CN111185620B - Ear milling device for anode plate - Google Patents

Abstract

The invention discloses an anode plate ear milling device which comprises a frame, a milling support assembly, a milling cutter assembly, a top clamping mechanism, a bottom clamping mechanism and an electrode plate transfer mechanism, wherein the milling support assembly is arranged on the frame; the polar plate transfer mechanisms are respectively and transversely arranged at two ends of the frame, and the polar plate transfer mechanisms drive the anode plates to move on the frame; the milling support assemblies are respectively and transversely fixed at two ends of the frame, are longitudinally arranged at the milling ear stations, and the upper surfaces of the milling support assemblies are higher than the upper surfaces of the polar plate transfer mechanisms; after the anode plate is longitudinally conveyed to the ear milling station, the anode plate is clamped by the top clamping mechanism and the bottom clamping mechanism, the bottom of the lifting lug of the anode plate is supported by the milling support assembly, and the moving assembly drives the milling cutter assembly to do feeding motion, so that the milling cutter assembly is fed to the lower side of the lifting lug of the anode plate, and the bottom of the lifting lug is milled by the milling cutter assembly. The invention can solve the problems that the prior anode plate ear milling device has complex structure and can cause great impact on the device during milling.

Description

Ear milling device for anode plate

Technical Field

The invention relates to the technical field of metal smelting equipment, in particular to an anode plate ear milling device.

Background

In the zinc hydrometallurgy process, the quality of the lifting lug of the anode plate has important influence on the verticality and the conductivity of the anode plate. Therefore, milling is required to be performed on the bottom of the lifting lug of the anode plate so as to ensure the contact quality between the lifting lug and the copper busbar.

In an anode plate bottom milling device, a traditional polar plate transfer mechanism adopts a set of mechanism consisting of a plurality of gear clamps, a lifting mechanism and a horizontal mechanism, and has the advantages of complex structure, more faults, easy occurrence of the phenomena of asynchronous lifting and the like. Another polar plate transferring mechanism is to transfer polar plates together by a plurality of groups of chains at the top and the bottom. The two structures are complex in structure, and in the milling process, impact is large, and the service life of the blade is short.

Disclosure of Invention

The present invention aims to solve at least one of the technical problems existing in the prior art. The invention aims to provide an anode plate ear milling device which aims to solve the problems that the existing anode plate transfer technology is complex in structure and large in impact in the milling process, and the device is large in impact during milling.

An anode plate ear milling device comprises a frame, a milling support assembly, a milling cutter assembly, a top clamping mechanism, a bottom clamping mechanism and an anode plate transfer mechanism;

The milling cutter components are respectively hinged to two ends of the frame;

the polar plate transfer mechanisms are respectively and transversely arranged at two ends of the frame, and the polar plate transfer mechanisms drive the anode plates to move on the frame;

The milling support assemblies are respectively and transversely fixed at two ends of the frame, are longitudinally arranged at the ear milling stations, and the upper surfaces of the milling support assemblies are higher than the upper surfaces of the polar plate transfer mechanisms;

The top clamping mechanism is arranged at the top of the frame, the bottom clamping mechanism is arranged at the bottom of the frame, and the top clamping mechanism and the bottom clamping mechanism are both arranged at two ends of the frame;

when the anode plate is longitudinally conveyed to the ear milling station, the top clamping mechanism and the bottom clamping mechanism clamp the anode plate, the milling support assembly supports the lifting lug of the anode plate, the moving assembly drives the milling cutter assembly to do feeding motion, the milling cutter assembly is enabled to feed to the lower side of the lifting lug of the anode plate, and the bottom of the lifting lug is milled through the milling cutter assembly.

According to the anode plate ear milling device provided by the invention, after the anode plate moves to the ear milling station, the anode plate is clamped by the top clamping mechanism and the bottom clamping mechanism, the moving assembly drives the milling cutter assembly to do feeding motion, so that the milling cutter assembly is fed below the lifting lug of the anode plate, and the bottom of the lifting lug is milled through the milling cutter assembly.

In addition, the anode plate ear milling device provided by the invention can also have the following additional technical characteristics:

Further, the milling cutter assembly comprises a milling cutter disc and a power head for driving the milling cutter disc to work, and the milling cutter disc is installed above the power head.

Further, the polar plate transfer mechanism adopts chains, the polar plate transfer mechanism is provided with at least two chains, and two ends of the frame are respectively provided with at least one chain.

Further, the polar plate transfer mechanism adopts a steel plate which can horizontally and vertically move, and the anode plate is horizontally transferred in a stepping way.

Further, the upper surface of milling support assembly is the structure that middle height, both ends are low, and intermediate position is higher than the chain top surface, after the anode plate moved to milling ear station, by milling support assembly is right the lug of anode plate supports.

Further, at least two sets of top clamping mechanisms are arranged, and after the anode plate moves to the ear milling station, the top clamping mechanisms clamp the two lifting lugs of the anode plate respectively.

Further, the bottom clamping mechanisms are at least two sets, and after the anode plate moves to the ear milling station, the bottom clamping mechanisms clamp the bottom of the anode plate.

Further, the bottom clamping mechanism is transplanted to a side of the anode plate for clamping the side of the anode plate.

Further, the chain is provided with a plurality of bulges which are uniformly arranged at intervals, and the anode plate is pushed to the upper surface of the milling support assembly by the bulges on the chain.

Further, the moving assembly comprises a mounting seat, a rotary arm driver, a rotary arm and a rotary power source, wherein the mounting seat and the rotary power source are respectively fixed on the frame, the rotary arm is hinged on the frame, and the rotary arm and the rotary power source are concentrically arranged on the frame;

one end of the rotary arm driver is rotationally connected with the mounting seat, the other end of the rotary arm driver is rotationally connected with the rotary arm, the rotary arm is respectively connected with an output shaft of the rotary power source and the power head, the rotary arm is driven to rotate by the rotary power source, and then the power head and the milling cutter disc are driven to rotate, and meanwhile, the rotary arm drives the power head and the milling cutter disc to move along a coiling shaft under the driving of the rotary arm driver.

Drawings

The foregoing and/or additional aspects and advantages of the invention will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

fig. 1 is a schematic perspective view of an ear milling device for an anode plate according to an embodiment of the invention;

fig. 2 is a schematic front view of an ear milling device for an anode plate according to an embodiment of the present invention;

fig. 3 is a schematic structural view of an anode plate;

FIG. 4 is a schematic view of the mating structure of the milling support assembly and the frame;

FIG. 5 is a schematic view of the mating structure of the milling support assembly and the plate transfer mechanism;

Fig. 6 is a schematic structural view of a milling ear mechanism.

Detailed Description

In order that the objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Several embodiments of the invention are presented in the figures. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," "upper," "lower," and the like are used herein for descriptive purposes only and not to indicate or imply that the apparatus or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the invention.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 6, an anode plate ear milling device according to an embodiment of the present invention includes a frame 10, an ear milling mechanism, a clamping mechanism 30, and an anode plate transferring mechanism 40. The ear milling mechanism, the clamping mechanism 30 and the polar plate transferring mechanism 40 are respectively arranged on the frame 10.

The anode plate 50 is driven to move on the frame 10 by the plate transfer mechanism 40. The plate transferring mechanisms 40 are respectively and transversely arranged at two ends of the frame 10, in this embodiment, the plate transferring mechanisms 40 adopt at least two chains 42, and at least one chain 42 is respectively arranged at two ends of the frame 10. The chain 42 is driven by a drive assembly (not shown), and a plurality of anode plates 50 are provided on the chain 42 in a uniformly spaced arrangement. Specifically, the chain 42 is provided with a plurality of protrusions arranged at uniform intervals, and the anode plate 50 is pushed by the protrusions on the chain 42.

It should be noted that in other embodiments, the plate transfer mechanism 40 may also employ a stepped transfer anode plate 50 that is translatable horizontally and up and down.

The milling mechanism comprises a milling cutter assembly 21 and a moving assembly 22, the chain 42 is driven by the driving assembly to drive the anode plate 50 to move, after the anode plate 50 moves to a milling position, the clamping mechanism 30 stretches out and clamps the anode plate 50, the moving assembly 22 drives the milling cutter assembly 21 to perform feeding movement, so that the milling cutter assembly 21 is fed below the lifting lug 51, and the bottom of the lifting lug 51 is milled through the milling cutter assembly 21. In this embodiment, two milling cutter assemblies 21 are hinged to two ends of the frame 10, and the two milling cutter assemblies 21 are respectively disposed at two ends of the frame 10 and are used for milling two lifting lugs 51 of the anode plate 50 simultaneously. It should be noted that in other embodiments the milling cutter assembly 21 may be mounted on only one side.

The frame 10 is provided with milling support assemblies 60, specifically, the milling support assemblies 60 are respectively and transversely fixed at two ends of the frame 10, are longitudinally arranged at the ear milling station, the upper surface of the milling support assemblies 60 is higher than the upper surface of the polar plate transfer mechanism 40, and the milling support assemblies 60 are used for bearing the impact function and the positioning function. In this embodiment, the upper surface of the milling support assembly 60 has a structure with a high middle and low two ends, the middle position is higher than the top surface of the chain 42, and after the anode plate 50 moves to the ear milling station, the milling support assembly 60 supports the lifting lug 51, so that the lifting lug 51 is no longer in direct contact with the chain 42. It will be appreciated that if the milling support assembly 60 is removed, the bottom of the tab 51 of the anode plate 50 will rest directly on the upper surface of the plate transfer mechanism 40 after the anode plate 50 is delivered to the ear milling station. It should be noted that if the milling support assembly 60 is eliminated, the shackle 50 of the anode plate is placed directly on the chain 42, and can also work, only to affect the life of the milling cutter.

The milling cutter assembly 21 comprises a milling cutter disc 211 and a power head 212 for driving the milling cutter disc 211 to work, wherein the milling cutter disc 211 is arranged above the power head 212.

The moving assembly 22 comprises a mounting seat 221, a rotary arm driver 222, a rotary arm 223 and a rotary power source 224, wherein the mounting seat 221 and the rotary power source 224 are respectively fixed on the frame 10, the rotary arm 223 is hinged on the frame 10, and the rotary arm 223 and the rotary power source 224 are concentrically arranged on the frame 10.

One end of the rotary arm driver 222 is rotatably connected with the mounting seat 221, the other end of the rotary arm driver 222 is rotatably connected with the rotary arm 223, the rotary arm 223 is respectively connected with an output shaft of the rotary power source 224 and the power head 212, the rotary power source 224 drives the rotary arm 223 to rotate, and further drives the power head 212 and the milling cutter disc 211 to rotate, and meanwhile, the rotary arm 223 drives the power head 212 and the milling cutter disc 211 to move around a shaft under the driving of the rotary arm driver 222.

The clamping mechanism 30 comprises a top clamping mechanism 31 and a bottom clamping mechanism 32, the top clamping mechanism 31 is arranged at the top of the frame 10, the bottom clamping mechanism 32 is arranged at the bottom of the frame 10, and the top clamping mechanism 31 and the bottom clamping mechanism 32 are respectively arranged at two ends of the frame 10.

After the anode plate 50 moves to the ear milling station, the top clamping mechanism 31 clamps the lifting lug 51 of the anode plate 50, and the bottom clamping mechanism 32 clamps the bottom of the anode plate 50. The milling support assembly 60 supports the lifting lug 51 of the anode plate 50, the milling cutter assembly 21 is driven by the moving assembly 22 to perform feeding motion, the milling cutter assembly 21 is fed below the lifting lug 51 of the anode plate 50, and the bottom of the lifting lug 51 is milled by the milling cutter assembly 21.

Specifically, the top clamping mechanism 31 includes two top clamping plates 311 and a top telescopic cylinder 312 respectively connected to the two top clamping plates 311, the lifting lug 51 of the anode plate 50 is clamped between the two top clamping plates 311, the top clamping plates 311 are driven by the top telescopic cylinder 312 to clamp and unclamp the lifting lug 51, the top telescopic cylinder 312 is fixed on the frame 10, and the two top clamping plates 311 are movably connected.

The bottom clamping mechanism 32 comprises two bottom clamping plates 321 and bottom telescopic cylinders 322 respectively connected with the two bottom clamping plates 321, the bottom of the anode plate 50 is clamped between the two bottom clamping plates 321, the bottom clamping plates 321 are driven by the bottom telescopic cylinders 322 to clamp and unclamp the anode plate 50, the bottom telescopic cylinders 322 are fixed on the frame 10, and the two bottom clamping plates 321 are movably connected. It should be noted that the bottom clamping mechanism 32 may also be implanted into the side of the anode plate 50 for clamping the side of the anode plate 50.

The working principle of the anode plate ear milling device is described below, after one anode plate 50 is transported to an ear milling station by a chain 42, 4-point clamping and fixing are carried out on the anode plate 50 by a top clamping mechanism 31 and a bottom clamping mechanism 32 at the same time, after the anode plate 50 is clamped, a moving assembly 22 drives a milling cutter assembly 21 to do feeding motion, so that the milling cutter assembly 21 is fed below a lifting lug 51 of the anode plate 50, a power head 212 drives a milling cutter disc 211 to work so as to mill the lifting lug 51, during milling, the lifting lug 51 is supported by a milling pin supporting assembly 60, the impact force of milling operation on the device is relieved, after milling is completed, the moving assembly 22 drives the milling cutter assembly 21 to do feeding motion, so that the milling cutter assembly 21 leaves the bottom of the lifting lug 51, and simultaneously, the top clamping mechanism 31 and the bottom clamping mechanism 32 loosen the clamping of the anode plate 50, and the next anode plate 50 is conveyed to the ear milling station by the chain 42, so that ear milling of the next anode plate 50 is achieved.

According to the anode plate ear milling device, after the anode plate moves to the ear milling station, the anode plate is clamped by the top clamping mechanism and the bottom clamping mechanism, the moving assembly drives the milling cutter assembly to conduct feeding motion, the milling cutter assembly is used for feeding the milling cutter assembly to the lower side of the lifting lug of the anode plate, compared with a traditional structure, the structure of the anode plate ear milling device is simpler, copper scraps can not influence rotary motion, the milling process is more stable and effective, and the milling support assembly is arranged on the frame, so that after the anode plate moves to the ear milling station, the lifting lug can be supported by the milling support assembly, and when an ear is milled, the generated impact force can be born by the milling support assembly, so that the impact can be effectively reduced, and the service life of the blade is prolonged.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing examples illustrate only a few embodiments of the invention and are described in detail herein without thereby limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (7)

1. The anode plate ear milling device is characterized by comprising a frame, a milling support assembly, a milling cutter assembly, a top clamping mechanism, a bottom clamping mechanism and an anode plate transfer mechanism;

The milling cutter components are respectively hinged to two ends of the frame;

the polar plate transfer mechanisms are respectively and transversely arranged at two ends of the frame, and the polar plate transfer mechanisms drive the anode plates to move on the frame;

The milling support assemblies are respectively and transversely fixed at two ends of the frame, are longitudinally arranged at the ear milling stations, and the upper surfaces of the milling support assemblies are higher than the upper surfaces of the polar plate transfer mechanisms;

The top clamping mechanism is arranged at the top of the frame, and the bottom clamping mechanism is arranged at the bottom of the frame;

When the anode plate is longitudinally conveyed to an ear milling station, the top clamping mechanism and the bottom clamping mechanism clamp the anode plate, the milling support assembly supports the lifting lug of the anode plate, the moving assembly drives the milling cutter assembly to do feeding motion, the milling cutter assembly is enabled to be fed below the lifting lug of the anode plate, and the bottom of the lifting lug is milled through the milling cutter assembly;

The milling cutter assembly comprises a milling cutter disc and a power head for driving the milling cutter disc to work, and the milling cutter disc is arranged above the power head;

The polar plate transfer mechanism adopts chains, the polar plate transfer mechanism is at least provided with two chains, and two ends of the rack are respectively provided with at least one chain;

The movable assembly comprises a mounting seat, a rotary arm driver, a rotary arm and a rotary power source, wherein the mounting seat and the rotary power source are respectively fixed on the frame, the rotary arm is hinged on the frame, and the rotary arm and the rotary power source are concentrically arranged on the frame;

one end of the rotary arm driver is rotationally connected with the mounting seat, the other end of the rotary arm driver is rotationally connected with the rotary arm, the rotary arm is respectively connected with an output shaft of the rotary power source and the power head, the rotary arm is driven to rotate by the rotary power source, and then the power head and the milling cutter disc are driven to rotate, and meanwhile, the rotary arm drives the power head and the milling cutter disc to move along a coiling shaft under the driving of the rotary arm driver.

2. The anode plate ear milling device according to claim 1, wherein the plate transfer mechanism is configured to transfer the anode plate in horizontal steps using a steel plate that can be horizontally and vertically moved.

3. The anode plate ear milling device of claim 1, wherein the upper surface of the milling support assembly has a structure with a high middle and low two ends, the middle position is higher than the top surface of the chain, and the lifting lug of the anode plate is supported by the milling support assembly after the anode plate moves to the ear milling station.

4. The anode plate ear milling device of claim 1, wherein the top clamping mechanism has at least two sets, and the top clamping mechanism clamps the two lifting lugs of the anode plate respectively after the anode plate moves to the ear milling station.

5. The anode plate ear milling device of claim 1, wherein the bottom clamping mechanism has at least two sets, and the bottom clamping mechanism clamps the bottom of the anode plate after the anode plate moves to the ear milling station.

6. The anode plate ear milling device of claim 5, wherein the bottom clamping mechanism is grafted to a side of the anode plate for clamping the side of the anode plate.

7. The anode plate ear milling device of claim 1, wherein the chain is provided with a plurality of protrusions arranged at uniform intervals, and the anode plate is pushed to the upper surface of the milling support assembly by the protrusions on the chain.