CN211758757U - Anode plate ear milling device - Google Patents

Abstract

The utility model discloses an anode plate ear milling device, which comprises a frame, a milling pin supporting component, a milling cutter component, a top clamping mechanism, a bottom clamping mechanism and a polar plate transferring mechanism; the polar plate transfer mechanisms are respectively transversely arranged at two ends of the rack and drive the anode plate to move on the rack through the polar plate transfer mechanisms; the milling pin supporting components are respectively and transversely fixed at two ends of the frame and are longitudinally arranged at the milling lug stations, and the upper surfaces of the milling pin supporting components are higher than the upper surface of the polar plate transfer mechanism; after the anode plate is longitudinally conveyed to the lug milling station, the top clamping mechanism and the bottom clamping mechanism clamp the anode plate, the milling pin supporting assembly supports the bottom of a lifting lug of the anode plate, the moving assembly drives the milling cutter assembly to perform 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. The utility model discloses can solve current anode plate and mill the ear device structure complicated, can cause the problem of very big impact to the device when milling.

Description

Anode plate ear milling device

Technical Field

The utility model relates to a metal smelting equipment technical field especially relates to an anode plate mills ear device.

Background

In the wet zinc smelting process, the quality of the anode plate lifting lug has important influence on the verticality and the conductivity of the anode plate. Therefore, the bottom of the lifting lug of the anode plate needs to be milled so as to ensure the contact quality of the lifting lug and the copper busbar.

In the milling device at the bottom of the anode plate, a traditional polar plate transfer mechanism is composed of a plurality of gear clamps, a lifting mechanism and a horizontal mechanism, and has the defects of complex structure, more faults, asynchronous lifting and the like. The other polar plate transfer mechanism transfers polar plates together by a plurality of groups of chains at the top and the bottom. The two structures are complex in structure, impact is large in the milling process, and the service life of the blade is short.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. An object of the utility model is to provide an anode plate mills ear device to it is great to solve current polar plate and transfer technical structure complicacy and mill the in-process and strike, can cause the problem of great impact to the device when milling.

An anode plate lug milling device comprises a rack, a milling pin supporting assembly, a milling cutter assembly, a top clamping mechanism, a bottom clamping mechanism and a polar plate transferring mechanism;

the milling cutter assemblies are respectively hinged to two ends of the rack;

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

the milling pin supporting components are respectively and transversely fixed at two ends of the rack and are longitudinally arranged at milling lug stations, and the upper surfaces of the milling pin supporting components are higher than the upper surface of the polar plate transfer mechanism;

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

after the anode plate is longitudinally conveyed to a lug milling station, the top clamping mechanism and the bottom clamping mechanism clamp the anode plate, the milling pin supporting assembly supports the lifting lug of the anode plate, the moving assembly drives the milling cutter assembly to perform 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.

According to the utility model provides an anode plate mills ear device, after the anode plate moves and mills ear station, top clamping mechanism and bottom clamping mechanism press from both sides the anode plate tightly, it drives milling cutter subassembly and is feed motion to remove the subassembly, make milling cutter subassembly feed the below of the lug of anode plate, mill the lug bottom through milling cutter subassembly, compare traditional structure, the device's structure is simpler, the copper scraps can not influence rotary motion, it is more steady effective to mill the process, through be equipped with in the frame and mill round pin supporting component, therefore, after the anode plate moves and mills ear station, can support the lug by milling round pin supporting component, when milling the ear, the impact force of production can be born by milling round pin supporting component, can effectively reduce the impact, promote the life of blade.

In addition, according to the utility model provides an anode plate mills ear device can also have following additional technical characterstic:

further, the milling cutter subassembly includes the milling cutter dish and is used for the drive the unit head of milling cutter dish work, the milling cutter dish is installed the top of unit head.

Further, 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.

Furthermore, the polar plate transfer mechanism adopts a steel plate which can move horizontally and vertically, and the anode plate is transferred horizontally and step by step.

Furthermore, the upper surface of the milling pin support assembly is of a structure with a high middle part and low two ends, the middle position of the milling pin support assembly is higher than the top surface of the chain, and the lifting lugs of the anode plate are supported by the milling pin support assembly after the anode plate moves to the milling lug station.

Furthermore, the number of the top clamping mechanisms is at least two, and after the anode plate moves to the lug milling station, the top clamping mechanisms respectively clamp the two lifting lugs of the anode plate.

Furthermore, the bottom clamping mechanisms are at least two, and the bottom of the anode plate is clamped by the bottom clamping mechanisms after the anode plate moves to the lug milling station.

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

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

Furthermore, the moving assembly comprises a mounting seat, a rotary arm driver, a rotary arm and a rotary power source, the mounting seat and the rotary power source are respectively fixed on the rack, the rotary arm is hinged on the rack, and the rotary arm and the rotary power source are concentrically mounted on the rack;

the one end of gyration arm driver with the mount pad rotates to be connected, the other end of gyration arm driver with the gyration arm rotates to be connected, the gyration arm respectively with the output shaft of gyration power supply with the unit head is connected, through the gyration power supply drives the gyration arm rotates, and then drives the unit head with the milling cutter dish rotates, simultaneously, under the drive of gyration arm driver, the gyration arm drives the unit head with the milling cutter dish moves around the axle.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

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

fig. 2 is a schematic front view of an anode plate ear milling device 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 housing;

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

fig. 6 is a schematic structural diagram of the lug milling mechanism.

Detailed Description

In order to make the objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. Several embodiments of the invention are given in the accompanying drawings. The 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 "secured to" 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. As used herein, the terms "vertical," "horizontal," "left," "right," "up," "down," and the like are for illustrative purposes only and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

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

The anode plate 50 is driven by the plate transfer mechanism 40 to move on the frame 10. The pole plate transfer mechanisms 40 are respectively and transversely arranged at two ends of the rack 10, in this embodiment, the pole plate transfer mechanisms 40 adopt chains 42, the number of the chains 42 is at least two, and at least one chain 42 is respectively arranged at two ends of the rack 10. The chain 42 is driven by a driving assembly (not shown), and a plurality of anode plates 50 are uniformly arranged on the chain 42 at intervals. Specifically, the chain 42 is provided with a plurality of protrusions uniformly spaced from each other, 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 be configured to transfer the anode plate 50 in steps that may be translated horizontally and up and down.

The milling lug mechanism comprises a milling cutter component 21 and a moving component 22, the chain 42 is driven by the driving component to transmit, so that the anode plate 50 is driven to move, after the anode plate 50 moves to a milling lug station, the clamping mechanism 30 extends out and clamps the anode plate 50, the moving component 22 drives the milling cutter component 21 to perform feeding motion, so that the milling cutter component 21 is fed to the position below the lifting lug 51, and the bottom of the lifting lug 51 is milled through the milling cutter component 21. In this embodiment, two milling cutter assemblies 21 are provided, and the two milling cutter assemblies 21 are respectively hinged to two ends of the frame 10 and respectively arranged at two ends of the frame 10, and are used for simultaneously milling two lifting lugs 51 of the anode plate 50. 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 a milling support assembly 60, specifically, the milling support assembly 60 is transversely fixed at two ends of the frame 10 and longitudinally arranged at a milling lug station, the upper surface of the milling support assembly 60 is higher than the upper surface of the plate transfer mechanism 40, and the milling support assembly 60 has the functions of bearing impact and positioning. In this embodiment, the upper surface of the milling support assembly 60 has a structure with a high middle part and low ends, the middle position is higher than the top surface of the chain 42, and after the anode plate 50 moves to the milling lug 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 and the anode plate 50 is transported to the milling lug station, the bottom of the lug 51 of the anode plate 50 will rest directly on the upper surface of the plate transfer mechanism 40. It should be noted that if the milling support assembly 60 is eliminated, the anode plate lugs 50 can be placed directly on the chain 42 and still operate, but only to affect the milling cutter life.

Milling cutter subassembly 21 includes milling cutter disc 211 and is used for the drive the unit head 212 of milling cutter disc 211 work, milling cutter disc 211 installs the top of unit head 212.

The moving assembly 22 includes a mounting seat 221, a revolving arm driver 222, a revolving arm 223 and a revolving power source 224, the mounting seat 221 and the revolving power source 224 are respectively fixed on the rack 10, the revolving arm 223 is hinged on the rack 10, and the revolving arm 223 and the revolving power source 224 are concentrically mounted on the rack 10.

The one end of gyration arm driver 222 with mount pad 221 rotates to be connected, the other end of gyration arm driver 222 with gyration arm 223 rotates to be connected, gyration arm 223 respectively with gyration power supply 224 the output shaft with the unit head 212 is connected, through gyration power supply 224 drives gyration arm 223 rotates, and then drives the unit head 212 with milling cutter dish 211 rotates, simultaneously under the drive of gyration arm driver 222, gyration arm 223 drives the unit head 212 with milling cutter dish 211 moves around the axle.

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 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 moving assembly 22 drives the milling cutter assembly 21 to perform a feeding motion, so that 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 two top telescopic cylinders 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 telescopic cylinders 312 drive the top clamping plates 311 to clamp and loosen the lifting lug 51, the top telescopic cylinders 312 are fixed to the frame 10, and the two top clamping plates 311 are movably connected to each other.

Bottom clamping mechanism 32 includes two bottom splint 321 and with two the flexible hydro-cylinder 322 in bottom that bottom splint 321 connects respectively, the bottom of anode plate 50 is by the centre gripping two between the bottom splint 321, drive bottom splint 321 by the flexible hydro-cylinder 322 in bottom and press from both sides tightly and loosen anode plate 50, the flexible hydro-cylinder 322 in bottom is fixed on the frame 10, two swing joint between the bottom splint 321. It should be noted that the bottom clamping mechanism 32 may also be implanted on the side of the anode plate 50 for clamping the side of the anode plate 50.

The working principle of the anode plate milling lug device is explained below, when one of the anode plates 50 is transported to the milling lug station by the chain 42, the top clamping mechanism 31 and the bottom clamping mechanism 32 simultaneously clamp and fix the anode plate 50 at 4 points, after the anode plate 50 is clamped, the moving assembly 22 drives the milling cutter assembly 21 to make a feeding motion, so that the milling cutter assembly 21 is fed below the lifting lug 51 of the anode plate 50, the power head 212 drives the milling cutter disc 211 to work to mill the lifting lug 51, during milling, the lifting lug 51 is supported by the milling pin supporting assembly 60, so as to reduce the impact force generated by the milling operation on the device, after the milling is completed, the moving assembly 22 drives the milling cutter assembly 21 to make a feeding motion, so that the milling cutter assembly 21 leaves the bottom of the lifting lug 51, meanwhile, the top clamping mechanism 31 and the bottom clamping mechanism 32 loosen the clamping of the anode plate 50, and then the next anode plate 50 is transported to the milling lug station by, the ear milling of the next anode plate 50 is achieved.

According to foretell anode plate mills ear device, after the anode plate moved to milling ear station, top clamping mechanism and bottom clamping mechanism pressed from both sides the anode plate tightly, the removal subassembly drives milling cutter subassembly and is feed motion, make the below of the lug of milling cutter subassembly feeding anode plate, mill the lug bottom through milling cutter subassembly, compare traditional structure, the device's structure is simpler, the copper scraps can not influence rotary motion, it is more steady effective to mill the process, through be equipped with milling round pin supporting component in the frame, therefore, after the anode plate moved to milling ear station, can support the lug by milling round pin supporting component, when milling the ear, the impact force of production can be born by milling round pin supporting component, can effectively reduce the impact, promote the life of blade.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean 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 invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. 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 above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. An anode plate lug milling device is characterized by comprising a rack, a milling pin supporting assembly, a milling cutter assembly, a top clamping mechanism, a bottom clamping mechanism and a pole plate transferring mechanism;

the milling cutter assemblies are respectively hinged to two ends of the rack;

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

the milling pin supporting components are respectively and transversely fixed at two ends of the rack and are longitudinally arranged at milling lug stations, and the upper surfaces of the milling pin supporting components are higher than the upper surface of the polar plate transfer mechanism;

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

after the anode plate is longitudinally conveyed to a lug milling station, the top clamping mechanism and the bottom clamping mechanism clamp the anode plate, the milling pin supporting assembly supports the lifting lug of the anode plate, the moving assembly drives the milling cutter assembly to perform 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.

2. The anode plate lug milling device according to claim 1, wherein 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.

3. The anode plate lug milling device according to claim 1, wherein the electrode plate transfer mechanism is provided with at least two chains, and at least one chain is respectively arranged at two ends of the frame.

4. The anode plate lug milling device according to claim 1, wherein the plate transfer mechanism uses a steel plate which can move horizontally and up and down to transfer the anode plate horizontally and step by step.

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

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

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

8. The anode plate lug milling apparatus of claim 7, wherein the bottom clamping mechanism is implanted to the side of the anode plate for clamping the side of the anode plate.

9. The anode plate lug milling device according to claim 3, wherein a plurality of protrusions are uniformly spaced on the chain, and the anode plate is pushed to the upper surface of the milling pin support assembly by the protrusions on the chain.

10. The anode plate lug milling device according to claim 2, wherein the moving assembly comprises a mounting seat, a rotary arm driver, a rotary arm and a rotary power source, the mounting seat and the rotary power source are respectively fixed on the rack, the rotary arm is hinged on the rack, and the rotary arm and the rotary power source are concentrically mounted on the rack;

the one end of gyration arm driver with the mount pad rotates to be connected, the other end of gyration arm driver with the gyration arm rotates to be connected, the gyration arm respectively with the output shaft of gyration power supply with the unit head is connected, through the gyration power supply drives the gyration arm rotates, and then drives the unit head with the milling cutter dish rotates, simultaneously, under the drive of gyration arm driver, the gyration arm drives the unit head with the milling cutter dish moves around the axle.

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