CN209957908U - Transverse anode carbon block grouping machine - Google Patents

Abstract

The utility model discloses a transverse anode carbon block grouping machine, which comprises a conveyor, a first conveying device and a second conveying device, wherein the conveyor is used for conveying transverse green carbon blocks to be grouped and horizontally placed; the automatic turning device comprises a block pushing machine and a turning machine, wherein the block pushing machine is connected with the output end of the conveyor, the block pushing machine pushes the raw carbon blocks conveyed by the conveyor to the turning machine, and the turning machine turns the horizontally placed raw carbon blocks to be in a vertical state; the grouping basket is connected with the turnover machine, the block pushing machine pushes the raw carbon blocks in a vertical state on the turnover machine to the grouping basket, and the grouping basket is used for receiving the grouped raw carbon blocks; the central lines of the conveyor, the block pushing machine, the turnover machine and the marshalling basket are all on the same straight line. So set up, simple structure, action part are few, and area is little to solved current marshalling equipment whole asymmetry, the overall arrangement is in disorder and area is great, the structure is complicated, the problem that the fault rate is high.

Description

Transverse anode carbon block grouping machine

Technical Field

The utility model relates to the technical field of electrolytic aluminum industry, in particular to a transverse anode carbon block braiding machine.

Background

The anode carbon block grouping machine set is a large-scale automatic set and is used in an anode roasting workshop to group the green anode carbon blocks so that a multifunctional crown block can clamp the roasted carbon blocks into a roasting furnace for roasting. The anode carbon block used in the electrolytic aluminum industry is a cooked carbon block formed by roasting a green carbon block. The carbon blocks which are not treated by the roasting process are called green carbon blocks, the roasted carbon blocks are called cooked carbon blocks, the roasting furnace is pit-shaped, in order to facilitate the carbon blocks to enter and exit the roasting furnace and improve the production efficiency, the horizontally placed carbon blocks need to be erected side by side, the carbon bowls 17 face to the positive direction and the negative direction in sequence, and the process is called grouping. The carbon bowl 17 is a specially made process pit for assembling the carbon block and the anode rod together for convenience.

As shown in fig. 1 to 3, the operation process of the present apparatus for grouping horizontally arranged carbon blocks in the electrolytic aluminum industry is as follows: a group of horizontally-arranged raw carbon blocks 1 clamped by a stacking crown block and received by a conveyor 2 in a raw carbon block warehouse stops conveying the raw carbon blocks 1 to the tail end of the conveyor 2 in a roasting workshop at one time, the raw carbon blocks are pushed onto an L-shaped turnover machine 15 by a first material pushing machine 13 which is positioned on one side of the conveyor 2 and is vertical to the conveyor 2, the raw carbon blocks are turned over by the L-shaped turnover machine 15 for 90 degrees, carbon bowls 17 are turned upside down, and the raw carbon blocks 1 vertically placed on the L-shaped turnover machine 15 are pushed by a second material pushing machine 14 which is parallel to the conveyor 2 to pass through a horizontal rotary table 16 and then are continuously pushed forwards into a marshalling basket 5; repeating the above actions, and when the next carbon block 1 reaches the horizontal rotary table 16, rotating the next carbon block by 180 degrees through the horizontal rotary table 16 to realize that the carbon bowl 17 faces to the direction opposite to the direction of the previous carbon block 1, and then pushing the carbon block into the marshalling basket 5 through the second material pushing machine 14; repeating the procedures until the receiving groove of the grouping basket 5 receives 7-8 vertically-arranged charcoal block groups, translating the grouping basket 5 to make the other groove hollow basket align to the horizontal rotary table 16, and then grouping the charcoal blocks. Due to the design layout, the central lines of the marshalling basket 5, the horizontal rotary table 16 and the conveyor 2 are in parallel positions but not on the same central line, the first material pusher 13 is arranged on one side of the conveyor 2 and is perpendicular to the conveyor 2, the overall layout of the equipment is asymmetric, the layout is messy, and the occupied area is large; the whole device is provided with the first pusher 13 and the second pusher 14, so that the structure is complex, and the failure rate is higher. Therefore, a flat-row green anode carbon block braiding machine which is simple in structure, less in action parts and smaller in occupied area needs to be researched.

Therefore, how to solve the problems of overall asymmetry, messy layout, large occupied area, complex structure and high failure rate of the existing marshalling equipment becomes an important technical problem to be solved by technical personnel in the field.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a horizontal anode carbon piece marshalling machine to solve the whole asymmetry of current marshalling equipment, the overall arrangement is in disorder and area is great, the structure is complicated, the problem that the fault rate is high.

The utility model aims at realizing through the following technical scheme:

a transverse anode carbon block grouping machine comprises:

the conveyer is used for conveying the horizontal row of the carbon blocks to be grouped and horizontally placed;

the automatic turning device comprises a block pushing machine and a turning machine, wherein the block pushing machine is connected with the output end of the conveyor, the block pushing machine pushes the raw carbon blocks conveyed by the conveyor to the turning machine, and the turning machine turns the horizontally placed raw carbon blocks to be in a vertical state;

the grouping basket is connected with the turnover machine, the block pushing machine pushes the raw carbon blocks in a vertical state on the turnover machine to the grouping basket, and the grouping basket is used for receiving the grouped raw carbon blocks;

the central lines of the conveyor, the block pushing machine, the turnover machine and the marshalling basket are all on the same straight line.

Preferably, a push plate is rotatably arranged on the block pushing machine, two rows of rollers are arranged on two sides of the block pushing machine, the rollers are used for conveying the raw carbon blocks to the position, close to the turnover machine, on the block pushing machine, the upper ends of the push plate extend out of the rollers, and when the raw carbon blocks move forwards to the push plate on the rollers, the raw carbon blocks push the push plate to rotate to a first position in the advancing direction of the raw carbon blocks; when the green carbon blocks move forwards to leave the push plate, the push plate rotates to the initial position, the block pushing machine moves forwards, and the push plate pushes the green carbon blocks to the turnover machine.

Preferably, a stop block is arranged on one side, close to the conveyor, of the push plate on the push block machine to prevent the push plate from rotating towards the conveyor, and a balancing weight is arranged on one side, close to the conveyor, of the lower end of the push plate to enable the green carbon blocks to move forwards until the green carbon blocks leave the push plate, and the push plate returns to an initial position under the action of gravity.

Preferably, the rollers are unpowered rollers, both rows of which are inclined downwardly.

Preferably, the turnover machine comprises a rotatable shell, an empty slot for placing the carbon block is arranged in the shell in a penetrating manner, the carbon block enters the empty slot in a horizontal state, and the turnover machine rotates clockwise or anticlockwise for 90 degrees so that the carbon block is in a vertical state.

Preferably, the empty groove is two, and mutually perpendicular, is "ten" the setting.

Preferably, two the dead slot is square, the shell of upset machine still runs through and is equipped with circular recess, circular recess and two the center of dead slot is located same department, just the diameter of circular recess is greater than two the length of the crossing department of dead slot, be less than each the length of dead slot, circular recess is used for avoiding pusher machine when advancing with the mutual interference of upset machine.

Preferably, the housing of the upender is circular in cross section.

Preferably, the charcoal block group sorting device further comprises a grouping basket traveling rail, wherein the grouping baskets are arranged in a plurality along the length direction of the grouping basket traveling rail, each grouping basket receives a plurality of charcoal blocks to form a charcoal block group, and when one of the grouping baskets receives a grouped charcoal block group, the charcoal block group sorting device moves along the grouping basket traveling rail to align the empty grouping basket with the overturning machine to receive another charcoal block group.

Preferably, the conveyer includes the conveyer belt and sets up respectively two bearing rollers at the both ends of conveyer belt, the bearing roller rotates under the drive of motor.

The technical scheme provided by the utility model is that the transverse anode carbon block grouping machine comprises a conveyor for conveying transverse carbon blocks to be grouped and horizontally placed; the device comprises a block pushing machine and a turnover machine, wherein the block pushing machine is connected with the output end of a conveyor and pushes the carbon blocks conveyed by the conveyor to the turnover machine, and the turnover machine turns the horizontally placed carbon blocks to be vertical; the grouping basket is connected with the turnover machine, the block pushing machine pushes the carbon blocks in a vertical state on the turnover machine to the grouping basket, and the grouping basket is used for receiving the grouped carbon blocks; the central lines of the conveyor, the block pushing machine, the turnover machine and the marshalling basket are all on the same straight line. So set up, simple structure, action part are few, and area is little to solved current marshalling equipment whole asymmetry, the overall arrangement is in disorder and area is great, the structure is complicated, the problem that the fault rate is high.

Drawings

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

FIG. 1 is a top view of a row anode carbon block grouping machine in the prior art;

FIG. 2 is a front view of a row anode carbon block braiding machine in the prior art;

FIG. 3 is a side view of a block pusher and an L-flipper of the prior art;

FIG. 4 is a top view of a row anode carbon block grouping machine according to an embodiment of the present invention;

FIG. 5 is a front view of a row anode carbon block grouping machine in an embodiment of the present invention;

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

fig. 7 is a side view of the upender in an embodiment of the present invention;

FIG. 8 is a diagram illustrating a forward pushing stroke of the pushing block after the pushing block is pushed by the raw charcoal block in the embodiment of the present invention;

FIG. 9 is a front view of a horizontal row of charcoal blocks in an embodiment of the present invention;

FIG. 10 is a top view of a horizontal row of charcoal blocks in an embodiment of the present invention;

FIG. 11 is a side view of a horizontal row of charcoal blocks in an embodiment of the present invention;

fig. 12 is a schematic diagram of the anode carbon blocks in rows before and after the grouping process in the embodiment of the present invention.

In FIGS. 1 to 12:

1-a green carbon block, 2-a conveyor, 3-a block pusher, 4-a turnover machine, 5-a grouping basket, 6-a roller, 7-a push plate, 8-a stop block, 9-a balance weight block, 10-an empty groove, 11-a circular groove, 12-a walking track, 13-a first pusher, 14-a second pusher, 15-an L-shaped turnover machine, 16-a horizontal rotary table and 17-a carbon bowl.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be described in detail below. It is obvious that the described embodiments are only some of the embodiments of the present invention, and not all of them. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The purpose of this embodiment is to provide a transverse anode carbon block grouping machine, which solves the problems of the existing grouping equipment, such as asymmetric whole, messy layout, large occupied area, complex structure and high failure rate.

Hereinafter, embodiments will be described with reference to the drawings. The embodiments described below do not limit the scope of the invention described in the claims. Further, the entire contents of the configurations shown in the following embodiments are not limited to those necessary as a solution of the invention described in the claims.

Referring to fig. 1 to 12, the present embodiment provides a transverse anode carbon block grouping machine, including: the automatic sorting machine comprises a conveyor 2, a block pushing machine 3, a turnover machine 4 and a marshalling basket 5 which are arranged in sequence, and the central lines are all on the same straight line. A group of horizontal raw carbon blocks 1 clamped by a stacking crown block and received by a conveyor 2 in a raw carbon block warehouse are conveyed to the tail end of the conveyor 2 in a roasting workshop at one time, a horizontal raw carbon block 1 is pushed into a turnover machine 4 by a block pushing machine 3, a carbon bowl 17 is arranged on the upper surface of the raw carbon block 1 horizontally placed on the conveyor 2, the turnover machine 4 rotates clockwise 90 degrees to realize that the raw carbon blocks 1 are in a vertical state, the carbon bowl 17 faces to the lateral direction, and the raw carbon blocks 1 are pushed into a marshalling basket 5 by the block pushing machine 3; when the block pushing machine 3 pushes the next green carbon block 1 into the turnover machine 4, the turnover machine 4 rotates 90 degrees along the anticlockwise direction, so that the carbon bowls 17 sequentially face the positive direction and the negative direction, and the above procedures are repeated until the grouping basket 5 fully receives the green carbon blocks 1. The layout is designed, the central lines of the conveyor 2, the block pushing machine 3, the turnover machine 4 and the marshalling basket 5 are all on the same straight line, the overall layout of the equipment is symmetrical, the layout is neat, the occupied area is small, the whole equipment only uses one set of block pushing machine 3, the structure is simpler, and the operation is more reliable. The direction of the arrow in the drawing is the traveling direction of the green carbon block 1.

As an optional implementation manner, in a specific embodiment of the present invention, a push plate 7 for pushing the green coal block 1 is rotatably disposed on the push block machine 3 through a bolt, two rows of rollers 6 for conveying the green coal block 1 to the push block machine 3 near the turnover machine 4 are disposed on two sides of the push block machine 3, an upper end surface of the push block machine 3 is lower than the rollers 6, an upper end of the push plate 7 extends out of the rollers 6, as shown in fig. 8, a push plate is at an initial position in fig. 8, as shown in b in fig. 8, when the green coal block 1 moves forward on the rollers 6 to the push plate 7, the green coal block 1 pushes the push plate 7 to rotate to a first position in a forward direction of the green coal block 1, and the first position is a position of the push plate 7 in b in fig. 8; when the carbon block 1 moves forward away from the push plate 7 as shown in fig. 8 c, the push plate 7 rotates to an initial position, and the initial position of the push plate 7 is in a vertical state. As shown in d in fig. 8, the pusher 3 moves forward, the pusher 7 pushes the green coal block 1 to the turnover mechanism 4, then the pusher 3 starts to return and returns to the original position, the turnover mechanism 4 rotates to make the green coal block 1 in a vertical state, the pusher 3 moves forward again, and the green coal block 1 is pushed into the marshalling basket 5 through the front end of the pusher 3. Preferably, the push plates 7 are two and are respectively arranged on two sides of the pusher 3.

As an alternative, as shown in fig. 8, a stop 8 is provided on the pusher 3 at a side of the pusher 7 close to the conveyor 2 to prevent the pusher 7 from rotating in the direction of the conveyor 2, thereby ensuring that the pusher 7 does not rotate in the direction opposite to the direction of travel of the green pellet 1 when pushing the green pellet 1 forward. The lower end of the push plate 7 is provided with a balancing weight 9 at one side close to the conveyor 2, so that when the carbon block 1 moves forwards to leave the push plate 7, the push plate 7 returns to the initial position under the action of gravity.

In addition, the rollers 6 are unpowered rollers, and both rows of unpowered rollers are inclined downwards, so that the green carbon blocks 1 move to the front of the push plate 7 on the block pushing machine 3 along the rollers 6 inclined downwards, and the front is the advancing direction of the green carbon blocks 1.

In some embodiments, the turnover machine 4 includes a rotatable housing, an empty slot 10 for placing the carbon block is arranged in the housing in a penetrating manner, the initial position of the empty slot 10 is in a horizontal direction, the carbon block 1 enters the empty slot 10 in the horizontal state, and the turnover machine 4 rotates clockwise or counterclockwise by 90 degrees so that the carbon block 1 is in a vertical state.

Furthermore, the empty grooves 10 are vertical to each other and are arranged in a cross shape, so that after the carbon blocks 1 are rotated to the vertical direction in one empty groove 10, the turnover machine 4 does not need to turn over, and the next carbon block 1 can directly enter the empty groove 10 in the other horizontal direction, thereby saving time and equipment operation flow.

In the preferred scheme of this embodiment, two empty slots 10 are square, the shell of the upender 4 is further provided with a circular slot 11 in a penetrating manner, the centers of the circular slot 11 and the two empty slots 10 are located at the same position, the diameter of the circular slot 11 is greater than the length of the intersection of the two empty slots 10 and smaller than the length of each empty slot 10, and the circular slot 11 can avoid the mutual interference between the pusher 3 and the upender 4 when the pusher is pushed forward.

In order to facilitate the rotation of the tilter 4, the housing of the tilter 4 is circular in cross-section.

As an optional implementation manner, in the embodiment of the present invention, the row anode carbon block grouping machine further includes a grouping basket walking track 12, the grouping baskets 5 are arranged in a plurality and along the length direction of the grouping basket walking track 12, each grouping basket 5 receives a plurality of carbon blocks 1 respectively to form a carbon block group for completing grouping, when one of the grouping baskets 5 receives 7-8 carbon block groups vertically installed, the grouping basket walking track 12 moves to align another empty grouping basket 5 with the turnover machine 4 to receive another carbon block group.

As an optional embodiment, the conveyor 2 includes a conveyor belt and two carrier rollers respectively disposed at two ends of the conveyor belt, the carrier rollers are driven by a motor to rotate, and the carbon block 1 is driven by the conveyor belt to move forward.

It should be noted that the devices or components with different functions in the above embodiments may be combined, for example, the transverse anode carbon block grouping machine in this embodiment includes a conveyor 2, a pusher 3, a turner 4 and a grouping basket 5 which are arranged in sequence with their center lines on the same straight line. The horizontal row of the green carbon blocks 1 are conveyed to the tail end of the conveyor 2 by the conveyor 2, the green carbon blocks 1 continuously slide forwards through the inclined unpowered rollers, in the forward sliding process, the push blocks 7 of the push block machines 3 in the middles of the unpowered rollers on the two sides are firstly pressed down by the green carbon blocks 1, after the green carbon blocks 1 pass through the push plates 7, the push plates 7 are restored to an initial vertical state, one side, close to the conveyor 2, of the push plate 7 on the push block machines 3 is provided with a stop block 8 to prevent the push plate 7 from rotating towards the conveyor 2, one side, close to the conveyor 2, of the lower end of the push plate 7 is provided with a balancing weight 9 to enable the green carbon blocks 1 to move forwards to leave the push plate 7, and the push plate 7 is restored to an initial position. The block pushing machine 3 starts to operate, the block pushing machine 3 drives the pushing block 7 to move forwards, the pushing block 7 pushes the green carbon blocks 1 into the empty grooves 10 of the turnover machine 4, wherein the turnover machine 4 is a cross turnover machine, and the cross turnover machine comprises two empty grooves 10 which are perpendicular to each other. After the block pushing machine 3 starts to return and returns to the original position, the overturning machine 4 starts to rotate clockwise by 90 degrees, so that the green carbon block 1 is in a vertical state, and the carbon bowl 17 faces to the side direction; when the next green brick block 1 is pushed into the turning machine 4 and the block pushing machine 3 starts to return to the original position, the turning machine 4 starts to rotate 90 degrees along the anticlockwise direction, meanwhile, the front end of the block pushing machine 3 props against the vertical green brick block 1, and the green brick block 1 is pushed into the marshalling basket 5. Repeating the procedures until the receiving groove of the grouping basket 5 receives 7-8 vertically-arranged charcoal block groups, translating the grouping basket 5 to make the other groove empty to be aligned with the turnover machine 4, and then grouping the charcoal blocks 1.

So set up, the central line of conveyer 2, ejector pad machine 3, upset machine 4 and marshalling basket 5 is in same straight line, and the whole overall arrangement of equipment is symmetrical, and the overall arrangement is neat and area is less, and just whole equipment is with one set of ejector pad machine 1, and the structure is simpler, and the operation is more reliable, and the fault rate is lower.

The above description is only for the specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered within the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. A transverse anode carbon block grouping machine is characterized by comprising:

a conveyor (2) for conveying the horizontal row of carbon blocks (1) to be grouped into a horizontal arrangement;

the automatic turning device comprises a block pushing machine (3) and a turning machine (4), wherein the block pushing machine (3) is connected with the output end of the conveyor (2), the block pushing machine (3) pushes the green carbon blocks (1) conveyed by the conveyor (2) to the turning machine (4), and the turning machine (4) turns the horizontally placed green carbon blocks (1) to be in a vertical state;

the grouping basket (5) is connected with the turnover machine (4), the block pushing machine (3) pushes the carbon blocks (1) in a vertical state on the turnover machine (4) to the grouping basket (5), and the grouping basket (5) is used for receiving the grouped carbon blocks (1);

the central lines of the conveyor (2), the pusher (3), the turnover machine (4) and the marshalling basket (5) are all on the same straight line.

2. The transverse anode carbon block grouping machine according to claim 1, wherein a push plate (7) is rotatably arranged on the push block machine (3), two rows of rollers (6) are arranged on two sides of the push block machine (3), the rollers (6) are used for conveying the raw carbon blocks (1) to the positions, close to the turnover machine (4), on the push block machine (3), the upper ends of the push plates (7) extend out of the rollers (6), and when the raw carbon blocks (1) move forwards to the positions of the push plates (7) on the rollers (6), the raw carbon blocks (1) push the push plates (7) to rotate to a first position towards the advancing direction of the raw carbon blocks (1); when the green carbon block (1) moves forwards to leave the push plate (7), the push plate (7) rotates to an initial position, the block pushing machine (3) moves forwards, and the push plate (7) pushes the green carbon block (1) to the turnover machine (4).

3. The transverse anode carbon block grouping machine according to claim 2, wherein a stop block (8) is arranged on one side, close to the conveyor (2), of the push plate (7) on the push block machine (3) to prevent the push plate (7) from rotating towards the conveyor (2), and a balancing weight (9) is arranged on one side, close to the conveyor (2), of the lower end of the push plate (7) to enable the push plate (7) to return to an initial position under the action of gravity when the green carbon blocks (1) move forwards to leave the push plate (7).

4. The transverse anode carbon block grouping machine according to claim 2, wherein the rollers (6) are unpowered rollers, and both rows of the unpowered rollers are inclined downward.

5. The transverse anode carbon block grouping machine according to claim 1, wherein the turning machine (4) comprises a rotatable shell, an empty groove (10) for placing the green carbon block (1) is formed in the shell in a penetrating mode, the green carbon block (1) enters the empty groove (10) in a horizontal state, and the turning machine (4) rotates clockwise or anticlockwise by 90 degrees so that the green carbon block (1) is in a vertical state.

6. The transverse anode carbon block grouping machine according to claim 5, wherein the number of the empty grooves (10) is two, and the empty grooves are perpendicular to each other and are arranged in a cross shape.

7. The transverse anode carbon block grouping machine according to claim 6, wherein the two empty slots (10) are square, a circular slot (11) is further arranged through the shell of the turnover machine (4), the centers of the circular slot (11) and the two empty slots (10) are located at the same position, the diameter of the circular slot (11) is larger than the length of the intersection of the two empty slots (10) and smaller than the length of each empty slot (10), and the circular slot (11) is used for avoiding the mutual interference of the push block machine (3) and the turnover machine (4) when the push block machine (3) is pushed forwards.

8. The transverse anode carbon block grouping machine according to claim 5, wherein the cross section of the shell of the turnover machine (4) is circular.

9. The row anode carbon block grouping machine according to claim 1, further comprising a grouping basket traveling rail (12), wherein the grouping baskets (5) are arranged in a plurality along the length direction of the grouping basket traveling rail (12), each grouping basket (5) receives a plurality of carbon blocks (1) to form a carbon block group, and when one of the grouping baskets (5) receives a grouped carbon block group, the grouping basket traveling rail (12) moves to align the empty grouping basket (5) with the overturning machine (4) to receive another carbon block group.

10. The transverse anode carbon block grouping machine according to claim 1, wherein the conveyor (2) comprises a conveyor belt and two carrier rollers respectively arranged at two ends of the conveyor belt, and the carrier rollers are driven by a motor to rotate.

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