CN211488530U - A high-efficient multistage shale shaker for electrolytic aluminum carbon sediment discarded object - Google Patents

Abstract

The utility model discloses a high-efficient multistage shale shaker for electrolytic aluminum carbon sediment discarded object belongs to the high-efficient multistage shale shaker technical field of electrolytic aluminum carbon sediment discarded object, including the sieve case, spout b has been seted up to the sieve case, spout b sliding connection has bank of screens a, can dismantle in the bank of screens a and be connected with screen cloth an, screen cloth an is located the mounting groove, bank of screens a surface is seted up to the mounting groove, the mounting groove inwards extends flutedly, screw gap connection is passed through in the inside of sieve case to bank of screens an and bank of screens b both sides, clearance connection has screen cloth b in the bank of screens b, bank of screens b sliding connection has spout an, spout an is seted up in the bottom of the screen case portion. The screen mesh is fixed on the screen frame, the screen frame slides along the upper chute of the screen box and is fixed through screws at two sides, so that the screen mesh is convenient to disassemble and use; the air drives the aluminium granule and moves to the left through oblique mouthful oblique spraying on the screen cloth in the screening process, can avoid the filter screen to block up, and is quick screens the aluminium ash.

Description

A high-efficient multistage shale shaker for electrolytic aluminum carbon sediment discarded object

The technical field is as follows:

the utility model relates to an efficient multistage vibrating screen technical field of electrolytic aluminum carbon residue discarded object especially relates to an efficient multistage vibrating screen for electrolytic aluminum carbon residue discarded object.

Background art:

carbon slag, aluminum ash and overhaul slag are generated in the production process of the electrolytic aluminum industry, and cyanide and fluoride contained in the three materials are listed in the list of dangerous solid waste. The industry has not been provided with mature technology and corresponding professional equipment for many years for disposal, and aluminum ash produces aluminum particles, ammonia water and calcium aluminate balls after crushing, grinding, sorting, denitrifying and flotation impurity removal in the waste disposal process. The ground powder is sorted by a multistage vibrating screen

The prior art multistage vibrating screen has the following disadvantages: 1. after a large amount of aluminum ash is screened by the multistage vibrating screen, the screen is damaged, most of the screen is fixed on the screen box, the screen is not easy to disassemble and replace, and the damaged screen needs a large amount of time to replace, so that the use is inconvenient; 2. in the screening process, aluminum particles are accumulated on a screen to be blocked, so that the subsequent screening of aluminum ash is influenced, and the screening efficiency is low.

The utility model has the following contents:

the utility model aims at providing an efficient multistage vibrating screen for electrolytic aluminum carbon residue waste, wherein a screen mesh is fixed on a screen frame, and the screen frame slides along an upper chute of a screen box and is fixed by screws at two sides, so that the screen frame is convenient to disassemble and use; the air drives the aluminium granule and moves to the left on spouting the screen cloth to one side through the bevel connection in the screening process, can avoid the filter screen to block up, and is quick to the aluminium ash screening to solve prior art not enough.

The utility model discloses by following technical scheme implement:

the utility model provides an efficient multistage vibrating screen for electrolytic aluminum carbon residue waste, which comprises a screen box, the screen box is provided with a chute b, the chute b is connected with a screen frame a in a sliding way, a screen mesh a is detachably connected in the screen frame a, the screen a is positioned in an installation groove, the installation groove is arranged on the surface of the screen frame a, the installation groove extends inwards to form a groove, the two sides of the sieve frame a and the sieve frame b are connected with the inside of the sieve box through screws in a clearance way, a sieve mesh b is connected with the inside of the sieve frame b in a clearance way, the screen frame b is connected with a chute a in a sliding way, the chute a is arranged at the bottom of the screen box, the air injection pipes are bonded above the right sides of the screen frame a and the screen frame b, the air jet system is characterized in that an inclined opening is formed in the left side of the air jet pipe, an air inlet of the air jet pipe extends to the inside of the air delivery pipe through a sprayer, the bottom end of the air delivery pipe is detachably connected with an air blower, and the sprayer is inserted into the right side of the screen box.

Optionally, a vibrating motor is installed at the bottom of the screen box, and supports are welded on two sides of the bottom end of the screen box.

Optionally, the sieve frame a is located below the box door a, and the sieve frame b is located below the box door c.

Optionally, a box door b is detachably connected to the bottom of the screen box.

Optionally, the current input ends of the blower and the vibration motor are electrically connected with an external power supply through a lead.

Optionally, the right sides of the sieve frame a and the sieve frame b are fixedly connected with a push plate.

The utility model has the advantages that:

the embodiment of the utility model provides an efficient multistage shale shaker for electrolysis aluminium carbon sediment discarded object:

1. the screen mesh is fixed on the screen frame, the screen frame slides along the upper chute of the screen box and is fixed through screws at two sides, so that the screen mesh is convenient to disassemble and use; the screen cloth is fixed in mounting groove on the bank of screens, has seted up the spout in the sieve case, and the bank of screens can be fixed the screen cloth in the sieve incasement along the spout inside slip, inwards screws up sieve case both sides screw, and the screw can fasten the bank of screens in the sieve incasement after passing sieve case and bank of screens, can unscrew the screw after the screen cloth damages, and the bank of screens is taken out and is changed, and the dismantlement time is short, convenient to use.

2. The air drives the aluminium granule and moves to a left side through spouting the screen cloth to one side to the bevel connection in the screening process, can avoid the filter screen to block up, quick screening the aluminium ash, aluminium granule piles up on the filter screen after the screening a period of time, the air-blower starts and lasts to blowing in the gas transmission pipe, the air is blown to the jet-propelled intraductal shower nozzle on the gas transmission pipe, the air drives the filter screen on the filter screen to the bevel connection to one side aluminium granule roll left along the filter screen, can avoid the filter screen to block up, last efficient screening aluminium ash process.

Description of the drawings:

in order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of an efficient multistage vibrating screen for electrolyzing aluminum carbon residue waste.

Fig. 2 is a schematic structural diagram of a screen frame of the efficient multistage vibrating screen for electrolyzing aluminum carbon residue waste of the utility model.

Fig. 3 is a schematic structural diagram of the connection of the screen frames of the efficient multistage vibrating screen for electrolyzing aluminum carbon residue waste of the utility model.

Fig. 4 is a schematic circuit diagram of the efficient multistage vibrating screen for electrolyzing aluminum carbon residue waste of the present invention.

1. A screen box; 2. a screen mesh a; 3. a box door a; 4. a screen frame a; 5. a gas ejector tube; 6. a spray head; 7. a screw; 8. a gas delivery pipe; 9. a bevel opening; 10. a chute a; 11. a screen frame b; 12. a blower; 13. a support; 14. a vibration motor; 15. a box door b; 16. a screen b; 17. a box door c; 18. mounting grooves; 19. a groove; 20. pushing the plate; 21. and a chute b.

The specific implementation mode is as follows:

the technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1 to 4, an embodiment of the present invention provides an efficient multistage vibrating screen for electrolytic aluminum carbon residue waste, which comprises a screen box 1, wherein the screen box 1 is provided with a sliding groove b21, a sliding groove b21 is slidably connected with a screen frame a4, a screen mesh a2 is detachably connected in the screen frame a4, the screen mesh a2 is located in a mounting groove 18, the mounting groove 18 is arranged on the surface of a screen frame a4, the mounting groove 18 is inwardly extended with a groove 19, two sides of the screen frame a4 and the screen frame b11 are connected inside the screen box 1 through a screw 7, a screen mesh b16 is connected in a screen frame b11 through a gap, the screen frame b11 is slidably connected with the sliding groove a10, the sliding groove a10 is arranged at the bottom of the screen box 1, a pipe 5 is arranged above the right side of the screen frame a4 and the screen frame b11 in an adhering manner, an oblique port 9 is arranged on the left side of the air injection pipe 5, the air injection pipe extends to the inside of an air, the bottom end of the gas pipe 8 is detachably connected with a blower 12, and the spray head 6 is inserted on the right side of the sieve box 1.

Illustratively, the screen box 1 comprises a screen frame a4, a screen frame b11 and an air injection pipe 5, the screen frame a4 and the screen frame b11 have the same structure, the screen hole a2 arranged on the screen frame a4 is slightly larger than the screen hole b16 arranged on the screen frame b11, an inclined opening 9 formed in the left side of the air injection pipe 5 inclines downwards at a certain angle, the sprayed air is obliquely sprayed onto the screen frame to drive aluminum particles on the screen frame to slide towards the left side, a box door connected to the screen box 1 can be detached, and the box door can be opened to take out articles in the screen box 1 when the screen box is used.

Referring to fig. 1, a vibration motor 14 is installed at the bottom of the screen box 1, and brackets 13 are welded to both sides of the bottom end of the screen box 1.

For example, after the vibrating motor 14 is powered on, the vibrating motor generates vibration to drive the whole screen box 1 to vibrate for screening, and the support 13 provides support for the screen box 1.

Referring to fig. 1, the screen frame a4 is positioned below the door a3, and the screen frame b11 is positioned below the door c 17.

For example, door a3 may be opened to remove slightly larger aluminum particles from screen a2, and door c17 may be opened to remove small particles of aluminum from screen b 16.

Referring to fig. 1 and 2, a box door b15 is detachably connected to the bottom of the screen box 1, and a push plate 20 is fixedly connected to the right side of the screen frame a4 and the screen frame b 11.

For example, the bottom of the screen box 1 can be removed from the screen box 1 by opening the door b15, and the screen frame a4 and the screen frame b11 can be fixed by the push plate 20.

Referring to fig. 4, the current input terminals of the blower 12 and the vibration motor 14 are electrically connected to an external power source through wires.

Illustratively, an external power source provides power to the blower 12 and the vibration motor 14.

When the aluminum ash screening machine is used, power is supplied by an external power supply, aluminum ash in dangerous solid waste is crushed by a hammer crusher and a dry ball mill and then ground into powder, the powdery aluminum ash is slowly added into a screen box 1, a vibration motor 14 is started in the adding process, the model of the vibration motor 14 is YZS, the vibration motor 14 generates vibration to drive the screen box 1 to vibrate integrally, the screen box 1 vibrates to drive a screen frame a4 and a screen frame b11 in the screen box 1 to vibrate, the aluminum ash enters the screen box 1 and is contacted with a screen a2 on a screen frame a4 before entering the screen box 1, large-particle aluminum is left on a screen a2 without passing through a screen a2, when the aluminum ash continuously advances downwards and passes through a screen frame b11, small-particle aluminum in the aluminum ash is left on a screen b16, the aluminum ash continuously moves downwards at the bottom of the screen box 1, the aluminum particles are accumulated on the surface of the screen to obstruct subsequent aluminum ash screening, at the moment, the blower 12 is started and blows outwards, the model of the blower is DLS, air-blower 12 is connected with gas-supply pipe 8, the air that air-blower 12 blew out spouts in the jet-propelled pipe 5 through shower nozzle 6 on the gas-supply pipe 8, the air is blown to the screen cloth slope through bevel connection 9 and is driven the aluminium granule and remove to the left side, avoid the aluminium granule to pile up and cause the jam, open the chamber door after the sieve is got and take out the aluminium granule and the aluminium ash after the screening, the screen cloth damages after using for a long time, unscrew screen box 1 and go up the fixed screw 7 in screen frame both sides, screw 7 is unscrewed and then outside pull push pedal 20 can be from screen box 1 interior roll-off to the screen frame, can change the screen frame after the screen frame roll-off, can clear up the screen cloth after shifting out the screen frame with the same reason, can be fixed through screw 7 after the screen frame slides into screen box 1 after changing or.

The utility model relates to an efficient multistage vibrating screen for electrolytic aluminum carbon residue waste, which comprises a screen box 1; 2. a screen mesh a; 3. a box door a; 4. a screen frame a; 5. a gas ejector tube; 6. a spray head; 7. a screw; 8. a gas delivery pipe; 9. a bevel opening; 10. a chute a; 11. a screen frame b; 12. a blower; 13. a support; 14. a vibration motor; 15. a box door b; 16. a screen b; 17. a box door c; 18. mounting grooves; 19. a groove; 20. pushing the plate; 21. the chute b and the components are all universal standard parts or components known to those skilled in the art, and the structure and the principle of the chute b are known to those skilled in the art through technical manuals or through routine experiments.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The utility model provides a high-efficient multistage shale shaker for electrolytic aluminum carbon sediment discarded object, includes sieve case (1), its characterized in that, spout b (21) have been seted up to sieve case (1), spout b (21) sliding connection has bank a (4), can dismantle in bank a (4) and be connected with screen cloth a (2), screen cloth a (2) are located mounting groove (18), mounting groove (18) are seted up in bank a (4) surface, mounting groove (18) inwards extend fluted (19), the inside of bank a (4) and bank b (11) both sides through screw (7) clearance connection in sieve case (1), bank b (11) internal clearance connection has screen cloth b (16), bank b (11) sliding connection has spout a (10), spout a (10) are seted up in sieve case (1) bottom, all there is jet-propelled pipe (5) above bank a (4) and bank b (11) right side, oblique mouth (9) have been seted up on jet-propelled pipe (5) left side, the air inlet of jet-propelled pipe (5) passes through shower nozzle (6) and extends to the inside of gas-supply pipe (8), gas-supply pipe (8) bottom can be dismantled and be connected with air-blower (12), shower nozzle (6) are pegged graft on sieve case (1) right side.

2. The efficient multistage vibrating screen for the electrolytic aluminum carbon residue waste is characterized in that a vibrating motor (14) is installed at the bottom of the screen box (1), and supports (13) are welded on two sides of the bottom end of the screen box (1).

3. The efficient multistage vibrating screen for electrolytic aluminum carbon residue waste as claimed in claim 1, wherein the screen frame a (4) is located below the box door a (3), and the screen frame b (11) is located below the box door c (17).

4. The efficient multistage vibrating screen for the electrolytic aluminum carbon residue waste as claimed in claim 1, wherein the bottom of the screen box (1) is detachably connected with a box door b (15).

5. The efficient multistage vibrating screen for the electrolytic aluminum carbon residue waste as claimed in claim 1, wherein the current input ends of the blower (12) and the vibrating motor (14) are electrically connected with an external power supply through conducting wires.

6. The efficient multistage vibrating screen for the electrolytic aluminum carbon residue waste as claimed in claim 4, wherein the right sides of the screen frames a (4) and b (11) are fixedly connected with a push plate (20).

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