CN217411700U - Electrolysis trough anode mud cleaning treatment system - Google Patents

Abstract

The utility model discloses an electrolysis trough anode mud cleaning treatment system, including the rotatory liquid mechanism that falls of kerve, with the rotatory cylinder rotary screen who falls liquid mechanism intercommunication of kerve, the export of cylinder rotary screen sediment thick liquid passes through pipeline and pressure filter feed inlet intercommunication, the slag notch and the positive pole sediment collecting box intercommunication of cylinder rotary screen, the filtrate export and the positive pole liquid transfer pond entry intercommunication of pressure filter, the filter press bottom is equipped with the positive pole sediment collection subassembly that is used for receiving the filter cake, the rotatory liquid mechanism that falls of backflow pipeline intercommunication kerve is passed through in the export of positive pole liquid transfer pond, is equipped with the pump on the backflow pipeline. The utility model discloses well system greatly reduced intensity of labour, and realized solid-liquid separation, the liquid of isolating washs the rotatory liquid mechanism of falling of kerve, has reduced the use amount of water.

Description

Electrolysis trough anode mud cleaning treatment system

Technical Field

The utility model relates to an electrolysis trough anode slime handles the field, especially relates to an electrolysis trough anode slime cleaning and processing system.

Background

In the industrial production of electrolytic manganese, about 100Kg of anode mud is generated when 1 ton of manganese is produced, in order to realize high-efficiency production, an electrolytic tank must be cleaned regularly, the general cleaning period is 10-15 days, anode slag is directly discharged to an anode ditch when the electrolytic tank is cleaned in an electrolytic workshop, large particles are shoveled out manually, and fine anode slag enters an anode liquid pool along with anode liquid, so that complete solid-liquid separation is not achieved. The anode slag is not thoroughly cleaned by the treatment method, part of the anode slag flows to the anode tank, so that the tank body is blocked, the anode liquid tank expands, the solid-liquid separation is not thorough, and the water content of the anode slag is high.

A cleaning system capable of quickly separating and cleaning the anode mud of the electrolytic cell is urgently needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an electrolysis trough anode slime cleaning and processing system.

The utility model discloses an innovation point lies in the utility model discloses well system greatly reduced intensity of labour, and realized solid-liquid separation, the liquid of isolating washs the rotatory liquid mechanism of falling of kerve, has reduced the use amount of water.

In order to realize the purpose of the utility model, the technical proposal of the utility model is that: the utility model provides an electrolysis trough anode mud washs processing system, includes the rotatory liquid mechanism that falls of kerve, and the rotatory rotary drum sieve that falls liquid mechanism intercommunication of kerve, the export of rotary drum sieve sediment thick liquid passes through pipeline and pressure filter feed inlet intercommunication, the slag notch and the positive pole sediment collecting box intercommunication of rotary drum sieve, the filtrate export and the positive pole liquid transfer pond entry intercommunication of pressure filter, the filter press bottom is equipped with the positive pole sediment collection subassembly that is used for receiving the filter cake, the positive pole liquid transfer pond export is equipped with the pump through the rotatory liquid mechanism that falls of backflow pipeline intercommunication kerve on the backflow pipeline.

Further, the rotary bottom groove liquid pouring mechanism comprises a bottom groove support frame and a liquid receiving pool located below the bottom groove support frame, a driving assembly for driving the bottom groove support frame to rotate is arranged on the bottom groove support frame, and more than two groups of locking assemblies used for locking the bottom groove are further arranged on the top surface of the bottom groove support frame.

Furthermore, the locking assembly comprises side brackets positioned at two side edges of the bottom groove supporting frame, top brackets are hinged to the tops of the side brackets, and two free end parts of the two top brackets are locked through locking parts.

Furthermore, one or two top supports in each group of locking assemblies are provided with waist-shaped holes arranged along the length direction of the top supports, each locking assembly comprises a sleeve sleeved at the free end parts of the two top supports, each sleeve is provided with a sliding block sliding in the waist-shaped hole on one top support, each sleeve is also provided with a threaded hole, a jacking screw is screwed in each threaded hole, and the end part of each jacking screw is provided with a pressing plate; when the sliding block slides to the end part of the waist-shaped hole at the position close to the free end part of one top bracket, the sleeve is sleeved on the other top bracket; when the sliding block slides to the end part of the waist-shaped hole at the position of the free end part far away from one top bracket, the sleeve leaves the other top bracket. The bottom groove is convenient and quick to fix and open.

Furthermore, one or two top supports in each group of locking assemblies are provided with waist-shaped holes arranged along the length direction of the top supports, each locking assembly comprises a sleeve sleeved at the free end parts of the two top supports, each sleeve is provided with a sliding block sliding in the waist-shaped hole on one top support, each sleeve is also provided with a threaded hole, a jacking screw is screwed in each threaded hole, when the sleeves are sleeved at the free end parts of the two top supports, a space is reserved between the free end parts of the two top supports, and the jacking screws can be screwed in the spaces between the free end parts of the two top supports; when the sliding block slides to the end part of the waist-shaped hole at the position close to the free end part of one top bracket, the sleeve is sleeved on the other top bracket; when the sliding block slides to the end part of the waist-shaped hole at the position of the free end part far away from one top bracket, the sleeve leaves the other top bracket. The bottom groove is convenient and quick to fix and open.

Furthermore, a discharge branch pipe is arranged on the return pipeline. Part of the separated liquid is used for reproduction.

Further, a liquid outlet is formed in one end of the liquid receiving pool, a diversion liquid hopper is arranged at the liquid outlet and is communicated with the roller rotary screen through a pipeline.

Furthermore, a liquid receiving hopper is arranged at the outlet of the roller rotary screen slag slurry, the outlet of the liquid receiving hopper is communicated with a filter press through a pipeline, and an overflow port of the liquid receiving hopper is communicated with an anolyte transit pool through a pipeline. The workload of the filter press is reduced.

The utility model has the advantages that:

1. the utility model provides a system greatly reduced intensity of labour, and realized solid-liquid separation, the liquid of isolating washs the rotatory liquid mechanism of falling of kerve, has reduced the use amount of water.

2. The utility model discloses well electrolysis trough bottom tank emptys through rotary mechanism, and is convenient quick, the labour that has significantly reduced has reduced intensity of labour.

3. The equipment in the utility model realizes the ordered production in the electrolysis workshop, and the environment is clean and tidy.

Drawings

FIG. 1 is a flow chart of example 1.

FIG. 2 is a flowchart of example 2.

FIG. 3 is a schematic structural view of a bottom tank rotating liquid pouring mechanism.

FIG. 4 is a schematic view of the bottom tank rotating pouring mechanism with the liquid receiving tank removed.

Fig. 5 is a schematic structural view of the locking assembly.

Fig. 6 is a schematic view showing the structure of the locker of embodiment 1.

FIG. 7 is a schematic view showing the structure of a locker according to embodiment 2.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings.

Example 1: as shown in fig. 1, 3, 4, 5 and 6, the electrolytic bath anode mud cleaning treatment system comprises a bottom tank rotating liquid pouring mechanism 1 and a roller rotating sieve 2 communicated with the bottom tank rotating liquid pouring mechanism 1, wherein a liquid outlet 1.5 is arranged at one end of a liquid receiving tank 1.2, a diversion liquid hopper 11 is arranged at the position of the liquid outlet 1.5, and the diversion liquid hopper 11 is communicated with the roller rotating sieve 2 through a pipeline. 2 sediment thick liquids of cylinder rotary screen export is through pipeline and 3 feed inlets of pressure filter intercommunication, 2 slag notch and the 4 intercommunications of positive pole sediment collecting box of cylinder rotary screen, the filter liquor export of pressure filter 3 and the 5 entrys of positive pole liquid transfer pond intercommunication, 3 bottoms of pressure filter are equipped with the positive pole sediment collection subassembly 6 that is used for receiving the filter cake, the rotatory mechanism 1 that falls of liquid of return line 7 intercommunication kerve is passed through in the export of positive pole liquid transfer pond 5, be equipped with pump 9 on the return line 7, be equipped with on the return line 7 and discharge branch pipe 10.

The rotary bottom groove liquid pouring mechanism 1 comprises a bottom groove support frame 1.1 and a liquid receiving pool 1.2 positioned below the bottom groove support frame 1.1, a driving assembly 1.3 for driving the bottom groove support frame 1.1 to rotate is arranged on the bottom groove support frame 1.1, a support frame 1.5 is arranged above the liquid receiving pool 1.2, rotating shafts are arranged at two ends of the bottom groove support frame 1.1, a bearing seat for fixing the rotating shafts is arranged on the support frame 5, and the rotating shafts 1.1 are connected with the bearing seat through bearings; the drive assembly 1.3 is a motor. The top surface of the bottom groove support frame 1.1 is also provided with more than two groups of locking assemblies 1.4 for locking the bottom groove, each locking assembly 1.4 comprises side supports 1.41 positioned at two side edges of the bottom groove support frame 1.1, the tops of the side supports 1.41 are hinged with top supports 1.42, two free end parts of the two top supports 1.42 are locked through locking pieces 1.43, one top support 1.42 or the two top supports 1.42 in each group of locking assemblies 1.4 is provided with a waist-shaped hole 1.44 arranged along the length direction of the top support 1.42, each locking assembly 1.4 comprises a sleeve 1.45 sleeved at the free end part of the two top supports 1.42, the sleeve 1.45 is provided with a sliding block 1.46 sliding in the waist-shaped hole 1.44 on one top support 1.42, the sleeve 1.45 is also provided with a threaded hole 1.47, a jacking screw 1.48 is screwed in the threaded hole 1.47, and the end part of the jacking screw 1.48 is provided with a pressing plate 1.49; when the sliding block 1.46 slides to the end part of the waist-shaped hole 1.44 at the position close to the free end part of one top bracket, the sleeve 1.45 is sleeved on the other top bracket; when the sliding block 1.46 is slid to the end of one top bracket 1.42 away from the kidney-shaped hole 1.44 at the free end, the sleeve 1.45 leaves the other top bracket 1.42.

When in work: pouring the anode mud out through a bottom tank rotating liquid pouring mechanism 1, introducing the anode mud into a roller rotating sieve 2 for screening, and collecting coarse slag which is screened by the roller rotating sieve 2 and is larger than 1.0 mm; pumping the residue slurry which is screened by the roller rotary screen 2 and is less than or equal to 1.0mm into a filter press 3 by a slurry pump 8, collecting filter liquor after filter pressing into an anolyte transfer pool 5, collecting filter cakes, and pumping the filter liquor in the anolyte transfer pool 5 into a bottom tank rotary liquor pouring mechanism 1 by a pump 9 to clean the bottom tank rotary liquor pouring mechanism 1. Draining the collected coarse slag, and sending the drained coarse slag and the collected filter cake to an anode reservoir; part of the filtrate in the anolyte transfer tank is discharged into the anode ditch through a discharge branch pipe 10.

When the bottom groove on the bottom groove rotating liquid pouring mechanism 1 is installed, the diaphragm frame above the bottom groove is detached, the locking assembly 1.4 is locked, during locking, only the sleeve 1.45 needs to be moved to wrap the end parts of the two top supports 1.42, the jacking screw 1.48 is jacked, and the pressing plate presses the two top supports 1.42.

Example 2: as shown in fig. 2, 3, 4, 5 and 7, the electrolytic bath anode mud cleaning treatment system comprises a bottom tank rotating liquid pouring mechanism 1 and a roller rotating sieve 2 communicated with the bottom tank rotating liquid pouring mechanism 1, wherein a liquid outlet 1.5 is arranged at one end of a liquid receiving tank 1.2, a diversion liquid hopper 11 is arranged at the position of the liquid outlet 1.5, and the diversion liquid hopper 11 is communicated with the roller rotating sieve 2 through a pipeline. 2 sediment thick liquid exits of cylinder rotary screen are equipped with and receive liquid fill 12, it passes through pipeline and pressure filter 3 intercommunication to receive the export of liquid fill 12, the overflow mouth that receives liquid fill 12 passes through pipeline and 5 intercommunications in the positive pole liquid transfer pond, the slag notch and the positive pole sediment collecting box 4 intercommunications of cylinder rotary screen 2, the filtrating export and the 5 entrys in the positive pole liquid transfer pond intercommunication of pressure filter 3, the 3 bottoms of pressure filter are equipped with the positive pole sediment collection subassembly 6 that is used for receiving the filter cake, the rotatory mechanism 1 of falling liquid of return line 7 intercommunication kerve is passed through in the export of positive pole liquid transfer pond 5, be equipped with pump 9 on the return line 7, be equipped with emission branch pipe 10 on the return line 7.

The rotary bottom groove liquid pouring mechanism 1 comprises a bottom groove support frame 1.1 and a liquid receiving pool 1.2 positioned below the bottom groove support frame 1.1, a driving assembly 1.3 for driving the bottom groove support frame 1.1 to rotate is arranged on the bottom groove support frame 1.1, a support frame 1.5 is arranged above the liquid receiving pool 1.2, rotating shafts are arranged at two ends of the bottom groove support frame 1.1, a bearing seat for fixing the rotating shafts is arranged on the support frame 5, and the rotating shafts 1.1 are connected with the bearing seat through bearings; the drive assembly 1.3 is a motor. The top surface of the bottom groove support frame 1.1 is also provided with more than two groups of locking assemblies 1.4 for locking the bottom groove, each locking assembly 1.4 comprises side brackets 1.41 positioned at two side edges of the bottom groove support frame 1.1, the top parts of the side brackets 1.41 are hinged with top brackets 1.42, two free end parts of the two top brackets 1.42 are locked through locking parts 1.43, one top bracket 1.42 or the two top brackets 1.42 in each group of locking assemblies 1.4 is provided with a waist-shaped hole 1.44 arranged along the length direction of the top bracket 1.42, each locking assembly 1.4 comprises a sleeve 1.45 sleeved at the free end part of the two top brackets 1.42, the sleeve 1.45 is provided with a slide block 1.46 sliding in the waist-shaped hole 1.44 on one top bracket 1.42, the sleeve 1.45 is also provided with a threaded hole 1.47, a jacking screw 1.48 is screwed in the threaded hole 1.47, and the sleeve 1.45 is sleeved at the free end parts of the two top brackets 1.42, a space is reserved between the free end parts of the two top supports 1.42, and the jacking screws 1.48 can be screwed into the space between the free end parts of the two top supports 1.42; when the sliding block 1.46 slides to the end part of the waist-shaped hole 1.44 at the position of the free end part of one top bracket 1.42, the sleeve 1.45 is sleeved on the other top bracket 1.42; when the slide block 1.46 slides to the end of one top bracket 1.42 far away from the kidney-shaped hole 1.44 at the free end, the sleeve 1.45 leaves the other top bracket 1.42.

When in work: pouring the anode mud out through a bottom tank rotating liquid pouring mechanism 1, introducing the anode mud into a roller rotating sieve 2 for screening, and collecting coarse slag which is screened by the roller rotating sieve 2 and is larger than 1.0 mm; the method comprises the steps of firstly introducing the supernatant of a liquid receiving bucket 12 into an anolyte transfer pool 5 through the liquid receiving bucket 12 by using the residue slurry which is screened by a roller rotary screen 2 and is less than or equal to 1.0mm, pumping the anode mud at the liquid receiving bucket 12 into a filter press 3 through a mud pump 8, converging the filter-pressed filtrate into the anolyte transfer pool 5, collecting filter cakes, and pumping the filtrate in the anolyte transfer pool 5 into a bottom tank rotary liquid pouring mechanism 1 through a pump 9 to clean the bottom tank rotary liquid pouring mechanism 1. Draining the collected coarse slag, and sending the drained coarse slag and the collected filter cake to an anode reservoir; part of the filtrate in the anolyte transfer tank is discharged into the anode ditch through a discharge branch pipe 10.

When the bottom groove on the bottom groove rotary liquid pouring mechanism 1 is installed, the diaphragm frame above the bottom groove is detached, the locking assembly 1.4 is locked, and when the locking assembly is locked, the sleeve 1.45 is only required to be moved to wrap the end parts of the two top supports 1.42, and the jacking screws 1.48 are screwed into the space between the two top supports 1.42.

The described embodiments are only some, but not all embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Claims (8)

1. The utility model provides an electrolysis trough anode mud cleaning treatment system, its characterized in that, includes that the kerve is rotatory to fall liquid mechanism, and the rotatory cylinder rotary screen who falls liquid mechanism intercommunication of kerve, the export of cylinder rotary screen sediment thick liquid passes through pipeline and pressure filter feed inlet intercommunication, the slag notch and the positive pole sediment collecting box intercommunication of cylinder rotary screen, the filter liquor export and the positive pole liquid transfer pond entry intercommunication of pressure filter, the filter press bottom is equipped with the positive pole sediment collection subassembly that is used for receiving the filter cake, the rotatory liquid mechanism that falls of return line intercommunication kerve is passed through in the export of positive pole liquid transfer pond, is equipped with the pump on the return line.

2. The cleaning and processing system for the anode mud of the electrolytic cell as recited in claim 1, wherein the bottom tank rotating and pouring mechanism comprises a bottom tank supporting frame and a liquid receiving tank located below the bottom tank supporting frame, the bottom tank supporting frame is provided with a driving assembly for driving the bottom tank supporting frame to rotate, and the top surface of the bottom tank supporting frame is further provided with more than two groups of locking assemblies for locking the bottom tank.

3. The cleaning and processing system for anode mud of the electrolytic cell as claimed in claim 2, wherein the locking assembly comprises side brackets positioned at two side edges of the bottom cell support frame, top brackets are hinged at the tops of the side brackets, and two free ends of the top brackets are locked through locking pieces.

4. The electrolytic cell anode slime cleaning and processing system according to claim 3, wherein one or both top brackets in each set of locking assemblies are provided with waist-shaped holes arranged along the length direction of the top brackets, each locking assembly comprises a sleeve sleeved at the free end parts of the two top brackets, the sleeve is provided with a slide block sliding in the waist-shaped hole on one of the top brackets, the sleeve is further provided with a threaded hole, a puller screw is screwed in the threaded hole, and the end part of the puller screw is provided with a pressing plate; when the sliding block slides to the end part of the waist-shaped hole at the position close to the free end part of one top bracket, the sleeve is sleeved on the other top bracket; when the sliding block slides to the end part of the waist-shaped hole at the position of the free end part far away from one top bracket, the sleeve leaves the other top bracket.

5. The electrolytic cell anode mud cleaning treatment system according to claim 3, wherein one or two top supports in each group of locking assemblies are provided with waist-shaped holes arranged along the length direction of the top supports, each locking assembly comprises a sleeve sleeved at the free end parts of the two top supports, each sleeve is provided with a sliding block sliding in the waist-shaped hole on one of the top supports, each sleeve is further provided with a threaded hole, a jacking screw is screwed in each threaded hole, when the sleeve is sleeved at the free end parts of the two top supports, the free end parts of the two top supports are spaced, and each jacking screw can be screwed in the space between the free end parts of the two top supports; when the sliding block slides to the end part of the waist-shaped hole at the position close to the free end part of one top bracket, the sleeve is sleeved on the other top bracket; when the sliding block slides to the end part of the waist-shaped hole at the position of the free end part far away from one top bracket, the sleeve leaves the other top bracket.

6. The electrolytic cell anode slime cleaning and processing system according to claim 1, wherein said return line is provided with a drain branch.

7. The cleaning treatment system for the anode mud of the electrolytic cell as recited in claim 2, wherein a liquid outlet is provided at one end of the liquid receiving tank, a diversion liquid hopper is provided at the liquid outlet, and the diversion liquid hopper is communicated with the rotary drum screen through a pipeline.

8. The electrolytic cell anode slime cleaning and processing system according to claim 1, wherein a liquid receiving hopper is arranged at an outlet of the rotary drum sieve residue slurry, an outlet of the liquid receiving hopper is communicated with a filter press through a pipeline, and an overflow port of the liquid receiving hopper is communicated with an anode liquid transfer pool through a pipeline.

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