CN210426067U

CN210426067U - Aluminum ingot feeding device

Info

Publication number: CN210426067U
Application number: CN201921244905.8U
Authority: CN
Inventors: 张瑾; 广田二郎; 叶翔; 周建波
Original assignee: Ningbo Jinyue New Material Co ltd
Current assignee: Ningbo Jinyue New Material Co ltd
Priority date: 2019-08-02
Filing date: 2019-08-02
Publication date: 2020-04-28
Anticipated expiration: 2029-08-02

Abstract

The utility model relates to an aluminum ingot feeding device, which comprises a feeding box, a feeding mechanism, a guide wheel and a material pushing cylinder, wherein the feeding box is arranged at one side of a smelting furnace, a feeding station is arranged in the feeding box, the feeding mechanism places an aluminum ingot at the feeding station, a discharge port is arranged at the side surface of the feeding box close to the smelting furnace, and the material pushing cylinder and the discharge port are respectively positioned at two sides of the feeding station; the material guide wheel is positioned above a feeding port of the smelting furnace, and a plurality of accommodating spaces with openings positioned on the circumferential surface are formed in the circumferential direction of the material guide wheel and used for accommodating aluminum ingots; the extension of the piston rod of the material pushing cylinder pushes the aluminum ingot of the feeding station, the aluminum ingot enters the accommodating space of the guide wheel through the discharge port, the piston rod of the material pushing cylinder retracts, the guide wheel rotates to put the aluminum ingot into the melting furnace, the problem that dirty objects on the surface of the aluminum ingot are caused by manually taking the aluminum ingot is avoided, and the problems of a large amount of manpower for manually putting in the aluminum ingot and waiting for heating and wasting time for manual feeding are reduced.

Description

Aluminum ingot feeding device

Technical Field

The utility model relates to an aluminium ingot processingequipment, in particular to material device is thrown to aluminium ingot.

Background

Aluminum is a nonferrous metal with the world yield and the consumption second to steel, has wide application and is an essential raw material for manufacturing a plurality of industrial products. The density of aluminum is small, about 1/3 times the density of steel, copper or brass. Because of the light weight of aluminum, aluminum is often used for manufacturing land, sea and air vehicles such as automobiles, trains, subways, ships, airplanes, rockets, airships and the like so as to reduce the self weight and increase the loading capacity.

The raw material used in industry for the processing of artware is called aluminum ingots, which are produced by electrolysis from alumina-cryolite. In the production of aluminum ingots, smelting furnace equipment is needed to be used for melting the aluminum ingots and then processing the products. In the prior art, aluminum ingots are put into a smelting furnace in a manual putting mode, on one hand, operators are required to put the aluminum ingots into the smelting furnace one at a time, great difficulty exists in actual operation and management, and the problem that the temperature of aluminum liquid in the furnace cannot be controlled within a process specified range is easily caused; on the other hand, because the operating personnel pollutes the aluminum ingot when taking the aluminum ingot, the surface of the aluminum ingot is provided with oil stain, water vapor or impurities, and then the aluminum ingot is directly put into the high-temperature aluminum liquid in the furnace, so that the aluminum liquid is easy to splash due to explosion, serious potential safety hazard exists, and the danger coefficient is large.

Disclosure of Invention

The utility model aims to solve the technical problem how to provide a simple structure, can drop into the aluminium ingot of aluminium ingot automatically and throw material device.

The utility model provides a technical scheme that above-mentioned technical problem adopted does:

an aluminum ingot feeding device comprises a feeding box, a feeding mechanism, a guide wheel and a material pushing cylinder, wherein the feeding box is arranged on one side of a smelting furnace, a feeding station is arranged in the feeding box, an aluminum ingot is placed on the feeding station by the feeding mechanism, a discharge hole is formed in the side surface, close to the smelting furnace, of the feeding box, and the material pushing cylinder and the discharge hole are respectively located on two sides of the feeding station; the material guide wheel is positioned above a feeding port of the smelting furnace, and a plurality of accommodating spaces with openings positioned on the circumferential surface are formed in the circumferential direction of the material guide wheel and used for accommodating aluminum ingots;

and a piston rod of the material pushing cylinder extends to push an aluminum ingot of the feeding station, the aluminum ingot enters the accommodating space of the guide wheel through the discharge port, the piston rod of the material pushing cylinder retracts, and the guide wheel rotates to put the aluminum ingot into the smelting furnace.

Preferably, the material guiding wheel is located on the left side of the material loading box, an elastic lock catch is arranged on one side edge of an opening of the accommodating space, the elastic lock catch blocks part of the opening, or the elastic lock catch rotates to enable the opening to be completely opened, and the accommodating space rotates anticlockwise from one side with the elastic lock catch to the other side around a central shaft of the material guiding wheel.

Preferably, the elastic lock catch comprises a torsion spring and an adjusting block, a rotating shaft parallel to a central shaft of the guide wheel is arranged at the edge of an opening of the accommodating space of the guide wheel, the torsion spring is wound on the rotating shaft, two ends of the torsion spring are positioned on the same side of the rotating shaft and are perpendicular to the rotating shaft and extend in opposite directions along the guide wheel, one end of the torsion spring is fixed with the adjusting block, and the other end of the torsion spring abuts against the outer surface of the guide wheel and is used for driving the adjusting block to keep blocking part of the opening;

the outer side of the part, which blocks the opening, of the elastic lock catch is provided with a guide surface which inclines inwards from the edge of the opening, a piston rod of the material pushing cylinder pushes an aluminum ingot to apply external force to the guide surface, so that the elastic lock catch is stressed to rotate clockwise to open, the material pushing cylinder pushes the aluminum ingot to enter the accommodating space, then the piston rod of the material pushing cylinder retracts, and the elastic lock catch rebounds to block part of the opening to limit the aluminum ingot to be in the accommodating space;

and a deflector rod is arranged on the smelting furnace below the material guide wheel and is used for pulling the elastic lock catch rotating to the opening of the containing space above the smelting furnace to open so that the aluminum ingot in the containing space falls into the smelting furnace.

Preferably, a guide rail is arranged between the feeding station and the discharge port and used for limiting the movement direction of the aluminum ingot.

Preferably, the edge of the discharge hole is provided with a brush protruding inwards.

Preferably, the discharge port is circular, the brush is connected with the belt pulley, the belt pulley is surrounded by a belt and is driven to rotate through the motor, and then the brush is driven to rotate.

Preferably, the edge of the feeding port of the smelting furnace extends upwards, the inner surface of the extension part of the feeding port is provided with elastic baffles which incline downwards from the inner wall to the center at intervals, and the aluminum ingot exerts pressure on the baffles to enable the elastic baffles to further incline and fall into the smelting furnace from the space between the elastic baffles.

Preferably, the elastic baffle is provided with a vent hole.

Preferably, the material pushing cylinder, the material loading station and the material outlet are positioned at the same height.

Preferably, the receiving spaces are uniformly spaced around a central axis of the guide wheel.

Compared with the prior art, the utility model provides an aluminium ingot throws material device's advantage lies in

The utility model discloses a feed mechanism can place the aluminium ingot on the material loading station, piston rod extension through pushing away the material cylinder releases the aluminium ingot along the guide rail to the accommodation space of guide wheel in, the aluminium ingot rotates along the center pin of guide wheel in accommodation space, hot gas through the dog-house exhaust from the smelting pot heats a period, elastic lock catch is stirred to the rethread driving lever, make the aluminium ingot fall into in the smelting pot, the temperature of control smelting pot that can be fine, the problem that the aluminium ingot leads to aluminium ingot surperficial stolen goods of having avoided the manual work to take, the artifical extravagant a large amount of manpower and materials of aluminium ingot of puting in has been reduced, also avoided artifical material loading wait to heat, the problem of waste time.

Drawings

Fig. 1 is a schematic structural view of an aluminum ingot feeding device in this embodiment;

FIG. 2 is a schematic structural view of a loading box in the present embodiment;

FIG. 3 is a schematic view showing a state where an aluminum ingot enters the accommodating space in the present embodiment;

FIG. 4 is a schematic view showing a state where an aluminum ingot is dropped into the melting furnace in the present embodiment;

FIG. 5 is a sectional view showing the discharge port position of the upper hopper in the present embodiment;

fig. 6 is a schematic sectional view of a charging port of the melting furnace in this embodiment.

In the figure, 1, a material loading box; 11. a discharge port; 12. a guide rail; 13. a brush; 14. a belt pulley; 15. a belt; 2. a feeding mechanism; 3. a material guide wheel; 31. an accommodating space; 311. a rotating shaft; 32. elastic lock catches; 321. a torsion spring; 322. an adjusting block; 3221. a guide surface; 4. a material pushing cylinder; 5. a furnace; 51. a feeding port; 52. an elastic baffle plate; 521. a vent hole; 6. an aluminum ingot; 7. a deflector rod; 71-pushing the inclined plane.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

An aluminum ingot feeding device is shown in fig. 1-2 and comprises a feeding box 1, a feeding mechanism 2, a guide wheel 3 and a material pushing cylinder 4, wherein the feeding box 1 is arranged on the left side of a smelting furnace 5, and the guide wheel 3 is arranged above a feeding port 51 of the smelting furnace 5 and is driven to rotate by a motor.

A feeding station is arranged in the feeding box 1, the aluminum ingots 6 are placed on the feeding station by the feeding mechanism 2, a discharging port 11 is arranged on the side face, close to the smelting furnace 5, of the feeding box 1, the material pushing cylinder 4 and the discharging port 11 are respectively located on two sides of the feeding station, and a plurality of containing spaces 31, with openings evenly spaced on the circumferential face, for placing the aluminum ingots 6 are circumferentially arranged on the guide wheel 3. Preferably, the material pushing cylinder 4, the material loading station and the material outlet 11 are positioned at the same height.

The feeding mechanism 2 comprises a supporting plate in the feeding box 1, aluminum ingots 6 are stacked on the supporting plate, the supporting plate is driven to lift by a mode that a motor drives a screw or a chain, the uppermost aluminum ingot 6 is located at a feeding station, the aluminum ingot 6 at the feeding station is pushed by the extension of a piston rod of the material pushing cylinder 4, the aluminum ingot 6 enters the accommodating space 31 of the guide wheel 3 through the discharge port 11, the piston rod of the material pushing cylinder 4 retracts, and the guide wheel 3 rotates to put the aluminum ingot 6 into the smelting furnace 5.

It should be understood by those skilled in the art that feeding mechanism 2 may place aluminum ingots 6 at a feeding station, may stack aluminum ingots 6 above feeding box 1, and control dropping one aluminum ingot 6 to the feeding station at a time, or may be provided with a mechanism capable of horizontally conveying aluminum ingots 6, and conveying one aluminum ingot 6 to the feeding station at a time.

This material device is thrown to aluminium ingot can also include the electric cabinet, and the electric cabinet with push away material cylinder 4 and guide wheel 3 electric connection, the piston rod that the control pushed away material cylinder 4 stretches out or contracts to and guide wheel 3 pivoted function chronogenesis.

As shown in fig. 3 to 6, an elastic latch 32 is disposed along one side of the opening of the accommodating space 31, and the elastic latch 32 cooperates with the aluminum ingot 6 or the shift lever 7 on the melting furnace 5 to open the opening of the accommodating space 31 so that the aluminum ingot 6 can enter or leave the accommodating space 31. The accommodating space 31 rotates from side to side with the elastic locking catches 32 around the central axis of the guide wheel 3.

The elastic lock 32 includes a torsion spring 321 and an adjusting block 322, the guide wheel 3 is provided with a rotating shaft 311 parallel to the central axis of the guide wheel 3 at the edge of the opening of the accommodating space 31, the torsion spring 321 is wound on the rotating shaft 311, two ends of the torsion spring 321 are located on the same side of the rotating shaft 311 and perpendicular to the rotating shaft 311, and extend in the opposite direction along the guide wheel 3, one end of the torsion spring 321 is fixed with the adjusting block 322, and the other end of the torsion spring 321 abuts against the outer surface of the guide wheel 3 to drive the adjusting block 322 to keep blocking part of the opening.

The outer side of the part of the elastic lock catch 32 blocking the opening is provided with a guide surface 3221 which is inclined inwards from the edge of the opening, when the aluminum ingot pushing device is used, a piston rod of the material pushing cylinder 4 pushes the aluminum ingot 6 to apply external force to the guide surface 3221, so that the elastic lock catch 32 is forced to rotate clockwise to be opened, the material pushing cylinder 4 pushes the aluminum ingot 6 to enter the accommodating space 31, then the piston rod of the material pushing cylinder 4 retracts, and the elastic lock catch 32 is forced to rotate anticlockwise by resilience force of the torsion spring 321 to block part of the opening to limit the aluminum ingot in the.

Be equipped with driving lever 7 on the smelting pot 5 of guide wheel 3 below, the accommodation space 31 that is equipped with aluminium ingot 6 rotates around the center pin anticlockwise of guide wheel 3, one side of accommodation space 31 opening inelastic hasp 32 passes through driving lever 7 earlier, when elastic hasp 32 rotated the top of driving lever 7, the one end of adjusting block 322 towards feed box 1 of elastic hasp 32 supports in driving lever 7, guide wheel 3 continues anticlockwise rotation, driving lever 7's promotion inclined plane 71 exerts the resistance to the adjusting block, make adjusting block 322 revolute the axle 311 clockwise rotation, and then make the opening of accommodation space 31 open completely, make aluminium ingot 6 in the accommodation space 31 fall into in the smelting pot 4.

A guide rail 12 is arranged between the feeding station and the discharge port 11 and used for limiting the movement direction of the aluminum ingot 6, so that the aluminum ingot 6 can penetrate out of the discharge port 11 and enter the accommodating space 31 of the guide wheel 3.

The edge of the discharge port 11 is provided with a brush 13 protruding inwards for brushing off impurities on the surface of the aluminum ingot 6, wherein the discharge port 11 is circular, the brush 13 is connected with a belt pulley 14, the belt pulley 14 is surrounded by a belt 15 and is driven by a motor to rotate, and then the brush 13 rotates.

The edge of a feeding port 51 of the smelting furnace 5 extends upwards, elastic baffles 52 inclining downwards from the inner wall to the center are arranged on the inner surface of the extending part of the feeding port 51 at intervals, the aluminum ingot 6 exerts pressure on the baffles to enable the baffles to further incline and fall into the smelting furnace 5 from the space between the elastic baffles 52, and the elastic baffles 52 are arranged to block the aluminum liquid splashed when the aluminum ingot 6 falls into the smelting furnace 5. The elastic baffle plates 52 are provided with vent holes 521, and hot air exhausted from between the elastic baffle plates 52 and the vent holes 521 of the elastic baffle plates 52 can heat the aluminum ingots 6 in the material guide wheel 3 for a period of time.

Compared with the prior art, the utility model provides an aluminium ingot throws material device's advantage lies in can placing aluminium ingot 6 on the material loading station through feed mechanism 2, piston rod extension through pushing away material cylinder 4 releases aluminium ingot 6 in guide rail 12 releases the accommodation space 31 to guide wheel 3, aluminium ingot 6 rotates along the center pin of guide wheel 3 in accommodation space 31, hot gas heating a period through the dog-house 51 exhaust from smelting pot 5, elastic lock catch 32 is stirred to rethread driving lever 7, make aluminium ingot 6 fall into in smelting pot 5, the temperature of control smelting pot 5 that can be fine, the problem of aluminium ingot 6 that has avoided the manual work to take leads to aluminium ingot 6 surperficial foul substances has reduced artifical a large amount of manpower and materials of throwing in aluminium ingot 6 extravagant, also avoided artifical material loading to wait to heat, the problem of waste time.

Although the preferred embodiments of the present invention have been described in detail hereinabove, it should be clearly understood that modifications and variations of the present invention are possible to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides an aluminium ingot feeding device which characterized in that: the aluminum ingot feeding device comprises a feeding box (1), a feeding mechanism (2), a guide wheel (3) and a material pushing cylinder (4), wherein the feeding box (1) is arranged on one side of a smelting furnace (5), a feeding station is arranged in the feeding box (1), the feeding mechanism (2) is used for conveying an aluminum ingot (6) to the feeding station, a discharge hole (11) is formed in the side surface, close to the smelting furnace (5), of the feeding box (1), and the material pushing cylinder (4) and the discharge hole (11) are respectively located on two opposite sides of the feeding station; the material guide wheel (3) is positioned above a feeding port (51) of the smelting furnace (5), and a plurality of accommodating spaces (31) with outward openings and used for accommodating aluminum ingots (6) are formed in the material guide wheel (3) along the circumferential direction; a piston rod of the pushing cylinder (4) extends to push an aluminum ingot (6) at the feeding station, the aluminum ingot (6) enters the accommodating space (31) of the guide wheel (3) through the discharge hole (11), and the guide wheel (3) rotates to put the aluminum ingot (6) into the smelting furnace (5).

2. An aluminum ingot feeding device according to claim 1, characterized in that: an elastic lock catch (32) is arranged on one side edge of the opening of the accommodating space (31), the elastic lock catch (32) blocks part of the opening, or the elastic lock catch (32) rotates to enable the opening to be completely opened, and the accommodating space (31) rotates from one side with the elastic lock catch (32) to the other side around the central shaft of the material guide wheel (3).

3. An aluminum ingot feeding device according to claim 2, characterized in that: the elastic lock catch (32) comprises a torsion spring (321) and an adjusting block (322), a rotating shaft (311) parallel to the central shaft of the guide wheel (3) is arranged at the edge of an opening of the accommodating space (31) of the guide wheel (3), the torsion spring (321) is wound on the rotating shaft (311), two ends of the torsion spring (321) are positioned on the same side of the rotating shaft (311) and are perpendicular to the rotating shaft (311), and extend in opposite directions along the guide wheel (3), one end of the torsion spring (321) is fixed with the adjusting block (322), and the other end of the torsion spring (321) abuts against the outer surface of the guide wheel (3) and is used for driving the adjusting block (322) to keep blocking part of the opening;

a guide surface (3221) which is inclined inwards from the edge of the opening is arranged on the outer side of the part, which blocks the opening, of the elastic lock catch (32), a piston rod of the pushing cylinder (4) pushes the aluminum ingot (6) to apply external force to the guide surface (3221), so that the elastic lock catch (32) is forced to rotate and open, the pushing cylinder (4) pushes the aluminum ingot (6) to enter the accommodating space (31), then the piston rod of the pushing cylinder (4) retracts, and the elastic lock catch (32) rebounds to block the part of the opening to limit the aluminum ingot (6) in the accommodating space (31);

and a deflector rod (7) is arranged on the smelting furnace below the material guide wheel (3) and is used for deflecting an elastic lock catch (32) which rotates to an opening of the containing space above the smelting furnace (5) so as to enable the aluminum ingot (6) in the containing space (31) to fall into the smelting furnace (5).

4. An aluminum ingot feeding device according to claim 1, characterized in that: and a guide rail (12) is arranged between the feeding station and the discharge hole (11) and is used for limiting the movement direction of the aluminum ingot (6).

5. An aluminum ingot feeding apparatus according to any one of claims 1 to 4, wherein: the edge of the discharge hole (11) is provided with a brush (13) protruding inwards.

6. An aluminum ingot feeding device according to claim 5, characterized in that: the discharge hole (11) is circular, the brush (13) is connected with the belt pulley (14), the belt pulley (14) is surrounded by a belt (15) and is driven to rotate by a motor, and then the brush (13) is rotated.

7. An aluminum ingot feeding device according to claim 5, characterized in that: the edge of a feeding port (51) of the smelting furnace (5) extends upwards, elastic baffles (52) inclining downwards from the inner wall to the center are arranged on the inner surface of the extending part of the feeding port (51) at intervals, and the aluminum ingot (6) exerts pressure on the elastic baffles (52) to enable the baffles to incline further and fall into the smelting furnace (5) from the space between the elastic baffles (52).

8. An aluminum ingot feeding device according to claim 7, characterized in that: the elastic baffle (52) is provided with a vent hole (521).

9. An aluminum ingot feeding device according to claim 1, characterized in that: the material pushing cylinder (4), the feeding station and the discharge hole (11) are located at the same height.

10. An aluminum ingot feeding device according to claim 1, characterized in that: the accommodating spaces (31) are uniformly arranged at intervals around the central shaft of the material guide wheel (3).