KR200317024Y1 - Automatic arraying machine of solar cells - Google Patents

Abstract

The present invention relates to a solar cell automatic arranging device, the purpose of which is to automate the solar cell module setup process, to increase the productivity of the photovoltaic module (minimizing defective rate), thereby reducing the economic loss It is to provide a solar cell automatic array device that can be.

The present invention is a test for measuring the current / voltage value of the solar cell transporting the solar cell placed in the string jig integrally installed on one side of the upper and lower support frame portion consisting of a plurality of vertical support and horizontal support and the lower support frame portion And an upper suction part installed at an upper end of the upper support frame part and moved up / down by an operating air cylinder and a servomotor, and having a plurality of vacuum pads, and installed at an upper end of the upper support frame part so as to be positioned at the lower end of the upper suction part. It is rotated by an air cylinder and moved forward / backward along the LM guide by a position control motor and at the same time includes a mobile adsorption unit having a plurality of vacuum pads. In providing.

Description

Automatic arraying machine of solar cells}

The present invention relates to a solar cell automatic arranging device, and the solar cell in which the solar cell and the solar cell are soldered in a row on the jig by using soldering M / C during the photovoltaic module manufacturing process. The present invention relates to a solar cell automatic arranging apparatus for inspecting the solderability and electrical defect rate of the solar cell after carrying it automatically and modularizing the solar cell by automatically controlling the position according to the set procedure.

Currently, the solar cell arraying device used in the solar cell module production line is soldered on a jig prepared in advance from small solar cell modules to large solar cell modules, such as solar cells 4 * 9 rows or 8 * 12 rows. After removing the solar cell from the jig using a vacuum pad and rotating it, it only plays the role of seating on the plate.In the case of manual operation, dozens of solar cells are soldered from the jig by placing the plate on the jig and turning it over. However, both of the above methods require the manufacture of a new jig whenever the solar cell model is changed, and in the case of manual operation, the solar cell is damaged and thinned in the process of inverting and transporting dozens of solar cells. The bowing of the ribbon and the disturbance of the arrangement are occurring, resulting in reduced productivity and economical There were several problems with such a huge loss to the.

The present invention has been made in consideration of the above problems, and its purpose is to automate the solar cell module setup process, thereby increasing the productivity of the solar cell module (Photovoltaic Module), minimizing the electrical defect rate, and thereby economic loss It is to provide a solar cell automatic arrangement that can reduce the.

The present invention is a test for measuring the current / voltage value of the solar cell transporting the solar cell placed in the string jig integrally installed on one side of the upper and lower support frame portion consisting of a plurality of vertical support and horizontal support and the lower support frame portion And an upper suction part installed on an upper end of the upper support frame part and being moved up / down by a servo motor and having a plurality of vacuum pads, and installed on a suspension of the upper support frame part so as to be positioned at the lower end of the upper suction part. It is rotated by a position control motor is moved forward / backward along the LM guide and at the same time comprising a mobile adsorption unit having a plurality of vacuum pads is provided to provide a solar cell automatic array device for automatically transport arrangement arrangement.

1 is a front view showing a configuration according to the present invention

Figure 2 is a side view showing a configuration according to the present invention

3 is an exemplary view showing a configuration of a solar cell test unit according to the present invention

4 is an exemplary view showing the operation state of the test pin and the solar cell according to the present invention

5 is an exemplary view showing the configuration of the upper adsorption portion according to the present invention

FIG. 6 is a detailed view 'A' of FIG. 5.

7 is an exemplary view showing a configuration of a ball carrier plate portion according to the present invention

8 is an exemplary view showing a schematic configuration of a mobile adsorption unit according to the present invention

9 is an exemplary view showing a solder connection state of a solar cell.

10 is an exemplary view showing an arrangement of a solar cell

11 is an exemplary view showing the configuration of a string jig (string jig) according to the present invention

* Explanation of symbols for the main parts of the drawings

(10): string jig (20): mobile adsorption part

(21): LM guide (22): position control motor

(23): rotating air cylinder (24): rotating gear

25: guide bar 26: balance axis

(27): movable air cylinder (28): support plate

(29): vacuum pad (30): test section

31: conveying conveyor 32: detecting sensor

33: test pin 34: test jig

35: test frame 36: halogen lamps

(37): lifting and lowering air cylinder

40: upper adsorption unit

(41): servomotor (42): worm gear

(43): guide rod (44): support plate

(45): vacuum pad (46): working air cylinder

50: ball carrier plate

(61): upper support frame 62: lower support frame

100: solar cell 101: solar cell upper and lower conductor ribbon

1 is a front view showing a configuration according to the present invention, Figure 2 is a side view showing a configuration according to the present invention, the present invention is several or dozens of solar cells soldered before lamination (Lamination) Is separated from the string jig, and the solar cell is placed on the test jig.The halogen lamp is turned on to measure the voltage and current, and then the defect rate is checked. The vacuum pad and PLC program can be arranged automatically and accurately in the form designed by the user to facilitate setting work for manufacturing the solar cell module.

That is, the present invention transfers the string jig 10 in which a plurality of solar cells 100 soldered in a row by a conveyor, and absorbs the solar cells 100 by the mobile adsorption unit 20 to test part ( 30), and inspects whether the electrical failure of the solar cell by the test unit 30, and then absorbed by the mobile adsorption unit 20 again to move to the lower portion of the upper upper adsorption unit 40, and this It is adapted to be down-loaded into the glass conveyed by the ball carrier plate 50 after being adsorbed by the upper adsorption part 40.

The test part 30 is installed on one side of the lower support frame 62 among the upper and lower support frames 61 and 62 formed of a plurality of vertical supports and horizontal supports, as shown in FIG. Transfer conveyor 31 for transferring the string jig in which the battery is placed, the detection sensor 32 is installed to be positioned at the end of the transfer conveyor 31, and located under the transfer conveyor 31, moved by an air cylinder in a row The test pins 33 contacting several solar cell upper and lower conductor ribbons 101 soldered with the test strips, the test jig 34 provided on the upper surface of the test pins 33, and the test jig 34 are lowered. Lifting and lowering air cylinder 37, and the conveying conveyor 31, the sensor 32 is installed and consists of a test frame 35 for supporting the lifting air cylinder 37, the test unit 30 Halogen lamp 36 on one side of the upper support frame 61 to be located in the upper ) Is installed.

The mobile adsorption unit 20 is to absorb the solar cell 100 from the string jig 10 and then move it to the test jig 34 or the upper adsorption unit 40, as shown in FIG. Both ends of the LM guides 21 are installed on both sides of the support frame 61 so as to be parallel to each other, and LM guides 21 located on both sides thereof are connected to each other and moved by the position control motor 22. Based on the rotary shaft guide bar 25 rotated by the cylinder 23 and the rotary gear 24, the balance shaft 26 fixed to the rotary shaft guide bar 25, and the rotary shaft guide bar 25. A mobile air cylinder 27 installed on both sides of a position symmetrical with the balance shaft 26, a vacuum pad support 28 connected to the ends of the two mobile air cylinders 27, and the vacuum pad support It consists of the several vacuum pad 29 provided in 28. As shown in FIG. In this case, the plurality of vacuum pads 29 installed on the vacuum pad support 28 are equally spaced with the arrangement of the solar cells 100 so as to simultaneously adsorb a plurality of solar cells transferred by the transfer conveyor 31. Installed in an array.

In the mobile adsorption unit 20 configured as described above, the vacuum pad support 28 is lowered by the moving air cylinder 27, and the solar cell is adsorbed by the vacuum pad 29, and the rotating air cylinder 23 is provided. By rotating the rotary shaft guide bar 25 by operating the rotary gear 24 by rotating the vacuum pad 29 and the vacuum pad support 28, the solar cell is vacuum-adsorbed around the rotary shaft guide bar 25 It is supposed to be. As described above, the solar cell, which is sucked by the vacuum pad 29 and rotated by 180 ° by the rotary air cylinder 23, is installed in the position control motor 22 installed at the connection portion between the LM guide 21 and the rotary shaft guide bar 25. It moves to the position set along the LM guide 21 by this. The movement of the mobile adsorption unit is operated according to a preset value set by the operator, so as to adsorb several solar cells soldered in a row with a vacuum pad, and then rotate and automatically position them accurately.

The upper adsorption part 40 is to absorb the solar cells vacuum-absorbed in the mobile adsorption part 20 to download the glass transferred by the ball conveyor plate 50, as shown in Figures 5 and 6 Similarly, the servo motor 41 installed on the upper support frame 61, the worm gear 42 connected to the servo motor 41, and the worm gear 42 connected to the upper support frame 61 are provided. It is operated by a support plate 44 having a plurality of guide rods 43 penetrating through it, a plurality of actuating air cylinders 46 installed in the lower vertical direction at the bottom of the support plate 44 and the actuating air cylinders. It consists of the vacuum pad 45 which becomes.

4 is an exemplary view showing an operating state of the test pin and the solar cell according to the present invention, Figure 9 is an exemplary view showing a solder connection state of the solar cell, the test unit and the mobile adsorption unit and the upper adsorption unit In connection with the description, the string jig supporting the solar cell soldered from the soldering apparatus is located in the conveying conveyor through the conveyor of the Naming apparatus, and the string jig conveyed by the conveying conveyor is stopped by the detection of the sensing sensor. As such, when the solar cell is transferred by the string jig, the vacuum pad is lowered by the operation of the moving air cylinder of the movable adsorption unit, so that several solar cells soldered in a row in the string jig are absorbed, and the string jig is moved by the transfer conveyor. It will exit, and it will be detected by the sensor.

In this way, when the detection sensor detects that the string jig is pulled out, the test jig plate provided with the test pin is moved upwards to the position where the string jig was placed by the elevating air cylinder, and the moving air cylinder of the movable adsorption unit is operated. The solar cell is then loaded onto the test jig plate.

When several solar cells soldered on the test jig are lifted up, as shown in FIG. 1, a halogen lamp installed at one side of the upper side of the upper support frame is turned on so that the test pin is positioned by the air cylinder as shown in FIG. 1. It operates in contact with the upper and lower conductor ribbon of the solar cell to measure voltage and current.

In this way, when the measured value is passed by the measurement, the mobile adsorption unit resorbs several solar cells that are soldered in a row on the test jig plate, and the rotary cylinder is operated by the rotary cylinder to rotate the rotary shaft guide bar by 180 °. After the rotation, the rotary shaft guide bar that absorbs the solar cell is moved to the position set by the user by the position control motor. At this time, the test plate moves to the original position, and the halogen lamp is turned off.

When the vacuum pad and the rotating shaft guide bar that have absorbed the solar cells arrive at the position set by the position control motor, the operation air cylinder of the upper adsorption unit is operated to descend to the surface of the solar cell rear surface placed on the vacuum pad of the mobile adsorption unit. The rear surface of the solar cell moved to the set-up position by the mobile adsorption unit by the lowering of the upper adsorption unit is adsorbed on the vacuum pad of the upper adsorption unit located at the upper end thereof, and the mobile adsorption unit releases the adsorption of the solar cell and the home position ( Initial standby position).

When the mobile adsorption unit is located at the home position, the servomotor of the upper adsorption unit is operated to operate the worm gear, and the vacuum pad and the support plate supporting the solar cell are lowered by the operation of the worm gear to lower the ball carrier. The solar cell is down-loaded onto the glass loaded onto the plate. The mobile adsorption unit moves down to the original position after down-loading the solar cell onto the glass.

By repeating the operation as described above, the solar cell module is arranged in the form of the solar cell module as shown in FIG. 10, and it is possible to lift and lower dozens of solar cells arranged as a user's option, and complete the solar cell module setting. Will be terminated.

The present invention is not limited to the above-described specific preferred embodiments, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As such, the present invention automatically checks whether the solar cell is defective, and is able to align it in an arbitrary form by adsorbing it, thereby enabling automation of the solar cell module manufacturing process, thereby improving productivity. In addition, there are many effects such as preventing damage of the solar cell and minimizing an electrical failure rate.

Claims (4)

Upper / lower support frame consisting of multiple longitudinal supports and horizontal supports A test unit which is integrally installed on one side of the lower support frame unit and is transported with a solar cell placed on a string jig, and measures a current voltage value of the solar cell; An upper suction part installed at an upper end of the upper support frame part and moved up / down by an operating air cylinder and a servomotor and having a plurality of vacuum pads; It is installed on the upper support frame stop to be located at the lower end of the upper adsorption unit, rotated by an air cylinder, and moved along the LM guide by a position control motor, and includes a mobile adsorption unit having a plurality of vacuum pads at the same time Solar cell automatic arranging device. The method of claim 1; The test unit includes a transfer conveyor for transferring a string jig loaded with a solar cell, a sensing sensor installed to be positioned at the end of the transfer conveyor, and a plurality of solar cells that are positioned under the transfer conveyor and moved by an air cylinder to be soldered in a row. A test pin in contact with the upper and lower conductor ribbons, a test jig provided on the upper surface of the test pin, a lifting air cylinder for moving the test jig up and down, the transfer conveyor and a sensing sensor are installed to support the lifting air cylinder. And a test frame integrally installed on the lower support frame, and a halogen lamp installed on one side of the upper support frame. The method of claim 1; The upper suction part includes a support plate having a servo motor installed on the upper support frame, a worm gear connected to the servo motor, a plurality of guide rods connected to the worm gear and penetrating the upper support frame, and the support. And a plurality of operating air cylinders installed in the lower vertical direction at the bottom of the plate, and vacuum pads connected to and installed in the operating air cylinders. The method of claim 1; The movable adsorption unit has LM guides installed on both sides of the upper support frame so as to be parallel to each other, and both ends are connected to the LM guides located at both sides, and are moved by a position control motor, and are rotated by a rotating air cylinder. A bar and a balance shaft fixed to the rotary shaft guide bar, a movable air cylinder installed on both sides of a position symmetrical to the balance shaft with respect to the rotary shaft guide bar, and a vacuum pad connected to the ends of the two movable air cylinders. Solar cell automatic array device, characterized in that consisting of a support and a plurality of vacuum pads installed on the vacuum pad support.