CN221026338U - Automatic unloading platform of piece material multichannel - Google Patents

Abstract

The utility model discloses a multi-channel automatic blanking platform for sheet materials, which is used for bearing and conveying the sheet materials and comprises a first conveying section and a second conveying section which are connected with each other along a linear direction and independently move; at least two transmission channels are arranged on the first transmission section and the second transmission section at intervals along the direction perpendicular to the transmission direction; the first transmission section and the second transmission section comprise at least two transmission shafts which are arranged in parallel at intervals; at least two rollers are sleeved on the transmission shaft at intervals; the distance between two adjacent rollers in the at least two rollers is not larger than the width of the sheet material; at least two transmission shafts in the first transmission section synchronously and co-rotate to transmit sheet materials; at least two transmission shafts in the second transmission section synchronously and co-rotate to transmit the sheet materials. According to the utility model, the transfer buffer storage of the materials is realized through the independently driven material sections, the blanking storage capacity is improved, the materials are synchronously transmitted through multiple channels, the material transmission efficiency is effectively improved, the standby time is reduced, and the whole line productivity is improved.

Description

Automatic unloading platform of piece material multichannel

Technical Field

The utility model relates to the field of automatic display screen manufacturing equipment, in particular to a multi-channel automatic blanking platform for sheet materials.

Background

In the intelligent terminal equipment, a screen is a core accessory, glass is an important component part of the screen, along with the improvement and upgrade of an automatic production line, screen manufacturing gradually progresses from a traditional manual or single-machine operation mode to the direction of the automatic production line, and for the automatic production line of glass, an automatic feeding process of the glass is involved in the production process.

An important process involved in an automated glass production line is automatic glass blanking, and the existing blanking mode generally uses a mechanical arm to directly move the processed glass from a processing position to a material belt, and then the processed glass is transferred to a subsequent processing station through the material belt. The defect is that the blanking mode can not transfer and buffer the materials; and to the equipment that needs a plurality of materials of simultaneous processing, the material needs the manipulator to take out the material from the material area many times, because the manipulator gets and puts the material and need consume time, consequently need the material area to pause transmission or through control material clearance and material area transmission rate for the manipulator gets and puts just next piece material motion to the manipulator below when a slice material returns the material area, this kind of mode has restricted whole line material transmission efficiency.

Disclosure of utility model

The utility model aims to solve the technical problems of the prior art, and provides a sheet material multi-channel automatic blanking platform which realizes the transfer buffering of materials through independently driven material segments, improves the blanking storage capacity, effectively improves the material transmission efficiency through multi-channel synchronous material transmission, reduces the standby time and improves the whole line productivity.

The technical scheme adopted by the utility model is as follows: the multi-channel automatic blanking platform for carrying and conveying sheet materials comprises a first conveying section and a second conveying section which are connected with each other along a linear direction and independently move; one of the first transmission section and the second transmission section is used for receiving materials, and the other transmission section is used for guiding out the materials; at least two transmission channels are arranged on the first transmission section and the second transmission section at intervals along the direction perpendicular to the transmission direction of the first transmission section and the second transmission section and are used for bearing and transmitting at least two materials; the first transmission section and the second transmission section comprise at least two transmission shafts which are arranged in parallel at intervals; at least two rollers are sleeved on the transmission shaft at intervals; the distance between two adjacent rollers in the at least two rollers is not larger than the width of the sheet material; at least two transmission shafts in the first transmission section synchronously and co-rotate to transmit sheet materials; at least two transmission shafts in the second transmission section synchronously and co-rotate to transmit the sheet materials.

Preferably, the transmission channels include a first transmission channel, a second transmission channel, a third transmission channel and a fourth transmission channel which are arranged in parallel at intervals.

Preferably, at least two transmission shafts in the first transmission section are driven by a first driving assembly to synchronously and co-rotate; at least two transmission shafts in the second transmission section are driven by a second driving component to synchronously and co-rotate.

Preferably, the first driving component and the second driving component are arranged on the bearing component; the bearing assembly comprises a carrier plate and a support plate, wherein the carrier plate is of a rectangular plate-shaped structure and is horizontally arranged; the support plates comprise two support plates, the two support plates are arranged on the carrier plate at intervals in parallel, the two support plates are vertically arranged on the carrier plate, and a transmission channel is formed between the two support plates.

Preferably, the first driving assembly comprises a first motor, a first transmission rod, a first transmission wheel and a second transmission wheel, wherein the first motor is horizontally connected to the lower part of the carrier plate; the first transmission rods are arranged on the outer sides of the two support plates along the support plate direction respectively, are supported by support blocks arranged on the support plates, and are rotatably connected with the support blocks; the first driving wheels comprise at least two first driving wheels which are sleeved on the first driving rod at intervals; the second driving wheels comprise at least two, and the at least two second driving wheels are respectively sleeved at the end parts of the transmission shafts and are connected with the first driving wheels; the first motor drives the first transmission rod to drive at least two first transmission wheels to synchronously and co-directionally rotate, and the at least two first transmission wheels drive at least two transmission shafts to synchronously and co-directionally rotate through the second transmission wheels.

Preferably, the second driving assembly comprises a second motor, a second transmission rod, a first transmission wheel and a second transmission wheel, wherein the second motor is horizontally connected to the lower part of the carrier plate; the two second transmission rods are respectively arranged at the outer sides of the two support plates along the support plate direction and are supported by the support blocks arranged on the carrier plates in a bearing way, and the second transmission rods are rotatably connected with the support blocks; the first driving wheels comprise at least two first driving wheels which are sleeved on the second driving rod at intervals; the second driving wheels comprise at least two, and the at least two second driving wheels are respectively sleeved at the end parts of the transmission shafts and are connected with the first driving wheels; the second motor drives the second transmission rod to drive the at least two first transmission wheels to synchronously and co-directionally rotate, and the at least two first transmission wheels drive the at least two transmission shafts to synchronously and co-directionally rotate through the second transmission wheels.

Preferably, the device also comprises a support bar seat; the support bar bases comprise four support bar bases which are arranged in parallel at intervals and are respectively positioned in the first transmission channel, the second transmission channel, the third transmission channel and the fourth transmission channel.

Preferably, the support bar seat is provided with a material sensor; the material sensor is located in a clearance space between two adjacent transmission shafts along the vertical projection direction and is used for sensing sheet materials transmitted on the transmission shafts.

The utility model has the beneficial effects that:

The utility model designs a multi-channel automatic blanking platform for sheet materials, which realizes the transfer buffering of the materials through the independently driven material sections, improves the blanking storage capacity, effectively improves the material transmission efficiency through multi-channel synchronous material transmission, reduces the standby time and improves the whole line productivity.

The utility model aims to design an occasion for transferring and discharging sheet materials such as glass, which is mainly used for butting glass processing stations, and solves the problems that the prior material belt transmission cannot be used for independently caching materials, the synchronous transmission of a plurality of pieces of materials cannot be realized, and the productivity is limited. Specifically, the utility model integrally comprises a first transmission section and a second transmission section which are connected and independently move and transmit, wherein one transmission section is used for receiving and buffering materials, the other transmission section is used for realizing synchronous discharging (feeding) of a plurality of materials after receiving and buffering the buffered materials, the two mutually independent material transmission sections enable the utility model to have a transfer buffering function, namely, the materials are buffered and transferred in one transmission section according to the feeding requirement of a post-section work station, and the materials can be stored in a buffering part and the angles, positions, front sides and back sides and the like of the materials can be adjusted on the premise that the other transmission section maintains intermittent feeding, so as to adapt to different material processing requirements; meanwhile, the transmission channels of the first transmission section and the second transmission section are mutually communicated, and four transmission channels which are arranged in parallel at intervals are formed in the first transmission section and the second transmission section, so that the function of synchronously transmitting four materials at a time is realized, and the material transmission and feeding efficiency is improved in a multiplied manner. In the practical application process, the number of channels can be controlled according to the processing requirements of subsequent work stations so as to adapt to different processing scenes. Specifically, the utility model takes a horizontally arranged carrier plate and two support plates arranged on the carrier plate at intervals in parallel as a bearing structure, the two support plates vertically extend to form a material transmission channel between the two support plates, a plurality of transmission shafts are arranged between the two support plates at intervals in parallel, a plurality of rollers are sleeved on the transmission shafts at intervals according to the number of the channels, each roller is formed into four groups on the transmission shafts, a piece of material is limited between the two rollers of the single group, the cross section of each roller is of a T-shaped structure, the part with large diameter at the end part is used for limiting the flaky material from two sides, the material placed between the two rollers in the actual transmission process drives the rollers to rotate through the transmission shaft to realize forward linear transmission, the transmission shaft between the two support plates is divided into two groups, the two groups of transmission shafts are respectively driven to rotate through a first transmission rod and a second transmission rod arranged at the end part of each transmission shaft, the first transmission rod and the second transmission rod are respectively driven by a first motor and a second motor to independently rotate, and the first transmission rod and the second transmission rod are respectively sleeved on the transmission shafts are respectively driven by the first motor and the second motor and the transmission rod are respectively driven by the transmission rods to rotate synchronously, and the transmission shafts are synchronously driven by the transmission shafts to a plurality of transmission shafts; in the practical application process, the first driving wheel and the second driving wheel can adopt magnetic wheels for transmitting and converting power or adopt a helical gear structure.

Drawings

Fig. 1 is a schematic perspective view of the present utility model.

FIG. 2 is a schematic diagram of a second perspective structure of the present utility model.

FIG. 3 is a third perspective view of the present utility model.

Detailed Description

The utility model will be further described with reference to the accompanying drawings in which:

As shown in fig. 1 to 3, the technical scheme adopted by the utility model is as follows: the multi-channel automatic blanking platform for carrying and conveying sheet materials comprises a first conveying section D and a second conveying section E which are connected with each other along a linear direction and independently move; one of the first transmission section D and the second transmission section E is used for receiving materials, and the other transmission section is used for guiding out the materials; at least two transmission channels are arranged on the first transmission section D and the second transmission section E at intervals along the direction perpendicular to the transmission direction of the first transmission section D and the second transmission section E and are used for bearing and transmitting at least two materials; the first transmission section D and the second transmission section E include at least two transmission shafts 88 arranged in parallel at intervals; at least two rollers 810 are sleeved on the transmission shaft 88 at intervals; the distance between two adjacent rollers 810 in the at least two rollers 810 is not greater than the width of the sheet material; at least two transmission shafts 88 in the first transmission section D rotate synchronously and in the same direction to transmit the sheet material; at least two drive shafts 88 in the second conveying section E rotate synchronously and in the same direction to convey sheet material.

The transmission channels comprise a first transmission channel F1, a second transmission channel F2, a third transmission channel F3 and a fourth transmission channel F4 which are arranged in parallel at intervals.

At least two transmission shafts 88 in the first transmission section D are driven by the first driving assembly to synchronously and co-rotate; at least two drive shafts 88 in the second transmission section E are driven by the second drive assembly to move synchronously and in the same direction.

The first driving component and the second driving component are arranged on the bearing component; the bearing assembly comprises a bearing plate 81 and a support plate 87, wherein the bearing plate 81 is of a rectangular plate-shaped structure, and the bearing plate 81 is horizontally arranged; the support plates 87 comprise two support plates 87 which are arranged on the carrier plate 81 at intervals in parallel, the two support plates 87 are vertically arranged on the carrier plate 81, and a transmission channel is formed between the two support plates 87.

The first driving assembly comprises a first motor 84, a first transmission rod 85, a first transmission wheel 86 and a second transmission wheel 89, wherein the first motor 84 is horizontally connected to the lower part of the carrier plate 81; the first transmission rods 85 comprise two first transmission rods 85, the two first transmission rods 85 are respectively arranged outside the two support plates 87 along the direction of the support plates 87 and are supported by the support blocks arranged on the carrier plates 81 in a bearing way, and the first transmission rods 85 are rotatably connected with the support blocks; the first driving wheels 86 comprise at least two first driving wheels 86 which are sleeved on the first driving rod 85 at intervals; the second driving wheels 89 comprise at least two second driving wheels 89, and the at least two second driving wheels 89 are respectively sleeved at the end parts of the transmission shafts 88 and are connected with the first driving wheels 86; the first motor 84 drives the first transmission rod 85 to drive at least two first transmission wheels 86 to synchronously and co-rotate, and the at least two first transmission wheels 86 drive at least two transmission shafts 88 to synchronously and co-rotate through the second transmission wheels 89.

The second driving assembly comprises a second motor 82, a second transmission rod 83, a first transmission wheel 86 and a second transmission wheel 89, wherein the second motor 82 is horizontally connected to the lower part of the carrier plate 81; the two second transmission rods 83 are arranged outside the two support plates 87 along the direction of the support plates 87 respectively, and are supported by the support blocks arranged on the carrier plates 81 in a bearing way, and the second transmission rods 83 are rotatably connected with the support blocks; the first driving wheels 86 comprise at least two first driving wheels 86 which are sleeved on the second driving rod 83 at intervals; the second driving wheels 89 comprise at least two second driving wheels 89, and the at least two second driving wheels 89 are respectively sleeved at the end parts of the transmission shafts 88 and are connected with the first driving wheels 86; the second motor 82 drives the second transmission rod 83 to drive at least two first transmission wheels 86 to synchronously and co-rotate, and the at least two first transmission wheels 86 drive at least two transmission shafts 88 to synchronously and co-rotate through the second transmission wheels 89.

Also includes a support bar seat 811; the supporting bar bases 811 include four supporting bar bases 811 arranged in parallel at intervals and respectively located in the first transmission channel F1, the second transmission channel F2, the third transmission channel F3 and the fourth transmission channel F4.

A material sensor 812 is arranged on the support bar seat 811; the material sensor 812 is located in a gap space between two adjacent transmission shafts 88 along a vertical projection direction, and is used for sensing the sheet material conveyed on the transmission shafts 88.

Furthermore, the utility model designs a multi-channel automatic blanking platform for sheet materials, which realizes the transfer buffering of the materials through the independently driven material sections, improves the blanking storage capacity, and effectively improves the material transmission efficiency through multi-channel synchronous transmission of the materials, reduces the standby time and improves the whole line productivity. The utility model aims to design an occasion for transferring and discharging sheet materials such as glass, which is mainly used for butting glass processing stations, and solves the problems that the prior material belt transmission cannot be used for independently caching materials, the synchronous transmission of a plurality of pieces of materials cannot be realized, and the productivity is limited. Specifically, the utility model integrally comprises a first transmission section and a second transmission section which are connected and independently move and transmit, wherein one transmission section is used for receiving and buffering materials, the other transmission section is used for realizing synchronous discharging (feeding) of a plurality of materials after receiving and buffering the buffered materials, the two mutually independent material transmission sections enable the utility model to have a transfer buffering function, namely, the materials are buffered and transferred in one transmission section according to the feeding requirement of a post-section work station, and the materials can be stored in a buffering part and the angles, positions, front sides and back sides and the like of the materials can be adjusted on the premise that the other transmission section maintains intermittent feeding, so as to adapt to different material processing requirements; meanwhile, the transmission channels of the first transmission section and the second transmission section are mutually communicated, and four transmission channels which are arranged in parallel at intervals are formed in the first transmission section and the second transmission section, so that the function of synchronously transmitting four materials at a time is realized, and the material transmission and feeding efficiency is improved in a multiplied manner. In the practical application process, the number of channels can be controlled according to the processing requirements of subsequent work stations so as to adapt to different processing scenes. Specifically, the utility model takes a horizontally arranged carrier plate and two support plates arranged on the carrier plate at intervals in parallel as a bearing structure, the two support plates vertically extend to form a material transmission channel between the two support plates, a plurality of transmission shafts are arranged between the two support plates at intervals in parallel, a plurality of rollers are sleeved on the transmission shafts at intervals according to the number of the channels, each roller is formed into four groups on the transmission shafts, a piece of material is limited between the two rollers of the single group, the cross section of each roller is of a T-shaped structure, the part with large diameter at the end part is used for limiting the flaky material from two sides, the material placed between the two rollers in the actual transmission process drives the rollers to rotate through the transmission shaft to realize forward linear transmission, the transmission shaft between the two support plates is divided into two groups, the two groups of transmission shafts are respectively driven to rotate through a first transmission rod and a second transmission rod arranged at the end part of each transmission shaft, the first transmission rod and the second transmission rod are respectively driven by a first motor and a second motor to independently rotate, and the first transmission rod and the second transmission rod are respectively sleeved on the transmission shafts are respectively driven by the first motor and the second motor and the transmission rod are respectively driven by the transmission rods to rotate synchronously, and the transmission shafts are synchronously driven by the transmission shafts to a plurality of transmission shafts; in the practical application process, the first driving wheel and the second driving wheel can adopt magnetic wheels for transmitting and converting power or adopt a helical gear structure.

The examples of the present utility model are presented only to describe specific embodiments thereof and are not intended to limit the scope of the utility model. Certain modifications may be made by those skilled in the art in light of the teachings of this embodiment, and all equivalent changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (8)

1. The utility model provides a piece multichannel automatic unloading platform for bear and transport piece material, its characterized in that: comprises a first transmission section (D) and a second transmission section (E) which are connected with each other along the straight line direction and independently move;

One of the first transmission section (D) and the second transmission section (E) is used for receiving materials, and the other transmission section is used for guiding out the materials;

At least two transmission channels are arranged on the first transmission section (D) and the second transmission section (E) at intervals along the direction perpendicular to the transmission direction of the first transmission section (D) and the second transmission section (E) and are used for bearing and transmitting at least two pieces of materials;

The first transmission section (D) and the second transmission section (E) comprise at least two transmission shafts (88) which are arranged in parallel at intervals; at least two rollers (810) are sleeved on the transmission shaft (88) at intervals;

The distance between two adjacent rollers (810) in the at least two rollers (810) is not larger than the width of the sheet material;

At least two transmission shafts (88) in the first transmission section (D) synchronously and co-rotate to transmit sheet materials; at least two transmission shafts (88) in the second transmission section (E) synchronously and co-rotate to transmit the sheet material.

2. The multi-channel automatic blanking platform of claim 1, wherein: the transmission channels comprise a first transmission channel (F1), a second transmission channel (F2), a third transmission channel (F3) and a fourth transmission channel (F4) which are arranged in parallel at intervals.

3. The multi-channel automatic blanking platform of claim 1, wherein: at least two transmission shafts (88) in the first transmission section (D) are driven by a first driving component to synchronously and co-rotate; at least two transmission shafts (88) in the second transmission section (E) are driven by a second driving assembly to synchronously and co-rotate.

4. A sheet stock multi-channel automatic blanking platform according to claim 3, wherein: the first driving component and the second driving component are arranged on the bearing component; the bearing assembly comprises a bearing plate (81) and a support plate (87), wherein the bearing plate (81) is of a rectangular plate-shaped structure, and the bearing plate (81) is horizontally arranged; the support plates (87) comprise two support plates (87), the two support plates (87) are arranged on the carrier plate (81) at intervals in parallel, the two support plates (87) are vertically arranged on the carrier plate (81), and a transmission channel is formed between the two support plates.

5. The multi-channel automatic blanking platform for sheets according to claim 4, wherein: the first driving assembly comprises a first motor (84), a first transmission rod (85), a first transmission wheel (86) and a second transmission wheel (89), wherein the first motor (84) is horizontally connected to the lower part of the carrier plate (81); the first transmission rods (85) comprise two first transmission rods (85), the two first transmission rods (85) are respectively arranged on the outer sides of the two support plates (87) along the direction of the support plates (87), and are supported by the support blocks arranged on the support plates (81), and the first transmission rods (85) are rotatably connected with the support blocks; the first driving wheels (86) comprise at least two first driving wheels (86) which are sleeved on the first driving rod (85) at intervals; the second driving wheels (89) comprise at least two, and the at least two second driving wheels (89) are respectively sleeved at the end parts of the transmission shafts (88) and are connected with the first driving wheels (86); the first motor (84) drives the first transmission rod (85) to drive at least two first transmission wheels (86) to synchronously and in the same direction to rotate, and the at least two first transmission wheels (86) drive at least two transmission shafts (88) to synchronously and in the same direction to rotate through the second transmission wheels (89).

6. The multi-channel automatic blanking platform for sheets according to claim 4, wherein: the second driving assembly comprises a second motor (82), a second transmission rod (83), a first transmission wheel (86) and a second transmission wheel (89), wherein the second motor (82) is horizontally connected to the lower part of the carrier plate (81); the second transmission rods (83) comprise two second transmission rods (83), the two second transmission rods (83) are respectively arranged on the outer sides of the two support plates (87) along the direction of the support plates (87), and are supported by supporting blocks arranged on the support plates (81), and the second transmission rods (83) are rotatably connected with the supporting blocks; the first driving wheels (86) comprise at least two first driving wheels (86) which are sleeved on the second driving rod (83) at intervals; the second driving wheels (89) comprise at least two, and the at least two second driving wheels (89) are respectively sleeved at the end parts of the transmission shafts (88) and are connected with the first driving wheels (86); the second motor (82) drives the second transmission rod (83) to drive at least two first transmission wheels (86) to synchronously and co-directionally rotate, and the at least two first transmission wheels (86) drive at least two transmission shafts (88) to synchronously and co-directionally rotate through the second transmission wheels (89).

7. A multi-channel automatic blanking platform for sheet stock according to claim 2, wherein: also comprises a support bar seat (811); the support bar bases (811) comprise four support bar bases (811) which are arranged at intervals in parallel and are respectively positioned in the first transmission channel (F1), the second transmission channel (F2), the third transmission channel (F3) and the fourth transmission channel (F4).

8. The multi-channel automatic blanking platform of claim 7, wherein: a material sensor (812) is arranged on the supporting bar seat (811); the material sensor (812) is located in a clearance space between two adjacent transmission shafts (88) along the vertical projection direction and is used for sensing sheet materials conveyed on the transmission shafts (88).