CN218753697U - Stacking device for aluminum-magnesium-carbon production - Google Patents

Abstract

The utility model discloses a pile up neatly device is used in almag carbon production relates to pile up neatly device technical field. The utility model discloses a: the device comprises two supports and two conveying machine tools, wherein the conveying machine tools are positioned between two sides of the inner wall of each support; the moving plate is slidably arranged between the two brackets; the reciprocating assembly is arranged on the bracket and is used for driving the moving plate to slide in a reciprocating manner along the sliding track of the moving plate; the U-shaped plate is rotatably installed at the bottom of the movable plate, a rotating motor is fixedly installed at the top of the U-shaped plate, and the output end of the rotating motor is fixedly connected with the U-shaped plate. The utility model discloses a reciprocal subassembly, electric telescopic handle, gripper, removal subassembly, lift and collecting box's cooperation can realize the pile up neatly work of carrying on of a plurality of almag carbon bricks, has improved pile up neatly operating speed and efficiency, has saved staff's operating time and labour, makes things convenient for people's use.

Description

Stacking device for aluminum-magnesium-carbon production

Technical Field

The utility model relates to a pile up neatly device technical field, concretely relates to aluminium magnesium carbon production is with pile up neatly device.

Background

The aluminum-magnesium-carbon brick is a fire-resistant product made from special-grade high-alumina or corundum sand, magnesite and flake graphite as main raw materials, and is a fire-lined product made from special-grade high-alumina or corundum sand, magnesite and flake graphite as main raw materials, and is characterized in that the aluminum-magnesium-carbon brick not only has the advantages of high erosion resistance and difficult peeling due to carbon-containing but also has the advantage of high residual linear expansion rate due to spinel generated by heating during use, thereby becoming a newly developed high-quality lining brick,

at present, magnesia carbon brick among the prior art is at production and processing during operation, need carry out the work of pile up neatly to the almag carbon brick of processing completion, but common pile up neatly mode is all through the work of artifical or gripper to single almag carbon brick transport, cooperates relevant transfer device, carries out pile up neatly work, and the speed and the efficiency of not only work are not high like this, and the staff still wastes time and energy, the use of people of not being convenient for.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: for solving the problem that provides in the above-mentioned background art, the utility model provides a pile up neatly device is used in almag carbon production.

The utility model discloses a realize above-mentioned purpose and specifically adopt following technical scheme: the utility model provides an almag carbon production is with pile up neatly device, includes: the device comprises two supports and two conveying machine tools, wherein the conveying machine tools are positioned between two sides of the inner wall of each support; the moving plate is arranged between the two brackets in a sliding way; the reciprocating assembly is arranged on the bracket and is used for driving the moving plate to slide in a reciprocating manner along the sliding track of the moving plate; the U-shaped plate is rotatably arranged at the bottom of the moving plate, a rotating motor is fixedly arranged at the top of the U-shaped plate, the output end of the rotating motor is fixedly connected with the U-shaped plate, two electric telescopic rods which are symmetrically distributed are slidably arranged at the bottom of the U-shaped plate, and a mechanical claw is fixedly arranged at the telescopic end of each electric telescopic rod; the moving assembly is arranged on the U-shaped plate and used for driving the two electric telescopic rods to synchronously approach or depart from each other; the sliding plates are arranged between the two brackets in a sliding mode, the lifting piece is arranged at the bottom of each sliding plate, the collecting boxes used for placing the alumina-magnesia carbon bricks are arranged at the tops of the two sliding plates, and the limiting pieces used for limiting and fixing the collecting boxes are arranged at the tops of the sliding plates.

Furthermore, the reciprocating assembly comprises two electric guide rails and two sliding blocks, the two electric guide rails are respectively and fixedly installed on one side of the two supports, the two sliding blocks are respectively and slidably installed on the outer surfaces of the two electric guide rails, and the moving plate is fixedly installed between the two sliding blocks.

Further, the removal subassembly includes two-way threaded rod, driving motor and two screw thread pieces, two-way threaded rod fixed mounting in between the both sides of U template inner wall, driving motor fixed mounting in one side of U template, its output with the one end fixed connection of two-way threaded rod, two the screw thread piece be the symmetric distribution screw thread install in the surface of two-way threaded rod, the top of screw thread piece with the top sliding connection of U template inner wall, two electric telescopic handle respectively with two screw thread piece fixed connection.

Further, the lifting piece comprises a scissor type lifter, the scissor type lifter is placed on the ground, and the top of the scissor type lifter is fixed to the bottom of the sliding plate.

Furthermore, the limiting part comprises two limiting plates, the limiting plates are U-shaped, the two limiting plates are symmetrically distributed and fixedly mounted at the top of the sliding plate, and the collecting box is placed between the two limiting plates.

Furthermore, the claw wall of the mechanical claw is fixedly provided with an anti-skid pad.

The utility model has the advantages as follows:

the utility model discloses a reciprocal subassembly, electric telescopic handle, gripper, removal subassembly, lift and collecting box's cooperation can realize the pile up neatly work of carrying on of a plurality of almag carbon bricks, has improved pile up neatly operating speed and efficiency, has saved staff's operating time and labour, makes things convenient for people's use.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is another perspective view of the present invention;

fig. 3 is a plan elevation view of the present invention.

Reference numerals are as follows: 1. a support; 2. conveying the machine tool; 3. moving the plate; 4. a reciprocating assembly; 41. an electric rail; 42. a slider; 5. a U-shaped plate; 6. rotating the motor; 7. an electric telescopic rod; 8. a gripper; 9. a moving assembly; 91. a bidirectional threaded rod; 92. a drive motor; 93. a thread block; 10. a sliding plate; 11. a lifting member; 111. a scissor lift; 12. a collection box; 13. a stopper; 131. a limiting plate; 14. a non-slip mat.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the drawings in the embodiments of the present invention are combined below to clearly and completely describe the technical solutions in the embodiments of the present invention.

As shown in fig. 1-3, an embodiment of the utility model provides an almag carbon production is with pile up neatly device, include: the device comprises supports 1 and conveying machine tools 2, wherein the number of the supports 1 is two, and the conveying machine tools 2 are positioned between two sides of the inner wall of each support 1; the moving plate 3 is slidably arranged between the two brackets 1; the reciprocating assembly 4 is arranged on the bracket 1 and is used for driving the moving plate 3 to slide in a reciprocating manner along the sliding track of the moving plate; the U-shaped plate 5 is rotatably installed at the bottom of the moving plate 3, a rotating motor 6 is fixedly installed at the top of the U-shaped plate 5, the output end of the rotating motor is fixedly connected with the U-shaped plate 5, two electric telescopic rods 7 which are symmetrically distributed are slidably installed at the bottom of the U-shaped plate 5, and a mechanical claw 8 is fixedly installed at the telescopic end of each electric telescopic rod 7; the moving assembly 9 is arranged on the U-shaped plate 5 and is used for driving the two electric telescopic rods 7 to synchronously approach or depart from each other; the number of the sliding plates 10 is two, the two sliding plates 10 are slidably mounted between the two brackets 1, a lifting part 11 is mounted at the bottom of each sliding plate 10, a collecting box 12 for placing the alundum bricks is placed at the top of each sliding plate 10, a limiting part 13 for limiting and fixing the collecting box 12 is mounted at the top of each sliding plate 10, the limiting part 13 can limit and fix the collecting box 12 to prevent the alundum bricks from moving and affecting stacking, when the alundum bricks are placed on the conveying machine tool 2 and conveyed below the brackets 1, the two electric telescopic rods 7 are started to drive the two mechanical claws 8 to move downwards, then the mechanical claws 8 are used for clamping the alundum bricks on the conveying machine tool 2, then the moving component 9 is started to drive the two electric telescopic rods 7 to be away from each other to be above the two collecting boxes 12, and then the electric telescopic rods 7 are started to drive the mechanical claws 8 to move downwards into the collecting boxes 12, loosening the alumina-magnesia carbon bricks to stack the alumina-magnesia carbon bricks in the collecting box 12, thereby realizing that both sides of the conveying machine tool 2 can stack the alumina-magnesia carbon bricks, improving the stacking efficiency, and also can clamp the alumina-magnesia carbon bricks, starting the reciprocating component 4 to drive the movable plate 3 to move to the upper part of one collecting box 12, then starting the rotating motor 6 to drive the U-shaped plate 5 to rotate 90 degrees to be vertically parallel to the collecting box 12, then starting the moving component 9 to drive the two electric telescopic rods 7 to be close to each other, so that the alumina-magnesia carbon bricks on the two mechanical claws 8 are both positioned above the collecting box 12, then loosening the alumina-magnesia carbon bricks to be placed in the collecting box 12, wherein the two stacking modes are according to the sizes of the alumina-magnesia carbon bricks, the first mode is that the size of the alumina-magnesia carbon bricks is the same as the placing space of the collecting box 12, both sides can be placed, and the other mode is that the size of the alumina-magnesia carbon bricks is smaller, can press from both sides simultaneously and get two almag carbon bricks, place in the collecting box 12 of one side, collecting box 12 is when using, and usable lifting unit 11 will rise to and carry lathe 2 the same height, and when the collecting box 12 pile up neatly is full, descends the height again, and the staff of being convenient for takes.

As shown in fig. 1, in some embodiments, the reciprocating assembly 4 includes two electric rails 41 and two sliding blocks 42, the two electric rails 41 are respectively and fixedly installed at one side of the two brackets 1, the two sliding blocks 42 are respectively and slidably installed at the outer surfaces of the two electric rails 41, the moving plate 3 is fixedly installed between the two sliding blocks 42, the electric rails 41 and the sliding blocks 42 are conventional, and the two electric rails 41 are activated to respectively drive the two sliding blocks 42 to move, so as to drive the moving plate 3 to move.

As shown in fig. 1, in some embodiments, the moving assembly 9 includes a bidirectional threaded rod 91, a driving motor 92 and two threaded blocks 93, the bidirectional threaded rod 91 is fixedly installed between two sides of an inner wall of the U-shaped plate 5, the driving motor 92 is fixedly installed on one side of the U-shaped plate 5, an output end of the driving motor is fixedly connected with one end of the bidirectional threaded rod 91, the driving motor 92 is a forward and reverse rotation motor, the two threaded blocks 93 are symmetrically installed on an outer surface of the bidirectional threaded rod 91 in a threaded manner, a top of the threaded block 93 is slidably connected with a top of the inner wall of the U-shaped plate 5, the two electric telescopic rods 7 are respectively fixedly connected with the two threaded blocks 93, and when the two electric telescopic rods 7 need to be synchronously moved, the driving motor 92 is started to drive the bidirectional threaded rod 91 to rotate, and the two threaded blocks 91 are driven to synchronously move toward or away from each other by driving the bidirectional threaded rod 91 to drive the two threaded blocks 93 to synchronously move toward or away from each other, so as to realize that the two electric telescopic rods 7 are close to or away from each other.

As shown in fig. 1, in some embodiments, the lifting member 11 includes a scissor lift 111, the scissor lift 111 is placed on the ground, the top of the scissor lift 111 is fixed to the bottom of the sliding plate 10, when the sliding plate 10 needs to be driven to ascend, the scissor lift 111 is started to drive the sliding plate 10 to ascend, so as to drive the collecting box 12 to ascend, so as to conveniently place the alundum bricks in the collecting box 12 for stacking, when stacking is completed, the scissor lift 111 is used to descend, so as to reduce the height of the collecting box 12, so as to conveniently carry the collecting box 12 by workers, and the scissor lift 111 is arranged to bear a certain weight.

As shown in fig. 1, in some embodiments, the limiting member 13 includes two limiting plates 131, the limiting plates 131 are U-shaped, the two limiting plates 131 are symmetrically distributed and fixedly mounted on the top of the sliding plate 10, the collecting box 12 is placed between the two limiting plates 131, and the two U-shaped limiting plates 131 can limit the bottom of the collecting box 12 and are not easy to move, so that the collecting box 12 can be stacked conveniently, and at the same time, the limiting of the collecting box 12 can be released conveniently, and only the collecting box 12 needs to be lifted upwards.

As shown in fig. 1, in some embodiments, a non-slip pad 14 is fixedly mounted on a claw wall of the mechanical claw 8, and the non-slip pad 14 is made of rubber, so that the almag brick is convenient to grasp, the surface of the almag brick is not easy to wear, the surface of the almag brick is guaranteed to be perfect, and the almag brick is convenient to sell.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (6)

1. The utility model provides an almag carbon production is with pile up neatly device which characterized in that includes:

the device comprises supports (1) and conveying machine tools (2), wherein the number of the supports (1) is two, and the conveying machine tools (2) are positioned between two sides of the inner wall of each support (1);

the moving plate (3) is arranged between the two brackets (1) in a sliding way;

the reciprocating assembly (4) is arranged on the bracket (1) and is used for driving the moving plate (3) to slide in a reciprocating manner along the sliding track of the moving plate;

the U-shaped plate (5) is rotatably arranged at the bottom of the movable plate (3), a rotating motor (6) is fixedly arranged at the top of the U-shaped plate (5), the output end of the rotating motor is fixedly connected with the U-shaped plate (5), two electric telescopic rods (7) which are symmetrically distributed are slidably arranged at the bottom of the U-shaped plate (5), and a mechanical claw (8) is fixedly arranged at the telescopic end of each electric telescopic rod (7);

the moving assembly (9) is arranged on the U-shaped plate (5) and is used for driving the two electric telescopic rods (7) to synchronously approach or depart from each other;

the number of the sliding plates (10) is two, the two sliding plates (10) are all slidably mounted between the two brackets (1), the lifting piece (11) is mounted at the bottom of each sliding plate (10), the collecting boxes (12) used for placing the alumina-magnesia carbon bricks are all placed at the tops of the two sliding plates (10), and the limiting pieces (13) used for limiting and fixing the collecting boxes (12) are mounted at the tops of the sliding plates (10).

2. The stacking device for producing aluminum magnesium carbon according to claim 1, wherein the reciprocating assembly (4) comprises two electric guide rails (41) and two sliding blocks (42), the two electric guide rails (41) are fixedly installed on one side of the two brackets (1), the two sliding blocks (42) are slidably installed on the outer surfaces of the two electric guide rails (41), and the moving plate (3) is fixedly installed between the two sliding blocks (42).

3. The stacking device for producing aluminum-magnesium-carbon as claimed in claim 1, wherein the moving assembly (9) comprises a bidirectional threaded rod (91), a driving motor (92) and two threaded blocks (93), the bidirectional threaded rod (91) is fixedly installed between two sides of the inner wall of the U-shaped plate (5), the driving motor (92) is fixedly installed on one side of the U-shaped plate (5), the output end of the driving motor is fixedly connected with one end of the bidirectional threaded rod (91), the two threaded blocks (93) are symmetrically installed on the outer surface of the bidirectional threaded rod (91) in a threaded manner, the tops of the threaded blocks (93) are slidably connected with the tops of the inner wall of the U-shaped plate (5), and the two electric telescopic rods (7) are fixedly connected with the two threaded blocks (93) respectively.

4. The palletizing device for producing aluminum magnesium carbon according to claim 1, wherein the lifting member (11) comprises a scissor lift (111), the scissor lift (111) is placed on the ground, and the top of the scissor lift (111) is fixed with the bottom of the sliding plate (10).

5. The stacking device for producing aluminum-magnesium-carbon according to claim 1, wherein the limiting member (13) comprises two limiting plates (131), the limiting plates (131) are U-shaped, the two limiting plates (131) are symmetrically distributed and fixedly mounted on the top of the sliding plate (10), and the collecting box (12) is placed between the two limiting plates (131).

6. The stacking device for producing aluminum magnesium carbon according to claim 1, wherein a non-slip mat (14) is fixedly mounted on the claw wall of the mechanical claw (8).

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