front friction stir welding device comprises a front friction stir welding machine I and a front friction stir welding machine II, wherein the front friction stir welding machine I and the front friction stir welding machine II are symmetrically arranged on two sides of the second conveying rail and close to the position of the middle-turning overturning platform by taking the second conveying rail as a symmetry axis.

According to one embodiment of the invention, the welding and milling automatic line production system for the bottom plate of the battery tray is characterized in that: the front milling CNC device comprises a front milling CNC machine, a front milling CNC machine and a front milling CNC machine, wherein the front milling CNC machine is arranged on the first machine, the front milling CNC machine is arranged on the second machine, the second machine is arranged on two sides of the second conveying rail and close to the position of the middle turning table, the front milling CNC machine is arranged on the second conveying rail and is arranged on one side, the same as the front milling CNC machine, of the second conveying rail and close to the tail end of the second symmetrical shaft, and the blanking station is symmetrical to the front milling CNC machine with the second machine, the second conveying rail is arranged on the second conveying rail.

According to one embodiment of the invention, the welding and milling automatic line production system for the bottom plate of the battery tray is characterized in that: the first transfer robot can slide relative to the first conveying track.

According to one embodiment of the invention, the welding and milling automatic line production system for the bottom plate of the battery tray is characterized in that: the second transfer robot is slidable relative to the second conveying rail.

By the technical scheme, the invention at least has the following advantages:

the automatic production line of the invention effectively improves the production efficiency of the product, and the stability and the quality of the product are also ensured; meanwhile, the occupied area of production is reduced, the production cost is reduced, and the production period is shortened; and moreover, people are liberated from heavy physical labor and severe and dangerous working environments, and personal safety accidents of the personnel caused by personnel operation are reduced.

In conclusion, the special automatic production line system for welding and milling the battery tray bottom plate can effectively solve the problems in the prior art. The welding and milling production system has the advantages and practical values, does not have similar design publication or use in the similar schemes, is innovative, has great improvement on the structure or the function, has great technical progress, produces good and practical effects, has multiple enhanced effects compared with the existing welding and milling production system of the bottom plate of the battery tray, is more suitable for practical use, has industrial wide utilization value, and is a novel, improved and practical new design.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical solutions of the present invention more clearly understood and to implement them in accordance with the contents of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings.

The specific configuration of the present invention is given in detail by the following examples and the drawings thereof.

Drawings

Fig. 1 shows a schematic structural diagram of a battery tray bottom plate welding and milling automatic line production system of the invention.

The reference numbers in the drawings are as follows: reverse side production system-1; front side production system-2; a transfer overturning platform-3; a feeding station-4; a first transfer robot-5; a second transfer robot-6; a blanking station-7; a first conveying track-11; a first machine-12 of back friction stir welding; a second machine-13 of back friction stir welding; milling a CNC machine I14 for deburring on the reverse side; a CNC second machine 15 for deburring and milling the reverse side; a second conveying track-21; front friction stir welding machine-22; a second machine 23 for front friction stir welding; milling the front surface of a CNC machine I-24; milling the front surface of a CNC second machine-25; and (3) face milling to machine a CNC three-size machine 26.

Detailed Description

To further illustrate the technical means and effects of the present invention for achieving the predetermined objects, the following detailed description will be given of the embodiments, methods, structures, features and effects of the welding and milling automatic line production system for battery tray bottom plate according to the present invention with reference to the accompanying drawings and preferred embodiments.

Referring to fig. 1, a welding and milling automatic line production system for a battery tray base plate according to a preferred embodiment of the present invention mainly includes a back production system 1 and a front production system 2. The tail end of the back production system 1 is connected with the head end of the front production system 2 through a transfer overturning platform 3. The reverse producing system 1 includes a first conveying rail 11. The head end of the first conveying track 11 is provided with a feeding station 4, and the first conveying track 11 is provided with a first transfer robot 5. The first conveying track 11 is taken as a symmetry axis, and a back-side friction stir welding device and a back-side deburring milling CNC device are respectively arranged at two ends of the first conveying track. The front production system 2 includes a second conveying rail 21, and the second conveying rail 21 is provided with a second transfer robot 6. The second conveying track 21 is taken as a symmetry axis, and the two ends of the second conveying track are respectively provided with a front friction stir welding device, a front milling CNC device and a blanking station 7. The first transfer robot 5 can slide relative to the first conveying rail 11, and the first transfer robot 5 mainly functions to carry out loading and unloading and transfer of each station. The second transfer robot 6 can slide relative to the second conveying track 21, and the main function of the second transfer robot 6 is to transfer the parts to the blanking area to complete blanking.

The back friction stir welding device comprises a back friction stir welding first machine 12 and a back friction stir welding second machine 13. The first reverse side friction stir welding machine 12 and the second reverse side friction stir welding machine 13 are symmetrically arranged on two sides of the first conveying rail 11 and close to the feeding station 4 by taking the first conveying rail 11 as a symmetry axis. The back side deburring milling CNC device comprises a back side deburring milling CNC first machine 14 and a back side deburring milling CNC second machine 15. The reverse side deburring milling CNC primary machine 14 and the reverse side deburring milling CNC secondary machine 15 are symmetrically arranged on two sides of the first conveying track 11 and close to the middle turning table 3 by taking the first conveying track 11 as a symmetry axis.

The front friction stir welding apparatus includes a front friction stir welding first machine 22 and a front friction stir welding second machine 23. The front friction stir welding first machine 22 and the front friction stir welding second machine 23 are symmetrically arranged on both sides of the second conveying rail 21 near the position of the turn-over table 3 with the second conveying rail 21 as a symmetry axis. The face milling CNC device includes a face milling CNC one machine 24, a face milling CNC two machine 25, and a face milling CNC three machine 26. The face milling CNC one machine 24 and the face milling CNC three machine 26 are symmetrically arranged on both sides of the second conveying rail 21 near the position of the middle turning table 3 with the second conveying rail 21 as a symmetry axis. The face milling CNC one machine 25 is disposed on the same side of the second conveying rail 21 as the face milling CNC one machine 24 and near the end of the second symmetry axis 21. The blanking station 7 and the front milling CNC second machine 25 are symmetrical by taking the second conveying track 21 as a symmetry axis.

The specific implementation principle of the automatic production line system is as follows: the system is divided into a first stage and a second stage.

The specific example steps of the first stage are as follows: firstly, a worker places the parts on a feeding station, the first transfer robot 5 automatically carries out grabbing in the forward direction after the completion, and the workpieces are transferred to the first machine 12 for back friction stir welding from the feeding station 4. After the parts are grabbed at the feeding station 4, the tool automatically moves to a safe operation position, the workers continue to place the parts, and the first transfer robot 5 transfers the parts to the second machine 13 for back friction stir welding. After the stirring welding is finished, the first transfer robot 5 transfers the semi-finished product to the first CNC machine 14 or the second CNC machine 15 for deburring and milling on the reverse side. If the product on the CNC is machined, the first transfer robot 5 transfers the product to the transfer overturning platform 3 and enters the second stage.

The second stage comprises the following specific steps: the second transfer robot 6 grabs the semi-finished bottom plate on the overturning platform 3 to the front friction stir welding first machine 22 or the second machine 23. After the friction stir welding is completed, the second transfer robot 6 transfers the semi-finished part to the first CNC machine 24, the second CNC machine 25 or the third CNC machine 26 for face milling. After all parts on the CNC are machined, the second transfer robot 6 transfers the parts to the area of the blanking station 7, and blanking is completed.

The automatic production line effectively improves the production efficiency of products, and ensures the stability and quality of the products; meanwhile, the occupied area of production is reduced, the production cost is reduced, and the production period is shortened; and moreover, people are liberated from heavy physical labor and severe and dangerous working environments, and personal safety accidents of the personnel caused by personnel operation are reduced.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (7)

1. The utility model provides a battery tray bottom plate welding mills transfer machine production system which characterized in that: the automatic deburring and milling machine comprises a reverse side production system and a front side production system, wherein the tail end of the reverse side production system is connected with the head end of the front side production system through a transfer overturning platform, the reverse side production system comprises a first conveying rail, the head end of the first conveying rail is provided with a feeding station, the first conveying rail is provided with a first carrying robot, the first conveying rail is taken as a symmetry axis, and the two ends of the first conveying rail are respectively provided with a reverse side friction stir welding device and a reverse side deburring and milling CNC device; the front production system comprises a second conveying rail, wherein a second transfer robot is arranged on the second conveying rail, the second conveying rail is a symmetry axis, and the two ends of the second conveying rail are respectively provided with a front friction stir welding device, a front milling CNC device and a blanking station.

2. The battery tray floor welding milling automation line production system of claim 1, characterized in that: the back friction stir welding device comprises a first back friction stir welding machine and a second back friction stir welding machine, wherein the first back friction stir welding machine and the second back friction stir welding machine are symmetrically arranged on two sides of the first conveying rail and close to the feeding station by taking the first conveying rail as a symmetry axis.

3. The battery tray floor welding milling automation line production system of claim 1, characterized in that: the reverse side deburring milling CNC device comprises a reverse side deburring milling CNC first machine and a reverse side deburring milling CNC second machine, wherein the reverse side deburring milling CNC first machine and the reverse side deburring milling CNC second machine are arranged on two sides of the first conveying rail and close to the position of the middle turning table as symmetrical axisymmetric positions of the first conveying rail.

4. The battery tray floor welding milling automation line production system of claim 1, characterized in that: the front friction stir welding device comprises a front friction stir welding machine I and a front friction stir welding machine II, wherein the front friction stir welding machine I and the front friction stir welding machine II are symmetrically arranged on two sides of the second conveying rail and close to the position of the middle-turning overturning platform by taking the second conveying rail as a symmetry axis.

5. The battery tray floor welding milling automation line production system of claim 1, characterized in that: the front milling CNC device comprises a front milling CNC machine, a front milling CNC machine and a front milling CNC machine, wherein the front milling CNC machine is arranged on the first machine, the front milling CNC machine is arranged on the second machine, the second machine is arranged on two sides of the second conveying rail and close to the position of the middle turning table, the front milling CNC machine is arranged on the second conveying rail and is arranged on one side, the same as the front milling CNC machine, of the second conveying rail and close to the tail end of the second symmetrical shaft, and the blanking station is symmetrical to the front milling CNC machine with the second machine, the second conveying rail is arranged on the second conveying rail.

6. The battery tray floor welding milling automation line production system of claim 1, characterized in that: the first transfer robot can slide relative to the first conveying track.

7. The battery tray floor welding milling automation line production system of claim 1, characterized in that: the second transfer robot is slidable relative to the second conveying rail.

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