CN219750830U - Aluminium ingot pile up neatly mechanism - Google Patents

Abstract

The utility model provides an aluminum ingot stacking mechanism, which belongs to the field of aluminum ingot production management equipment and mainly comprises a frame and a conveying belt for conveying aluminum ingots, wherein a driving wheel of the conveying belt is connected with a mounting frame through a linkage assembly, a plurality of object placing plates are horizontally fixedly connected to the mounting frame, the object placing plates are spaced from each other, and each aluminum ingot can just enter the object placing plate moving to the corresponding height when moving towards one side of the object placing plate along with the conveying belt. This aluminium ingot pile up neatly mechanism, the structure is succinct, realizes the transmission pile up neatly of aluminium ingot automatically.

Description

Aluminium ingot pile up neatly mechanism

Technical Field

The utility model relates to the field of aluminum production management equipment, in particular to aluminum ingot stacking equipment.

Background

When aluminum ingots are processed and produced, the aluminum ingots need to be conveyed out after being molded, then are stacked in order for transportation and management, the common aluminum ingots are of an isosceles trapezoid structure, are integrally long-shaped and stacked together layer by layer, and are hung on a pillow after being tied up in a hoisting mode in production at present, the stacking mode mainly depends on manual hoisting and stacking, the efficiency is low, the existing special stacking equipment can not be directly transferred from a production line for stacking, manual assistance or other equipment is still needed for transferring the aluminum ingots to a set position, and auxiliary equipment like a forklift is adopted for transferring and stacking.

Disclosure of Invention

The utility model aims to provide an aluminum ingot stacking mechanism which can rapidly stack aluminum ingots in a simple and effective mode.

In order to achieve the purpose, the aluminum ingot stacking mechanism comprises a frame and a conveying belt for conveying aluminum ingots, wherein a driving wheel of the conveying belt is connected with a mounting frame through a linkage assembly, a plurality of object placing plates are horizontally fixedly connected to the mounting frame, the object placing plates are spaced from each other, and each aluminum ingot can just enter the object placing plate moving to the corresponding height when moving towards one side of the object placing plate along with the conveying belt.

Preferably, the conveyor belt is provided with a plurality of limit stops for contacting one side of the aluminum ingot.

Preferably, the cross section of the limit stop is in a right trapezoid shape, and the inclined plane where the inclined side is positioned is in contact with the side face of the aluminum ingot.

Preferably, the limit stop is a soft rubber block.

Preferentially, the placement frame further comprises a vertical plate and a sliding frame, wherein the vertical plate is uniformly fixed with the placement plates at intervals along the vertical direction towards one side surface of the conveying belt, the placement plates are perpendicular to the vertical plate, the vertical plate is inserted on the sliding frame, and the sliding frame is vertically and slidably connected with the frame;

the driving plate is also fixed on the sliding frame, the driving plate is arranged below the driving plate and is in sliding contact with the driving plate, a plurality of circular arc side faces are arranged on the edge of the driving plate, the central angles corresponding to the circular arc side faces are consistent, but the radiuses are different, and the radiuses of the circular arc side faces are gradually increased along the circumferential direction, so that when the driving plate rotates, the sliding frame rises to the corresponding height each time and is kept at the corresponding height for a certain time.

Preferably, the free end of the storage plate is an inclined surface.

Preferably, the top of the carriage is connected with a locking piece by a bolt, and the locking piece can be pressed on the vertical plate when being vertically hung.

Preferably, the carriage is slidably mounted on said frame by means of guide posts.

Preferentially, the driving disc is coaxially and fixedly connected with a worm wheel, the worm wheel is in transmission connection with a worm, the worm is coaxially and fixedly connected with an input wheel, and the input wheel is in transmission connection with an output wheel coaxially and fixedly connected with the driving wheel through a transmission mechanism.

Preferentially, the output wheel and the input wheel are gears, and the transmission mechanism is a plurality of gear components; the output wheel and the input wheel are all chain wheels, and the transmission mechanism comprises a plurality of chain wheels and a chain for transmitting the plurality of chain wheels.

The utility model designs a special matching structure to match with the conveying belt, and the aluminum ingots on the conveying belt are conveyed to the object placing plate one by one and gradually lifted upwards, so that the aluminum ingot goods shelves are stacked up, and the utility model is very efficient. And can adopt multiple transmission modes to realize linkage, and the aluminum ingot is automatically piled up while being conveyed.

Drawings

The drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and, together with the description, serve to explain the principles of the utility model.

FIG. 1 is a schematic view of a construction of the present utility model;

FIG. 2 is a schematic illustration of the cooperation of a drive disk and a drive plate;

FIG. 3 is an enlarged view of a portion of the structure shown in FIG. 2;

fig. 4 is a transmission diagram of the case where the output wheel and the input wheel are sprockets.

In the figure, a conveying belt 1, a driving wheel 2, an aluminum ingot 3, a limit stop 4, a storage plate 5, a vertical plate 6, a sliding frame 7, a locking block 8, a rack 9, a guide post 10, a driving plate 11, a driving disc 12, a worm wheel 13, a worm 14, an input wheel 15, an output wheel 16, a chain 17 and a chain wheel 18.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to the structure shown in fig. 1, the aluminum ingot stacking mechanism described in this embodiment includes a frame 9 and a conveyor belt for transporting aluminum ingots 3, where, the driving wheel 2 of the conveyor belt is connected with a rest frame through a linkage assembly, a plurality of object placing plates 5 are horizontally and fixedly connected on the rest frame, the object placing plates 5 are spaced from each other, and may be a plurality of flat plates from top to bottom, each flat plate may be arranged to place an aluminum ingot 3, when each aluminum ingot 3 moves towards one side of the object placing plate 5 along with the conveyor belt 1, it can just enter the object placing plate 5 moving to a corresponding height, that is, when the conveyor belt 1 is transported, based on the driving of the linkage assembly, the rest frame also moves gradually, when each aluminum ingot 3 moves to the free end of the object placing plate 5 close to the corresponding object placing plate, along with further forward movement, the aluminum ingot 3 adaptively slides onto the object placing plate 5, and finally slides onto the object placing plate 5 to be thoroughly and stably separated from the conveyor belt 1, and automatic stacking of the aluminum ingots 3 is automatically and efficiently achieved.

During specific manufacturing, a producer can be provided with a plurality of limit stops 4 on the conveying belt 1, and the limit stops 4 are used for contacting one side of the aluminum ingot 3, so that the aluminum ingot 3 is driven to move forward better along with the forward movement of the conveying belt 1. Specifically, the cross section of the limit stop 4 is in a right trapezoid shape, the inclined plane where the inclined edge is located is in contact with the side face of the aluminum ingot 3, the inclined plane is better in contact fit with the existing aluminum ingot 3, the aluminum ingot 3 is pushed to move forward, and the limit stop 4 is preferably a soft rubber block, so that the limit stop 4 can be freely transited when crossing the driving wheel 2 of the conveying belt 1.

As shown in fig. 1, the placement frame in this embodiment further includes a riser 6 and a carriage 7, where the riser 6 is fixed with a placement plate 5 along a vertical direction at uniform intervals toward a side surface of the conveyor belt, the placement plate 5 is perpendicular to the riser 6, and may specifically be integrally formed, and the riser 6 is plugged onto the carriage 7, that is, when in use, may be integrally plugged onto the carriage 7 so as to be centrally transferred and transported, and the carriage 7 may be vertically and slidably connected with the frame 9, so as to stably vertically slide and ensure that the corresponding placement plate 5 may sequentially move to a horizontal position of the conveyor belt 1.

As a specific implementation structure, a driving plate 11 is further fixed on the carriage 7, the driving plate 11 may be a rectangular plate, edges at two sides of a bottom end surface of the driving plate 11 are preferably rounded, and a driving plate 12 in sliding contact with the bottom of the driving plate 11 is further arranged below the driving plate 11, specifically, as shown in fig. 2-3, a plurality of circular arc sides are arranged on a plate edge of the specially-made driving plate 12, corresponding central angles of each circular arc side are consistent, but the radius is different, and the radius of each circular arc side is gradually increased along the circumferential direction, so that when the driving plate 12 rotates, the circular arc sides with the corresponding radius length are sequentially contacted with the bottom of the driving plate 11, so that the driving plate 11 is gradually lifted, that is, the carriage 7 is lifted up each time to a corresponding height, and is kept for a certain time at the corresponding height, so that each object placing plate 5 can be gradually lifted up, passes through the transmission level of the transmission belt 1, and is correspondingly stopped, the corresponding aluminum ingots 3 can be slid onto the object placing plates 5 and then continuously lifted, and automatic stacking of the aluminum ingots 3 is realized.

During specific manufacturing, the free ends of the object placing plates 5 are inclined planes so as to better match with the structure of the existing trapezoid aluminum ingot 3 and smoothly slide into the object placing plates 5. As shown in fig. 1, the top of the sliding frame 7 is connected with a locking block 8 through a bolt, and when the locking block 8 is vertically hung, the locking block can be pressed on the vertical plate 6, so that the vertical plate 6 can be lifted to take away the aluminum ingots 3 with corresponding quantity, and the transfer and the transportation of the aluminum ingots 3 are also convenient. In addition, the carriage 7 is slidably mounted on the frame 9 through a guide post 10, as shown in fig. 1, a worm wheel 13 is coaxially and fixedly connected to a driving disc 12, the worm wheel 13 is in transmission connection with a worm 14, an input wheel 15 is coaxially and fixedly connected to the worm 14, and the input wheel 15 is in transmission connection with an output wheel 16 coaxially and fixedly connected to the driving wheel 2 through a transmission mechanism. Specifically, the output wheel 16 and the input wheel 15 are gears, and the transmission mechanism is a plurality of gear assemblies, so that the transmission effect can be realized; of course, the output wheel 16 and the input wheel 15 may be sprockets 18, the transmission mechanism is a plurality of sprockets 18 and a chain 17 for driving the plurality of sprockets 18, and corresponding transmission ratios can be obtained, so that the aluminum ingots 3 are transported, lifted and stacked one by one.

The above disclosure is only a preferred embodiment of the present utility model, and it should be understood that the scope of the utility model is not limited thereto, and those skilled in the art will appreciate that all or part of the procedures described above can be performed according to the equivalent changes of the claims, and still fall within the scope of the present utility model.

Claims (10)

1. The utility model provides an aluminium ingot pile up neatly mechanism, includes frame (9) and transmission aluminium ingot (3) conveyer belt, its characterized in that: the driving wheel (2) of the conveying belt is connected with a mounting frame through a linkage assembly, a plurality of object placing plates (5) are horizontally fixedly connected to the mounting frame, the object placing plates (5) are spaced from each other, and each aluminum ingot (3) can just enter the object placing plate (5) moving to the corresponding height along with the movement of the conveying belt (1) towards one side of the object placing plate (5).

2. The aluminum ingot palletizing mechanism of claim 1 wherein: a plurality of limit stops (4) are arranged on the conveying belt (1), and the limit stops (4) are used for being contacted with one side of the aluminum ingot (3).

3. The aluminum ingot palletizing mechanism of claim 2 wherein: the cross section of the limit stop (4) is in a right-angle trapezoid shape, and the inclined plane where the inclined edge is positioned is in fit contact with the side face of the aluminum ingot (3).

4. An aluminium ingot palletising mechanism as claimed in claim 3, wherein: the limit stop (4) is a soft rubber block.

5. The aluminum ingot palletizing mechanism of claim 1 wherein: the placement frame further comprises a vertical plate (6) and a sliding frame (7), wherein the vertical plate (6) is uniformly fixed with the placement plates (5) at intervals along the vertical direction towards one side surface of the conveying belt, the placement plates (5) are perpendicular to the vertical plate (6), the vertical plate (6) is inserted on the sliding frame (7), and the sliding frame (7) is vertically and slidably connected with the frame (9);

the sliding frame (7) is also fixedly provided with a transmission plate (11), a driving disc (12) in sliding contact with the transmission plate (11) is arranged below the transmission plate (11), a plurality of circular arc side faces are arranged on the disc edge of the driving disc (12), the central angles corresponding to the circular arc side faces are consistent, but the radiuses are different, and the radiuses of the circular arc side faces are gradually increased along the circumferential direction, so that when the driving disc (12) rotates, the sliding frame (7) rises to a corresponding height each time, and is kept at the corresponding height for a certain time.

6. The aluminum ingot palletizing mechanism of claim 5 wherein: the free end of the object placing plate (5) is an inclined surface.

7. The aluminum ingot palletizing mechanism of claim 5 wherein: the top of the sliding frame (7) is connected with a locking block (8) through a bolt, and the locking block (8) can be pressed on the vertical plate (6) when being vertically hung.

8. The aluminum ingot palletizing mechanism of claim 5 wherein: the carriage (7) is slidably mounted on the frame (9) by means of guide posts (10).

9. Aluminium ingot palletizing mechanism according to any one of claims 5-8, wherein: the driving disc (12) is coaxially fixedly connected with a worm wheel (13), the worm wheel (13) is in transmission connection with a worm (14), the worm (14) is coaxially fixedly connected with an input wheel (15), and the input wheel (15) is in transmission connection with an output wheel (16) coaxially fixedly connected with the driving wheel (2) through a transmission mechanism.

10. The aluminum ingot palletizing mechanism of claim 9 wherein: the output wheel (16) and the input wheel (15) are gears, and the transmission mechanism is a plurality of gear components; the output wheel (16) and the input wheel (15) are all chain wheels (18), and the transmission mechanism is a plurality of chain wheels (18) and a chain (17) for transmitting the plurality of chain wheels (18).