CN111792455A - Full-automatic photovoltaic solder strip winding device - Google Patents

Abstract

The invention relates to a full-automatic photovoltaic solder strip winding device, which comprises: the first wire coil is provided with a first end plate, and a first wire hook is arranged at the outer edge of the first end plate; the second wire coil is provided with a second end plate, and a second wire hook is arranged at the outer edge of the second end plate; the wire feeding mechanism is used for outputting a welding strip, and the output end of the wire feeding mechanism is movably arranged; a push rod having at least an operating state to push the solder strip into a position in a rotational path of the first wire hook or the second wire hook and a withdrawal state from the solder strip; the blade is provided with two pieces of blades which are respectively positioned between the first wire coil or the second wire coil and the push rod. Therefore, the switching between the first wire coil and the second wire coil is realized, the welding strip is not wound continuously in the switching process, a wire storage frame which is equipped for replacing the wire coil in the prior art is not needed, the wire coil replacing time is saved, and the production efficiency is improved.

Description

Full-automatic photovoltaic solder strip winding device

Technical Field

The invention relates to a full-automatic photovoltaic solder strip winding device.

Background

The photovoltaic solder strip is a tinned copper strip, is applied to the connection of photovoltaic module battery pieces, and is an important raw material in the welding process of the photovoltaic module.

A female coil of a photovoltaic solder strip round wire tin coating machine is a hundred thousand copper wires, and after annealing and tin coating, a small coil with the diameter of about 7000-10000 meters needs to be precisely wound. In the existing method, a wire storage frame is added after tin coating and before precise wire take-up, so that a tin coating continuous machine can be realized, the wire storage frame can provide 40 seconds of time, and workers can manually change a disk of the precise wire take-up machine. Because the wire storage frame consists of about 35-40 guide wheels, the yield strength of the welding strip can be increased. With the improvement of the process requirement, the yield requirement of the welding strip is further reduced, and a wire storage frame must be cancelled to realize automatic disk replacement without stopping on line.

Disclosure of Invention

The invention aims to provide a full-automatic photovoltaic solder strip winding device which can realize automatic disk replacement without shutdown.

In order to achieve the purpose, the invention adopts the technical scheme that:

the invention provides an automatic disk changing assembly of a full-automatic photovoltaic solder strip winding device, which comprises:

the first wire coil is provided with a first end plate, and a first wire hook is arranged at the outer edge of the first end plate;

the second wire coil is provided with a second end plate, and a second wire hook is arranged at the outer edge of the second end plate;

the wire feeding mechanism is used for outputting a welding strip, and the output end of the wire feeding mechanism is movably arranged;

a push rod having at least an operating state to push the solder strip into a position in a rotational path of the first wire hook or the second wire hook and a withdrawal state from the solder strip;

the blade is provided with two pieces of blades which are respectively positioned between the first wire coil or the second wire coil and the push rod.

Preferably, the thread feeding mechanism comprises two positioning wheels, and a threading gap is formed between the two positioning wheels.

Furthermore, the positioning wheel is arranged on a mounting plate, two parallel positioning strips are arranged on the mounting plate, a strip-shaped gap is formed between the two positioning strips, and the strip-shaped gap is positioned at the downstream of the threading gap.

Furthermore, a first supporting rod and a second supporting rod are arranged on the mounting plate, and the positioning strip is arranged between the first supporting rod and the second supporting rod.

Still further, the positioning strip is made of a flexible material.

Preferably, a push rod accommodating space is formed between the two blades.

The full-automatic photovoltaic solder strip winding device comprises any one of the automatic disc changing assemblies.

Preferably, it further comprises:

a frame;

the feeding assembly comprises a feeding plate which is obliquely arranged, a waiting position is arranged at the lower end of the feeding plate, material blocking plates are respectively arranged on the front side and the rear side of the waiting position, and the material blocking plates at least have a material blocking state extending into a space above the feeding plate and a withdrawing state withdrawing from the space above the feeding plate;

a chuck assembly including chuck jaws for gripping a wire coil;

an outfeed assembly comprising a conveyor belt;

the conveying assembly comprises a material bearing groove, a rotary driving mechanism for driving the material bearing groove to horizontally rotate, a lifting driving mechanism for driving the material bearing groove to lift and a horizontal driving mechanism for driving the material bearing groove to horizontally move, and the material bearing groove can be respectively butted with the lower end of the feeding plate, the chuck jaws and the material receiving end of the conveying belt in the moving process.

Further, the chuck jaws include a pair of gripper arms having an open state and a tightened state.

Further, it also includes: the outer surface of the conveying belt is provided with a plurality of partition plates, and a disc placing position is formed between every two adjacent partition plates.

Due to the application of the technical scheme, compared with the prior art, the invention has the following advantages:

according to the full-automatic photovoltaic solder strip winding device, the solder strip is supplied by the wire feeding mechanism, the solder strip is switched between the first wire coil and the second wire coil by moving the output end of the wire feeding mechanism, for example, when the first wire coil is switched to the second wire coil, the output end of the wire feeding mechanism is moved from the first wire coil to the second wire coil, the solder strip is pushed by the push rod to be positioned in the rotating path of the second wire hook, the second wire hook is rotated by the second end plate to hook the solder strip, the solder strip is driven to be cut off by the blade, the end part of the solder strip is clamped in the second wire hook, and the solder strip is continuously wound on the second wire coil along with the rotation of the second wire coil, so that the switching between the first wire coil and the second wire coil is realized, the solder strip is not stopped to be wound in the switching process, a wire storage frame which is prepared for disc changing in the prior art is not needed, the disc changing time is saved, and the.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic perspective view of a full-automatic photovoltaic solder ribbon winding apparatus according to a preferred embodiment of the present invention (the automatic reel changer assembly of the full-automatic photovoltaic solder ribbon winding apparatus is not shown);

FIG. 2 is an enlarged schematic view of the feed assembly of FIG. 1;

FIG. 3 is an enlarged schematic view of the handling assembly of FIG. 1;

FIG. 4 is an enlarged schematic view of the take-off assembly of FIG. 1;

FIG. 5 is a schematic structural diagram of the automatic disc changing assembly of the full-automatic photovoltaic solder strip winding device installed in a rack;

FIG. 6 is an enlarged view at A of FIG. 5;

FIG. 7 is an enlarged view at B of FIG. 6;

FIG. 8 is a schematic view of a positioning strip configuration;

FIG. 9 is an enlarged view at C of FIG. 8;

wherein the reference numerals are as follows:

1. a frame;

2. a feeding assembly; 21. a feeding plate; 22. a wait bit; 23. a sensor I; 24. a cylinder I;

3. a chuck assembly; 31. a chuck jaw; 311. a material clamping arm;

4. a discharge assembly; 41. a conveyor belt; 42. a sensor II; 43. a sensor III; 44. a partition plate; 45. a diaphragm sensor;

5. a conveying assembly; 51. a material bearing groove; 52. a rotation driving mechanism; 521. a bearing; 522. a rotating shaft; 523. a swing lever; 524. a cylinder II; 53. a lifting drive mechanism; 54. a horizontal driving mechanism; 541. a motor;

6. an alarm light;

7. wire coils;

8. the full-automatic photovoltaic solder strip winding device automatically changes the disc assembly;

801. a first wire coil; 8011. a first end plate; 8012. a first thread hook;

802. a second wire coil; 8021. a second end plate; 8022. a second thread hook;

803. a wire feeding mechanism; 8031. positioning wheels; 8032. a threading gap; 8033. mounting a plate; 8034. a positioning bar; 8035. a first support bar; 8036. a second support bar; 8037. a strip-shaped gap; 8038. a bow rod;

804. a push rod;

805. a blade;

806. a push rod accommodating space;

9. and (7) welding the strip.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

Referring to fig. 1, the full-automatic photovoltaic solder strip winding device comprises a frame 1, a feeding assembly 2, a chuck assembly 3, a discharging assembly 4 and a conveying assembly 5. The automatic disc changing assembly 8 of the full-automatic photovoltaic solder strip winding device (see fig. 5) is not shown in fig. 1.

As shown in fig. 2, the feeding assembly 2 comprises a feeding plate 21, the feeding plate 21 is arranged obliquely, and the lower end of the feeding plate 21 is provided with a waiting position 22, so that the wire coil 7 automatically rolls to the waiting position 22 at the lower end. The front side and the rear side of the waiting position 22 are respectively provided with a material baffle plate (not shown), and the material baffle plate at least has a material baffle state extending into the space above the feeding plate 21 and a withdrawing state withdrawing from the space above the feeding plate 21. The striker plate is driven by two cylinders I24 to ascend or descend respectively.

The feeding assembly 2 further comprises a sensor I23, and a detection head of the sensor I23 corresponds to the waiting position 22 so as to monitor whether the wire coil 7 exists in the waiting position 22.

Taking the left side in fig. 2 as the front end and the right side as the rear end, the air cylinder I24 at the rear end drives the striker plate to be in a rising state, and the air cylinder I24 at the front end drives the striker plate to descend to allow one wire coil 7 to roll out forwards; when the wire coil 7 rolls out forwards, the air cylinder I24 at the front end drives the material baffle plate to ascend; the air cylinder I24 at the rear end drives the material blocking plate to descend, and a wire coil 7 at the rear is allowed to roll into the waiting position 22; after the air cylinder I24 at the rear end drives the striker plate to ascend, the air cylinder I24 at the front end drives the striker plate to descend to allow another wire coil 7 to roll out … … forwards, and the wire coils 7 can be discharged one by one.

As shown in fig. 1 and 3, the wire coil 7 rolled from the feed plate 21 is received by the receiving groove 51 in the conveying unit 5. The receiving groove 51 is in the shape of an inverted triangular prism horizontally placed, so that the wire coil 7 can be stabilized, and the wire coil 7 is placed in the receiving groove 51, and then the two ends of the wire coil 7 are clamped and exposed out of the receiving groove 51, so as to be conveniently clamped by the clamping disc claws 31 (described later).

The conveyance unit 5 includes a receiving tank 51, a rotation drive mechanism 52, an elevation drive mechanism 53, and a horizontal drive mechanism 54.

The rotation drive mechanism 52 includes a bearing 521, a rotating shaft 522, a swinging lever 523, and a cylinder ii 524. The rotating shaft 522 is fixed to the bottom of the material receiving groove 51, the rotating shaft 522 is inserted into the bearing 521 to smoothly rotate, and the swinging rod 523 extends radially away from the rotating shaft 522. The far end of the swinging rod 523 is connected with the driving end of the air cylinder II 524. The reception groove 51 can be rotated by means of the cylinder ii 524 to facilitate the ejection of the coil 7 to the outfeed assembly 4.

The elevation drive mechanism 53 is an air cylinder and can drive the receiving tank 51 to move up and down. The trough 51 is provided at the drive end of the elevation drive mechanism 53.

The horizontal driving mechanism 54 includes a motor 541 (see fig. 1), a guide rail, and the like, and drives the elevation driving mechanism 53 to move horizontally by the motor 541. The entire elevation drive mechanism 53 and the trough 51 are driven by the motor 541 to move horizontally.

The material receiving groove 51 can be butted against the lower end of the feeding plate 21, the chuck claws 31 (described later), and the receiving end of the conveyor belt 41 (described later) during the movement.

As shown in fig. 1, the wire coil can be conveyed to the chuck assembly 3 by the conveying assembly 5, the chuck assembly 3 includes two chuck positions, each chuck position is provided with a set of chuck jaws 31, and each set of chuck jaws 31 includes a pair of opposite material clamping arms 311. The two material clamping arms 311 can move towards or away from each other to form an opening state or a tightening state. The chuck jaws 31 are opened to receive the wire coil carried from the carrier assembly 5, and then the chuck jaws 31 are tightened to clamp both ends of the wire coil 7. When in clamping, the wire coil 7 is allowed to rotate to take up wires, namely, to take up welding strips.

After the winding of the wire coil 7 is completed, the material receiving groove 51 moves to be positioned below the chuck jaws 31, the chuck jaws 31 are opened, and the wire coil 7 automatically falls into the material receiving groove 51.

The material receiving groove 51 transports the wire coil 7 wound with the welding strip to the discharging assembly 4.

As shown in fig. 4, the outfeed assembly 4 includes a conveyor belt 41. The conveyor belt 41 is driven by a motor (not shown in fig. 4). When the trough 51 is driven to a predetermined docking position with the discharging assembly 4, the rotary driving mechanism 52 drives the trough 51 to rotate toward the conveyor 41, and the wire coil 7 is dumped onto the conveyor 41.

The receiving end of the conveyor belt 41 is provided with a sensor ii 42, a detection head of the sensor ii 42 corresponds to a wire coil on the conveyor belt 41, and the sensor ii 42 is used for detecting whether the wire coil 7 is on the conveyor belt 41 (in fig. 4, the wire coil 7 is shown in a state of not being wound with a welding strip, and actually, the wire coil 7 is wound with a welding strip).

The discharging end of the conveyor belt 41 is provided with a sensor III 43, a detection head of the sensor III 43 corresponds to a coil on the conveyor belt 41, when the sensor III 43 senses that the coil 7 on the conveyor belt 41 is full, an alarm lamp 6 (shown in figure 1) gives an alarm to indicate that the coil is full and the coil is required to be unloaded.

As shown in fig. 4, the outer surface of the conveyor belt 41 is further provided with a plurality of partitions 44, and adjacent partitions 44 form a plurality of coil placement positions, each for placing one coil 7. The baffles 44 help to stabilize the coil 7.

The discharging assembly 4 further comprises a baffle sensor 45, and the detection head of the baffle sensor 45 corresponds to any baffle 44 (in this case, the baffle sensor 45 corresponds to the baffle 44 at the discharging end, and in other embodiments, the position of the baffle sensor 45 can also correspond to other baffles 44). When the partition sensor 45 detects one partition 44, the motor driving the conveyor belt 41 is stopped, so that the conveyor belt 41 is conveyed by the distance of the adjacent partition 44 at a time. So that the coils 7 enter the conveyor belt 41 one by one until the conveyor belt 41 is full, at which time the coils 7 can be removed uniformly.

As shown in fig. 5, the automatic disc changing assembly 8 of the full-automatic photovoltaic solder strip winding device is installed in the rack 1.

As shown in fig. 6 and fig. 6 are enlarged views at a of fig. 5, and for convenience of explanation, the wire coils in the two chuck jaws 31 are named as a first wire coil 801 and a second wire coil 802, respectively.

The first wire coil 801 and the second wire coil 802 have the same structure and are similar to an I-shaped coil.

The first wire reel 801 has a first end plate 8011 at one end, and a first wire hook 8012 is disposed on an outer edge of the first end plate 8011.

The second wire coil 802 has a second end plate 8021 at one end, and a second wire hook 8022 is disposed on the outer edge of the second end plate 8021.

The solder strip is conveyed and supplied by the wire feeding mechanism 803, the output end of the wire feeding mechanism 803 is movably arranged, the mounting plate 8033 is the output end of the wire feeding mechanism 803, and the wire mounting plate 8033 is horizontally moved and lifted by a motor, a screw rod and the like.

Two positioning wheels 8031 are mounted on the mounting plate 8033, the positioning wheels 8031 are close to each other, a threading gap 8032 is formed between the two positioning wheels 8031, the threading gap 8032 is provided for the welding strip to pass through, and the welding strip is not easy to separate from the threading gap 8032. The positioning wheel 8031 is rotated by the solder ribbon. The positioning wheel 8031 is used for supporting and guiding the solder strip.

The outer edge of the positioning wheel 8031 is provided with a groove, so that the welding strip is embedded in the outer edge of the positioning wheel 8031, and the welding strip is not easy to fall off.

The solder ribbon is drawn by rotation of the first wire spool 801 or the second wire spool 802. The first wire coil 801 or the second wire coil 802 rotates in the opposite direction. The first wire coil 801 and the second wire coil 802 are rotated by a driving mechanism (not shown).

As shown in fig. 6, a push rod 804 is further provided, the push rod 804 is driven by an air cylinder to move, and the movable direction of the push rod 804 is approximately the axial direction of the first wire coil 801 or the second wire coil 802.

As shown in fig. 6, the solder ribbon is first wound on the first reel 801, and after the winding is completed, the winding needs to be switched to the second reel 802. At this time, the wire feeding mechanism 803 is moved from above the first wire reel 801 to above the second wire reel 802 (i.e., the state in fig. 6). The movement process of the wire feeding mechanism 803 is: keep away from first drum 801 and rise vertically- > move from above first drum 801 to above second drum 802- > descend vertically to second drum 802.

As shown in fig. 7 and fig. 7 is an enlarged view of fig. 6B, after the wire feeding mechanism 803 moves above the second reel 802 and descends, the cylinder drives the pushing rod 804 to move toward the solder strip 9 to push the solder strip 9, so as to push the solder strip 9 to be located in the rotation path of the second wire hook 8022, and when the second wire hook 8022 rotates along with the second end plate 8021, the second wire hook 8022 hooks the solder strip 9 and drives the solder strip 9 to rotate. If the pushing rod 804 pushes the solder strip to the rotation path of the second wire 8022 to be in the working state, and the pushing rod 804 leaves the solder strip to be in the withdrawing state, the pushing rod 804 has at least the working state and the withdrawing state.

In this example, as shown in fig. 7, a blade 805 is further provided for cutting the solder ribbon 9 when the spool is switched, the blade 805 being shown between the second spool 802 and the push rod 804. When the second wire hooks 8022 hook the solder strip 9 and drive the solder strip 9 to rotate together, the solder strip 9 is cut by the blade 805. After the welding strip 9 is cut off, the pushing rod 804 retreats, the end part of the welding strip 9 is clamped in the second wire hook 8022, and the welding strip is wound on the second wire coil 802 along with the rotation of the second wire coil 802.

As shown in fig. 6, if the second reel 802 is completely wound, a new empty reel is replaced at the first reel 801. The solder ribbon can now be switched from the second reel 802 to the first reel 801 in a similar manner as switching from the first reel 801 to the second reel 802. When the welding strip is switched, another blade 805 is used for cutting off the welding strip, and compared with fig. 6 and 7, the blade 805 is provided with two pieces, a push rod accommodating space 806 is arranged between the two pieces of blade 805, and the push rod accommodating space 806 is used for accommodating the push rod 804.

As shown in fig. 5 and 6, the lower end of the mounting plate 8033 is provided with an arch bar 8038. As shown in fig. 8, the two ends of the bow rod 8038 extend transversely and are respectively provided with a first vertical support rod 8035 (not shown in fig. 5 and 6) and a second vertical support rod 8036 (not shown in fig. 5 and 6), and two positioning bars 8034 are arranged between the first support rod 8035 and the second vertical support rod 8036. As shown in fig. 9, fig. 9 is an enlarged view of C in fig. 8, a strip-shaped gap 8037 is formed between two positioning strips 8034, and the solder strip 9 is inserted into the strip-shaped gap 8037. The strip-shaped gap 8037 is located downstream of the threading gap 8032 (formed between two positioning wheels 8031 in fig. 6). Thus, the solder ribbon 9 is released from between the two positioning wheels 8031 and then passes through the two positioning bars 8034 to reach the first wire coil 801 or the second wire coil 802, and the positioning bars 8034 are approximately perpendicular to the axial direction of the first wire coil 801 and the second wire coil 802. Under the strict limit of the positioning strip 8034, the solder strip can be accurately dropped on the first wire coil 801 or the second wire coil 802 to be wound. The first wire coil 801 or the second wire coil 802 is driven by a driving mechanism and can move slowly along the axial direction during winding, so that the uniform winding of the welding strip is realized.

The positioning strip 8034 of this example is made of a flexible material that is tightened to achieve accurate positioning, thereby protecting the solder ribbon.

In summary, in the fully automatic photovoltaic solder ribbon winding apparatus of this embodiment, the movement of the output end of the wire feeding mechanism 803 and the mutual cooperation of the push rod 804, the first wire hook 8012, the second wire hook 8022 and the blade 805 realize the non-stop switching of the solder ribbon between the first reel 801 and the second reel 802, and the winding of the solder ribbon is not stopped during the switching process, so that a wire storage rack in the prior art is omitted, the time consumed by reel changing is saved, and the production efficiency is improved.

The above embodiments are merely illustrative of the technical concept and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the content of the present invention and implement the invention, and not to limit the scope of the invention, and all equivalent changes or modifications made according to the spirit of the present invention should be covered by the scope of the present invention.

Claims (10)

1. The utility model provides a full-automatic photovoltaic solder strip winding device is from moving a set subassembly which characterized in that, it includes:

the first wire coil (801) is provided with a first end plate (8011), and a first wire hook (8012) is arranged on the outer edge of the first end plate (8011);

the second wire coil (802), the second wire coil (802) is provided with a second end plate (8021), and a second wire hook (8022) is arranged on the outer edge of the second end plate (8021);

the wire feeding mechanism (803), the wire feeding mechanism (803) is used for outputting the welding strip, and the output end of the wire feeding mechanism (803) is movably arranged;

a push rod (804), the push rod (804) having at least an active state to push the solder strip into a rotational path of the first wire hook (8012) or the second wire hook (8022) and a deactivated state to move away from the solder strip;

the blade (805), the blade (805) is provided with two and is located respectively between the first drum (801) or the second drum (802) and the catch bar (804).

2. The automatic reel changing assembly of the full-automatic photovoltaic solder strip winding device according to claim 1, characterized in that: the wire feeding mechanism (803) comprises two positioning wheels (8031), and a threading gap (8032) is formed between the two positioning wheels (8031).

3. The automatic reel changing assembly of the full-automatic photovoltaic solder strip winding device according to claim 2, characterized in that: positioning wheel (8031) set up on a mounting panel (8033), be provided with two location strips (8034) that parallel on mounting panel (8033), two be formed with bar clearance (8037) between location strip (8034), bar clearance (8037) are located threading clearance (8032) low reaches.

4. The automatic reel changing assembly of the full-automatic photovoltaic solder strip winding device according to claim 3, characterized in that: be provided with first bracing piece (8035) and second bracing piece (8036) on mounting panel (8033), location strip (8034) set up first bracing piece (8035) with between second bracing piece (8036).

5. The automatic reel changing assembly of the full-automatic photovoltaic solder strip winding device according to claim 4, characterized in that: the positioning strip (8034) is made of a flexible material.

6. The automatic reel changing assembly of the full-automatic photovoltaic solder strip winding device according to claim 1, characterized in that: a push rod accommodating space (806) is formed between the two blades (805).

7. A full-automatic photovoltaic solder strip winding device, characterized in that it comprises the automatic reel changing assembly of the full-automatic photovoltaic solder strip winding device of any one of claims 1 to 6.

8. The fully automatic photovoltaic solder ribbon winding apparatus of claim 7, further comprising:

a frame (1);

the feeding assembly (2) comprises a feeding plate (21) which is obliquely arranged, a waiting position (22) is arranged at the lower end of the feeding plate (21), and material blocking plates are respectively arranged at the front side and the rear side of the waiting position (22) and at least have a material blocking state which extends into a space above the feeding plate (21) and a withdrawing state which is withdrawn from the space above the feeding plate (21);

a chuck assembly (3), the chuck assembly (3) comprising chuck jaws (31) for gripping a wire coil;

an outfeed assembly (4), the outfeed assembly (4) comprising a conveyor belt (41);

the conveying assembly (5) comprises a material receiving groove (51), a rotary driving mechanism (52) used for driving the material receiving groove (51) to rotate horizontally, a lifting driving mechanism (53) used for driving the material receiving groove (51) to lift and a horizontal driving mechanism (54) used for driving the material receiving groove (51) to move horizontally, and the material receiving groove (51) can be respectively butted with the lower end of the feeding plate (21), the chuck jaw (31) and the material receiving end of the conveying belt (41) in the moving process.

9. The fully automatic photovoltaic solder ribbon winding apparatus of claim 8, further comprising: the chuck jaws (31) include a pair of gripper arms (311) having an open state and a tightened state.

10. The fully automatic photovoltaic solder ribbon winding apparatus of claim 8, further comprising: the outer surface of the conveyor belt (41) is provided with a plurality of partition plates (44), and a disc placing position is formed between every two adjacent partition plates (44).

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