CN219858911U - Stacked sheet arranging mechanism - Google Patents

Abstract

According to the stacked sheet arranging mechanism provided by the utility model, when the lifting platform formed by the bearing plates at the same position on the belt conveying assemblies corresponding to the two groups of conveying mechanisms moves to the highest position, materials conveyed by the feeding mechanism can be received, and in the process that a plurality of materials fall on the lifting platform one by one and are stacked upwards, the bearing plates of the other corresponding group of belt conveying assemblies in the two groups of conveying mechanisms synchronously move upwards until the materials on the lifting platform are stacked to the ideal number, the lifting platform at the highest position needs to move downwards, and when the lifting platform at the highest position moves downwards, the bearing plate of the other corresponding belt conveying assembly in the two groups of conveying mechanisms moves to the highest position, and as the original lifting platform moves downwards and the new lifting platform moves upwards, the time difference between the alternation of the two groups of lifting platforms can be reduced, so that a single sheet arranging machine can realize uninterrupted feeding matched with the feeding mechanism, the production efficiency is improved, and the production cost is reduced.

Description

Stacked sheet arranging mechanism

Technical Field

The utility model relates to the field of folding type sheet arranging mechanisms, in particular to a stacking type sheet arranging mechanism.

Background

The chip arranging machine has the main functions that: the automatic arrangement and the arrangement of the chips in the device are achieved through instantaneous swing; the traditional reason piece machine realizes automatic reason piece through the belt conveyor of two vertical settings to and the circulation lift platform that the loading board on the belt conveyor constitutes, corresponds the product stack of stipulation quantity behind lift platform, and lift platform descends, and new lift platform rises to follow-up being used for accepting of product, but because feed mechanism is incessantly material loading, consequently, in the time difference that two sets of lift platforms are alternated, feed mechanism can't carry new product to lift platform, conventional mode adopts two reason piece machines to realize alternate reason piece in the time difference that two sets of lift platforms are alternated, in order to realize the incessant material loading of joining in marriage feed mechanism, but use two reason piece machines to carry out alternate reason piece, not only high cost, area is big, moreover need consider two reason piece machines to join in marriage the harmony of reasonable piece in turn, the suitability is relatively poor.

Disclosure of Invention

First, the technical problem to be solved

In order to solve the above-mentioned problems of the prior art, the present utility model provides a stacked sheet arranging mechanism.

(II) technical scheme

In order to achieve the above purpose, the main technical scheme adopted by the utility model comprises the following steps:

the stacked sheet arranging mechanism comprises a conveying mechanism, wherein the conveying mechanism is provided with two groups and is vertically and oppositely arranged,

the conveying mechanism comprises a bearing plate and two groups of belt conveying components which are arranged side by side, the conveying directions of the two groups of belt conveying components are independently controlled, and at least one bearing plate is fixedly arranged on each group of belt conveying components;

the belt conveying components corresponding to the two groups of conveying mechanisms synchronously move and rotate in opposite directions, and the bearing plates at the same position on the belt conveying components corresponding to the two groups of conveying mechanisms form a lifting platform together and are used for conveying materials.

Preferably, the belt conveying assembly comprises a driving belt, an upper roller and a lower roller, wherein the driving belt is sleeved between the upper roller and the lower roller, and the bearing plate is fixedly arranged on the surface of the driving belt.

Preferably, the conveying mechanism further comprises a frame, an upper transmission shaft, a lower transmission shaft and a driving assembly;

the upper transmission shaft and the lower transmission shaft are respectively arranged at the upper end and the lower end of the frame, the two groups of belt conveying assemblies are respectively arranged in the frame, the upper idler wheels and the lower idler wheels of the belt conveying assemblies are respectively arranged on the corresponding upper transmission shaft and lower transmission shaft, one group of upper idler wheels of the belt conveying assemblies are fixedly connected with the upper transmission shaft, the lower idler wheels are rotatably connected with the lower transmission shaft, and the other group of upper idler wheels of the belt conveying assemblies are rotatably connected with the upper transmission shaft, and the lower idler wheels are fixedly connected with the lower transmission shaft;

the driving assembly is provided with two groups of driving assemblies which are respectively connected with the upper transmission shaft and the lower transmission shaft.

Preferably, the driving assembly comprises a motor, a driving wheel, a synchronous belt and a driven wheel;

the driven wheels are provided with two groups which are respectively arranged on the upper transmission shafts or the lower transmission shafts of the two groups of conveying mechanisms;

the driving wheel is arranged on the motor;

the driving wheel is connected with the two groups of driven wheels through a synchronous belt and drives the two groups of driven wheels to synchronously move and rotate in opposite directions.

Preferably, the driving assembly further comprises a guiding wheel, the synchronous belt is sequentially connected with the driving wheel, the guiding wheel and the driven wheel, one driven wheel is contacted with the inner wall of the synchronous belt, and the other driven wheel is contacted with the outer wall of the synchronous belt.

Preferably, the device further comprises an adjusting mechanism for adjusting the distance between the two groups of conveying mechanisms.

Preferably, the adjusting mechanism comprises a rectangular frame, a screw rod and a fixed block;

openings are formed in the top and the bottom of the rectangular frame, and the two groups of the rectangular frame enclose the conveying mechanism;

one end of the screw rod is rotatably arranged on the inner wall of the rectangular frame, the other end of the screw rod extends out of the rectangular frame and is fixedly provided with a hand wheel, and two thread sections with opposite rotation directions are symmetrically arranged on the screw rod;

the fixed block is provided with two groups which are respectively and fixedly arranged on the two groups of conveying mechanisms, and the fixed block is provided with screw holes corresponding to the threaded sections on the screw rod.

Preferably, the adjusting mechanism further comprises a guide assembly, the guide assembly comprises a guide rod and a sliding block, the guide rod is fixedly mounted on the inner wall of the rectangular frame, the sliding block is provided with two groups and is respectively and fixedly mounted on the two groups of conveying mechanisms, and the sliding block can horizontally slide on the guide rod.

Preferably, the adjusting mechanism further comprises guide plates, wherein the guide plates are provided with two groups, are fixed on the inner wall of the rectangular frame through fixing pieces, and are distributed on two sides of the lifting platform.

(III) beneficial effects

The utility model has the beneficial effects that: by adopting the technical scheme, when the lifting platform formed by the bearing plates at the same position on the belt conveying assemblies corresponding to the two groups of conveying mechanisms moves to the highest position, materials conveyed by the feeding mechanism can be received, and a plurality of materials fall on the lifting platform one by one and are stacked upwards, the bearing plates of the other corresponding group of belt conveying assemblies in the two groups of conveying mechanisms synchronously move upwards until the materials on the lifting platform are stacked to the ideal number, the lifting platform at the highest position needs to move downwards, and when the lifting platform at the highest position moves downwards, the bearing plate of the other corresponding belt conveying assembly in the two groups of conveying mechanisms moves to the highest position to form a new lifting platform.

Drawings

FIG. 1 is a schematic diagram of a stacked wafer handling mechanism;

FIG. 2 is a schematic diagram of a stacking type sheet handling mechanism;

FIG. 3 is a schematic diagram of a front view of a stacked film arranging mechanism;

FIG. 4 is a schematic diagram of a second embodiment of the present utility model;

fig. 5 is a schematic structural diagram of a second embodiment of the present utility model.

[ reference numerals description ]

1. A conveying mechanism;

11. a belt conveyor assembly; 111. an upper roller; 112. a lower roller; 113. a drive belt;

12. a frame;

13. an upper transmission shaft;

14. a lower transmission shaft;

15. a drive assembly; 151. a motor; 152. a driving wheel; 153. driven wheel; 154. a guide wheel; 155. a synchronous belt;

2. a carrying plate;

3. an adjusting mechanism;

31. a rectangular frame;

32. a screw rod;

33. a fixed block;

34. a hand wheel;

35. a slide block;

36. and guiding the rod.

Detailed Description

The utility model will be better explained by the following detailed description of the embodiments with reference to the drawings.

Referring to fig. 1 to 3, a first embodiment of the present utility model:

a stacking type sheet arranging mechanism comprises a conveying mechanism 1, wherein the conveying mechanism 1 is provided with two groups which are vertically and oppositely arranged,

the conveying mechanism 1 comprises a bearing plate and two groups of belt conveying assemblies 11 which are arranged side by side, the conveying directions of the two groups of belt conveying assemblies 11 are independently controlled, and at least one bearing plate 2 is fixedly arranged on each group of belt conveying assemblies 11;

the belt conveying components 11 corresponding to the two groups of conveying mechanisms 1 synchronously move and rotate in opposite directions, and the bearing plates 2 at the same position on the belt conveying components 11 corresponding to the two groups of conveying mechanisms 1 form a lifting platform together and are used for conveying materials.

When the lifting platform formed by the bearing plates 2 at the same position on the corresponding belt conveying assemblies 11 of the two groups of conveying mechanisms 1 moves to the highest position, materials conveyed by the feeding mechanism can be received, a plurality of materials fall on the lifting platform one by one and are stacked upwards, the bearing plates 2 of the other corresponding belt conveying assemblies 11 in the two groups of conveying mechanisms 1 synchronously move upwards until the materials on the lifting platform are stacked to the ideal number, the lifting platform at the highest position needs to move downwards, the lifting platform at the highest position moves downwards, and the bearing plate 2 of the other corresponding belt conveying assembly 11 in the two groups of conveying mechanisms 1 moves to the highest position at the same time when the lifting platform at the highest position moves upwards, so that a new lifting platform is formed, and the time difference between the alternation of the two groups of lifting platforms can be reduced.

In this embodiment, the belt conveying assembly 11 includes a driving belt 113, an upper roller 111 and a lower roller 112, the driving belt 113 is sleeved between the upper roller 111 and the lower roller 112, and the bearing plate 2 is fixedly installed on the surface of the driving belt 113; the belt 113 can be driven circularly by rolling the upper roller 111 and the lower roller 112.

In this embodiment, the conveying mechanism 1 further includes a frame 12, an upper transmission shaft 13, a lower transmission shaft 14, and a driving assembly 15;

the upper transmission shaft 13 and the lower transmission shaft 14 are respectively arranged at the upper end and the lower end of the frame 12, the two groups of belt conveying assemblies 11 are respectively arranged in the frame 12, the upper roller 111 and the lower roller 112 of each belt conveying assembly 11 are respectively arranged on the corresponding upper transmission shaft 13 and lower transmission shaft 14, the upper roller 111 and the upper transmission shaft 13 of one group of belt conveying assemblies 11 are fixedly connected, the lower roller 112 and the lower transmission shaft 14 are rotationally connected, the upper roller 111 and the upper transmission shaft 13 of the other group of belt conveying assemblies 11 are rotationally connected, and the lower roller 112 and the lower transmission shaft 14 are fixedly connected;

the driving assembly 15 is provided with two groups of upper transmission shafts 13 and lower transmission shafts 14 respectively.

When the belt conveyer is used, under the drive of the drive assembly 15, the upper transmission shaft 13 and the lower transmission shaft 14 are independently controlled, when the upper transmission shaft 13 rotates, as the upper roller 111 of one group of belt conveyer assemblies 11 is fixedly connected with the upper transmission shaft 13, the lower roller 112 is rotationally connected with the lower transmission shaft 14, the upper roller 111 of the other group of belt conveyer assemblies 11 is rotationally connected with the upper transmission shaft 13, the lower roller 112 is fixedly connected with the lower transmission shaft 14, so that the upper transmission shaft 13 controls the transmission of one group of belt conveyer assemblies 11, and the rotation of the lower transmission shaft 14 can control the transmission of the other group of belt conveyer assemblies 11; thereby realizing the purpose of independently controlling the conveying direction of the two groups of belt conveying assemblies 11.

In this embodiment, the driving assembly 15 includes a motor 151, a driving wheel 152, a synchronous belt 155, and a driven wheel 153;

the driven wheels 153 are provided with two groups and are respectively arranged on the upper transmission shaft 13 or the lower transmission shaft 14 of the two groups of conveying mechanisms 1, and further comprise guide wheels 154

The driving wheel 152 is mounted on the motor 151;

the driving wheel 152 is connected with two groups of driven wheels 153 through a synchronous belt 155, and drives the two groups of driven wheels 153 to synchronously move and rotate in opposite directions;

the timing belt 155 is sequentially connected with the driving wheel 152, the guiding wheel 154 and the driven wheel 153, wherein one driven wheel 153 is contacted with the inner wall of the timing belt 155, and the other driven wheel 153 is contacted with the outer wall of the timing belt 155.

When the synchronous belt type motor is used, under the driving of the motor 151, the driving wheel 152 drives the guide wheel 154 and the driven wheels 153 to rotate once through the synchronous belt 155, and as one driven wheel 153 is contacted with the inner wall of the synchronous belt 155 and the other driven wheel 153 is contacted with the outer wall of the synchronous belt 155, the two driven wheels 153 can synchronously rotate and the rotation directions are opposite.

Referring to fig. 4 and 5, a second embodiment of the present utility model:

a stacking type sheet arranging mechanism comprises a conveying mechanism 1, wherein the conveying mechanism 1 is provided with two groups which are vertically and oppositely arranged,

the conveying mechanism 1 comprises a bearing plate and two groups of belt conveying assemblies 11 which are arranged side by side, the conveying directions of the two groups of belt conveying assemblies 11 are independently controlled, and at least one bearing plate 2 is fixedly arranged on each group of belt conveying assemblies 11;

the belt conveying components 11 corresponding to the two groups of conveying mechanisms 1 synchronously move and rotate in opposite directions, and the bearing plates 2 at the same position on the belt conveying components 11 corresponding to the two groups of conveying mechanisms 1 form a lifting platform together for conveying materials; an adjusting mechanism 3 is also included for adjusting the spacing between the two sets of conveyor mechanisms 1.

In this embodiment, the adjusting mechanism 3 includes a rectangular frame 31, a screw 32, and a fixing block 33;

openings are formed in the top and the bottom of the rectangular frame 31, and two groups of the rectangular frame 31 enclose the conveying mechanism 1;

one end of a screw rod 32 is rotatably arranged on the inner wall of the rectangular frame 31, the other end of the screw rod 32 extends out of the rectangular frame 31 and is fixedly provided with a hand wheel 34, and two thread sections with opposite rotation directions are symmetrically arranged on the screw rod 32;

the fixed block 33 is provided with two groups, which are respectively and fixedly arranged on the two groups of conveying mechanisms 1, and the fixed block 33 is provided with screw holes corresponding to the thread sections on the screw rod 32.

When the belt conveyer is used, the hand wheel 34 is rotated to drive the screw rod 32 to rotate, and the rotation of the screw rod 32 can drive the two groups of fixing blocks 33 to move in opposite directions or in opposite directions, so that the distance between the two groups of belt conveyer assemblies 11 is adjusted.

In this embodiment, the adjusting mechanism 3 further includes a guide assembly, the guide assembly includes a guide rod 36 and a slider 35, the guide rod 36 is fixedly mounted on the inner wall of the rectangular frame 31, the slider 35 is provided with two groups, respectively fixedly mounted on the two groups of conveying mechanisms 1, and the slider 35 can slide horizontally on the guide rod 36, the guide rod 36 and the slider 35 are arranged to provide a direction for movement of the fixed block 33, and the fixed block 33 is made to move more stably.

In this embodiment, the adjusting mechanism 3 further includes two sets of guide plates, which are fixed on the inner wall of the rectangular frame 31 by fixing members and distributed on two sides of the lifting platform; the setting of guide board makes the material that gets into lift platform more neat.

The working principle of the utility model is as follows: when the lifting platform formed by the bearing plates 2 at the same position on the corresponding belt conveying components 11 of the two groups of conveying mechanisms 1 moves to the highest position, materials conveyed by the feeding mechanism can be received, a plurality of materials fall on the lifting platform one by one and are stacked upwards, the bearing plates 2 of the corresponding other group of belt conveying components 11 in the two groups of conveying mechanisms 1 synchronously move upwards until the materials on the lifting platform are stacked to the ideal number, the lifting platform at the highest position needs to move downwards, and the lifting platform at the highest position moves downwards while the bearing plate 2 of the other corresponding belt conveying component 11 in the two groups of conveying mechanisms 1 moves to the highest position to form a new lifting platform.

The foregoing is only illustrative of the present utility model and is not to be construed as limiting the scope of the utility model, and all equivalent changes made by the description of the utility model and the accompanying drawings, or direct or indirect application in the relevant art, are intended to be included within the scope of the utility model.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (9)

1. A stacking type sheet arranging mechanism is characterized by comprising a conveying mechanism, wherein the conveying mechanism is provided with two groups and is vertically and oppositely arranged,

the conveying mechanism comprises a bearing plate and two groups of belt conveying components which are arranged side by side, the conveying directions of the two groups of belt conveying components are independently controlled, and at least one bearing plate is fixedly arranged on each group of belt conveying components;

the belt conveying components corresponding to the two groups of conveying mechanisms synchronously move and rotate in opposite directions, and the bearing plates at the same position on the belt conveying components corresponding to the two groups of conveying mechanisms form a lifting platform together and are used for conveying materials.

2. The stacked sheet handling mechanism of claim 1 wherein said belt conveyor assembly includes a drive belt, an upper roller and a lower roller, said drive belt being nested between said upper and lower rollers, said carrier plate being fixedly mounted on said drive belt surface.

3. The stacked sheet handling mechanism of claim 2 wherein said conveyor further comprises a frame, an upper drive shaft, a lower drive shaft, and a drive assembly;

the upper transmission shaft and the lower transmission shaft are respectively arranged at the upper end and the lower end of the frame, the two groups of belt conveying assemblies are respectively arranged in the frame, the upper idler wheels and the lower idler wheels of the belt conveying assemblies are respectively arranged on the corresponding upper transmission shaft and lower transmission shaft, one group of upper idler wheels of the belt conveying assemblies are fixedly connected with the upper transmission shaft, the lower idler wheels are rotatably connected with the lower transmission shaft, and the other group of upper idler wheels of the belt conveying assemblies are rotatably connected with the upper transmission shaft, and the lower idler wheels are fixedly connected with the lower transmission shaft;

the driving assembly is provided with two groups of driving assemblies which are respectively connected with the upper transmission shaft and the lower transmission shaft.

4. A stacked sheet organizer of claim 3, wherein the drive assembly comprises a motor, a drive wheel, a timing belt, and a driven wheel;

the driven wheels are provided with two groups which are respectively arranged on the upper transmission shafts or the lower transmission shafts of the two groups of conveying mechanisms;

the driving wheel is arranged on the motor;

the driving wheel is connected with the two groups of driven wheels through a synchronous belt and drives the two groups of driven wheels to synchronously move and rotate in opposite directions.

5. The stacked sheet handling mechanism of claim 4, wherein said drive assembly further comprises a guide wheel, said timing belt sequentially connecting said drive wheel, guide wheel, and driven wheel, one of said driven wheel being in contact with said timing belt inner wall and the other of said driven wheel being in contact with said timing belt outer wall.

6. The stacked sheet handling mechanism of claim 1, further comprising an adjustment mechanism for adjusting the spacing between the two sets of conveyor mechanisms.

7. The stacked sheet handling mechanism of claim 6 wherein said adjustment mechanism comprises a rectangular frame, a screw, a fixed block;

openings are formed in the top and the bottom of the rectangular frame, and the two groups of the rectangular frame enclose the conveying mechanism;

one end of the screw rod is rotatably arranged on the inner wall of the rectangular frame, the other end of the screw rod extends out of the rectangular frame and is fixedly provided with a hand wheel, and two thread sections with opposite rotation directions are symmetrically arranged on the screw rod;

the fixed block is provided with two groups which are respectively and fixedly arranged on the two groups of conveying mechanisms, and the fixed block is provided with screw holes corresponding to the threaded sections on the screw rod.

8. The stacked sheet handling mechanism of claim 7, wherein the adjustment mechanism further comprises a guide assembly comprising a guide rod and a slider, the guide rod is fixedly mounted on the inner wall of the rectangular frame, the slider is provided with two sets of guide rods, each set of guide rods is fixedly mounted on two sets of conveying mechanisms, and the slider is horizontally slidable on the guide rod.

9. The stacked sheet handling mechanism of claim 8, wherein the adjustment mechanism further comprises guide plates, wherein the guide plates are provided with two groups, are fixed on the inner wall of the rectangular frame by fixing pieces, and are distributed on two sides of the lifting platform.