CN114719606A - Quantitative control mechanism for aluminum ingot processing production forming and method thereof - Google Patents

Abstract

The invention discloses a quantitative control mechanism for processing, producing and forming an aluminum ingot and a method thereof, relating to the technical field of aluminum ingot production. The aluminum ingot casting device comprises a shell, a quantitative control mechanism and an aluminum ingot casting mechanism, wherein an inlet shell is arranged at the top of the shell, a switch door is rotatably connected to the outer surface of the shell, the quantitative control mechanism is installed inside the shell and positioned at the lower end of the inlet shell, the aluminum ingot casting mechanism is installed inside the shell, a heating seat is installed inside the shell, a molten pool is arranged at the top of the heating seat, material blocking mechanisms are arranged on two sides of an inner cavity of the device shell, and a discharging mechanism is arranged on the lower surface of a movable circular plate, so that aluminum ingots uniformly fall into the molten pool, the quantitative control of the aluminum ingots in casting processing production is realized, the automation degree is high, the aluminum ingots are not required to be added manually, the labor is saved, and the production efficiency is improved.

Description

Quantitative control mechanism for aluminum ingot processing production forming and method thereof

Technical Field

The invention belongs to the technical field of aluminum ingot production, and particularly relates to a quantitative control mechanism for aluminum ingot processing production forming and a method thereof.

Background

Aluminum ingots are produced by electrolysis from alumina-cryolite and have two major types after entering industrial applications: cast aluminum alloys and wrought aluminum alloys, cast aluminum and aluminum alloys are castings produced by casting methods.

In our daily life, various aluminum products are often seen, and in the production and processing of the aluminum products, aluminum ingots are usually used as raw materials, and the aluminum ingots are generally required to be continuously processed in a production workshop to be finally formed into the aluminum products required by people. At present, traditional aluminium ingot casting equipment needs the staff incessantly to add at the in-process that adds the aluminium ingot always, has consumeed very big manpower and materials, and brings fatigue for the staff easily to influence work efficiency, production efficiency is poor.

Prior publication patent CN202020652658.1 discloses a forming device for aluminum alloy ingot production, comprising a positioning bottom plate, the positioning upright posts are symmetrically fixed at the positions of the rear side above the positioning bottom plate, the end parts of the positioning upright posts are sleeved and fixed with a transmission mechanism, an upper pressing plate is fixed below a transmission arm in the transmission mechanism, an upper die is fixed below the upper pressing plate at the front position, a lower pressing plate is fixed above the positioning bottom plate at the middle position, a material pushing air pressure rod is fixed at the middle position below the positioning bottom plate, a material pushing clamping plate is fixed at the telescopic end of the material pushing air pressure rod, a pushing air pressure rod is fixed at one side of the lower pressing plate, and a placing table is fixed on the other side of the lower pressing plate, a die groove is embedded in the position, located on the front side, of the upper surface of the lower pressing plate, and a limiting sliding rod is fixed on the position, located on the rear side, of the upper side of the lower pressing plate.

However, the above disclosed technology cannot achieve quantitative control of the aluminum alloy ingot in the production process of the aluminum alloy ingot.

Disclosure of Invention

The invention aims to provide a quantitative control mechanism for processing, producing and forming an aluminum ingot and a method thereof.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a quantitative control mechanism for processing, producing and forming aluminum ingots, which comprises a shell, a quantitative control mechanism and an aluminum ingot casting mechanism, wherein the top of the shell is provided with an inlet shell; the outer surface of the shell is rotatably connected with a switch door; the quantitative control mechanism is arranged in the shell and is positioned at the lower end of the inlet shell; the aluminum ingot casting mechanism is arranged in the machine shell.

As a preferred technical scheme of the invention, the aluminum ingot casting mechanism comprises a heating seat, a molten pool, a burner, a gas pipe, a fan and an air outlet; the heating seat is arranged inside the shell; a molten pool is arranged at the top of the heating seat; a burner is arranged inside the heating seat; the bottom of the combustor is connected with a gas pipe; the gas pipe penetrates through the inner wall of the shell and extends to the outside of the shell; the fan is arranged on the outer side of the shell; the output end of the fan is connected with an air outlet; the air outlet is arranged in the heating seat.

As a preferred technical scheme of the invention, the quantitative control mechanism comprises a device shell, a material conveying pipe, an electric telescopic device and a material blocking mechanism; the top of the device shell is closed, and the bottom of the device shell is open; the conveying pipe penetrates through the device shell; the top end of the feed delivery pipe is positioned in the inlet shell; the bottom end of the conveying pipe is positioned at the lower part of the inner cavity of the device shell.

As a preferred technical solution of the present invention, the electric telescopic device is fixedly installed on the inner top surface of the device housing; the output end of the electric telescopic device is provided with an electric telescopic rod; the electric telescopic rod is vertically arranged; a movable circular plate is arranged at the bottom of the electric telescopic rod; the movable circular plate is provided with a through hole for the transmission pipe to movably pass through.

As a preferred technical scheme of the invention, two sides of an inner cavity of a shell of the device are provided with material blocking mechanisms; the material blocking mechanism comprises a transverse guide plate, a first motor, a transverse screw rod and a connecting plate; one end of the transverse guide plate is fixedly connected with the inner wall of the device shell; the other end of the transverse guide plate is provided with a supporting plate; the first motor is fixedly arranged on the inner wall of the device shell; one end of the transverse screw rod is fixedly connected with the output end of the first motor through a first coupling; the other end of the transverse screw rod is fixedly connected to the supporting plate; and a sliding block is arranged on the transverse guide plate in a sliding manner.

As a preferred technical scheme of the invention, the slide block is provided with a screw rod screw hole; the transverse screw rod is meshed with a screw rod screw hole on the sliding block; and the transverse screw rod drives the sliding block to slide left and right on the transverse guide plate.

As a preferred technical scheme of the invention, a moving block is arranged at the bottom of the sliding block; connecting rods are arranged on two sides of the moving block; one end of the connecting plate is fixedly connected with the connecting rod; and the other end of the connecting plate is provided with a baffle matched with the through hole.

As a preferred technical scheme of the invention, the lower surface of the movable circular plate is provided with a discharging mechanism; the discharging mechanism comprises a motor mounting shell, a rotating shaft and a rotating circular plate; the top of the motor mounting shell is fixedly connected with the middle of the lower surface of the movable circular plate; a second motor is arranged in the motor installation shell; the output end of the second motor is fixedly connected with the rotating shaft through a second coupling; the rotating shaft is vertically arranged and penetrates through the bottom of the motor installation shell to be fixedly connected with the rotating circular plate.

As a preferred technical scheme of the invention, strip-shaped moving plates are arranged on both sides of the moving circular plate; both sides of the inner cavity of the device shell are provided with button mounting plates; and the button mounting plate is provided with a control button matched with the bar-shaped moving plate.

A method for manufacturing a quantitative control mechanism for forming an aluminum ingot comprises the following steps:

the method comprises the following steps: opening a switch door on the shell, and then pouring the aluminum ingot into the molten pool;

step two: the gas pipe is connected with an external gas device and used for providing gas for the combustor, then the combustor starts to work, the combustor starts to combust the gas so as to provide heat energy for the molten pool, and the fan provides sufficient air for the combustor through the air outlet;

step three: pouring aluminum ingots into a material conveying pipe in an inlet shell, and enabling the aluminum ingots to fall onto a rotating circular plate along the material conveying pipe;

step four: the electric telescopic rod of the electric telescopic device is driven to extend downwards, so that the movable circular plate moves downwards, the strip-shaped moving plate touches the control button, the control button turns off the electric telescopic device and simultaneously starts the first motor to enable the baffle plate to block the through hole, and the aluminum ingot cannot fall onto the rotary circular plate;

step five: the second motor is driven to rotate the rotating circular plate, so that the aluminum ingots uniformly fall into the molten pool.

The invention has the following beneficial effects:

according to the invention, the inlet shell is arranged at the top of the shell, the quantitative control mechanism is arranged in the shell and is positioned at the lower end of the inlet shell, the aluminum ingot casting mechanism is arranged in the shell, the heating seat is arranged in the shell, the top of the heating seat is provided with the molten pool, the two sides of the inner cavity of the shell are provided with the material blocking mechanisms, and the lower surface of the movable circular plate is provided with the discharging mechanism, so that aluminum ingots uniformly fall into the molten pool, the quantitative control of the aluminum ingots in the casting processing production is realized, the automation degree is high, the aluminum ingots do not need to be added manually, the manpower is saved, and the production efficiency is improved.

Of course, it is not necessary for any one product that embodies the invention to achieve all of the above advantages simultaneously.

Drawings

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

FIG. 1 is a schematic structural diagram of a quantitative control mechanism for aluminum ingot processing, production and forming in accordance with the present invention;

FIG. 2 is a schematic cross-sectional view of the interior of the housing of the present invention;

FIG. 3 is a schematic cross-sectional view of the interior of the device housing;

FIG. 4 is a partially enlarged schematic view of the structure at A in FIG. 3;

FIG. 5 is a schematic view of the cross-sectional structure of the interior of the device housing in elevation;

FIG. 6 is an enlarged view of a portion of FIG. 5;

FIG. 7 is a schematic structural view of a strip-shaped moving plate connected to both sides of a moving circular plate;

FIG. 8 is a schematic structural view of a material stopping mechanism;

FIG. 9 is a schematic structural view of the discharging mechanism;

FIG. 10 is a schematic view of a front cross-sectional configuration of the interior of the motor mounting housing;

in the drawings, the components represented by the respective reference numerals are listed below:

1-a machine shell, 2-an inlet shell, 3-a heating seat, 4-a molten pool, 5-a burner, 6-a gas pipe, 7-a fan, 8-an air outlet, 9-a device shell, 10-a material conveying pipe, 11-an electric expansion device, 12-an electric expansion rod, 13-a moving circular plate, 14-a through hole, 15-a transverse guide plate, 16-a support plate, 17-a first motor, 18-a transverse screw rod, 19-a first shaft connector, 20-a sliding block, 21-a moving block, 22-a connecting rod, 23-a connecting plate, 24-a baffle plate, 25-a motor installation shell, 26-a second motor, 27-a second shaft connector, 28-a rotating shaft, 29-a rotating circular plate and 30-a strip-shaped moving plate, 31-button mounting plate, 32-control button, 33-switch door.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Referring to fig. 1-10, a quantitative control mechanism for aluminum ingot processing, production and forming includes a housing 1, a quantitative control mechanism, and an aluminum ingot casting mechanism. The top of the shell body 1 is provided with an inlet shell body 2, and the outer surface of the shell body 1 is rotatably connected with a switch door 33. The dosing control mechanism is mounted inside the housing 1 and at the lower end of the inlet housing 2. The aluminum ingot casting mechanism is arranged in the shell body 1.

Referring to fig. 2, the aluminum ingot casting mechanism includes a heating base 3, a molten pool 4, a burner 5, a gas pipe 6, a fan 7, and an air outlet 8. Heating seat 3 is installed in the inside of casing 1, and molten bath 4 has been seted up at the top of heating seat 3, and the internally mounted of heating seat 3 has combustor 5, and the bottom of combustor 5 is connected with gas pipe 6, and gas pipe 6 runs through the inner wall of casing 1 and extends in the outside of casing 1, and fan 7 is installed in the outside of casing 1, and the output of fan 7 is connected with air outlet 8, and air outlet 8 sets up the inside at heating seat 3.

Referring to fig. 3-10, the quantitative control mechanism includes a device housing 9, a material conveying pipe 10, an electric telescopic device 11, an electric telescopic rod 12, a moving circular plate 13, a strip-shaped moving plate 30, a button mounting plate 31, a control button 32, a material blocking mechanism, and a material discharging mechanism. The top of the device shell 9 is closed, the bottom is open, the device shell 9 is fixedly arranged on the upper part of the inner cavity of the device shell 1, the material conveying pipe 10 penetrates through the device shell 9, the top end of the material conveying pipe 10 is positioned in the inlet shell 2, and the bottom end of the material conveying pipe 10 is positioned on the lower part of the inner cavity of the device shell 9.

The electric telescopic device 11 is fixedly installed on the inner top surface of the device shell 9, an electric telescopic rod 12 is arranged at the output end of the electric telescopic device 11, the electric telescopic rod 12 is vertically arranged, a movable circular plate 13 is arranged at the bottom of the electric telescopic rod 12, a through hole 14 for the conveying pipe 10 to movably penetrate is formed in the movable circular plate 13, and the conveying pipe 10 penetrates through the through hole 14 to vertically move up and down.

Referring to fig. 8, material blocking mechanisms are respectively disposed on two sides of an inner cavity of the device housing 9, each material blocking mechanism includes a transverse guide plate 15, a support plate 16, a first motor 17, a transverse lead screw 18, a first coupler 19, a slider 20, a moving block 21, a connecting rod 22, a connecting plate 23, and a baffle 24, one end of the transverse guide plate 15 is fixedly connected to an inner wall of the device housing 9, the other end of the transverse guide plate 15 is provided with the support plate 16, the first motor 17 is fixedly mounted on an inner wall of the device housing 9, one end of the transverse lead screw 18 is fixedly connected to an output end of the first motor 17 through the first coupler 19, the other end of the transverse lead screw 18 is fixedly connected to the support plate 16, and the slider 20 is slidably mounted on the transverse guide plate 15. The sliding block 20 is provided with a screw rod screw hole, the transverse screw rod 18 is meshed and connected with the screw rod screw hole on the sliding block 20, and the transverse screw rod 18 drives the sliding block 20 to slide left and right on the transverse guide plate 15.

The bottom of the slider 20 is provided with a moving block 21, two sides of the moving block 21 are provided with connecting rods 22, one end of a connecting plate 23 is fixedly connected with the connecting rods 22, and the other end of the connecting plate 23 is provided with a baffle plate 24 matched with the through hole 14.

Referring to fig. 9-10, the lower surface of the movable circular plate 13 is provided with a discharging mechanism, which includes a motor mounting housing 25, a second motor 26, a second coupling 27, a rotating shaft 28, and a rotating circular plate 29. The top of the motor installation shell 25 is fixedly connected with the middle of the lower surface of the movable circular plate 13, a second motor 26 is installed in the motor installation shell 25, the output end of the second motor 26 is fixedly connected with a rotating shaft 28 through a second coupling 27, and the rotating shaft 28 is vertically arranged and penetrates through the bottom of the motor installation shell 25 to be fixedly connected with a rotating circular plate 29.

The two sides of the movable circular plate 13 are provided with strip-shaped movable plates 30, the two sides of the inner cavity of the device shell 9 are provided with button mounting plates 31, the button mounting plates 31 are provided with control buttons 32 matched with the strip-shaped movable plates 30, and the control buttons 32 control the first motor 17 to start.

This embodiment is through pouring the aluminium ingot into the conveying pipeline 10 in the import casing 2 in, the aluminium ingot falls into rotatory plectane 29 along conveying pipeline 10 on, then the electric telescopic handle 12 of drive electric telescoping device 11 extends downwards, make rotatory plectane 29 be located molten bath 4, drive second motor 26 makes rotatory plectane 29 rotatory after that, and then make the even drop in molten bath 4 of aluminium ingot, realize the quantitative control of aluminium ingot in founding processing production, degree of automation is high, do not need the manual work to add the aluminium ingot, the manpower is saved and production efficiency has been improved.

Example two

A method for a quantitative control mechanism for processing, producing and forming an aluminum ingot comprises the following steps:

the method comprises the following steps: opening an opening and closing door 33 on the shell body 1, and then pouring aluminum ingots into the molten pool 4;

step two: the gas pipe 6 is connected with an external gas device and is used for supplying gas to the burner 5, then the burner 5 starts to work, the burner 5 starts to burn the gas so as to supply heat energy to the molten pool 4, and the fan 7 supplies sufficient air to the burner 5 through the air outlet 8;

step three: pouring aluminum ingots into a material conveying pipe 10 in the inlet shell 2, and enabling the aluminum ingots to fall onto a rotating circular plate 29 along the material conveying pipe 10;

step four: the electric telescopic rod 12 of the electric telescopic device 11 is driven to extend downwards, the movable circular plate 13 moves downwards, the strip-shaped movable plate 30 touches the control button 32, the control button 32 turns off the electric telescopic device 11 and simultaneously starts the first motor 17 to enable the baffle plate 24 to block the through hole 14, and an aluminum ingot cannot fall onto the rotary circular plate 29;

step five: the second motor 26 is driven to rotate the rotating circular plate 29, so that the aluminum ingots uniformly fall into the molten pool 4, quantitative control of the aluminum ingots in casting processing production is realized, the automation degree is high, manual addition of the aluminum ingots is not needed, manpower is saved, and the production efficiency is improved.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. The utility model provides an aluminium ingot processing production is shaped and is used quantitative control mechanism which characterized in that: comprises that

The device comprises a shell (1), wherein an inlet shell (2) is arranged at the top of the shell (1); the outer surface of the shell (1) is rotatably connected with a switch door (33);

the quantitative control mechanism is arranged in the shell (1) and is positioned at the lower end of the inlet shell (2);

the aluminum ingot casting mechanism is installed in the shell (1).

2. The quantitative control mechanism for processing, producing and forming the aluminum ingot according to claim 1, wherein: the aluminum ingot casting mechanism comprises a heating seat (3), a molten pool (4), a burner (5), a gas pipe (6), a fan (7) and an air outlet (8); the heating seat (3) is arranged in the shell (1); a molten pool (4) is arranged at the top of the heating seat (3);

a burner (5) is arranged in the heating seat (3); the bottom of the combustor (5) is connected with a gas pipe (6); the gas pipe (6) penetrates through the inner wall of the shell (1) and extends to the outside of the shell (1);

the fan (7) is arranged on the outer side of the shell (1); the output end of the fan (7) is connected with an air outlet (8); the air outlet (8) is arranged inside the heating seat (3).

3. The quantitative control mechanism for processing, producing and forming the aluminum ingot as claimed in claim 2, wherein: the quantitative control mechanism comprises a device shell (9), a material conveying pipe (10), an electric telescopic device (11) and a material blocking mechanism; the top of the device shell (9) is closed, and the bottom of the device shell is open; the material conveying pipe (10) penetrates through the device shell (9); the top end of the material conveying pipe (10) is positioned in the inlet shell (2); the bottom end of the material conveying pipe (10) is positioned at the lower part of the inner cavity of the device shell (9).

4. The quantitative control mechanism for processing, producing and forming the aluminum ingot according to claim 3, wherein: the electric telescopic device (11) is fixedly arranged on the inner top surface of the device shell (9); the output end of the electric telescopic device (11) is provided with an electric telescopic rod (12); the electric telescopic rod (12) is vertically arranged; a movable circular plate (13) is arranged at the bottom of the electric telescopic rod (12); the moving round plate (13) is provided with a through hole (14) for the transmission pipe (10) to movably pass through.

5. The quantitative control mechanism for processing, producing and forming the aluminum ingot as claimed in claim 4, wherein: two sides of the inner cavity of the device shell (9) are provided with material blocking mechanisms; the material blocking mechanism comprises a transverse guide plate (15), a first motor (17), a transverse screw rod (18) and a connecting plate (23); one end of the transverse guide plate (15) is fixedly connected with the inner wall of the device shell (9); the other end of the transverse guide plate (15) is provided with a support plate (16); the first motor (17) is fixedly arranged on the inner wall of the device shell (9);

one end of the transverse screw rod (18) is fixedly connected with the output end of the first motor (17) through a first coupling (19); the other end of the transverse screw rod (18) is fixedly connected to the supporting plate (16); and a sliding block (20) is arranged on the transverse guide plate (15) in a sliding way.

6. The quantitative control mechanism for processing, producing and forming the aluminum ingot as claimed in claim 5, wherein: the sliding block (20) is provided with a screw rod screw hole; the transverse screw rod (18) is meshed and connected with a screw rod screw hole on the sliding block (20); the transverse screw rod (18) drives the sliding block (20) to slide left and right on the transverse guide plate (15).

7. The quantitative control mechanism for processing, producing and forming the aluminum ingot as claimed in claim 5, wherein: a moving block (21) is arranged at the bottom of the sliding block (20); connecting rods (22) are arranged on two sides of the moving block (21); one end of the connecting plate (23) is fixedly connected with the connecting rod (22); the other end of the connecting plate (23) is provided with a baffle (24) matched with the through hole (14).

8. The quantitative control mechanism for processing, producing and forming the aluminum ingot as claimed in claim 4, wherein: the lower surface of the movable circular plate (13) is provided with a discharging mechanism; the discharging mechanism comprises a motor mounting shell (25), a rotating shaft (28) and a rotating circular plate (29); the top of the motor mounting shell (25) is fixedly connected with the middle of the lower surface of the movable circular plate (13); a second motor (26) is arranged in the motor mounting shell (25);

the output end of the second motor (26) is fixedly connected with the rotating shaft (28) through a second coupling (27); the rotating shaft (28) is vertically arranged and penetrates through the bottom of the motor installation shell (25) to be fixedly connected with the rotating circular plate (29).

9. The quantitative control mechanism for processing, producing and forming the aluminum ingot as claimed in claim 7, wherein: strip-shaped moving plates (30) are arranged on two sides of the moving circular plate (13); both sides of the inner cavity of the device shell (9) are provided with button mounting plates (31); and a control button (32) matched with the strip-shaped moving plate (30) is arranged on the button mounting plate (31).

10. A method for manufacturing a quantitative control mechanism for forming an aluminum ingot is characterized by comprising the following steps:

the method comprises the following steps: opening a switch door (33) on the shell body (1), and then pouring an aluminum ingot into the molten pool (4);

step two: the gas pipe (6) is connected with an external gas device and used for supplying gas to the combustor (5), then the combustor (5) starts to work, the combustor (5) starts to burn the gas so as to supply heat energy to the molten pool (4), and the fan (7) supplies sufficient air to the combustor (5) through the air outlet (8);

step three: pouring aluminum ingots into a material conveying pipe (10) in an inlet shell (2), and enabling the aluminum ingots to fall onto a rotary circular plate (29) along the material conveying pipe (10);

step four: an electric telescopic rod (12) of the electric telescopic device (11) is driven to extend downwards, so that a movable circular plate (13) moves downwards, a strip-shaped movable plate (30) touches a control button (32), the control button (32) turns off the electric telescopic device (11) and simultaneously starts a first motor (17) to enable a baffle plate (24) to block a through hole (14), and an aluminum ingot cannot fall onto a rotary circular plate (29);

step five: the second motor (26) is driven to rotate the rotating circular plate (29), so that the aluminum ingot is uniformly dropped in the molten pool (4).

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