CN216004459U - Secondary aluminum recovery ingot stacking machine - Google Patents

Abstract

The utility model discloses a secondary aluminum recovery ingot stacking machine, which comprises an ingot casting device and an ingot stacking device; the ingot casting device comprises a first conveying mechanism, and a plurality of ingot casting molds are arranged on a first conveying belt of the first conveying mechanism; the ingot stacking device comprises a second conveying mechanism, a plurality of turnover mechanisms, an ingot baffle, a liftable bearing platform and a transfer mechanism with a push plate; one end of a second conveying belt of the second conveying mechanism is arranged below the first conveying belt, the other end of the second conveying belt is arranged below the ingot baffle, and the second conveying belt is divided into a plurality of placing stations; the plurality of turnover mechanisms are uniformly arranged beside the second conveying belt at intervals, and a placing station is arranged between any two adjacent turnover mechanisms at intervals; the liftable bearing platform and the push plate are symmetrically arranged on two sides of the second conveying belt and are positioned on the front side of the ingot baffle plate; the push plate can move back and forth along the direction close to or far away from the liftable bearing platform. The utility model discloses can accomplish folding spindle of aluminium ingot fast, be favorable to subsequent transportation and transfer.

Description

Secondary aluminum recovery ingot stacking machine

Technical Field

The utility model relates to an aluminium ingot production facility technical field especially relates to a secondary aluminium retrieves and folds spindle machine.

Background

Aluminum and aluminum alloys are one of the most economically feasible materials with a wide range of applications. Aluminum ingots are the name of aluminum on daily industrial raw materials, are produced by an electrolytic method by using alumina-cryolite, and need to be stacked for convenient transportation and storage operation.

In the stacking process of aluminum ingots, most of the aluminum ingots are trapezoidal hexahedrons with the cross sections of the same specification, the stacking device in the prior art can only stack the parallel aluminum ingots according to the same bottom surface orientation of the trapezoidal cross section, the longer bottom of the trapezoidal cross section like a row of aluminum ingots faces downwards, the waists of the trapezoidal cross sections of two adjacent aluminum ingots stacked by the stacking method cannot contact, a gap is reserved between the two adjacent aluminum ingots, the occupied space of the stacked aluminum ingots is larger, the stacked aluminum ingots are easy to move away when being transported, and the transportation is more inconvenient.

SUMMERY OF THE UTILITY MODEL

For solving the technical problem who exists among the background art, the utility model provides a secondary aluminum retrieves and folds ingot machine.

The utility model provides a pair of secondary aluminum retrieves and folds ingot machine, include: the ingot casting device and the ingot stacking device;

the ingot casting device comprises a first conveying mechanism, and a plurality of ingot casting molds are uniformly arranged on a first conveying belt of the first conveying mechanism;

the ingot stacking device comprises a second conveying mechanism, a plurality of turnover mechanisms, an ingot baffle, a liftable bearing platform and a transfer mechanism with a push plate;

one end of a second conveying belt of the second conveying mechanism is arranged below the first conveying belt, the other end of the second conveying belt is arranged below the ingot baffle, and the second conveying belt is divided into a plurality of placing stations for placing aluminum ingots along the direction from the second conveying mechanism to the ingot baffle;

the plurality of turnover mechanisms are uniformly arranged beside the second conveying belt at intervals along the direction from the second conveying mechanism to the ingot baffle plate, and a placing station is arranged between any two adjacent turnover mechanisms at intervals;

the liftable bearing platform and the push plate are symmetrically arranged on two sides of the second conveying belt and are positioned on one side, close to the first transmission mechanism, of the ingot baffle;

the push plate can move back and forth relative to the lifting bearing platform along the direction close to or far away from the lifting bearing platform.

Further, the lifting and transferring device further comprises a controller, and the controller is electrically connected with the first conveying mechanism, the second conveying mechanism, the turnover mechanism, the lifting and bearing platform and the transferring mechanism respectively.

Further, the transfer mechanism further comprises a horizontal pushing assembly, the horizontal pushing assembly is in driving connection with the push plate, and the horizontal pushing assembly is used for pushing the aluminum ingots accumulated in front of the ingot baffle plate to the bearing platform.

Furthermore, one side of the lifting bearing platform, which is far away from the transfer mechanism, is provided with a first positioning plate.

Furthermore, the bearing platform is symmetrically provided with second positioning plates at two sides of the first positioning plate.

Furthermore, one end of the second positioning plate, which is far away from the first positioning plate, is bent outwards to form a guide part.

Further, the push plate is in sliding contact with the ingot baffle.

In the utility model, the ingot stacking machine for recycling secondary aluminum can rapidly complete the ingot stacking of aluminum ingots by the cooperation of the first conveying mechanism, the second conveying mechanism, the plurality of turnover mechanisms, the ingot baffle, the liftable bearing platform and the transfer mechanism, thereby greatly reducing the starting and stopping times of the first conveying mechanism and the second conveying mechanism; wherein, can overturn simultaneously to being the partial aluminium ingot in the plurality of aluminium ingots that the syntropy single-row arranged through a plurality of tilting mechanism, make the longer end heterodromous of two arbitrary adjacent aluminium ingots, be favorable to the aluminium ingot to stack before the fender spindle board, make and do not have the clearance between the adjacent aluminium ingot after stacking, it is better to pile up the effect, the aluminium ingot after will stacking is wholly shifted to liftable load-bearing platform through the push pedal in the transfer mechanism work of being convenient for, and the work efficiency is improved, thereby be favorable to subsequent transportation and transfer.

Drawings

Fig. 1 is the schematic structural diagram of the secondary aluminum recovery ingot folding machine provided by the utility model.

Fig. 2 is a schematic diagram of aluminum ingot transfer in the present invention.

Detailed Description

Referring to fig. 1 and 2, the utility model provides a secondary aluminum retrieves and folds ingot machine, include: the ingot casting device and the ingot stacking device;

the ingot casting device comprises a first conveying mechanism, wherein a plurality of ingot casting molds are uniformly arranged on a first conveying belt 1 of the first conveying mechanism;

the ingot stacking device comprises a second conveying mechanism, a plurality of turnover mechanisms 3, an ingot baffle 4, a liftable bearing platform 6 and a transfer mechanism with a push plate 5;

one end of a second conveying belt 2 of the second conveying mechanism is arranged below the first conveying belt 1, the other end of the second conveying belt is arranged below the ingot baffle 4, and the second conveying belt 2 is divided into a plurality of placing stations for placing aluminum ingots along the direction from the second conveying mechanism to the ingot baffle 4;

the turnover mechanisms 3 are uniformly arranged beside the second conveying belt 2 at intervals along the direction from the second conveying mechanism to the ingot baffle 4, and a placing station is arranged between any two adjacent turnover mechanisms 3 at intervals;

the liftable bearing platform 6 and the push plate 5 are symmetrically arranged at two sides of the second conveying belt 2 and are positioned at one side of the ingot baffle 4 close to the first transmission mechanism; wherein, the push plate 5 can move back and forth relative to the liftable bearing platform 6 along the direction close to or far away from the liftable bearing platform 6.

When the utility model is used in detail, the first conveying mechanism and the second conveying mechanism work, and the aluminum ingots on the ingot casting mold of the first conveying belt 1 fall off to the second conveying belt 2 one by one; when aluminum ingots are placed on the placing stations on the second conveying belt 2, the first transmission mechanism and the second conveying mechanism stop working, then the plurality of turnover mechanisms 3 work simultaneously to turn over the aluminum ingots on the corresponding placing stations simultaneously, so that the longer bottoms of the aluminum ingots on any two adjacent placing stations face opposite directions, namely one is upward and the other is downward;

when the overturning is finished, the first conveying mechanism and the second conveying mechanism continue to work, and the second conveying belt 2 drives the aluminum ingot to move to the ingot baffle 4 and pile up before the ingot baffle 4; meanwhile, the aluminum ingots on the ingot casting molds of the first conveying belt 1 fall off one by one to the second conveying belt 2 for conveying;

after the aluminum ingots after being turned over are stacked, the first transmission mechanism and the second conveying mechanism stop working, and the push plate 5 of the transfer mechanism moves the stacked aluminum ingots towards the direction close to the liftable bearing platform 6, so that the stacked aluminum ingots are transferred to the liftable bearing platform 6;

meanwhile, the aluminum ingots on the corresponding placing stations are simultaneously overturned by the plurality of overturning mechanisms 3.

Therefore, the utility model can complete the ingot stacking of the aluminum ingots rapidly through the cooperation of the first conveying mechanism, the second conveying mechanism, the plurality of turnover mechanisms 3, the ingot baffle 4, the liftable bearing platform 6 and the transfer mechanism, and greatly reduce the starting and stopping times of the first conveying mechanism and the second conveying mechanism; wherein, can overturn simultaneously to being the partial aluminium ingot in a plurality of aluminium ingots that the syntropy single-row arranged through a plurality of tilting mechanism 3, make the longer end heterodromous of two arbitrary adjacent aluminium ingots, be favorable to stacking of aluminium ingot before fender spindle board 4, make and not have the clearance between the adjacent aluminium ingot after stacking, it is better to pile up the effect, the aluminium ingot after will stacking is wholly shifted to liftable load-bearing platform 6 through push pedal 5 in the transfer mechanism work of being convenient for, be favorable to subsequent transportation and transfer.

Of course, the gap between the first conveyor belt 1 and the second conveyor belt 2 is set according to the design of the person skilled in the art, which is the prior art, so that the aluminum ingots falling off from the ingot casting mold onto the second conveyor belt 2 are all unidirectional, that is, the longer bottom of the aluminum ingot faces downward.

In this embodiment, the lifting device further comprises a controller, and the controller is electrically connected with the first conveying mechanism, the second conveying mechanism, the turnover mechanism 3, the lifting bearing platform 6 and the transfer mechanism respectively.

In this embodiment, the transfer mechanism further comprises a horizontal pushing assembly, the horizontal pushing assembly is in driving connection with the pushing plate 5, and the horizontal pushing assembly is used for pushing the aluminum ingots stacked in front of the ingot baffle 4 onto the bearing platform 6.

In order to avoid the position change of the stacked aluminum ingots when being stressed, in the embodiment, a first positioning plate 7 is arranged on one side, away from the transfer mechanism, of the liftable bearing platform 6.

In a further embodiment, the bearing platform 6 is symmetrically provided with second positioning plates 8 at two sides of the first positioning plate 7.

So set up, two second locating plates 8 of accessible and a first locating plate 7 are fixed a position the aluminium ingot of piling up, have effectively avoided being shifted to the position change of the aluminium ingot of piling up of previous batch that liftable load-bearing platform 6 leads to at new aluminium ingot, have made things convenient for subsequent transportation.

In order to facilitate the transfer of a new batch of aluminum ingots, in a further embodiment, an end of the second positioning plate 8 remote from the first positioning plate 7 is bent outwards to form a guide.

In order to turn over the aluminum ingot conveniently, in the present embodiment, each turning mechanism 3 includes two turning clamping mechanisms symmetrically disposed on the second transmission mechanism.

Of course, in other embodiments, the turnover mechanism 3 may also be other turnover structures for turning over aluminum ingots, and the turnover clamping mechanism is the prior art and will not be described herein.

To further avoid the stacked aluminum ingots from being deformed during pushing, the push plate 5 is in sliding contact with the ingot guard 4 in this embodiment.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. A secondary aluminum recovery ingot stacking machine is characterized by comprising: the ingot casting device and the ingot stacking device;

the ingot casting device comprises a first conveying mechanism, wherein a plurality of ingot casting molds are uniformly arranged on a first conveying belt (1) of the first conveying mechanism;

the ingot stacking device comprises a second conveying mechanism, a plurality of turnover mechanisms (3), an ingot baffle plate (4), a liftable bearing platform (6) and a transfer mechanism with a push plate (5);

one end of a second conveying belt (2) of the second conveying mechanism is arranged below the first conveying belt (1), the other end of the second conveying belt is arranged below the ingot baffle plate (4), and the second conveying belt (2) is divided into a plurality of placing stations for placing aluminum ingots along the direction from the second conveying mechanism to the ingot baffle plate (4);

the turnover mechanisms (3) are uniformly arranged beside the second conveying belt (2) at intervals along the direction from the second conveying mechanism to the ingot baffle (4), and a placing station is arranged between any two adjacent turnover mechanisms (3);

the liftable bearing platform (6) and the push plate (5) are symmetrically arranged on two sides of the second conveying belt (2) and are positioned on one side, close to the first transmission mechanism, of the ingot baffle (4);

wherein, the push plate (5) can move back and forth relative to the lifting bearing platform (6) along the direction close to or far away from the lifting bearing platform (6).

2. The secondary aluminum recovery ingot folding machine according to claim 1, further comprising a controller, wherein the controller is electrically connected with the first conveying mechanism, the second conveying mechanism, the turnover mechanism (3), the liftable bearing platform (6) and the transfer mechanism respectively.

3. A secondary aluminum recovery ingot folding machine according to claim 1, characterized in that the transfer mechanism further comprises a horizontal pushing assembly, the horizontal pushing assembly is in driving connection with the pushing plate (5), and the horizontal pushing assembly is used for pushing the aluminum ingots stacked in front of the ingot baffle plate (4) onto the bearing platform (6).

4. A secondary aluminum recovery ingot stacking machine according to claim 1, wherein a first positioning plate (7) is arranged on one side of the liftable bearing platform (6) far away from the transfer mechanism.

5. A secondary aluminum recovery ingot folding machine according to claim 4, characterized in that the bearing platform (6) is symmetrically provided with a second positioning plate (8) at two sides of the first positioning plate (7).

6. A secondary aluminum recovery ingot folding machine according to claim 5, characterized in that the end of the second positioning plate (8) away from the first positioning plate (7) is bent outwards to form a guide.

7. A secondary aluminum recovery ingot stacker according to claim 1, wherein the push plate (5) is in sliding contact with the ingot baffle plate (4).

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