CN117184844A - A high-efficient turning device and upset assembly line for preprinting aluminum plate pile up neatly - Google Patents

Abstract

A high-efficient turning device and upset assembly line for preprinting aluminum plate pile up neatly, including two relative distribution's carousel, be used for driving carousel pivoted upset actuating mechanism and fix two sets of first conveying rollers between two carousels, the direction of delivery of two sets of first conveying rollers is parallel to each other to be equipped with between two sets of first conveying rollers along the gliding rectangle baffle of direction of delivery that can follow first conveying roller, the position that is close to the tip on the rectangle baffle side all is equipped with the sliding shaft, is equipped with the sliding shaft sliding fit's of supply department on the carousel respectively spout. The turnover device is used for improving turnover efficiency to adapt to capacity adaptation requirements of a plurality of aluminum plate drying production lines.

Description

A high-efficient turning device and upset assembly line for preprinting aluminum plate pile up neatly

Technical Field

The invention relates to the technical field of production and processing of preprinted aluminum plates, in particular to a high-efficiency turnover device and a turnover assembly line for stacking the preprinted aluminum plates.

Background

The preprinted aluminum plate is a prefabricated plate-shaped raw material for producing the cover bodies of various containers such as beverages, beer, cans and the like, marks such as trademark patterns, text information and the like required by customers are printed on an aluminum belt in an array mode, the continuous aluminum belt is cut into the aluminum plate, and the preprinted aluminum plate is obtained after drying and cooling. In downstream production, a single piece of pre-printed aluminum sheet is stamped to simultaneously obtain a plurality of corresponding container tops. Conventional aluminum plate drying line 3 typically dries the aluminum plate with the printing face up through a conveyor belt continuously through a drying tunnel. The aluminum sheets passing through the drying tunnel are turned over and dropped onto the pallet 10 in the palletizing box, so that the plurality of aluminum sheets form the pre-printed aluminum sheet palletizing 11 in a print-facing downward posture.

Because of the requirements of some customers, the printed surface is required to be kept upwards for subsequent processing when the pre-printed aluminum plates are delivered, and the pre-printed aluminum plates produced by the drying production line are required to be stacked 11 and turned over and then stored or directly loaded for delivery. Based on this applicant developed a turnover special mechanism for preprinted aluminum sheets, which has two turntables 2 and a turnover driving mechanism 6 for driving the turntables 2 to rotate, wherein two groups of first conveying rollers 1 are arranged between the two turntables 2, a track 4 for covering a plurality of aluminum sheet drying production lines 3 is arranged on the front side of the first conveying rollers 1, and a second conveying roller 5 is arranged on the track 4 in a sliding manner, as shown in fig. 8 and 9. The implementation process of the special overturning mechanism is as follows: after the second conveying roller 5 receives the pre-printed aluminum plate stacks 11 produced by each aluminum plate drying production line 3, the pre-printed aluminum plate stacks 11 are conveyed to the position shown in fig. 8 along the track 4, another tray 10 is placed on the top of the pre-printed aluminum plate stacks 11, and the pre-printed aluminum plate stacks 11 are conveyed to the first conveying roller 1 at the bottom through the cooperation of the second conveying roller 5 and the first conveying roller 1. Then the first conveying roller 1 positioned above is driven to be pressed down to contact with the upper tray 10, and the turnover driving mechanism 6 drives the turntable 2 to rotate 180 degrees, so that the turnover of the pre-printed aluminum plate stacking 11 is completed, and the pre-printed aluminum plate stacking 11 can be forked out at the rear side of the turnover mechanism through a forklift.

In the overturning process, in order to prevent the pre-printed aluminum plate stacking 11 from falling off from the rear side of the first conveying roller 1 in the overturning process, a rectangular baffle plate 9 is arranged at a position, which is located at the rear side of the first conveying roller 1, between the turntables 2. As shown in fig. 9, the rectangular baffle plate 9 is fixedly mounted on the turntable 2 in a matched manner, so that when one pre-printed aluminum plate stacking 11 is turned over, the rectangular baffle plate 9 is synchronously turned over to the front side of the first conveying roller 1 close to the track 4, and the second conveying roller 5 is prevented from being fed into the other pre-printed aluminum plate stacking 11 towards the turning mechanism. At this time, after the turntable 2 needs to be driven to rotate 180 ° again by the turnover driving mechanism 6 to reset to the initial state shown in fig. 8, the subsequent turnover of the pre-printed aluminum plate stacking 11 can be continued. In order to ensure the overturning stability of the pre-printed aluminum plate stacking 11, the overturning driving mechanism 6 only drives the turntable 2 to rotate at a slower speed, so that the overturning efficiency of the technical scheme is lower, and the output matching requirement of the aluminum plate drying production line 3 cannot be met.

Disclosure of Invention

The invention aims to provide a high-efficiency overturning device and an overturning assembly line for pre-printed aluminum plate stacking, which improve overturning efficiency to adapt to capacity adaptation requirements of a plurality of aluminum plate drying production lines.

In order to solve the technical problems, the invention adopts the following specific scheme: the utility model provides a high-efficient turning device for preprinting aluminum plate pile up neatly, including two relative distribution's carousel, be used for driving carousel pivoted upset actuating mechanism and fix two sets of first conveying rollers between two carousels, the direction of delivery of two sets of first conveying rollers is parallel to each other to be equipped with along the gliding rectangle baffle of direction of delivery along first conveying roller between two sets of first conveying rollers, the position that is close to the tip on the rectangle baffle side all is equipped with the sliding shaft, is equipped with the sliding shaft sliding fit's of supply department on the carousel respectively.

Preferably, the turntable is provided with a lifting driving mechanism, and the lifting driving mechanism is used for driving the first conveying roller to slide along the direction perpendicular to the conveying direction; the roller frame of the first conveying roller is arranged on a sliding rail fixed on the turntable in a sliding way, and the lifting driving mechanism is a hydraulic cylinder acting on the roller frame of the first conveying roller.

Preferably, the overturning driving mechanism is a driving motor, and an output shaft of the driving motor is in transmission connection with a central shaft arranged at the center of one of the turntables.

Preferably, the two turntables are fixedly connected through an arc-shaped reinforcing plate at the outer side of the first conveying roller.

Preferably, the sliding shafts are respectively provided with a linkage gear in a rotating way, and the opposite sides of the two sliding grooves on the same rotary table are respectively provided with racks for the corresponding linkage gears to be meshed and matched;

and one of the two linkage gears on the same rotary table is in running fit with an idler wheel arranged on the outer side of the rotary table after penetrating out of the rotary table, the idler wheel is rotatably sleeved on a supporting shaft and is concentrically fixed with a first sprocket, the supporting shaft is in sliding fit with a guide groove arranged on the outer side of the rotary table, and the first sprocket is in transmission connection with a second sprocket arranged on a sliding shaft where the other linkage gear is arranged through a chain.

Preferably, the chute is disposed through the thickness direction of the turntable.

Preferably, the guide slot is T-shaped or dovetail-shaped.

The utility model provides a high-efficient upset assembly line for preprinting aluminum plate pile up neatly, includes track, slip second conveying roller and foretell high-efficient turning device that is used for preprinting aluminum plate pile up neatly that sets up on the track, and the track is along horizontal many aluminum plate stoving production lines of covering, and the second conveying roller is used for carrying the preprinting aluminum plate pile up neatly of each aluminum plate stoving production line output to be located on the first conveying roller of a set of high-efficient turning device bottom.

Advantageous effects

The rectangular baffle plate is arranged between the two first conveying rollers in a sliding manner along the conveying direction of the first conveying rollers, overturning of the pre-printed aluminum plate stacking is completed by rotating the turntable by 180 degrees, after the rectangular baffle plate is rotated to the front side of the first conveying rollers, another pre-printed aluminum plate stacking can be directly connected from the front side of the first conveying rollers again, and the rectangular baffle plate is synchronously moved backwards by the pre-printed aluminum plate stacking itself in the backward moving process of pushing the pre-printed aluminum plate stacking by the first conveying rollers until the rectangular baffle plate moves to the rear end of the chute to limit and block the pre-printed aluminum plate stacking, and then the turntable can be rotated by 180 degrees again to overturn the pre-printed aluminum plate stacking. The process is repeatedly carried out, namely, the problem that after one preprinted aluminum plate is turned over to be stacked, the rectangular baffle plate is reset by rotating the turntable again, and then the other preprinted aluminum plate is connected to the first conveying roller to be stacked is solved, so that the turnover efficiency of the preprinted aluminum plate to be stacked is greatly improved, and the continuous output of a plurality of aluminum plate drying production lines is adapted.

In the preferred embodiment of the invention, the top and the bottom of the same side of the rectangular baffle plate are matched through the linkage gears, the chain wheels and the chains to realize synchronous and same-amplitude movement along the corresponding sliding grooves, so that the rectangular baffle plate can be kept to be always vertical to the conveying direction of the first conveying roller, the phenomenon that the rectangular baffle plate is inclined to the conveying direction of the first conveying roller due to center deviation caused by overturning of a turntable, vibration of a motor or other factors in the operation process is avoided, and the problem that the inclined top of the rectangular baffle plate reversely pushes the upper part of the prefabricated aluminum plate to incline in the process of pushing the rectangular baffle plate to move towards the rear side of the first conveying roller is caused, thereby being beneficial to maintaining the shape regularity of the appearance of the overturned prefabricated aluminum plate stack and avoiding reworking and shaping.

Drawings

Fig. 1 is a schematic structural diagram of a high-efficiency overturning assembly line for pre-printing aluminum plate stacking according to embodiment 1 of the present invention;

FIGS. 2-4 are schematic cross-sectional views of A-A in FIG. 1, which are schematic views of a high-efficiency turnover device for pre-printing aluminum plate stacking in the embodiment 1 in the implementation process;

fig. 5 is a schematic view showing the inclined state of the rectangular shutter in embodiment 1;

fig. 6 is a schematic side view of a high-efficiency turnover device in a high-efficiency turnover line for pre-printing aluminum plate stacking according to embodiment 2 of the present invention;

FIG. 7 is a schematic view of the cross-sectional structure B-B of FIG. 6;

fig. 8 is a schematic view of the front side structure of a turnover dedicated mechanism for preprinted aluminum sheets mentioned in the background art;

fig. 9 is a schematic view of the rear side structure of a turnover dedicated mechanism for preprinted aluminum sheets mentioned in the background art;

the marks in the figure: 1. the aluminum plate drying device comprises a first conveying roller, 101, a roller body, 102, a roller frame, 2, a turntable, 3, an aluminum plate drying production line, 4, a track, 5, a second conveying roller, 6, a turnover driving mechanism, 7, a chute, 8, a sliding shaft, 9, a rectangular baffle plate, 10, a tray, 11, a pre-printed aluminum plate stacking, 12, a second sprocket, 13, a linkage gear, 14, a rack, 15, a chain, 16, an idler, 17, a first sprocket, 18, a supporting shaft, 19, a guide groove, 20 and a connecting plate.

Detailed Description

The following describes a high-efficiency turnover device and turnover assembly line for pre-printing aluminum plate stacking by two embodiments:

example 1

As shown in fig. 1, an efficient overturning assembly line for pre-printed aluminum plate stacking in this embodiment includes a rail 4, a second conveying roller 5 slidably disposed on the rail 4, and an efficient overturning device for pre-printed aluminum plate stacking 11. A plurality of aluminum plate drying production lines 3 (two are shown in the figure) are longitudinally distributed along the rail 4, and the output positions of the pre-printed aluminum plate stacking 11 of all the aluminum plate drying production lines 3 are close to the rail 4. The efficient turnover device is provided with two turntables 2 which are distributed vertically, the two turntables 2 are distributed oppositely, and two groups of first conveying rollers 1 are symmetrically arranged between the two turntables 2 at intervals. The second conveying roller 5 is used for receiving the pre-printed aluminum plate stacking 11 produced by each aluminum plate drying production line 3, and conveying the pre-printed aluminum plate stacking 11 to the first conveying roller 1 positioned at the bottom of the efficient turnover device through the same-direction conveying cooperation with the first conveying roller 1 positioned at the bottom of the efficient turnover device. Then the turntable 2 can be driven to rotate 180 degrees through the turnover driving mechanism 6, and the turnover of the pre-printed aluminum plate stacking 11 is completed.

As shown in fig. 2, a rectangular baffle plate 9 is further arranged between the two groups of first conveying rollers 1 and positioned at the rear side of the production line, and the rectangular baffle plate 9 is used for preventing the pre-printed aluminum plate stacking 11 from falling off from the rear side of the first conveying rollers 1 in the overturning process. In order to further improve the overturning efficiency, the top and bottom positions of the two side edges of the rectangular baffle plate 9 in the embodiment are respectively fixedly provided with a sliding shaft 8, the turntable 2 is correspondingly provided with sliding grooves 7 for sliding fit of the sliding shafts 8, and the sliding grooves 7 are distributed along the conveying direction parallel to the first conveying roller 1, so that under the condition that the rectangular baffle plate 9 is not required to be driven to reset, the high-efficiency overturning device is continuously connected with the pre-printed aluminum plate stacking 11 and continuously carries out overturning operation, and the overturning efficiency is improved. Specific:

in the process of moving the pre-printed aluminum plate stack 11 to the high-efficiency turnover mechanism along the track 4 through the second conveying roller 5, another tray 10 is placed on the top of the pre-printed aluminum plate stack 11, after the second conveying roller 5 shown in fig. 2 corresponds to the first conveying roller 1 positioned at the bottom of the high-efficiency turnover mechanism, each conveying roller in the first conveying roller 1 and the second conveying roller 5 is controlled to rotate at a synchronous constant speed and clockwise, and the pre-printed aluminum plate stack 11 is fed onto the first conveying roller 1 positioned at the bottom. After the first conveying roller 1 at the top is driven to be downwards pressed to the tray 10 at the top, the turntable 2 is driven to rotate 180 degrees through the turnover driving mechanism 6 to finish turnover of the pre-printed aluminum plate stacking 11, and at the moment, after the first conveying roller 1 at the top is driven to ascend, the reversed pre-printed aluminum plate stacking 11 can be taken out through fork loading tools such as forklifts and ground cows.

After taking out the pre-printed aluminum plate stacking 11, the rectangular baffle plate 9 is positioned at the position shown in fig. 3, at the moment, the next pre-printed aluminum plate stacking 11 is directly conveyed into the efficient turnover mechanism by the cooperation of the second conveying roller 5 and the first conveying roller 1, the rectangular baffle plate 9 is pushed by the pre-printed aluminum plate stacking 11 to move rightwards until each sliding shaft 8 moves to the right end of the sliding groove 7 along the corresponding sliding groove 7 as shown in fig. 4, and the right end of the sliding groove 7 supports and blocks each sliding shaft 8, so that the reset of the rectangular baffle plate 9 is automatically completed, and the turnover driving mechanism 6 drives the rotary disc 2 to rotate 180 degrees, so that the turnover of the pre-printed aluminum plate stacking 11 is completed.

In this embodiment, a central shaft is disposed at the center of one of the turntables 2, the overturning driving mechanism 6 is a driving motor, and an output shaft of the driving motor is in transmission connection with the central shaft through a speed reducer, so as to control the turntables 2 to rotate at a specific angle by controlling the rotation angle of the driving motor. For the two groups of first conveying rollers 1, a lifting driving mechanism is arranged on the turntable 2, the lifting driving mechanism is a hydraulic cylinder, the cylinder body of the hydraulic cylinder is fixed on the turntable 2, and a piston rod is connected with a roller frame 102 of the first conveying roller 1 so as to realize the integral lifting of the first conveying roller 1 by pushing and pulling the roller frame 102 through the piston rod. The above lifting drive mechanism drives the overall lifting of the first conveying roller 1 as a conventional technical means in the art, and is not shown in the drawings. In order to ensure the overall structural strength of the efficient turnover device, arc-shaped reinforcing plates are respectively arranged between the two turntables 2 and positioned outside the two first conveying rollers 1 for fixing, as shown in fig. 8 and 9.

Example 2

In the efficient turnover mechanism of the above embodiment 1, in order to avoid the blocking caused by uneven stress of the rectangular baffle 9 in the matching process of the sliding shaft 8 and the sliding groove 7 in the process of pushing the rectangular baffle 9 by the pre-printed aluminum plate stacking 11 along with the first conveying roller 1, the width of the sliding groove 7 needs to be slightly larger than the outer diameter of the sliding shaft 8. However, in the implementation process, it is found that the rectangular baffle plate 9 is easy to be in an inclined state as shown in fig. 5 after the overturning of the pre-printed aluminum plate stacking 11 due to the change of the gravity center position of the rectangular baffle plate 9 or the vibration action generated by the driving motor in the rotating process of the turntable 2. At this time, the second conveying roller 5 and the first conveying roller 1 cooperate to convey the pre-printed aluminum plate stack 11 into the first conveying roller 1, and in the process that the first conveying roller 1 pushes the pre-printed aluminum plate stack 11 rightward and pushes the rectangular baffle plate 9 to reset to the right side of the first conveying roller 1, the upper part of the inclined rectangular baffle plate 9 abuts against the upper part of the pre-printed aluminum plate stack 11, and the friction force between a plurality of pre-printed aluminum plates positioned on the upper part of the pre-printed aluminum plate stack 11 is smaller due to the lack of necessary pressure, so that the pre-printed aluminum plates are easy to skew due to the pressure of the upper part of the rectangular baffle plate 9, the pre-printed aluminum plate stack is further corrected after overturning, and labor is wasted.

In order to solve the above technical problems possibly existing in embodiment 1, in this embodiment, the top and the bottom of the rectangular baffle plate 9 are linked, so that the top and the bottom of the rectangular baffle plate 9 are always kept perpendicular to the conveying direction of the first conveying roller 1, so that the pre-printed aluminum plate stack 11 is in full contact with the side portion of the rectangular baffle plate 9 in the process of pushing the rectangular baffle plate 9 to reset, and further, the situation that the reaction force of the rectangular baffle plate 9 on the pre-printed aluminum plate stack 11 is concentrated on a plurality of pre-printed aluminum plates on the upper portion of the pre-printed aluminum plate stack 11 to cause the whole skew of the pre-printed aluminum plate stack 11 is avoided, which is as follows:

the present embodiment is identical to the main structure of embodiment 1, and differs only in the linkage structure of the top and bottom of the rectangular shutter 9 in the high-efficiency tilting mechanism of the present embodiment: as shown in fig. 6 and 7, the sliding shafts 8 in the present embodiment are each rotatably provided with a (by rolling bearing rotation, the same applies hereinafter) interlocking gear 13. The sliding grooves 7 are all formed through the rotary table 2, racks 14 longitudinally distributed along the sliding grooves 7 are arranged on the lower edge of the upper sliding groove 7 and the upper edge of the lower sliding groove 7 of the same rotary table 2, and the racks 14 are engaged with the linkage gears 13 at corresponding positions. The engagement relationship between the linkage gear 13 and the corresponding rack 14 ensures that the rectangle is always in a state perpendicular to the conveying direction of the first conveying roller 1. The bottom-located linkage gear 13 in fig. 6 and 7 is longer in length, and the portion of the linkage gear that passes through the chute 7 is engaged with an idler gear 16. The idler wheel 16 is provided with a support shaft 18, one end of the support shaft 18 is in sliding fit with a guide groove 19 arranged on the outer side of the turntable 2, the guide groove 19 and the corresponding supported end are T-shaped, and the support shaft 18 and the idler wheel 16 on the support shaft are prevented from being separated while the flexible sliding is ensured; the other end of the support shaft 18 is fixed with the sliding shaft 8 at the bottom through a connecting plate 20 (not shown in fig. 6 because shielding is avoided), so that the support shaft 18 and the sliding shaft 8 at the bottom are fixed through the connecting plate 20, and the meshing transmission connection of the idler gear 16 and the bottom linkage gear 13 is always kept. The outside of the idler wheel 16 is also concentrically and fixedly connected with a first sprocket 17, a second sprocket 12 is concentrically and fixedly arranged on the linkage gear 13 positioned at the top, and the second sprocket 12 is in transmission connection with the first sprocket 17 through a chain 15.

Based on the above difference from embodiment 1, this embodiment takes the example that in the process of pushing the rectangular shutter 9 to move by the pre-printed aluminum plate stack 11, the rectangular shutter 9 is pushed to move to the right side by the pre-printed aluminum plate stack 11 in the state shown in fig. 6: the bottom linkage gear 13 is matched with the corresponding rack 14 to rotate in the anticlockwise direction, the idler wheel 16 and the first sprocket 17 are driven to rotate in the clockwise direction, and the first sprocket 17 drives the second sprocket 12 and the top linkage gear 13 to synchronously rotate in the clockwise direction through the chain 15; while the top linkage gear 13 is rotated in the clockwise direction, the bottom linkage gear 13 can also be driven to rotate in the counterclockwise direction by the second sprocket 12-chain 15-first sprocket 17. Thereby ensuring that the linkage gears 13 at the top and the bottom rotate in the same transfer and reverse directions, so that the upper part and the lower part of the rectangular baffle plate 9 advance to the right at the same speed, and the rectangular baffle plate 9 is always distributed perpendicular to the conveying direction of the first conveying roller 1, thereby avoiding the generation of the inclined posture as shown in fig. 5 to press and skew the pre-printed aluminum plate stacking 11.

Claims (9)

1. A high-efficient turning device for preprinting aluminum plate pile up neatly, its characterized in that: including two relative distribution's carousel (2), be used for driving carousel (2) pivoted upset actuating mechanism (6) and fix two sets of first conveying roller (1) between two carousels (2), the direction of delivery of two sets of first conveying roller (1) is parallel to each other, and be equipped with between two sets of first conveying roller (1) along can follow the gliding rectangle baffle (9) of direction of delivery of first conveying roller (1), the position that is close to the tip on rectangle baffle (9) side all is equipped with sliding shaft (8), be equipped with respectively on carousel (2) and supply sliding shaft (8) sliding fit's of department spout (7).

2. A high efficiency turning device for palletizing preprinted aluminum sheets as defined in claim 1, wherein: the rotary table (2) is provided with a lifting driving mechanism which is used for driving the first conveying roller (1) to slide along the direction vertical to the conveying direction; the roller frame (102) of the first conveying roller (1) is arranged on a sliding rail fixed on the turntable (2) in a sliding way, and the lifting driving mechanism is a hydraulic cylinder acting on the roller frame (102) of the first conveying roller (1).

3. A high efficiency turning device for palletizing preprinted aluminum sheets as defined in claim 1, wherein: the overturning driving mechanism (6) is a driving motor, and an output shaft of the driving motor is in transmission connection with a central shaft arranged at the central position of one turntable (2).

4. A high efficiency turning device for palletizing preprinted aluminum sheets as defined in claim 3, wherein: the two turntables (2) are fixedly connected with each other through an arc-shaped reinforcing plate at positions positioned on the outer sides of the first conveying rollers (1).

5. A high efficiency turning device for palletizing preprinted aluminum sheets as defined in claim 1, wherein: the sliding shafts (8) are respectively provided with a linkage gear (13) in a rotating way, and racks (14) for the corresponding linkage gears (13) to be meshed and matched are respectively arranged on opposite sides of two sliding grooves (7) on the same rotary table (2);

in two linkage gears (13) located on the same rotary table (2), one linkage gear (13) is in running fit with an idler wheel (16) arranged on the outer side of the rotary table (2) after penetrating out of the rotary table (2), the idler wheel (16) is rotationally sleeved on a supporting shaft (18) and is concentrically fixed with a first sprocket (17), the supporting shaft (18) is in sliding fit with a guide groove (19) formed in the outer side of the rotary table (2), and the first sprocket (17) is in transmission connection with a second sprocket (12) arranged on a sliding shaft (8) where the other linkage gear (13) is located through a chain (15).

6. A high efficiency turning device for palletizing preprinted aluminum sheets as defined in claim 5, wherein: the supporting shaft (18) and the corresponding sliding shaft (8) are connected through a connecting plate (20).

7. A high efficiency turning device for palletizing preprinted aluminum sheets as defined in claim 5, wherein: the chute (7) penetrates through the thickness direction of the turntable (2).

8. A high efficiency turning device for palletizing preprinted aluminum sheets as defined in claim 5, wherein: the guide groove (19) is T-shaped or dovetail-shaped.

9. A high-efficient upset assembly line for preprinting aluminum plate pile up neatly, its characterized in that: including track (4), slip setting second conveying roller (5) on track (4) and be used for the high-efficient turning device of preprinting aluminum plate pile up neatly of arbitrary one of claim 1-8, track (4) are along transversely covering many aluminum plate stoving production lines (3), and second conveying roller (5) are used for carrying the preprinting aluminum plate pile up neatly (11) of each aluminum plate stoving production line (3) output to be located on a set of first conveying roller (1) of high-efficient turning device bottom.