CN215555192U - Automatic material folding mechanism - Google Patents

Abstract

The utility model provides an automatic material folding mechanism. The material receiving cage comprises a material receiving cage body, wherein a material receiving assembly is arranged on the material receiving cage body, the material receiving assembly comprises a material receiving frame, a material storage cavity is arranged on the material receiving frame, a material storage inlet for materials to enter is formed in the material storage cavity, a first material storage plate is arranged at the material storage inlet, a material storage groove is arranged on the first material storage plate in a penetrating mode, a second material storage plate and a material storage spring are arranged in the material storage cavity, the second material storage plate can slide up and down along the material storage cavity, the material storage spring is used for driving the second material storage plate to move upwards, and the upper plate surface of the second material storage plate can abut against the lower plate surface of the first material storage plate; the material storage device is characterized by further comprising a material storage driving part, wherein a driving head of the material storage driving part is connected with a driving block, and the material storage driving part drives the driving block to penetrate through the material storage groove and downwards extrude the second material storage plate. The automatic folding mechanism with the structure realizes the automation of material folding, and the neatness of the folded materials is high.

Description

Automatic material folding mechanism

Technical Field

The utility model relates to the technical field of material folding equipment, in particular to an automatic material folding mechanism.

Background

After the materials are processed, the materials are necessarily orderly stacked for the subsequent material transfer and reprocessing.

At present, the existing material stacking device generally comprises a stacking frame, wherein a stacking groove is arranged in the stacking frame; the processed materials are conveyed by the conveying belt to fall into the stacking groove, and the stacking action is completed.

To soft material, the material can be dropped to stacking the groove by the conveyer belt, and at the in-process that drops, soft material can take place to warp, stacks the regularity not high.

SUMMERY OF THE UTILITY MODEL

In view of this, the present invention provides an automatic material stacking mechanism, which has a high uniformity of stacked materials.

In order to solve the technical problems, the technical scheme of the utility model is as follows:

an automatic material folding mechanism comprises a material receiving cage body, wherein a material receiving assembly is arranged on the material receiving cage body and comprises a material receiving frame, a material storage cavity is arranged on the material receiving frame, a material storage inlet for materials to enter is arranged on the material storage cavity,

a first material storage plate is arranged at the material storage inlet, a material storage groove is arranged on the first material storage plate in a penetrating mode, a second material storage plate and a material storage spring are arranged in the material storage cavity, the second material storage plate can slide up and down along the material storage cavity, the material storage spring is used for driving the second material storage plate to move upwards, and the upper plate surface of the second material storage plate can abut against the lower plate surface of the first material storage plate;

the material storage device is characterized by further comprising a material storage driving part, wherein a driving head of the material storage driving part is connected with a driving block, and the material storage driving part drives the driving block to penetrate through the material storage groove and downwards extrude the second material storage plate.

Through the technical scheme, the elastic force of the material storage spring drives the upper plate surface of the second material storage plate to abut against the lower plate surface of the first material storage plate, the processed material can fall on the first material storage plate firstly, the material can cover the material storage inlet, the material storage driving part pushes the driving block to generate thrust to one side of the second material storage plate through the driving head, at the moment, the second material storage plate extrudes the material storage spring, the second material storage plate and the first material storage plate are mutually far away, the middle part of the material is always extruded between the driving block and the second material storage plate, the middle part of the material synchronously moves along with the second material storage plate, two side edges of the material are gradually overturned upwards along the side edge of the material storage inlet, when the two side edges of the material are positioned between the first material storage plate and the second material storage plate, the material storage driving part upwards moves, the material storage spring drives the second material storage plate to upwards move, and the two side edges of the material can be clamped between the first material storage plate and the second material storage plate, at the moment, the flatness of the materials is very high, and certainly, after the single material is folded, the next material is also folded in sequence according to the same sequence, so that all the materials can be gradually and orderly folded between the first material storage plate and the second material storage plate; the operation process realizes the automation of material folding, and the neatness of the folded materials is high.

Preferably, two opposite side walls of the driving block are respectively provided with a pressing sheet which extends outwards, the first material storage plate is provided with a pressing groove communicated with the material storage groove, and the pressing sheet can penetrate through the pressing groove.

Through above-mentioned technical scheme, after the drive block produced downward extrusion force to the material, press the flitch to mutually support with pressing the silo to can produce the bigger effect of flattening of scope to material both sides limit, reduce and push down the in-process because material both sides wall and stock entry contact and take place the possibility of abnormal deformation, further improved the stability and the roughness that the material was folded.

Preferably, a first material taking groove communicated with the interior of the material storage cavity is formed in the side wall of the material receiving frame;

a second material taking groove communicated with the material storing groove is formed in the first material storing plate;

a third material taking groove is formed in the second material storage plate;

the notches of the first material taking groove, the second material taking groove and the third material taking groove face to the same side.

According to the technical scheme, after the materials stacked on the first material storage plate and the second material storage plate are leveled and stacked to a certain number, on one hand, an operator can take all the materials out of the material receiving frame through the first material taking groove, the second material taking groove and the third material taking groove; on the other hand, all materials between the first material storage plate and the second material storage plate can be bound through the rope, and then the bound materials are taken out from the first material taking groove, so that the materials are taken conveniently.

Preferably, the material receiving frame is provided with a material receiving limiting part for limiting the sliding height of the second material storage plate.

Through above-mentioned technical scheme, after the material that stacks in first material storage plate and second material storage plate levelly and smoothly reaches a certain amount, the accessible connects the height of sliding of material limiting part restriction second material storage plate to take out the material that stacks in the material receiving frame in will receiving.

Preferably, connect material spacing portion including rotate connect in connect material spacing pole on the material receiving frame, connect to be equipped with a plurality of material spacing grooves on the material spacing pole, connect the material spacing groove to be used for with second material storage plate joint mutually.

Through above-mentioned technical scheme, when needs were limited to the high of sliding of second material stock board, rotate and connect the material gag lever post, connect the material spacing groove on the material gag lever post can with second material stock board joint, the material stock spring produces thrust upwards to second material stock board, whole second material stock board will be stabilized spacing to the appointed height on.

Preferably, the material receiving and connecting device further comprises a material receiving and connecting part, wherein the material receiving and connecting part comprises a material receiving and connecting driving part, a material pushing plate and a material receiving and connecting plate connected to the end part of the material receiving and connecting driving part, the material pushing plate is located on one side, close to the material storage driving part, of the material receiving and connecting plate, the material receiving and connecting plate is located between the material storage driving part and the material receiving assembly, the material receiving and connecting driving part is used for driving the material receiving and connecting plate to move towards the side edge of the material receiving frame, and the material receiving plate can push materials on the material receiving and connecting plate down onto a second material storage plate in the material storage inlet.

According to the technical scheme, the material receiving connecting plate is located between the material storage driving part and the material receiving assembly, materials can fall on the material receiving connecting plate firstly, the material receiving connecting driving part drives the material receiving connecting plate to move towards the side of the material receiving frame, and the material pushing plate can push the materials on the material receiving connecting plate to fall onto the first material storage plate; above-mentioned in-process has reduced the single in-process that drops, and the whole height that the material dropped is favorable to keeping the roughness when the material drops.

Preferably, a material storage guide post is arranged in the material storage cavity and penetrates through the second material storage plate, the second material storage plate can slide up and down along the material storage guide post, and the material storage spring is sleeved on the material storage guide post.

Through above-mentioned technical scheme, the material stock spring is more regular along the deformation of material stock guide post, and then has promoted the stationarity that slides of second material stock board by a wide margin.

Preferably, still including connecing the material drive division, connect the material drive division to be used for the drive to connect the material cage body to carry out the rotation in a circumferential direction, connect the material subassembly quantity that sets up on the material cage body to be more than two, all connect material subassembly circumferential distribution in connect on the material cage body.

According to the technical scheme, when the quantity of the materials stacked in one of the material receiving assemblies reaches a certain quantity, the material receiving driving part can drive the whole material receiving cage body to rotate, and the other material receiving assembly in an empty state can be rotated to a material receiving position to receive the materials; the material receiving assembly which has stored a certain amount of materials is transferred to another position to be used for an operator to take materials.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment;

FIG. 2 is a schematic diagram of a side view of the embodiment;

fig. 3 is a schematic structural diagram of a receiving assembly in the embodiment;

fig. 4 is a schematic top view of the receiving assembly in the embodiment;

fig. 5 is a schematic side view of the receiving assembly in the embodiment, which is used for mainly showing a structural state that the receiving limiting member limits the second material holding plate;

fig. 6 is a schematic structural view of a material receiving joint in the embodiment.

Reference numerals: 1. a receiving cage body; 2. a material receiving assembly; 21. a material receiving frame; 22. a material storage cavity; 23. a material storage inlet; 3. a first material storage plate; 31. a material storage groove; 4. a material pressing groove; 5. A second material storage plate; 6. a material storage spring; 7. a stock drive section; 71. a drive block; 72. pressing sheets; 8. a first material taking groove; 9. a second material taking groove; 10. a third material taking groove; 11. a material receiving limiting part; 111. a material receiving limiting rod; 112. a material receiving limit groove; 12. a material receiving joint part; 121. receiving material connecting driving pieces; 122. a material pushing plate; 123. receiving connecting plates; 13. a material storage guide column; 14. connect the material drive division.

Detailed Description

The following detailed description of the embodiments of the present invention is provided in order to make the technical solution of the present invention easier to understand and understand.

The utility model provides an automatic mechanism that folds of material, refers to fig. 1 and fig. 2, including connecing the material cage body 1, connect material drive division 14, should connect the material drive division 14 to choose the motor for use, connect the output of material drive division 14 to connect the material cage body 1, connect material drive division 14 to be used for the drive to connect the material cage body 1 to carry out the rotation in a circumferential direction, connect the rotation axis perpendicular to ground of material cage body 1.

Referring to fig. 1 and 2, the receiving cage body 1 is provided with receiving assemblies 2, preferably more than two receiving assemblies 2 are arranged on the receiving cage body 1, and all receiving assemblies 2 are circumferentially distributed around the receiving cage body 1 by taking a rotating shaft of the receiving cage body 1 as a central shaft.

Referring to fig. 3, each receiving assembly 2 includes a receiving frame 21, a storage cavity 22 is formed in the receiving frame 21, a storage inlet 23 for a material to enter is formed in the storage cavity 22, and the storage inlet 23 is arranged upward.

A first material storing plate 3 is arranged at the material storing inlet 23, a material storing groove 31 penetrates through the first material storing plate 3, and a second material taking groove 9 communicated with the material storing groove 31 is arranged on the first material storing plate 3.

Be equipped with second material storage plate 5 in material storage cavity 22, material storage guide post 13, material storage spring 6, material storage guide post 13 is vertical setting, material storage guide post 13 runs through in second material storage plate 5, second material storage plate 5 can carry out vertical upper and lower slip along material storage guide post 13, material storage spring 6 cover is located on material storage guide post 13, material storage spring 6 applies in the ascending elasticity of second material storage plate 5, the last face of second material storage plate 5 can offset with the hypoplastron face of first material storage plate 3.

The material storage device further comprises a material storage driving part 7, in the embodiment, the material storage driving part 7 preferably selects a driving cylinder, a driving block 71 is connected to a driving head of the material storage driving part 7, and the material storage driving part 7 drives the driving block 71 to penetrate through the material storage groove 31 and to press the second material storage plate 5 downwards.

Referring to fig. 6, two opposite side walls of the driving block 71 are respectively provided with two pressing sheets 72 extending outwards, as shown in fig. 6, the number of the pressing sheets 72 on the driving block 71 is four, and two opposite side walls of the driving block 71 are respectively provided with two pressing sheets 72.

Referring to fig. 3 and 4, the first material storage plate 3 is provided with material pressing grooves 4 communicated with the material storage groove 31, the number of the material pressing grooves 4 corresponds to the number of the material pressing pieces 72, and the material pressing pieces 72 can penetrate through the material pressing grooves 4 while the driving block 71 enters the material storage groove 31.

Referring to fig. 3, a first material taking groove 8 communicated with the interior of the material storage cavity 22 is arranged on the side wall of the material receiving frame 21.

Referring to fig. 4, a third material taking groove 10 is arranged on the second material storing plate 5.

Referring to fig. 3 and 4, the notches of the first material taking groove 8, the second material taking groove 9 and the third material taking groove 10 face to the same side.

Referring to fig. 5, the receiving frame 21 is provided with a receiving limiting portion 11 for limiting the sliding height of the second material storage plate 5.

Wherein, connect material spacing portion 11 including connect material gag lever post 111, connect the lower tip of material gag lever post 111 to rotate to connect in connecing work or material rest 21, connect the side of material gag lever post 111 to be equipped with a plurality of material spacing grooves 112 that connect, connect material spacing groove 112 to be used for depositing material board 5 looks joint with the second to inject the position of height on the second and deposit material board 5.

In addition, referring to fig. 1, fig. 2 and fig. 6, the material receiving connection portion 12 is further included, the material receiving connection portion 12 includes a material receiving connection driving member 121, a material pushing plate 122, and a material receiving connection plate 123 connected to an end portion of the material receiving connection driving member 121, the material receiving connection driving member 121 preferably selects a driving cylinder, the material receiving connection plate 123 is horizontally arranged as a whole, the material receiving connection plate 123 is located between the material storage driving portion 7 and the material receiving assembly 2, and the material pushing plate 122 is located on a side of the material receiving connection plate 123 close to the material storage driving portion 7; when the material receiving connecting plate 123 is located between the material storage driving part 7 and the material receiving assembly 2, the material drops on the material receiving connecting plate 123, the material receiving connecting driving part 121 drives the material receiving connecting plate 123 to move towards the side of the material receiving frame 21, and at this time, the material pushing plate 122 can push the material on the material receiving connecting plate 123 to drop on the second material storage plate 5 in the material storage inlet 23.

In the specific use process:

in the stacking process, the processed materials are transported to the material receiving connecting plates 123, the material receiving connecting driving piece 121 drives the material receiving connecting plates 123 to move towards the side edges, the material pushing plate 122 pushes the materials from the material receiving connecting plates 123 into the material storage groove 31, the material storage driving part 7 drives the driving block 71 to move towards one side of the material storage inlet 23, the driving block 71 and the material pressing piece 72 press the materials on the upper plate wall of the second material storage plate 5, the driving block 71 pushes the second material storage plate 5 to move downwards along with the gradual downward movement of the driving block 71, in the process, on one hand, the middle part of the materials can penetrate through the material storage inlet 23 to enter the position below the first material storage plate 3, on the other hand, the side edges of the materials can penetrate through the material pressing groove 4 to enter the position below the first material storage plate 3, the material storage driving part 7 drives the driving block 71 to move towards the side away from the material storage inlet 23, and the material storage spring 6 drives the first material storage plate 3 to move upwards, the side edge of the material is clamped between the first material storage plate 3 and the second material storage plate 5; by repeating the above process, a plurality of materials can be stacked between the first material storage plate 3 and the second material storage plate 5 in order.

In the material taking process, when a certain amount of materials stacked between the first material storage plate 3 and the second material storage plate 5 in one material receiving frame 21 is reached, that is, the material receiving frame 21 is in a full-load state, the material receiving driving part 14 drives the material receiving cage body 1 to rotate, the material receiving frame 21 filled with the materials rotates to other positions, the other material receiving frames 21 in an idle state rotate to positions below the material storage driving part 7, the material receiving limiting rod 111 on the material receiving frame 21 in the full-load state is rotated, the material receiving limiting groove 112 on the material receiving limiting rod 111 is clamped on the second material storage plate 5, the material storage spring 6 cannot continuously push the second material storage plate 5 to move upwards, and an operator can smoothly take the stacked materials out of the material receiving frame 21 through the first material taking groove 8, the second material taking groove 9 and the third material taking groove 10.

The above are only typical examples of the present invention, and besides, the present invention may have other embodiments, and all the technical solutions formed by equivalent substitutions or equivalent changes are within the scope of the present invention as claimed.

Claims (8)

1. The utility model provides an automatic mechanism of folding of material, is including connecing the material cage body (1), it connects material subassembly (2) to be equipped with on the material cage body (1) to connect, connect material subassembly (2) including connecing work or material rest (21), connect to be equipped with stock cavity (22) on work or material rest (21), be equipped with stock entry (23) that supply the material to get into on stock cavity (22), characterized by:

a first material storage plate (3) is arranged at the material storage inlet (23), a material storage groove (31) penetrates through the first material storage plate (3), a second material storage plate (5) and a material storage spring (6) are arranged in the material storage cavity (22), the second material storage plate (5) can slide up and down along the material storage cavity (22), the material storage spring (6) is used for driving the second material storage plate (5) to move upwards, and the upper plate surface of the second material storage plate (5) can abut against the lower plate surface of the first material storage plate (3);

the material storage device is characterized by further comprising a material storage driving part (7), a driving head of the material storage driving part (7) is connected with a driving block (71), and the material storage driving part (7) drives the driving block (71) to penetrate through the material storage groove (31) and downwards extrude the second material storage plate (5).

2. The automatic material folding mechanism as claimed in claim 1, wherein: the material pressing device is characterized in that two opposite side walls of the driving block (71) are respectively provided with a material pressing sheet (72) which extends outwards, a material pressing groove (4) communicated with the material storing groove (31) is formed in the first material storing plate (3), and the material pressing sheet (72) can penetrate through the material pressing groove (4).

3. The automatic material folding mechanism as claimed in claim 1, wherein:

a first material taking groove (8) communicated with the interior of the material storage cavity (22) is formed in the side wall of the material receiving frame (21);

a second material taking groove (9) communicated with the material storing groove (31) is arranged on the first material storing plate (3);

a third material taking groove (10) is formed in the second material storing plate (5);

the notches of the first material taking groove (8), the second material taking groove (9) and the third material taking groove (10) face to the same side.

4. The automatic material folding mechanism as claimed in claim 1, wherein: the material receiving frame (21) is provided with a material receiving limiting part (11) used for limiting the sliding height of the second material storage plate (5).

5. The automatic material folding mechanism as claimed in claim 4, wherein: connect material spacing portion (11) including rotate connect in connect material gag lever post (111) on material frame (21), connect to be equipped with a plurality of material spacing grooves (112) on material gag lever post (111), connect material spacing groove (112) and be used for with second material storage plate (5) looks joint.

6. The automatic material folding mechanism as claimed in claim 1, wherein: the material receiving connecting portion (12) comprises a material receiving connecting driving piece (121), a material pushing plate (122) and a material receiving connecting plate (123) connected to the end portion of the material receiving connecting driving piece (121), the material pushing plate (122) is located on one side, close to the material storage driving portion (7), of the material receiving connecting plate (123), the material receiving connecting plate (123) is located between the material storage driving portion (7) and the material receiving assembly (2), the material receiving connecting driving piece (121) is used for driving the material receiving connecting plate (123) to move towards the side edge of the material receiving frame (21), and the material on the material receiving connecting plate (123) can be pushed down onto a second material storage plate (5) in the material storage inlet (23) by the material pushing plate (122).

7. The automatic material folding mechanism as claimed in claim 1, wherein: the material storage device is characterized in that a material storage guide column (13) is arranged in the material storage cavity (22), the material storage guide column (13) penetrates through the second material storage plate (5), the second material storage plate (5) can slide up and down along the material storage guide column (13), and the material storage guide column (13) is sleeved with the material storage spring (6).

8. An automatic material folding mechanism according to any one of claims 1 to 7, characterized in that: still including connecing material drive division (14), connect material drive division (14) to be used for the drive to connect the material cage body (1) to carry out the rotation in a circumferential direction, connect the material cage body (1) to go up the material subassembly (2) quantity that sets up and be more than two, all connect material subassembly (2) circumferential distribution in connect on the material cage body (1).

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