CN221140141U - Multichannel multiple buffering aggregate device - Google Patents

Abstract

The utility model relates to the technical field of mechanical automation, and discloses a multichannel repeated buffer aggregate device, which comprises: a first-stage storage bin; the first-level bin bottom supporting plate is positioned at the bottom of the first-level bin and can be turned over; the second-level bin is transversely arranged and is positioned below the first-level bin; the second-level bin pushing plate is positioned in the second-level bin and can transversely move along the second-level bin; the secondary bin bottom supporting plate is positioned at the bottom of the secondary bin and can transversely move; the pressing plate is positioned above the bottom supporting plate of the secondary storage bin and can perform lifting movement; the third-level bin is transversely arranged and is positioned below the second-level bin; the supporting plate is positioned below the three-level bin base plate and can perform lifting movement; the third-level bin pushing plate is positioned in the third-level bin and can transversely move along the third-level bin; and the third-level bin flange is positioned below the third-level bin and can perform lifting motion. The problem of rollover is effectively solved by adopting a mode of collecting a small amount of materials for a plurality of times at a single time, and the speed can be also adapted to the feeding speed of the upper front section.

Description

Multichannel multiple buffering aggregate device

Technical Field

The utility model relates to the technical field of mechanical automation, in particular to a multi-channel multi-buffering aggregate device.

Background

During the collection and handling of sheet material, particularly for those thicker, softer textured sheet products such as cotton sheets and the like, the problem of rollover and dumping of the stacked material often occurs. This is because when the bulk of the material is too high, its stability is lowered, which easily results in dumping. In order to accommodate the speed of the incoming material at the front stage and avoid rollover and dumping of the material during processing, it is desirable to retrofit existing material collection and handling equipment.

Existing material collection devices are typically primary bins that directly stack sheet material together to form a higher stack of material, which increases the risk of material dumping. Therefore, there is a need to design a new type of material collection and handling device to improve the stability of the material stack, reduce the risk of dumping and to be able to adapt to the speed of the incoming material in the front section.

In order to achieve the above objects, the present utility model provides an improved material collection and handling apparatus comprising a primary bin, a secondary bin and a tertiary bin. After sheet materials are placed into the first-stage storage bin one by one, stacked materials with smaller quantity are formed, and then the stacked materials with larger quantity are finally formed in the third-stage storage bin through multiple transportation of the second-stage storage bin. The tertiary feed bin protects stacked materials through flange and push pedal to prevent it from empting. The design effectively solves the problems of rollover and dumping of the flaky materials with softer texture and thicker thickness in the stacking process, and can adapt to the feeding speed of the front section.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a multi-channel multi-buffering aggregate device.

In order to solve the technical problems, the utility model adopts the following technical scheme:

a multi-channel multiple cache aggregate device comprising:

The first-stage storage bin is used for containing stacked flaky materials;

the first-level bin bottom supporting plate is positioned at the bottom of the first-level bin and can be turned over;

the second-level bin is transversely arranged and is positioned below the first-level bin;

The second-level bin pushing plate is positioned in the second-level bin and can transversely move along the second-level bin;

The secondary bin bottom supporting plate is positioned at the bottom of the secondary bin and can transversely move;

The pressing plate is positioned above the bottom supporting plate of the secondary storage bin, can perform lifting movement, and can downwards penetrate through the secondary storage bin at the position of the bottom supporting plate of the secondary storage bin and extend into the tertiary storage bin;

the third-level bin is transversely arranged and is positioned below the second-level bin;

The supporting plate is positioned below the base plate of the three-level storage bin, can perform lifting movement, can extend upwards into the three-level storage bin and can clamp stacked flaky materials together with the pressing plate;

The third-level bin pushing plate is positioned in the third-level bin and can transversely move along the third-level bin;

The tertiary feed bin flange is located tertiary feed bin below, can carry out elevating movement, can upwards stretch into in the tertiary feed bin and keep relative static in horizontal with tertiary feed bin push pedal.

Further, an opening extending transversely is formed in the bottom of the three-level storage bin; the width of the opening is smaller than the width or the length of the sheet material; the width of the supporting plate and the width of the third-level bin flange are smaller than the width of the opening.

Further, the device also comprises a first cylinder of the vertical device and a first-stage bin flange fixedly connected with the moving end of the first cylinder; and under the condition that the first cylinder is in an extending state, the first-stage bin flange is positioned in the two-stage bin.

Further, the clamping jaw further comprises a second clamping jaw cylinder and a ninth cylinder; the rotating end of the second clamping jaw cylinder is fixedly connected with the first-stage bin bottom supporting plate; the ninth cylinder is arranged transversely, and the moving end of the bottom supporting plate of the secondary storage bin is fixedly connected with the moving end of the ninth cylinder.

Further, the device also comprises a third cylinder; the third cylinder is arranged transversely, and the second-level bin pushing plate is fixedly connected with the movable end of the third cylinder.

Further, the device also comprises a fifth cylinder; the fifth cylinder is arranged transversely, and the three-stage bin pushing plate is fixedly connected with the movable end of the fifth cylinder.

Further, the device also comprises a fourth cylinder; the fourth cylinder is vertically arranged, and the pressing plate is fixedly connected with the moving end of the fourth cylinder.

Further, the device also comprises an eighth cylinder; the eighth cylinder is vertically arranged, and the supporting plate is fixedly connected with the moving end of the eighth cylinder.

Further, the engine further comprises a sixth cylinder and a seventh cylinder; the sixth cylinder is transversely arranged, and the seventh cylinder is fixedly connected with the moving end of the sixth cylinder; the seventh cylinder is vertically arranged, and the third-level bin flange is fixedly connected with the seventh cylinder.

Compared with the prior art, the utility model has the beneficial technical effects that:

After being put into a first-stage storage bin in a piece-by-piece manner, the piece-shaped materials form a small number of stacked materials, then the stacked materials are transported for many times through a second-stage storage bin, a large number of stacked materials are formed in a third-stage storage bin by the small number of stacked materials, the stacked materials are protected in the third-stage storage bin through a third-stage storage bin flange and a third-stage storage bin pushing plate, and the stacked materials are placed to be poured; the utility model is suitable for collecting flaky products with thicker thickness and softer texture, and can be easily dumped and turned over under the condition that the thickness of soft (such as cotton sheets) materials is thicker and stacked too high, and the problem of turning over is effectively solved by adopting a single and small-quantity and repeated collection mode, and the speed can also be adapted to the feeding speed of the upper front section.

Drawings

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

FIG. 2 is a side view of the present utility model;

FIG. 3 is a schematic view of stacking sheet materials in a primary bin in an embodiment;

FIG. 4 is a schematic diagram of an embodiment in which sheet material passes from a primary bin to a secondary bin;

FIG. 5 is a schematic diagram of the transfer of sheet material in a secondary bin in an embodiment;

FIG. 6 is a schematic diagram of an embodiment in which sheet material passes from a secondary bin to a tertiary bin;

FIG. 7 is a schematic diagram of the transfer of sheet material in a tertiary bin in an embodiment;

FIG. 8 is a schematic view of three-stage bin flange descent in an embodiment;

Fig. 9 is a schematic diagram of an embodiment in which sheet material is located at the edge of a tertiary bin and is waiting for the next process to take material.

Detailed Description

A preferred embodiment of the present utility model will be described in detail with reference to the accompanying drawings.

As shown in fig. 1, the present utility model includes a first-stage bin 311, a second-stage bin 312, a third-stage bin 313, a first-stage bin bottom plate 322, a first-stage bin flange 392, a second-stage bin bottom plate 342, a second-stage bin push plate 332, a press plate 352, a support plate 362, a third-stage bin push plate 372, a third-stage bin flange 383, a first cylinder 391, a second-jaw cylinder 321, a third cylinder 331, a fourth cylinder 351, a fifth cylinder 371, a sixth cylinder 381, a seventh cylinder 382, an eighth cylinder 361, and a ninth cylinder 341.

In this embodiment, except for the second clamping jaw cylinder 321, all other cylinders are straight cylinders, including a cylinder body and a piston rod, the cylinder body is a fixed end of the cylinder, and the piston rod is a moving end of the cylinder. The second jaw cylinder 321 includes a cylinder body and a rotary working portion, which is a rotary end.

In the utility model, a plurality of primary bins 311, secondary bins 312 and tertiary bins 313 can be respectively arranged along the longitudinal direction according to the requirement so as to improve the efficiency.

In this embodiment, the primary bin 311, the secondary bin 312 and the tertiary bin 313 are arranged in a stepped manner, wherein the primary bin 311 is located at the upper part, the secondary bin 312 is located at the middle part and the tertiary bin 313 is located at the lower part.

As shown in fig. 1 to 9, in the previous process, the sheet materials 2 are stacked and placed in the first-stage bin 311, and the first-stage bin 311 has a smaller depth for caching a small amount of the sheet materials 2. When the sheet materials 2 in the first-level bin 311 reach a certain amount, the sheet materials enter the second-level bin 312 and then are transported to the third-level bin 313 through the second-level bin 312; while the secondary bin 312 is transferring, the primary bin 311 can store the next batch of material, which does not result in stacking of the materials of the previous process. When the secondary bin 312 is transported to the tertiary bin 313, the tertiary bin 313 can not be transported to the next process immediately, and the secondary bin 312 can transport a plurality of batches of sheet materials 2 to be stacked on the stack of the sheet materials 2 of the tertiary bin 313, and after a certain number of the sheet materials are reached, the sheet materials can be transported to the tail end of the tertiary bin 313 for use in the next process. According to the utility model, the first-stage bin 311 can store the sheet materials 2 in the previous process at any time, so that the speed of the whole production line is not delayed, the materials transported for many times by the second-stage bin 312 can be stacked and stacked in the third-stage bin 313, the follow-up process has less picking actions and high efficiency, and the stacked sheet materials can be prevented from toppling.

The first cylinder 391 is arranged vertically, and the moving end of the first cylinder 391 is fixedly connected with the first-stage bin flange 392. The primary bin flange 392 extends downwards to the side edge of the primary bin 311, so that stacked materials in the primary bin 311 can be protected, and the stacked materials are prevented from being poured.

The first-level feed bin bottom plate 322 is located first-level feed bin 311 bottom, and the rotation end and the first-level feed bin bottom plate 322 fixed connection of second clamping jaw cylinder 321, second clamping jaw cylinder 321 can drive first-level feed bin 311 bed plate rotation, and the sheet material of stacking on the first-level feed bin bottom plate 322 can fall to in the second grade feed bin 312.

The third cylinder 331 is arranged along the transverse direction, and the second-stage bin pushing plate 332 is fixedly connected with the movable end of the third cylinder 331. When the sheet material at one end of the secondary bin 312 needs to be pushed to the other end, the first cylinder 391 drives the primary bin flange 392 to rise, and the third cylinder 331 drives the secondary bin push plate 332 to move transversely, so that the sheet material is pushed to the other end and placed on the secondary bin bottom supporting plate 342.

As shown in fig. 1 to 9, a ninth cylinder 341 is arranged along the transverse direction, and the moving end of the secondary bin bottom supporting plate 342 is fixedly connected with the moving end of the ninth cylinder 341; when sheet materials need to be transferred from the secondary bin 312 to the tertiary bin 313, the supporting plate 362 ascends to the lower part of the secondary bin bottom supporting plate 342, the pressing plate 352 moves to the upper part of the sheet materials, then the ninth air cylinder 341 retracts to drive the secondary bin bottom supporting plate 342 to retract, the sheet materials fall to the upper part of the supporting plate 362, the pressing plate 352 and the supporting plate 362 descend simultaneously, and the sheet materials cannot be overturned and toppled in the descending process of the supporting plate 362 due to the action of the pressing plate 352, at the moment, the sheet materials between the pressing plate 352 and the supporting plate 362 are fewer, and the sheet materials need to be transferred through the secondary bin 312 for a plurality of times, so that the quantity of the sheet materials between the pressing plate 352 and the supporting plate 362 is improved. Before the next secondary bin 312 transfers the flaky materials each time, the pressing plate 352 is lifted, the ninth cylinder 341 extends to drive the secondary bin bottom supporting plate 342 to extend to the joint of the secondary bin 312 and the tertiary bin 313, when the third cylinder 331 drives the secondary bin pushing plate 332 to push the next flaky materials to the secondary bin bottom supporting plate 342, the pressing plate 352 descends, the secondary bin bottom supporting plate 342 retracts, the flaky materials fall onto the last flaky materials on the supporting plate 362, and then the pressing plate 352 and the supporting plate 362 descend simultaneously; after repeating the above process several times, the sheet material between the pressing plate 352 and the supporting plate 362 reaches a certain amount.

The fourth cylinder 351 is vertically arranged, and the pressing plate 352 is fixedly connected with the moving end of the fourth cylinder 351. The eighth cylinder 361 is vertically arranged, and the supporting plate 362 is fixedly connected with the moving end of the eighth cylinder 361. The fifth cylinder 371 is arranged transversely, and the three-stage stock bin pushing plate 372 is fixedly connected with the movable end of the fifth cylinder 371. The sixth cylinder 381 is arranged along the transverse direction, and the seventh cylinder 382 is fixedly connected with the moving end of the sixth cylinder 381; the seventh cylinder 382 is vertically arranged, and the third-stage bin flange 383 is fixedly connected with the seventh cylinder 382.

As shown in fig. 1 to 9, after the sheet material between the pressing plate 352 and the supporting plate 362 reaches a specific quantity, the pressing plate 352 rises and the supporting plate 362 descends, the seventh cylinder 382 drives the third-stage bin flange 383 to rise and pass through the opening below the third-stage bin 313, the sheet material previously located between the pressing plate 352 and the supporting plate 362 is located between the third-stage bin pushing plate 372 and the third-stage bin flange 383 at this time, the fifth cylinder 371 drives the third-stage bin pushing plate 372 to transversely move, and meanwhile, the sixth cylinder 381 drives the seventh cylinder 382 and the third-stage bin flange 383 to transversely move, namely, the third-stage bin pushing plate 372 and the third-stage bin flange 383 are kept relatively static, so that the sheet material between the third-stage bin pushing plate 372 and the third-stage bin flange 383 is prevented from being poured, and the sheet material is driven to the other end of the third-stage bin 313. Then the third-level bin flange 383 descends, one end of the third-level bin 313, which is far away from the second-level bin 312, is of an open structure, and after the third-level bin flange 383 descends, the stacked sheet materials can be taken away in the next procedure.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a single embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to specific embodiments, and that the embodiments may be combined appropriately to form other embodiments that will be understood by those skilled in the art.

Claims (9)

1. A multi-channel multiple cache aggregate unit comprising:

The first-stage storage bin is used for containing stacked flaky materials;

the first-level bin bottom supporting plate is positioned at the bottom of the first-level bin and can be turned over;

the second-level bin is transversely arranged and is positioned below the first-level bin;

The second-level bin pushing plate is positioned in the second-level bin and can transversely move along the second-level bin;

The secondary bin bottom supporting plate is positioned at the bottom of the secondary bin and can transversely move;

The pressing plate is positioned above the bottom supporting plate of the secondary storage bin, can perform lifting movement, and can downwards penetrate through the secondary storage bin at the position of the bottom supporting plate of the secondary storage bin and extend into the tertiary storage bin;

the third-level bin is transversely arranged and is positioned below the second-level bin;

The supporting plate is positioned below the base plate of the three-level storage bin, can perform lifting movement, can extend upwards into the three-level storage bin and can clamp stacked flaky materials together with the pressing plate;

The third-level bin pushing plate is positioned in the third-level bin and can transversely move along the third-level bin;

The tertiary feed bin flange is located tertiary feed bin below, can carry out elevating movement, can upwards stretch into in the tertiary feed bin and keep relative static in horizontal with tertiary feed bin push pedal.

2. The multi-channel multiple cache aggregate unit of claim 1, wherein: the bottom of the three-stage storage bin is provided with a transversely extending opening; the width of the opening is smaller than the width or the length of the sheet material; the width of the supporting plate and the width of the third-level bin flange are smaller than the width of the opening.

3. The multi-channel multiple cache aggregate unit of claim 1, wherein: the device also comprises a first cylinder of the vertical device and a first-stage bin flange fixedly connected with the moving end of the first cylinder; and under the condition that the first cylinder is in an extending state, the first-stage bin flange is positioned in the two-stage bin.

4. The multi-channel multiple cache aggregate unit of claim 1, wherein: the device also comprises a second clamping jaw cylinder and a ninth cylinder; the rotating end of the second clamping jaw cylinder is fixedly connected with the first-stage bin bottom supporting plate; the ninth cylinder is arranged transversely, and the moving end of the bottom supporting plate of the secondary storage bin is fixedly connected with the moving end of the ninth cylinder.

5. The multi-channel multiple cache aggregate unit of claim 1, wherein: the device also comprises a third cylinder; the third cylinder is arranged transversely, and the second-level bin pushing plate is fixedly connected with the movable end of the third cylinder.

6. The multi-channel multiple cache aggregate unit of claim 1, wherein: the device also comprises a fifth cylinder; the fifth cylinder is arranged transversely, and the three-stage bin pushing plate is fixedly connected with the movable end of the fifth cylinder.

7. The multi-channel multiple cache aggregate unit of claim 1, wherein: the device also comprises a fourth cylinder; the fourth cylinder is vertically arranged, and the pressing plate is fixedly connected with the moving end of the fourth cylinder.

8. The multi-channel multiple cache aggregate unit of claim 1, wherein: the device also comprises an eighth cylinder; the eighth cylinder is vertically arranged, and the supporting plate is fixedly connected with the moving end of the eighth cylinder.

9. The multi-channel multiple cache aggregate unit of claim 1, wherein: the engine further comprises a sixth cylinder and a seventh cylinder; the sixth cylinder is transversely arranged, and the seventh cylinder is fixedly connected with the moving end of the sixth cylinder; the seventh cylinder is vertically arranged, and the third-level bin flange is fixedly connected with the seventh cylinder.