CN217026097U - Silver automation line - Google Patents

Abstract

The utility model belongs to the field of silver ingot processing, and particularly relates to a silver automatic production line which comprises an anode plate manufacturing device, an electrolytic purification device, a silver ingot casting device and a blanking and packing device which are sequentially arranged, wherein the electrolytic purification device comprises an electrolytic tank and a lifting and transferring device for discharging and loading an anode plate assembly. In addition, the automatic discharging and loading of the anode plate assembly can be realized, the anode plate assembly does not need to be discharged and loaded manually after power failure, the electrolysis production efficiency and the automation degree are improved, and the potential safety hazard is reduced.

Description

Silver automation line

Technical Field

The utility model belongs to the field of silver ingot processing, and particularly relates to an automatic silver production line.

Background

In the existing noble metal production process, the noble metal production adopts the modes of manual casting of polar plates, transfer, manual anode bag bagging hanger grooving, silver powder transfer and manual/semi-automatic ingot casting, polishing and packaging. The whole production process has low automation degree, high labor intensity and low production efficiency, and the working environment has acidic chemical substances and high temperature, so occupational diseases and dangerous accidents are easy to occur. In addition, the replacement of the anode plate assembly is also performed manually. After the anode plate is electrolyzed, anode mud and anode plate residual electrodes are contained in the anode bag, the weight of the anode rod and anode mud reaches three kilograms to forty kilograms, the anode plate assembly is taken out of the tank and loaded into the tank manually, the labor intensity is very high, meanwhile, silver nitrate electrolyte in the anode plate assembly and volatile acid mist around the electrolytic tank are corrosive, the field working environment is very poor, in order to ensure the safety of workers, the whole electrolytic tank needs to be powered off and stopped when the anode plate is replaced, and the electrolytic tank needs to be powered on for electrolysis after all the anode plate assemblies are replaced, but the manual operation is slow, and the productivity of the electrolytic tank is seriously influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an automatic silver production line with high production efficiency and low labor degree.

The utility model comprises an anode plate manufacturing device, an electrolytic purification device, a silver ingot casting device and a blanking and packaging device which are sequentially arranged, wherein the electrolytic purification device comprises an electrolytic tank and a lifting and transferring device for discharging and loading an anode plate assembly.

Furthermore, the lifting and transferring device comprises a lifting mechanism and a first rail, wherein the lifting mechanism can move to the position above the electrolytic cell along the first rail.

Furthermore, the lifting and transferring device further comprises a water receiving tray and a second rail which is arranged in parallel with the first rail, and the water receiving tray can move to the position below the lifting mechanism along the second rail.

Furthermore, the lifting mechanism comprises a frame capable of moving along the first rail and a lifting frame arranged on the frame, the lifting frame comprises a moving seat, a hook and a rotary driving assembly, the rotary driving assembly and the hook are respectively arranged on two sides of the moving seat, a mounting hole is formed in the moving seat, and one end of the hook penetrates through the mounting hole to be connected with the rotary driving assembly.

Furthermore, the couple is provided with the several, and the several couple sets up along interval on the collinear, the rotation driving subassembly includes driving piece, carriage release lever and several connecting rod, and the one end of several connecting rod corresponds respectively and articulates with the several couple, and the other end of several connecting rod is articulated with the carriage release lever, and the driving piece is used for promoting the carriage release lever and removes.

The utility model also comprises a powder discharging device, wherein the powder discharging device comprises a discharging pipe, a material receiving barrel and a water receiving box, one end of the discharging pipe is communicated with the bottom of the electrolytic cell, the other end of the discharging pipe is arranged towards the material receiving barrel, the bottom of the material receiving barrel is provided with a draining hole, and the material receiving barrel is positioned above the water receiving box.

Still further, the anode plate manufacturing device comprises a crucible, an anode plate continuous casting machine, a manipulator and a transfer trolley.

Furthermore, a silver powder cleaning and drying device is arranged between the electrolytic purification device and the silver ingot casting device.

Furthermore, a silver ingot polishing device, a silver ingot cleaning device, a silver ingot marking device and a weighing device are sequentially arranged between the electrolytic purification device and the blanking packing device.

Furthermore, a storage device is arranged behind the blanking and packaging device.

The silver production process has the beneficial effects that the silver production process is converted from manual process to mechanical automation, and the whole process from raw materials to finished products is included, so that the silver production process is greatly helpful for production management and production security. In addition, the automatic discharging and loading of the anode plate assembly can be realized, the discharging and loading of the anode plate assembly are not required to be carried out manually after power failure, the electrolysis production efficiency and the automation degree are improved, and the potential safety hazard is reduced.

Drawings

Fig. 1 is a first angle structure diagram of the present invention.

Fig. 2 is a second angle structure diagram of the present invention.

FIG. 3 is a schematic view of the overall structure of the electrolytic purification apparatus.

Fig. 4 is a schematic structural view of a lifting and transferring device in the electrolytic refining device.

FIG. 5 is a schematic view showing the construction of a lifting mechanism in the electrolytic refining apparatus.

FIG. 6 is a schematic view showing the state of use of a lifting mechanism in the electrolytic refining apparatus.

FIG. 7 is a schematic structural diagram of a powder discharging device of the electrolytic purification device.

FIG. 8 is a schematic view of a first view angle of a receiving barrel of the electrolytic refining apparatus.

FIG. 9 is a second perspective view of the receiving vessel of the electrolytic refining apparatus.

In the figure, 1-anode plate manufacturing apparatus; 101-a crucible; 102-anode plate continuous casting machine; 103-a manipulator; 104-a transfer trolley; 2-an electrolytic purification device; 201-lifting and transferring device; 2011-a chassis; 2012-track one; 2013-track two; 2014-frame; 20141-a transmission shaft; 20142-gear; 2015-a hoist frame; 20151-moving seat; 20152-hanging hook; 20153-connecting rod; 20154-moving rod; 20155-a drive member; 2016-a water-receiving tray; 20161-an elongated arm; 2017-a first driving mechanism; 2018-driving mechanism II; 2019-a drive assembly; 202-an electrolytic cell; 204-powder discharging device; 2041-discharge pipe; 20411 — discharge header; 20412-discharge manifold; 2042-a receiving bucket; 20421-draining holes; 2043-water receiving tank; 2044-filter bag; 2045-sedimentation tank; 2046-transfer mechanism I; 20461-prongs; 205-a shelf; 206-a second transferring mechanism; 207-anode plate assembly; 3-silver powder cleaning and drying device; 4-silver ingot casting device; 5-silver ingot polishing device; 6-silver ingot cleaning device; 7-a silver ingot marking device; 8-a weighing device; 9-a blanking and packaging device; 10-a storage device; 11-anode plate feeding hoister.

Detailed Description

As shown in fig. 1-9, the utility model comprises an anode plate manufacturing device 1, an electrolytic purification device 2, a silver ingot casting device 4 and a blanking and packing device 9 which are arranged in sequence.

The utility model converts the silver production from manual process to mechanical automation, including the whole process from raw materials to finished products, and is greatly helpful for production management and production security.

In the preferred embodiment: the device comprises a crucible 101, an anode plate continuous casting machine 102, a manipulator 103, a transfer trolley 104, an electrolytic purification device 2, a silver powder cleaning and drying device 3, a silver ingot casting device 4, a silver ingot polishing device 5, a silver ingot cleaning device 6, a silver ingot pressing and marking device 7, a weighing device 8, a blanking and packaging device 9 and a storage device 10 which are sequentially arranged.

The specific working process comprises the following steps:

the raw materials are added into a crucible 101 for smelting, and the silver melt is quantitatively cast into a chain machine mould through a rotating container of an anode plate continuous casting machine 102, so that the forming, cooling and demoulding are realized. The robot 103 picks up the anodes and loads them into anode bags to form an anode plate assembly 207 and delivers them to the anode plate feeding elevator 11 via a transfer cart 104 having a pallet 205.

The anode plate feeding lifter 11 conveys the anode plate assembly 207 to the electrolytic purification device, specifically to the position below the lifting and transferring device 201 through the second transferring mechanism 206, and conveys the anode plate assembly to the electrolytic tank 202 through the lifting and transferring device 201;

after the anode plate is diluted, the lifting and transferring device 201 grabs the anode bag to be inserted into the shelf 205, and the anode bag is conveyed to the anode bag cleaning machine for automatic cleaning through the second transferring mechanism 206, and finally enters the manipulator 103 side for loading the anode plate again;

the silver powder generated after electrolysis is fed into a powder discharging device 204 below the electrolytic bath through a pipeline.

The silver powder in the powder discharging device 204 is cleaned and then transferred to the silver powder cleaning and drying device 3 for drying, the silver powder is granulated, ingot casting is carried out through the silver ingot casting device 4 in sequence, the silver ingot polishing device 5 carries out silver ingot polishing, the silver ingot cleaning device 6 carries out silver ingot cleaning, surface detection, the silver ingot marking device 7 carries out silver ingot marking, the weighing device 8 carries out weighing and recording, the blanking packing device 9 carries out packing blanking, and the storage device 10 carries out storage and warehousing.

In addition, the electrolytic refining apparatus 2 specifically includes an electrolytic bath 202 and a lifting and transferring apparatus 201 for discharging and loading the electrolytic bath, where the lifting and transferring apparatus 201 includes a lifting mechanism and a first rail 2012, and the lifting mechanism can move along the first rail 2012 to above the electrolytic bath 202. The utility model is provided with a shelf 205 and a second transfer mechanism 206, wherein the shelf 205 is used for placing the anode plate assembly 207, the second transfer mechanism 206 can drive the shelf 205 to move to the side of the electrolytic bath 202 or below the lifting mechanism, and the second transfer mechanism 206 is preferably an AGV jacking transfer trolley which can jack up the shelf 205 and move the shelf 205.

After the anode plate in the electrolytic cell 202 is electrolyzed, the lifting mechanism moves to the position above the electrolytic cell 202 along the rail I2012 to lift the anode plate assembly 207 in the electrolytic cell 202, moves to the shelf 205 for placing the anode plate assembly 207 along the rail I2012, lifts the anode plate assembly 207 on the shelf 205 to be placed in the electrolytic cell 202 through the lifting mechanism, moves to the position above the electrolytic cell 202 and then places the anode plate assembly into the electrolytic cell 202 to perform a new round of electrolysis work, so as to realize the automatic discharging and loading of the anode plate assembly 207, and the manual discharging and loading of the anode plate assembly 207 after power failure are not needed, so that the electrolysis production efficiency and the automation degree are improved, and the potential safety hazard is also reduced.

The lifting transfer device further comprises a frame 2011, two rails 2013 and a water receiving tray 2016, wherein the first rail 2012 and the second rail 2013 are fixedly arranged on the frame 2011, the first rail 2012 and the second rail 2013 are arranged in parallel, the lifting mechanism comprises a frame 2014 and a lifting frame 2015, the frame 2014 can move along the first rail 2012, the lifting frame 2015 is arranged on the frame 2014, the lifting frame 2015 can move along the length direction of the first rail 2012 along with the frame 2014, the lifting frame 2015 can move along the direction perpendicular to the first rail 2012, and the water receiving tray 2016 can move below the lifting frame 2015 along the second rail 2013.

When the water collecting tray 2016 is used for containing liquid dripped by an object, and the liquid can be prevented from falling to a transfer path to cause pollution or corrosion in the transfer process. When the lifting mechanism performs the grooving operation of the anode plate assembly 207, the water receiving tray 2016 does not move along with the lifting mechanism. Compare in setting up the mode on hoist mechanism with water collector 2016, in this promotion moves and carries the device, hoist mechanism and water collector 2016 can remove in step but both are autonomous working, when need not to use water collector 2016, can remove hoist mechanism alone and carry out work, hoist mechanism's whole load is little, and hoist mechanism's size also can be done littleer simultaneously, and required when removing dodges the space for a short time, and application scope is bigger.

The lift truck 2015 includes a movable seat 20151, a hook 20152 and a drive which are rotatably arranged on the movable seat 20151, and a rotary drive component for rotating the hook 20152. During the use, the hoisting frame 2015 moves down the side that makes couple 20152 be located pole portion in the anode plate subassembly 207 subassembly, rotates through rotary drive subassembly drive couple 20152, changes couple 20152's crotch orientation, makes the crotch be located pole portion west, and couple 20152 catches on pole portion and makes when hoisting frame 2015 shifts up and mention anode plate subassembly 207 subassembly.

Wherein, rotation driving subassembly and couple 20152 set up respectively in the both sides that remove seat 20151, have seted up the mounting hole on removing seat 20151, and the mounting hole is passed and rotation driving subassembly is connected to the one end of couple 20152. Compared with the mode that the rotary driving assembly and the hook 20152 are arranged on the same side of the moving seat 20151, the utility model has more compact and reasonable structure, and meanwhile, the moving seat 20151 can also play a role in isolating the rotary driving assembly, so that the phenomenon that liquid below is splashed onto the rotary driving assembly to cause corrosion is avoided.

Couple 20152 is provided with the several, several couple 20152 sets up along interval on the same straight line, the rotary drive subassembly includes drive piece 20155, carriage release lever 20154 and several connecting rod 20153, the one end one-to-one respectively of several connecting rod 20153 is articulated with several couple 20152, several connecting rod 20153's the other end is articulated with carriage release lever 20154, drive piece 20155's output and carriage release lever 20154 are direct or indirect to be connected, remove or reset in order to promote carriage release lever 20154, thereby drive several couple 20152 simultaneously and rotate, consequently, can transport a plurality of anode plate subassembly 207 components simultaneously, and the work efficiency is improved. In the present invention, the driving member 20155 may be an air cylinder, an oil cylinder or an electric cylinder.

The utility model further comprises a first driving mechanism 2017, the first rail 2012 is a rack, the frame 2014 is rotatably provided with a transmission shaft 20141, the transmission shaft 20141 is fixedly provided with a gear 20142 meshed with the rack, preferably, the first driving mechanism 2017 is a motor, and the first driving mechanism 2017 is connected with the transmission shaft 20141 directly or through a transmission structure (such as a chain wheel assembly), so that the transmission shaft 20141 is driven to rotate, and the lifting mechanism is driven to integrally move along the first rail 2012. In order to improve the stability and reliability of the lifting mechanism during movement, the first rails 2012 are provided with two rails, the frame 2014 is arranged between the first rails 2012, and two ends of the transmission shaft 20141 are respectively provided with a gear 20142 which is respectively matched with the first rails 2012.

The water receiving tray 2016 is fixedly connected with the traction rope, and the water receiving tray 2016 is in sliding fit with the second track 2013. When the second driving mechanism 2018 drives the driving wheel to rotate, the traction rope drives the water receiving disc 2016 to move along the second track 2013.

In order to facilitate the cooperation, the connection of water collector 2016 and two 2013 of track and haulage rope, control water collector 2016 and hoist mechanism's difference in height simultaneously, guarantee that water collector 2016 can move to the hoist mechanism below, the side of water collector 2016 is provided with lengthened arm 20161, and lengthened arm 20161 upwards extends the setting, the one end tip that water collector 2016 was kept away from to lengthened arm 20161 rotates and is provided with the pulley, pulley and two 2013 sliding fit of track, and lengthened arm 20161 and haulage rope fixed connection.

In order to improve stability and reliability when the water collector 2016 removes, track two 2013 and drive assembly 2019 all are provided with two sets ofly, the water collector 2016 is located between two sets of track two 2013, drive assembly 2019, water collector 2016 both sides all are provided with extension arm 20161, the hoisting frame 2015 can pass between the extension arm of both sides follow 1, the extension arm 20161 that is located water collector 2016 both sides respectively with two sets of track two 2013 sliding fit, and be located the extension arm 20161 of water collector 2016 both sides and correspond with the haulage rope in two sets of drive assembly 2019 respectively and be connected.

The lifting mechanism also comprises a third driving mechanism, a guide hole is formed in the frame 2014 in the direction perpendicular to the first rail 2012, a guide rod is arranged on the moving seat 20151, the guide rod penetrates through the guide hole and is in sliding fit with the guide hole to guide the movement of the lifting frame 2015, the third driving mechanism can be an air cylinder, an oil cylinder or an electric cylinder, and the third driving mechanism is connected with one end, far away from the moving seat 2051, of the guide rod to drive the lifting frame 2015 to move up and down integrally. The utility model discloses in, going on of corresponding work is controlled in proper order by the controller to driving piece 20155, actuating mechanism one 2017, two 2018 of actuating mechanism, three and controller electric connection of actuating mechanism.

Go out powder device 204 and include discharging pipe 2041, connect material bucket 2042 and water receiving case 2043, the one end and the electrolysis trough 202 bottom intercommunication of discharging pipe 2041, the other end orientation connects material bucket 2042 to set up, and silver powder and electrolyte can follow discharging pipe 2041 directly to connect in the material bucket 2042 in the electrolysis trough 202, draining hole 20421 has been seted up to material receiving bucket 2042 bottom, and draining hole 20421 is used for discharging the electrolyte that connects in the material bucket 2042, separates silver powder, and connects material bucket 2042 to be located water receiving case 2043 top, and electrolyte drips to the water receiving case 2043 along draining hole 20421. Wherein, a valve is arranged on the bottom of the electrolytic cell 202 or one end of the discharge pipe 2041 connected with the electrolytic cell 202 to control the opening and closing of the electrolytic cell 202 and the discharge pipe 2041.

According to the electrolytic cell powder discharging device provided by the utility model, silver powder can be directly discharged into the material receiving barrel 2042 along the material discharging pipe 2041 for solid-liquid separation, and meanwhile, the material receiving barrel 2042 can directly collect the silver powder, so that the subsequent silver powder transferring operation is facilitated. Compared with the powder discharging mode by arranging a chain or belt type lifting mechanism in the electrolytic tank 202, the utility model has the advantages that the structure is simpler and more reliable, the internal space of the electrolytic tank 202 is not required to be occupied, the utilization rate of the internal space of the electrolytic tank 202 is higher, meanwhile, the silver powder can be prevented from being retained in the electrolytic tank 202 due to the resistance of the electrolyte, the silver powder can be discharged as much as possible through the discharge pipe 2041, and the powder discharging efficiency is higher.

The silver-containing material collecting device further comprises a filter bag 2044, the filter bag 2044 is sleeved in the material collecting barrel 2042, the material discharging pipe 2041 is arranged in the filter bag 2044, and the filter bag 2044 is arranged, so that efficient solid-liquid separation can be guaranteed, and meanwhile, silver powder is prevented from being discharged from the draining hole 20421 as far as possible.

Under the condition that the electrolytic cells 202 are sequentially provided with a plurality of discharging pipes 2041 each including a discharging main pipe 20411 and a plurality of discharging branch pipes 20412, one ends of the discharging branch pipes 20412 are correspondingly communicated with the bottoms of the electrolytic cells 202, the other ends of the discharging branch pipes 20411 are communicated with the discharging main pipe 20411, and one discharging end of the discharging main pipe 20411 faces the material receiving barrel 2042. So as to collect the silver powder discharged from the plurality of electrolytic tanks 202 at the same time.

In order to facilitate the discharge of the silver powder and the electrolyte, the discharge header 20411 is disposed obliquely. Under the embodiment that discharge main 20411 is the slope setting, discharge main 20411 is provided with the ejection of compact elbow towards the one end that connects storage bucket 2042 to ensure that electrolyte and silver powder arrange to connect storage bucket 2042 smoothly in.

The bottom of the electrolytic bath 202 is funnel-shaped, so that the electrolyte and the silver powder can be conveniently discharged.

The utility model further comprises a sedimentation tank 2045, the water receiving tank 2043 is communicated with the sedimentation tank 2045 through a pipeline, the electrolyte separated by the material receiving barrel 2042 and falling into the water receiving tank 2043 flows into the sedimentation tank 2045 through a pipeline and stands for subsequent use or treatment. The sedimentation tank 2045 is connected to the electrolytic cell 202 through a circulation pipe, and the electrolyte in the sedimentation tank 2045 can be discharged to the electrolytic cell 202 through the circulation pipe for recycling.

The utility model also comprises a first shifting mechanism 2046 for transferring the material receiving barrel 2042, wherein the first shifting mechanism 2046 is provided with a pallet fork 20461, and a space for the pallet fork 20461 to pass through is reserved between the material receiving barrel 2042 and the water receiving tank 2043. In the present invention, the transferring mechanism 2046 is preferably an AGV forklift, and after the powder discharge is completed, the transferring mechanism 2046 can lift the material receiving barrel 2042 by the fork 20461 and transfer the material receiving barrel to the next station.

The specific working principle of the outlet slot of the anode plate assembly 207 of the utility model is as follows: after the anode plate in the electrolytic tank 202 is electrolyzed, the lifting mechanism moves to the upper part of the electrolytic tank 202, the anode plate assembly 207 is lifted by the lifting frame 2015, the water receiving tray 2016 moves to the position of the lifting mechanism, and the water receiving tray 2016 is positioned below the anode plate assembly 207 to prevent the residual electrolyte drops on the anode plate assembly 207 from scattering. Then the lifting mechanism and the water receiving tray 2016 synchronously move to the right of the electrolytic bath 202 above the shelf 205, the water receiving tray 2016 moves to the left, the lifting frame 2015 descends, and the anode plate assembly 207 is placed on the empty shelf 205. And the second transferring mechanism 206 jacks up the lifting shelf 205, conveys the anode plate assembly 207 out of the tank to a cleaning work area, and realizes the work of cleaning, new anode plate hanging rack and the like by manual or special equipment.

The specific working principle of the anode plate assembly 207 in the groove is as follows: the second transfer mechanism 206 conveys the rack 205 with the anode plate assembly 207 to the right side of the electrolytic tank 202, the lifting frame 2015 lifts the anode plate assembly 207, conveys the anode plate assembly to the upper part of the empty electrolytic tank 202, then descends, hangs the anode plate assembly 207 on the electrolytic tank 202, and then resets and moves to the right side of the electrolytic tank 202 to finish the automatic tank loading action.

Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to imply that the scope of the application is limited to these examples; within the context of the present application, features from the above embodiments or from different embodiments may also be combined, steps may be implemented in any order, and there are many other variations of different aspects of one or more embodiments in the present application as described above, which are not provided in detail for the sake of brevity.

The one or more embodiments of the present application are intended to embrace all such alternatives, modifications and variances that fall within the broad scope of the present application. Therefore, any omissions, modifications, substitutions, improvements, and the like that may be made without departing from the spirit or scope of one or more embodiments of the present application are intended to be included within the scope of the present application.

Claims (10)

1. The utility model provides a silver automation line, characterized by, including anode plate manufacturing installation (1), electrolysis purification device (2), silver ingot casting device (4) and unloading packing apparatus (9) that set gradually, electrolysis purification device (2) include electrolysis trough (202) and be used for anode plate subassembly (207) to go out the promotion of groove, dress groove and move and carry device (201).

2. The automated silver production line according to claim 1, wherein the lifting and transferring device (201) comprises a lifting mechanism and a first rail (2012), and the lifting mechanism can move along the first rail (2012) to the position above the electrolytic bath (202).

3. The automated silver production line as claimed in claim 1, wherein the lifting and transferring device (201) further comprises a water receiving tray (2016) and a second rail (2013) parallel to the first rail (2012), the water receiving tray (2016) being movable along the second rail (2013) to a position below the lifting mechanism.

4. The silver automatic production line of claim 3, characterized in that, the lifting mechanism includes a carriage (2014) capable of moving along a first rail (2012) and a lifting frame (2015) arranged on the carriage (2014), the lifting frame (2015) includes a moving seat (20151), a hook (20152) and a rotary driving component, the rotary driving component and the hook (20152) are respectively arranged at two sides of the moving seat (20151), a mounting hole is arranged on the moving seat (20151), and one end of the hook (20152) passes through the mounting hole to be connected with the rotary driving component.

5. The silver automatic production line of claim 4, characterized in that, the couple (20152) is provided with a plurality, several couples (20152) are arranged along the same straight line at intervals, the rotary driving assembly comprises a driving part (20155), a moving rod (20154) and several connecting rods (20153), one end of several connecting rods (20153) is hinged with several couples (20152) correspondingly, the other end of several connecting rods (20153) is hinged with the moving rod (20154), and the driving part (20155) is used for pushing the moving rod (20154) to move.

6. The automatic silver production line according to claim 1, further comprising a powder discharging device (204), wherein the powder discharging device (204) comprises a material discharging pipe (2041), a material receiving barrel (2042) and a water receiving tank (2043), one end of the material discharging pipe (2041) is communicated with the bottom of the electrolytic cell (202), the other end of the material discharging pipe faces the material receiving barrel (2042), a draining hole (20421) is formed in the bottom of the material receiving barrel (2042), and the material receiving barrel (2042) is located above the water receiving tank (2043).

7. The automatic silver production line according to any one of claims 1 to 6, wherein the anode plate manufacturing device (1) comprises a crucible (101), an anode plate continuous casting machine (102), a robot (103) and a transfer trolley (104).

8. The automatic silver production line according to any one of claims 1 to 6, wherein a silver powder cleaning and drying device (3) is further arranged between the electrolytic purification device (2) and the silver ingot casting device (4).

9. The silver automatic production line according to any one of claims 1 to 6, characterized in that a silver ingot polishing device (5), a silver ingot cleaning device (6), a silver ingot marking device (7) and a weighing device (8) are sequentially arranged between the electrolytic purification device (2) and the blanking and packing device (9).

10. The silver automatic production line according to any one of claims 1 to 6, characterized in that a storage device (10) is arranged after the blanking and packing device (9).

Images