CN219791590U

CN219791590U - Soft board buffer memory

Info

Publication number: CN219791590U
Application number: CN202320049361.XU
Authority: CN
Inventors: 庞晓东; 梁起昭; 庞其智
Original assignee: Shenzhen Langxing New Electric Automation Equipment Co ltd
Current assignee: Shenzhen Langxing New Electric Automation Equipment Co ltd
Priority date: 2023-01-09
Filing date: 2023-01-09
Publication date: 2023-10-03
Anticipated expiration: 2033-01-09

Abstract

The utility model relates to a soft board buffer memory, which comprises a feeding area, a conveying area and a buffer area; the flexible plate buffer storage machine is flexible to use and low in cost, when the lifting assembly drives the temporary storage material transmission assembly to move along the Z axis, the telescopic assembly on the temporary storage material transmission assembly drives the clutch assembly to rotate upwards to be separated from the first gear on the buffer storage material moving assembly, and at the moment, the plurality of first conveyor belt assemblies on the buffer storage material moving assembly are unpowered; when the temporary stock transmission assembly drives the workpiece plate to move towards the buffer stock shifting assembly, the telescopic assembly drives the clutch assembly to rotate downwards to be meshed with the first gear, so that power is provided for the buffer stock shifting assembly, a power source is not required to be additionally arranged for each buffer stock shifting assembly, the cost is greatly reduced, and the operation is flexible; the temporary storage transmission assembly and the buffer storage material moving assembly are matched with each other to convey the workpiece plate, so that the workpiece plate on the temporary storage material transmission assembly is moved to the buffer storage material moving assembly to finish plate collection, and the automation degree is high.

Description

Soft board buffer memory

Technical Field

The utility model relates to the technical field of cache memories, in particular to a soft board cache memory.

Background

The buffer storage machine is used for buffering materials during transportation, and is a common device for industrial automatic production; the buffer mechanism of the existing buffer machine is generally provided with a plurality of transmission devices for bearing a plurality of workpiece plates, and each transmission device is provided with a corresponding driving source, so that the number of the driving sources is large, the manufacturing cost is increased, and the working cost is also increased.

Disclosure of Invention

The utility model aims to solve the technical problem of providing a soft board buffer machine aiming at the defects in the prior art.

The technical scheme adopted for solving the technical problems is as follows: a soft board buffer comprises a feeding area, a conveying area and a buffer area which are sequentially arranged; a first material moving and conveying assembly for conveying the workpiece plate towards the conveying area is arranged in the feeding area; a plurality of longitudinally arranged buffer storage material moving assemblies are arranged in the buffer storage area; the buffer storage material moving assembly comprises a plurality of first conveyor belt assemblies which are distributed side by side; a plurality of first conveyor belt assemblies are connected in a synchronous rotation mode through a first rotating shaft; one end of the buffer storage material moving component, which is close to the conveying area, is also provided with a first gear fixedly connected with the first rotating shaft; a temporary storage material transmission assembly for conveying the workpiece plate towards the buffer area and a lifting assembly for driving the temporary storage material transmission assembly to intermittently move along a Z axis are arranged in the conveying area; a clutch assembly and a telescopic assembly for driving the clutch assembly to turn upwards or downwards are arranged at one end of the temporary storage material transmission assembly, which is close to the buffer area; when the clutch assembly is turned upwards to be separated from the first gear, no power is transmitted between the clutch assembly and the first gear; when the clutch assembly is turned down to engage the first gear, the clutch assembly transmits power to the first gear;

the utility model relates to a soft board buffer memory, wherein the temporary storage material transmission assembly comprises a first material frame; the first material frame is provided with a plurality of second conveyor belt components which are distributed side by side; the plurality of second conveyor belt components are synchronously and rotatably connected through a second rotating shaft; the first material frame is also provided with a first driving mechanism for driving the second rotating shaft to rotate;

the flexible board buffer memory comprises a clutch component and a first rotating shaft, wherein the clutch component comprises a mounting seat which is rotationally connected with the second rotating shaft; the upper end of the mounting seat is rotationally connected with a second gear meshed with the first gear, and the lower end of the mounting seat is provided with a connecting shaft connected with the telescopic component; a third gear fixedly connected with the second rotating shaft is further arranged in the mounting seat; the third gear is in meshed connection with the second gear;

the flexible board buffer storage machine comprises a flexible component, a buffer storage area and a buffer storage area, wherein the flexible component comprises a connecting rod which is rotationally connected with the connecting shaft, and a flexible cylinder which drives the connecting rod to approach or deviate from the buffer storage area;

the utility model relates to a soft board buffer memory, wherein the lifting component comprises a supporting upright post; the support upright post is provided with two Z-axis guide rods, a sliding block in sliding connection with the Z-axis guide rods and a Z-axis transmission assembly for driving the sliding block to move along the Z-axis guide rods along the length direction of the support upright post; the back of the sliding block is also provided with a plurality of sliding wheels matched with the two Z-axis guide rods; the temporary storage material transmission assembly is fixedly arranged on the front surface of the sliding block;

the soft board buffer memory provided by the utility model is characterized in that a plurality of support rods for supporting the temporary storage material transmission assembly are fixedly arranged on the sliding block;

the soft board buffer memory machine disclosed by the utility model is characterized in that a discharging channel is further arranged between any two adjacent buffer memory material moving assemblies; a discharge hole for the workpiece plate to pass through is formed in one end, far away from the buffer area, of the discharge channel; a second material moving and conveying assembly for conveying the workpiece plate towards the discharge port is arranged in the discharge channel;

the utility model discloses a soft board buffer memory, wherein the second material moving transmission assembly comprises a second material frame and a second driving mechanism arranged at one side of the second material frame; the second material frame is provided with a plurality of third conveyor belt assemblies which are distributed side by side; the plurality of third conveyor belt assemblies are synchronously and rotatably connected through third rotating shafts; the second driving mechanism drives the second rotating shaft to rotate;

the soft board buffer memory of the utility model, wherein, the lower part of a plurality of said third conveyor belt assemblies has dust-proof plates; the lower surface of the second material frame is fixedly provided with a plurality of L-shaped supporting strips for supporting the dust-proof plate;

the flexible board buffer storage machine provided by the utility model, wherein the second material moving transmission assembly corresponds to the first material moving transmission assembly.

The utility model has the beneficial effects that: the flexible plate buffer storage machine is flexible to use and low in cost, after the temporary storage material transmission assembly receives the workpiece plate transmitted from the first material moving transmission assembly, when the lifting assembly drives the temporary storage material transmission assembly to move along the Z axis, the telescopic assembly on the temporary storage material transmission assembly drives the clutch assembly to rotate upwards to be separated from the first gear on the buffer storage material moving assembly, and at the moment, the buffer storage material moving assembly is unpowered; when the lifting assembly pauses after transporting the temporary storage material transmission assembly to a preset position, the temporary storage material transmission assembly starts to drive the workpiece plate to move towards the buffer storage material moving assembly, and the telescopic assembly on the temporary storage material transmission assembly drives the clutch assembly to rotate downwards to be meshed with the first gear on the buffer storage material moving assembly, so that power is provided for the buffer storage material moving assembly, a power source is not required to be additionally arranged for each buffer storage material moving assembly, the cost is greatly reduced, and the operation is flexible; the temporary storage transmission assembly and the buffer storage material moving assembly are matched with each other to convey the workpiece plate, so that the workpiece plate on the temporary storage material transmission assembly is moved to the buffer storage material moving assembly to finish plate collection, and the automation degree is high.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the present utility model will be further described with reference to the accompanying drawings and embodiments, in which the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained by those skilled in the art without inventive effort:

FIG. 1 is a schematic diagram of a flexible printed circuit board buffer according to a preferred embodiment of the present utility model;

FIG. 2 is a schematic diagram of a flexible printed circuit buffer according to a second embodiment of the present utility model;

FIG. 3 is an enlarged view of A in FIG. 1;

FIG. 4 is a schematic view showing the structure of the temporary storage transporting assembly and the lifting assembly according to the preferred embodiment of the present utility model;

FIG. 5 is an enlarged view of B in FIG. 4;

FIG. 6 is a schematic diagram of a buffer and transfer assembly according to a preferred embodiment of the present utility model;

fig. 7 is a schematic structural view of a second material transferring assembly according to a preferred embodiment of the present utility model.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the following description will be made in detail with reference to the technical solutions in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by a person skilled in the art without any inventive effort, are intended to be within the scope of the present utility model, based on the embodiments of the present utility model.

The soft board buffer memory of the preferred embodiment of the utility model, as shown in figures 1-7, comprises a feeding area 11, a transmitting area 12 and a buffer area 13 which are sequentially arranged; a first material moving and conveying assembly 100 for conveying the workpiece plate 10 towards the conveying area 12 is arranged in the feeding area 11; the first material moving assembly is a plurality of conveyor belt assemblies for conveying the workpiece plates; it should be noted that, the first material transferring assembly may be other existing structures capable of transporting the workpiece plate in the prior art, which is not described herein again; the workpiece plate is a circuit board or other flexible board with larger area, and the specific workpiece plate is not limited; a plurality of longitudinally arranged buffer material moving components 200 are arranged in the buffer zone 13; the buffer material moving assembly 200 comprises a plurality of first conveyor belt assemblies 201 which are distributed side by side; a plurality of first conveyor belt assemblies 201 are rotationally coupled in synchrony by a first shaft 202; the first conveyor belt assembly comprises a conveyor belt, a driving wheel and a driven wheel; the main conveying wheel and the driven wheel synchronously rotate through a conveying belt; the first conveyor belt assembly is of the prior art and will not be described in detail herein; the buffer storage material moving assembly 200 is also provided with a first gear 203 fixedly connected with the first rotating shaft 202 at one end close to the conveying area 12; a temporary storage material transmission assembly 300 for conveying the workpiece plate 10 towards the buffer zone 13 and a lifting assembly 400 for driving the temporary storage material transmission assembly 300 to intermittently move along the Z axis are arranged in the conveying zone 12; the temporary storage conveying component 300 is provided with a clutch component 500 and a telescopic component 600 for driving the clutch component 500 to turn upwards or downwards at one end close to the buffer zone 13; when the clutch assembly 500 is turned up to be separated from the first gear 203, no power is transmitted between the clutch assembly 500 and the first gear 203; when the clutch assembly 500 is turned down to be meshed with the first gear 203, the clutch assembly 500 transmits power to the first gear 203 so as to drive the first conveyor belt assemblies to rotate, and at the moment, the temporary storage material conveying assembly and the buffer material moving assembly are mutually matched, so that a workpiece plate on the temporary storage material conveying assembly is moved to the buffer material moving assembly to finish plate collection.

The flexible plate buffer storage machine is flexible to use and low in cost, after the temporary storage material transmission assembly receives the workpiece plate transmitted from the first material moving transmission assembly, when the lifting assembly drives the temporary storage material transmission assembly to move along the Z axis, the telescopic assembly on the temporary storage material transmission assembly drives the clutch assembly to rotate upwards to be separated from the first gear on the buffer storage material moving assembly, and at the moment, the buffer storage material moving assembly is unpowered; when the lifting assembly pauses after transporting the temporary storage material transmission assembly to a preset position, the temporary storage material transmission assembly starts to drive the workpiece plate to move towards the buffer storage material moving assembly, and the telescopic assembly on the temporary storage material transmission assembly drives the clutch assembly to rotate downwards to be meshed with the first gear on the buffer storage material moving assembly, so that power is provided for the buffer storage material moving assembly, a power source is not required to be additionally arranged for each buffer storage material moving assembly, the cost is greatly reduced, and the operation is flexible; the temporary storage transmission assembly and the buffer storage material moving assembly are matched with each other to convey the workpiece plate, so that the workpiece plate on the temporary storage material transmission assembly is moved to the buffer storage material moving assembly to finish plate collection, and the automation degree is high.

Preferably, the temporary storage material transferring assembly 300 includes a first material frame 301; the first material frame 301 is provided with a plurality of second conveyor belt assemblies 302 which are distributed side by side; the second conveyor belt assembly adopts a structure like the first conveyor belt assembly, and is not described in detail herein; a plurality of second conveyor belt assemblies 302 are synchronously rotatably connected by a second rotary shaft 303; the first material frame 301 is also provided with a first driving mechanism 304 for driving the second rotating shaft 303 to rotate; the first driving mechanism comprises a driving motor and a conveying belt in transmission connection with the second rotating shaft; the driving motor drives the conveying belt to rotate, and it is worth to be noted that the first driving mechanism is in the prior art and is not described herein again; the temporary storage material transmission assembly synchronously rotates through a plurality of second conveyor belt assemblies, so that the workpiece plate is driven to move, and the operation is stable.

Preferably, the clutch assembly 500 includes a mounting 501 rotatably coupled to the second shaft 303; the upper end of the mounting seat 501 is rotatably connected with a second gear 502 meshed with the first gear 203, and the lower end of the mounting seat is provided with a connecting shaft 503 connected with the telescopic assembly 600; a third gear 504 fixedly connected with the second rotating shaft 303 is also arranged in the mounting seat 501; the third gear 504 is in meshed connection with the second gear 502; when the second rotating shaft rotates, the third gear also transfers along with the second rotating shaft, so that the second gear is driven to rotate.

Preferably, the telescopic assembly 600 includes a connecting rod 601 rotatably connected to the connecting shaft 503, and a telescopic cylinder 602 driving the connecting rod 601 to approach or depart from the buffer zone 13. When the telescopic cylinder pushes the connecting shaft at the lower end of the mounting seat to move towards the buffer area, the upper end of the mounting seat is lifted upwards, so that the second gear is separated from the first gear; when the connecting shaft at the lower end of the telescopic cylinder pulls the mounting seat to move away from the buffer area, the upper end of the mounting seat is turned downwards until the second gear is meshed with the first gear, so that power is conveniently transmitted to the first gear.

Preferably, the lifting assembly 400 includes a support column 401; the support column 401 is provided with two Z-axis guide rods 402, a sliding block 403 which is in sliding connection with the Z-axis guide rods 402 and a Z-axis transmission assembly 404 which drives the sliding block 403 to move along the Z-axis guide rods 402 along the length direction; the back of the slide block 403 is also provided with a plurality of sliding wheels 405 matched with the two Z-axis guide rods 402; the temporary storage conveying assembly 300 is fixedly arranged on the front surface of the sliding block 403; it should be noted that, the lifting assembly may also adopt other structures in the prior art that can drive the temporary storage conveying assembly to lift up and down, which will not be described herein.

In order to make the temporary storage material transferring assembly transport the workpiece plate more stable, a plurality of support rods 406 for supporting the temporary storage material transferring assembly 300 are further fixedly arranged on the slide block 403.

Preferably, a discharging channel is further arranged between any two adjacent buffer storage material moving assemblies 200; a discharge port 204 for the workpiece plate 10 to pass through is arranged at one end of the discharge channel far away from the buffer memory area 13; a second material moving and conveying assembly 700 for conveying the workpiece plate 10 towards the discharge port 204 is arranged in the discharge channel; preferably, the second pipetting transferring assembly 700 corresponds to the first pipetting transferring assembly 100.

Preferably, the second material transferring assembly 700 includes a second material frame 701, and a second driving mechanism 702 disposed at one side of the second material frame 701; the second material frame 701 is provided with a plurality of third conveyor belt assemblies 703 which are distributed side by side; a plurality of third conveyor belt assemblies 703 are rotationally connected in synchronization by a third shaft 704; the second driving mechanism 702 drives the second rotating shaft 303 to rotate; the third belt assembly is of the same construction as the first belt assembly.

Preferably, a dust guard 705 is also disposed under the plurality of third conveyor assemblies 703; the lower surface of the second material frame 701 is fixedly provided with a plurality of L-shaped supporting strips 706 for supporting the dust-proof plate 705.

It will be understood that modifications and variations will be apparent to those skilled in the art from the foregoing description, and it is intended that all such modifications and variations be included within the scope of the following claims.

Claims

1. The soft board buffer memory is characterized by comprising a feeding area, a conveying area and a buffer area which are sequentially arranged; a first material moving and conveying assembly for conveying the workpiece plate towards the conveying area is arranged in the feeding area; a plurality of longitudinally arranged buffer storage material moving assemblies are arranged in the buffer storage area; the buffer storage material moving assembly comprises a plurality of first conveyor belt assemblies which are distributed side by side; a plurality of first conveyor belt assemblies are connected in a synchronous rotation mode through a first rotating shaft; one end of the buffer storage material moving component, which is close to the conveying area, is also provided with a first gear fixedly connected with the first rotating shaft; a temporary storage material transmission assembly for conveying the workpiece plate towards the buffer area and a lifting assembly for driving the temporary storage material transmission assembly to intermittently move along a Z axis are arranged in the conveying area; a clutch assembly and a telescopic assembly for driving the clutch assembly to turn upwards or downwards are arranged at one end of the temporary storage material transmission assembly, which is close to the buffer area; when the clutch assembly is turned upwards to be separated from the first gear, no power is transmitted between the clutch assembly and the first gear; when the clutch assembly is flipped down into engagement with the first gear, the clutch assembly transmits power to the first gear.

2. The flexible printed circuit board buffer as described in claim 1, wherein the temporary storage material transmission assembly comprises a first material frame; the first material frame is provided with a plurality of second conveyor belt components which are distributed side by side; the plurality of second conveyor belt components are synchronously and rotatably connected through a second rotating shaft; the first material frame is also provided with a first driving mechanism for driving the second rotating shaft to rotate.

3. The flexible printed circuit board buffer memory of claim 2, wherein the clutch assembly comprises a mounting seat rotatably connected with the second rotating shaft; the upper end of the mounting seat is rotationally connected with a second gear meshed with the first gear, and the lower end of the mounting seat is provided with a connecting shaft connected with the telescopic component; a third gear fixedly connected with the second rotating shaft is further arranged in the mounting seat; the third gear is in meshed connection with the second gear.

4. A flexible printed circuit board buffer as in claim 3 wherein the telescoping assembly comprises a connecting rod rotatably connected to the connecting shaft and a telescoping cylinder driving the connecting rod to approach or depart from the buffer area.

5. The flexible printed circuit board buffer of claim 1, wherein the lifting assembly comprises a support post; the support upright post is provided with two Z-axis guide rods, a sliding block in sliding connection with the Z-axis guide rods and a Z-axis transmission assembly for driving the sliding block to move along the Z-axis guide rods along the length direction of the support upright post; the back of the sliding block is also provided with a plurality of sliding wheels matched with the two Z-axis guide rods; the temporary storage material transmission assembly is fixedly arranged on the front surface of the sliding block.

6. The flexible printed circuit board buffer memory of claim 5, wherein a plurality of support rods for supporting the temporary storage material transmission assembly are further fixedly arranged on the sliding block.

7. The flexible printed circuit board buffer storage machine according to any one of claims 2-4, wherein a discharge channel is further arranged between any two adjacent buffer storage material moving assemblies; a discharge hole for the workpiece plate to pass through is formed in one end, far away from the buffer area, of the discharge channel; and a second material moving and conveying assembly for conveying the workpiece plate towards the discharge port is arranged in the discharge channel.

8. The flexible printed circuit board buffer memory according to claim 7, wherein the second material moving transmission assembly comprises a second material frame and a second driving mechanism arranged at one side of the second material frame; the second material frame is provided with a plurality of third conveyor belt assemblies which are distributed side by side; the plurality of third conveyor belt assemblies are synchronously and rotatably connected through third rotating shafts; the second driving mechanism drives the second rotating shaft to rotate.

9. The flexible printed circuit board buffer memory of claim 8, wherein a dust-proof board is further arranged below the plurality of third conveyor belt assemblies; the lower surface of second material frame has set firmly a plurality of L shape holds in palm strip that are used for supporting the dust guard.

10. The flexible printed circuit buffer of claim 7, wherein the second transfer assembly corresponds to the first transfer assembly.