CN212967647U - Cache conveying device for solar silicon wafers - Google Patents

Abstract

The utility model discloses a cache conveying device for solar silicon wafers, which comprises a bottom plate arranged on a frame, a support, a transmission motor and transmission belts symmetrically arranged at the two sides of the support, the support is arranged on the upper surface of the bottom plate, two sides of the support are respectively provided with an air cylinder, a piston rod of each air cylinder is connected with a strip-shaped mounting plate arranged along the material conveying direction, the upper side of the strip-shaped mounting plate is provided with a plurality of rotatable guide wheels at intervals, the outer side of the conveying belt is provided with a vertical plate respectively, the two vertical plates are arranged in parallel face to face, a plurality of second convex strips arranged at intervals along the vertical direction are arranged on the inner surfaces, opposite to the other vertical plate, of the two vertical plates respectively, the upper end faces of the two vertical plates are connected through a top supporting plate, and a driving assembly is connected with at least one of the two vertical plates and used for driving the two vertical plates to synchronously move along the vertical direction. The utility model provides high stability and the security of transporting the silicon chip process avoid external force and artificial intervention, avoid the damage of silicon chip completely.

Description

Cache conveying device for solar silicon wafers

Technical Field

The utility model relates to a buffer memory conveyor of solar energy silicon chip belongs to line photovoltaic processing technology field.

Background

In recent years, solar photovoltaic power generation technology is continuously improved, production cost is continuously reduced, conversion efficiency is continuously improved, and the application of photovoltaic power generation is increasingly popularized and rapidly developed, so that the photovoltaic power generation technology gradually becomes an important source of power supply. The photovoltaic silicon chip is a core part in a solar power generation system and is also the part with the highest value in the solar power generation system. The photovoltaic silicon chip is used for converting solar energy into electric energy, and the electric energy is transmitted to the electric storage to be stored or is directly used for pushing a load to work. The quality and cost of the photovoltaic silicon wafer will directly determine the quality and cost of the entire solar power system.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a buffer memory conveyor of solar energy silicon chip, its stability and the security that has improved the silicon chip process of transporting avoid external force and artificial intervention, avoid the damage of silicon chip completely.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a cache conveying device for solar silicon wafers comprises a bottom plate, a support, a conveying motor and conveying belts, wherein the bottom plate is arranged on a rack, the support is arranged on the upper surface of the bottom plate, the conveying motor is used for driving the conveying belts and is arranged on the support, and the conveying belts are used for conveying material sheets and are arranged along a conveying direction;

the two sides of the support are respectively provided with an air cylinder, the two air cylinders are arranged oppositely, a piston rod of each air cylinder is connected with a strip-shaped mounting plate arranged along the conveying direction, a plurality of rotatable guide wheels are arranged above the strip-shaped mounting plate at intervals, the guide wheels positioned on the two strip-shaped mounting plates are arranged oppositely outside the conveying belt, when the piston rod of the air cylinder is in a contraction state, the circumferential end surface of each guide wheel is far away from the conveying belt, and when the piston rod of the air cylinder is in an extension state, the circumferential end surface of each guide wheel is close to the conveying belt;

the outer sides of the conveying belts are respectively provided with a vertical plate, the two vertical plates are arranged in parallel face to face, the inner surfaces of the two vertical plates, which are opposite to the other vertical plate, are provided with a plurality of second convex strips arranged at intervals along the vertical direction, so that a groove is formed between the adjacent second convex strips, and a material placing area in which a material feeding sheet is embedded is formed between the grooves formed on the two vertical plates;

the upper end surfaces of the two vertical plates are connected through a top supporting plate, and a driving assembly is connected with at least one of the two vertical plates and used for driving the two vertical plates to synchronously move along the vertical direction.

The further improved scheme in the technical scheme is as follows:

1. in the above scheme, the cylinder is installed on the bottom plate through a supporting seat.

2. In the scheme, 4-8 guide wheels are installed on each strip-shaped installation plate at equal intervals.

3. In the scheme, the guide wheel is coated with the rubber layer.

4. In the above scheme, the driving assembly comprises a motor, a vertically arranged screw rod and a movable block sleeved on the screw rod through threads, an output shaft of the motor is connected with the screw rod, and the movable block is connected with the outer surface of the vertical plate.

5. In the above scheme, a plurality of the second convex strips are arranged on the upper portion of the vertical plate at equal intervals, so that when the vertical plate is located at the initial position, the second convex strips are located above the transmission belt.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

1. the utility model discloses cache conveyor of solar wafer, it has realized transporting the full-automatic of monolithic silicon chip high-efficiently, piece by piece, has improved the stability and the security of transporting the process simultaneously, avoids external force and artificial intervention, avoids the damage of silicon chip completely, and degree of automation is high; furthermore, the outer sides of the conveying belts are respectively provided with a vertical plate, the two vertical plates are arranged in parallel face to face, the inner surfaces of the two vertical plates, which are respectively opposite to the other vertical plate, are provided with a plurality of second convex strips arranged at intervals along the vertical direction, so that a groove is formed between the adjacent second convex strips, a material placing area in which a material feeding piece is embedded is formed between the grooves oppositely formed on the two vertical plates, the upper end surfaces of the two vertical plates are connected through a top supporting plate, a driving assembly is connected with at least one of the two vertical plates and used for driving the two vertical plates to synchronously move along the vertical direction, and by the arrangement of a plurality of material placing areas between the oppositely arranged vertical plates, the plurality of silicon wafers can be temporarily stored when necessary in cooperation with the up-and-down movement of the material placing areas, so that the accurate cooperation with the lower section process equipment is realized, and the condition that the material, the production efficiency is improved.

2. The utility model discloses a buffer memory conveying device for solar silicon wafers, two cylinders are respectively arranged at two sides of a support, two cylinders are oppositely arranged, a bar-shaped mounting plate arranged along the conveying direction is connected on a piston rod of each cylinder, a plurality of rotatable guide wheels are arranged above the bar-shaped mounting plate at intervals, the guide wheels arranged on the two bar-shaped mounting plates are oppositely arranged at the outer side of a conveying belt, when the piston rod of the cylinder is in a contraction state, the circumferential end surface of each guide wheel is far away from the conveying belt, when the piston rod of the cylinder is in an extension state, the circumferential end surface of each guide wheel is close to the conveying belt, and the guide wheels are oppositely arranged to guide in the process of conveying the silicon wafers at high speed by the conveying belt, thereby not only avoiding the silicon wafers from being deviated and being collided and damaged, but also ensuring the flexible contact, further protecting the safety of the silicon wafer in the transportation process.

Drawings

Fig. 1 is a schematic overall structure diagram of the material conveying mechanism for photovoltaic processing of the present invention;

fig. 2 is a schematic partial structural view of a material conveying mechanism for photovoltaic processing according to the present invention;

fig. 3 is a schematic view of a partial structure of the material conveying mechanism for photovoltaic processing according to the present invention;

figure 4 is the utility model discloses a local structure schematic diagram three of a fortune material mechanism for photovoltaic processing.

In the above drawings: 1. a base plate; 2. a support; 3. a transmission motor; 4. a transfer belt; 5. a main drive wheel; 6. a first rotating shaft; 7. a driven wheel; 8. a first runner; 9. a second runner; 20. a cylinder; 21. a strip-shaped mounting plate; 22. a guide wheel; 23. a supporting seat; 31. a vertical plate; 32. a second convex strip; 33. a top support plate; 34. a drive assembly; 36. a web.

Detailed Description

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1: a cache conveying device for solar silicon wafers comprises a bottom plate 1, a support 2, a conveying motor 3 and conveying belts 4 symmetrically arranged on two sides of the support 2, wherein the support 2 is arranged on the upper surface of the bottom plate 1, the conveying motor 3 used for driving the conveying belt 4 is arranged on the support 2, and the conveying belt 4 used for conveying a material sheet 36 is arranged along a conveying direction;

a main driving wheel 5 is installed on an output shaft of the transmission motor 3, a first rotating shaft 6 is rotatably installed on the support 2, two ends of the first rotating shaft 6 respectively extend out from two sides of the support 2, a driven driving wheel 7 is installed at one end of the first rotating shaft 6 which is positioned at the same side of the main driving wheel 5, and the driven driving wheel 7 is in transmission connection with the main driving wheel 5 through a synchronous belt;

a first rotating wheel 8 is respectively arranged on the first rotating shaft 6 and positioned at two sides of the support 2, a plurality of second rotating wheels 9 are respectively rotatably arranged at two sides of the support 2, and the first rotating wheel 8 and the second rotating wheels 9 positioned at the same side of the support 2 are in transmission connection through a transmission belt 4;

two sides of the support 2 are respectively provided with an air cylinder 20, the two air cylinders 20 are arranged oppositely, a piston rod of each air cylinder 20 is connected with a strip-shaped mounting plate 21 arranged along the conveying direction, a plurality of rotatable guide wheels 22 are arranged above the strip-shaped mounting plate 21 at intervals, the guide wheels 22 arranged on the two strip-shaped mounting plates 21 are arranged at the outer sides of the transmission belts 4 oppositely, when the piston rod of the air cylinder 20 is in a contraction state, the circumferential end surface of each guide wheel 22 is far away from the transmission belts 4, and when the piston rod of the air cylinder 20 is in an extension state, the circumferential end surface of each guide wheel 22 is close to the transmission belts 4;

the outer side of the conveying belt 4 is respectively provided with a vertical plate 31, the two vertical plates 31 are arranged in parallel face to face, the inner surfaces of the two vertical plates 31, which are opposite to the other vertical plate 31, are provided with a plurality of second convex strips 32 arranged at intervals along the vertical direction, so that a groove is formed between the adjacent second convex strips 32, and an article placing area for embedding the material sheet 36 is formed between the grooves formed on the two vertical plates 31;

the upper end surfaces of the two vertical plates 31 are connected through a top supporting plate 33, and a driving assembly 34 is connected with at least one of the two vertical plates 31 and used for driving the two vertical plates 31 to move synchronously along the vertical direction.

The cylinder 20 is mounted on the base plate 1 through a supporting seat 23; each strip-shaped mounting plate 21 is provided with 4 guide wheels 22 at equal intervals; the guide wheel 22 is covered with a rubber layer.

Example 2: a cache conveying device for solar silicon wafers comprises a bottom plate 1, a support 2, a conveying motor 3 and conveying belts 4 symmetrically arranged on two sides of the support 2, wherein the support 2 is arranged on the upper surface of the bottom plate 1, the conveying motor 3 used for driving the conveying belt 4 is arranged on the support 2, and the conveying belt 4 used for conveying a material sheet 36 is arranged along a conveying direction;

a main driving wheel 5 is installed on an output shaft of the transmission motor 3, a first rotating shaft 6 is rotatably installed on the support 2, two ends of the first rotating shaft 6 respectively extend out from two sides of the support 2, a driven driving wheel 7 is installed at one end of the first rotating shaft 6 which is positioned at the same side of the main driving wheel 5, and the driven driving wheel 7 is in transmission connection with the main driving wheel 5 through a synchronous belt;

a first rotating wheel 8 is respectively arranged on the first rotating shaft 6 and positioned at two sides of the support 2, a plurality of second rotating wheels 9 are respectively rotatably arranged at two sides of the support 2, and the first rotating wheel 8 and the second rotating wheels 9 positioned at the same side of the support 2 are in transmission connection through a transmission belt 4;

two sides of the support 2 are respectively provided with an air cylinder 20, the two air cylinders 20 are arranged oppositely, a piston rod of each air cylinder 20 is connected with a strip-shaped mounting plate 21 arranged along the conveying direction, a plurality of rotatable guide wheels 22 are arranged above the strip-shaped mounting plate 21 at intervals, the guide wheels 22 arranged on the two strip-shaped mounting plates 21 are arranged at the outer sides of the transmission belts 4 oppositely, when the piston rod of the air cylinder 20 is in a contraction state, the circumferential end surface of each guide wheel 22 is far away from the transmission belts 4, and when the piston rod of the air cylinder 20 is in an extension state, the circumferential end surface of each guide wheel 22 is close to the transmission belts 4;

the outer side of the conveying belt 4 is respectively provided with a vertical plate 31, the two vertical plates 31 are arranged in parallel face to face, the inner surfaces of the two vertical plates 31, which are opposite to the other vertical plate 31, are provided with a plurality of second convex strips 32 arranged at intervals along the vertical direction, so that a groove is formed between the adjacent second convex strips 32, and an article placing area for embedding the material sheet 36 is formed between the grooves formed on the two vertical plates 31;

the upper end surfaces of the two vertical plates 31 are connected through a top supporting plate 33, and a driving assembly 34 is connected with at least one of the two vertical plates 31 and used for driving the two vertical plates 31 to move synchronously along the vertical direction.

Each strip-shaped mounting plate 21 is provided with 8 guide wheels 22 at equal intervals; the driving assembly 34 comprises a motor, a vertically arranged screw rod and a movable block sleeved on the screw rod through threads, an output shaft of the motor is connected with the screw rod, and the movable block is connected with the outer surface of the vertical plate 31; the second protruding strips 32 are disposed on the upper portion of the vertical plate 31 at equal intervals, so that when the vertical plate 31 is located at the initial position, the second protruding strips 32 are all located above the conveying belt 4.

When the cache conveying device for the solar silicon wafers is adopted, the efficient and piece-by-piece full-automatic conveying of the single silicon wafers is realized, the stability and the safety of the conveying process are improved, external force and manual intervention are avoided, the damage of the silicon wafers is completely avoided, and the automation degree is high;

furthermore, through the arrangement of the multiple layers of material placing areas between the oppositely arranged vertical plates and the up-and-down movement of the material placing areas, multiple silicon wafers can be temporarily stored when necessary, so that the silicon wafers are accurately matched with equipment in the next working procedure, the condition that the silicon wafers need to be stopped for material waiting due to the operation time difference between the silicon wafers and the equipment is avoided, and the production efficiency is improved;

in addition, a plurality of guide wheels arranged oppositely guide the silicon wafer in the process of conveying the silicon wafer by the conveying belt at a high speed, so that the silicon wafer is prevented from being collided and damaged due to deviation, flexible contact between the guide wheels and the silicon wafer can be guaranteed, and the safety of the silicon wafer in the conveying process is further protected.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (6)

1. The utility model provides a buffer memory conveyer of solar energy silicon chip which characterized in that: the conveying device comprises a bottom plate (1) arranged on a rack, a support (2), a conveying motor (3) and conveying belts (4) symmetrically arranged on two sides of the support (2), wherein the support (2) is arranged on the upper surface of the bottom plate (1), the conveying motor (3) used for driving the conveying belts (4) is arranged on the support (2), and the conveying belts (4) used for conveying material sheets (36) are arranged along the conveying direction;

the conveying device is characterized in that two sides of the support (2) are respectively provided with an air cylinder (20), the two air cylinders (20) are arranged oppositely, a piston rod of each air cylinder (20) is connected with a strip-shaped mounting plate (21) arranged along the conveying direction, a plurality of rotatable guide wheels (22) are arranged above the strip-shaped mounting plates (21) at intervals, the guide wheels (22) arranged on the two strip-shaped mounting plates (21) are arranged on the outer side of the conveying belt (4) oppositely, when the piston rods of the air cylinders (20) are in a contraction state, the circumferential end surfaces of the guide wheels (22) are far away from the conveying belt (4), and when the piston rods of the air cylinders (20) are in an extension state, the circumferential end surfaces of the guide wheels (22) are close;

the outer side of the conveying belt (4) is respectively provided with a vertical plate (31), the two vertical plates (31) are arranged in parallel face to face, a plurality of second convex strips (32) which are arranged at intervals along the vertical direction are arranged on the inner surfaces, opposite to the other vertical plate (31), of the two vertical plates (31), so that a groove is formed between the adjacent second convex strips (32), and a material placing area for embedding the material sheet (36) is formed between the grooves formed on the two vertical plates (31) oppositely;

the upper end surfaces of the two vertical plates (31) are connected through a top supporting plate (33), and a driving assembly (34) is connected with at least one of the two vertical plates (31) and used for driving the two vertical plates (31) to synchronously move along the vertical direction.

2. The buffer conveying device for solar silicon wafers according to claim 1, wherein: the air cylinder (20) is arranged on the bottom plate (1) through a supporting seat (23).

3. The buffer conveying device for solar silicon wafers according to claim 1, wherein: 4-8 guide wheels (22) are installed on each strip-shaped installation plate (21) at equal intervals.

4. The buffer conveying device for solar silicon wafers according to claim 1, wherein: the guide wheel (22) is coated with a rubber layer.

5. The buffer conveying device for solar silicon wafers according to claim 1, wherein: the driving assembly (34) comprises a motor, a vertically arranged screw rod and a movable block sleeved on the screw rod through threads, an output shaft of the motor is connected with the screw rod, and the movable block is connected with the outer surface of the vertical plate (31).

6. The buffer conveying device for solar silicon wafers according to claim 1, wherein: a plurality of second convex strips (32) are arranged on the upper portion of the vertical plate (31) at equal intervals, so that when the vertical plate (31) is located at the initial position, the second convex strips (32) are located above the transmission belt (4).

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