CN212485350U - Manufacturing device for forming selective emitter on substrate - Google Patents

Abstract

The invention provides a manufacturing device for forming a selective emitter on a substrate, comprising: laser emission portion, light conversion portion, polarizer, beam expansion portion, controller, box and support body. The laser emitting part emits a laser beam; the light conversion part converts the laser beam into corresponding polarized light; the polarizer allows one of an unpolarized laser beam and a polarized laser beam to transmit therethrough; the beam expanding part expands the laser beam transmitted through the polarizer to a set multiple; the melting laser emitter receives the expanded laser beam and emits a melting laser beam to a set position on the substrate; the controller is electrically connected with the light conversion part; the bases of the components are mounted on the frame body, and the controller controls the light conversion part to be opened or closed, so that the melting laser beam is closed when reaching the region beyond the preset selective emitter and is opened when reaching the region of the preset selective emitter. The manufacturing device of the invention can form the selective emitter without a mask.

Description

Manufacturing device for forming selective emitter on substrate

Technical Field

The invention relates to the field of laser manufacturing, in particular to a manufacturing device for forming a selective emitter on a substrate.

Background

A selective emitter cell is considered as an effective way to improve the efficiency of a solar cell, and a selective emitter (selective emitter) is an emitter structure in which a relatively thick emitter layer is disposed in a region adjacent to a front electrode in order to reduce the contact resistance between the front electrode and the emitter layer, so that the selective emitter structure can implement a lateral junction below the electrode, reduce the recombination of minority carrier holes in the region, and reduce the contact resistance between metal and semiconductor, thereby manufacturing the selective emitter solar cell, and greatly improving the conversion efficiency of the solar cell.

The existing selective emitter is mostly manufactured by adopting laser melting processing, so that laser beams emitted by a melting laser emitter are irradiated along the position of the preset selective emitter, dopants of a doping source layer are diffused to the lower side, and the selective emitter layer with higher concentration than that of a low-concentration emitter layer is formed. However, the laser beam for forming the selective emitter generally employs a continuous wave (continuous wave) laser beam or a quasi-continuous wave (quasi-continuous wave) laser beam. However, when moving between a plurality of lines of the preset selective emitter, it is necessary that the laser beam does not irradiate a region other than the preset selective emitter. If the regions of the substrate that are not associated with the selective emitter are damaged, the performance of the overall solar cell product may be affected. However, in the case of the continuous wave laser emitting portion, a switch for controlling the output of the laser beam is not installed therein, and thus it is difficult to perform on/off switching during the process of the selective emitter. Therefore, in the prior art, a mask is mostly disposed on the upper side of the substrate to protect the non-selective emitter region, but the reference of the mask greatly requires an additional process to align the mask and the substrate, so that the production efficiency of the process is degraded. Therefore, it is desirable to provide a manufacturing apparatus for forming a selective emitter on a substrate, which can perform automatic switching, to solve the above problems.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, an object of the present invention is to provide a manufacturing apparatus for forming a selective emitter on a substrate, which is used to solve the problem that the conventional manufacturing apparatus for forming a selective emitter on a substrate cannot autonomously switch the on/off of a laser beam in a selective emitter region and a non-selective emitter region to protect the non-selective emitter region from damage.

To achieve the above and other related objects, the present invention provides a manufacturing apparatus for forming a selective emitter on a substrate, comprising:

a laser emitting section that emits a continuous wave or quasi-continuous wave laser beam;

a light conversion portion that converts the laser beam into a corresponding first or second polarization;

a polarizer that allows one of the laser beam that is not polarized and the laser beam that is polarized to transmit therethrough, while blocking the other;

a beam expanding section expanding the laser beam transmitted through the polarizer to a set multiple;

a melting laser emitter that receives the expanded laser beam and emits a melting laser beam to a set position on the substrate;

a controller electrically connected to the light conversion part;

the cooling air inlet and the cooling air outlet are formed in the box body;

the frame body is clamped between the damping strips in the box body and connected with the damping strips through damping bolts;

the laser emitter, the light conversion part, the polarizer, the beam expansion part and the base of the melting laser emitter are all mounted on the frame body, and the controller controls the light conversion part to be opened or closed, so that the melting laser beam is closed when reaching the region except the preset selective emitter and is opened when reaching the preset selective emitter region.

In an example of the present invention, the manufacturing apparatus further includes a light blocking member and a driving device, wherein the driving device drives the light blocking member to act so as to cut off or release the laser beam between the laser emitting portion and the light conversion portion.

In an example of the present invention, the melting laser emitter includes a scanning galvanometer and a condenser lens.

In an example of the present invention, the beam expanding portion includes a zoom beam expander.

In an example of the present invention, the manufacturing apparatus further includes a case provided with a cooling air inlet and outlet.

In an example of the present invention, the laser emitting portion, the optical converting portion, the polarizer, the beam expanding portion, and the base of the fusion laser emitter are mounted on the same frame, and the frame is clamped between the damping bars in the box and connected to the damping bars through the shock absorbing bolts.

In an example of the present invention, the frame body is provided with two parallel first vertical plates and second vertical plates, and the laser emitting portion, the light conversion portion, the polarizer, the beam expansion portion, and two ends of the base of the melting laser emitter are all mounted on the first vertical plates and the second vertical plates through adjustable clamping grooves.

In an example of the present invention, the adjustable card slot includes: the damping piece is installed in the clamping groove of the clamping groove body, the base is located in the damping piece, and the at least two adjusting bodies are pressed against and pressed on the base from top to bottom.

In an example of the present invention, a groove is provided on the base at a position corresponding to the adjusting body, a damping plate is installed in the groove, the adjusting body is installed on the slot body in a threaded connection manner, and an end portion of the adjusting body abuts against the damping plate.

In an example of the present invention, the line width of the melting laser beam is greater than 10 μm and less than 20 μm.

As described above, the manufacturing apparatus for forming a selective emitter on a substrate according to the present invention irradiates a laser beam to a region on the substrate where the selective emitter is to be formed, and does not irradiate to a region other than the region on the substrate where the selective emitter is to be formed, so that the selective emitter can be formed without a mask, thereby improving the production yield and remarkably saving the maintenance cost of the apparatus. In addition, the manufacturing device for forming the selective emitter on the substrate integrally realizes the on-off of the laser beam through the light conversion part, the polarizer and the controller, not only can control the laser beam to be transmitted with higher efficiency, but also can filter out a part of stray light through the polarizer, can ensure that the quality of the laser beam irradiated on the substrate is uniform and stable, and improves the reliability of the selective emitter.

Drawings

FIG. 1 is a schematic cross-sectional view of one embodiment of an apparatus for forming a selective emitter on a substrate according to the present invention;

FIG. 2 is a sectional view taken along line A-A in FIG. 1;

FIG. 3 is a schematic view of the mounting of a submount in an embodiment of an apparatus for forming a selective emitter on a substrate according to the invention;

fig. 4 is a partially enlarged view of the region I in fig. 3.

In the figure:

1 manufacturing apparatus for forming selective emitter on substrate

100 laser emitting part

101 base of laser emitting part

200 light conversion part

201 base of light conversion part

300 polarizer

Base of 301 polarizer

400 beam expansion part

401 base of beam enlarging part

500 melting laser emitter

501 base of melting laser emitter

502 melting laser beam

600 box

601 first damping strip

602 second damping strip

603 third damping strip

604 fourth damping strip

605 cooling air inlet

606 outlet

700 shelf

701 first vertical plate

702 second vertical plate

710 adjustable clamping groove

711 card slot body

712 damping member

713 regulator

714 damping plate

800 light blocking component

801 base of light-blocking part

900 temperature sensor

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention.

It should be noted that the drawings provided in the present embodiment are only schematic and illustrate the basic idea of the present invention, and although the drawings only show the components related to the present invention and are not drawn according to the number, shape and size of the components in actual implementation, the form, quantity and proportion of the components in actual implementation may be changed arbitrarily, and the layout of the components may be more complicated.

As shown in fig. 1 to 4, the present invention provides a manufacturing apparatus 1 for forming a selective emitter on a substrate, which is used to solve the problem that the conventional manufacturing apparatus for forming a selective emitter on a substrate cannot autonomously switch the on/off of a laser beam in a selective emitter region and a non-selective emitter region to protect the non-selective emitter region from damage.

Referring to fig. 1, the apparatus 1 for forming a selective emitter on a substrate according to the present invention comprises: the laser emitting unit 100, the light converting unit 200, the polarizer 300, the beam expanding unit 400, the controller (not shown), the case 600, and the frame 700.

The laser emitting section 100 emits a continuous wave or quasi-continuous wave laser beam;

the light conversion section 200 converts the laser beam into a corresponding first polarization (e.g., P-polarization) or second polarization (e.g., S-polarization);

the polarizer 300 allows one of the laser beam unpolarized and the laser beam polarized to transmit therethrough, while blocking the other;

the beam expanding part 400 expands the laser beam transmitted through the polarizer 300 to a set multiple;

the melting laser emitter 500 receives the expanded laser beam and emits a melting laser beam 502 to a set position on the substrate;

the controller is electrically connected with the light conversion part 200; the controller controls the light conversion part 200 to be turned on or off such that the melting laser beam 502 is turned off when it reaches a region other than a preset selective emitter region and is turned on when it reaches the preset selective emitter region.

The box body 600 is provided with a cooling air inlet 605 and a cooling air outlet 606; the case 600 covers the laser emitting unit 100, the optical converter 200, the polarizer 300, the beam expander 400, and the fusion laser emitter 500 from the outside and isolates them from the external environment.

Referring to fig. 1 and 2, the frame body 700 is clamped between the damping bars in the box body 600 and connected with the damping bars through damping bolts; in an example of the present invention, the base 101 of the laser emitting portion, the base 201 of the light conversion portion, the base 301 of the polarizer, the base 401 of the beam expansion portion, and the base 501 of the melting laser emitter are all mounted on the same frame 700, two sides of the lower portion of the frame 700 are clamped between the first damping strip 601 and the second damping strip 602, and two sides of the upper portion of the frame 700 are clamped between the third damping strip 603 and the fourth damping strip 604; the frame body 700 is connected with the damping strips through damping bolts (not shown), and by the structure, the mounting error of each component on a light path can be greatly reduced, the influence of vibration on the light path can be reduced, and the whole device can work more stably. It should be noted that the mounting manner of each component in the present invention may be any other appropriate manner.

The manufacturing apparatus 1 for forming a selective emitter on a substrate according to the present invention irradiates a laser beam to a region on the substrate where the selective emitter is to be formed, and does not irradiate to a region other than the region on the substrate where the selective emitter is to be formed, and thus, the selective emitter can be formed without a mask, so that the production yield can be improved, and the maintenance cost of the apparatus can be remarkably saved. In addition, the manufacturing apparatus 1 for forming a selective emitter on a substrate of the present invention integrally implements on/off of a laser beam through the light conversion part 200, the polarizer 300, and the controller, and not only can control the laser beam to be transmitted with high efficiency, but also can filter a part of stray light through the polarizer 300, so that the quality of the laser beam irradiated on the substrate is uniform and stable, and the reliability of the selective emitter is improved.

In consideration of stability of processing quality, and most of the existing laser emitting portions 100 for emitter fabrication are continuous wave laser beams rather than pulse wave laser beams, and Q-switching cannot be performed inside, the laser emitting portion 100 in this embodiment is a continuous wave laser without Q-switching inside, which emits a continuous wave laser beam. In another embodiment of the present invention, the laser emitting unit 100 is a quasi-CW laser emitting unit 100 without a Q-switch therein, which emits a quasi-CW laser beam.

The light conversion section 200 in the manufacturing apparatus 1 for forming a selective emitter on a substrate in the present embodiment converts the laser beam emitted by the laser emission section 100 into the corresponding P-polarized light or S-polarized light.

The polarizer 300 in the manufacturing apparatus 1 of the present invention for forming a selective emitter on a substrate allows one of the laser beam not polarized and the laser beam polarized to transmit therethrough, while blocking the other; the polarizer 300 in this embodiment allows the polarized light converted by the light conversion part 200 to pass through to the beam expansion part 400, and after passing through the beam expansion part 400, enters the melting laser emitter 500, and is finally emitted by the melting laser emitter 500 to reach a predetermined selective emitter region to form a selective emitter. And simultaneously prevents the laser beam not converted by the light conversion part 200 from being reflected to be transmitted to the subsequent melting laser emitter 500.

The beam expanding part 400 in the manufacturing apparatus 1 of the present invention for forming a selective emitter on a substrate expands a laser beam transmitted through the polarizer 300 to a set multiple to adjust the diameter of the laser beam entering the melting laser emitter 500, thereby controlling the size of the melting laser beam 502 emitted from the melting laser emitter 500.

The melting laser emitter 500 in the manufacturing apparatus 1 for forming a selective emitter on a substrate according to the present invention receives the expanded laser beam and emits the melting laser beam 502 to a selective emitter position set on the substrate. It should be noted that the melting laser emitter 500 of the present invention can be any suitable structure capable of converting a low-energy laser beam into a high-energy melting laser beam 502, and the melting laser emitter 500 of the present invention includes a scanning galvanometer and a condenser lens. The scanning galvanometer is provided with a reflecting mirror and a rotating motor, and the light incident on the reflecting mirror can be reflected to a preset position by the rotation of the motor. A laser beam can be irradiated to a predetermined position on the substrate by using a pair of scanning galvanometers. Since the scanning galvanometer has a small mechanical inertia and almost no acceleration/deceleration section, the laser beam is moved to perform processing while being irradiated with a laser beam of a predetermined power, and the same processing quality can be obtained over the entire section.

In the present invention, a controller electrically connected to the light conversion part 200 may be separately provided, and the controller controls the on/off of the light conversion part 200 through the entire manufacturing apparatus without additionally providing a controller, in which the controller performs the on/off of the light conversion part 200 according to a predetermined moving track of the melting laser beam 502 on the substrate, so that the melting laser beam 502 is turned off when it reaches a region other than the predetermined selective emitter region, and is turned on when it reaches the predetermined selective emitter region.

The polarizer 300 in the present invention may be a polarizer 300 that allows only P light to pass through, or may be a polarizer 300 that allows only S light to pass through, for example, if the laser beam output from the laser emitting unit 100 is S polarized light, power is supplied from the controller to the light conversion unit 200 to convert the laser beam passing through the light conversion unit 200 into P polarized light, and if the polarizer 300 is designed to transmit the P polarized light and reflect the S polarized light, the laser beam converted into P polarized light by the light conversion unit 200 is transmitted through the polarizer 300 and transmitted to the melting laser emitter 500. When the melting laser beam 502 needs to be turned off in the region other than the selective emitter, the power supply of the light conversion portion 200 is turned off by the controller, and then the laser beam passing through the light conversion portion 200 is still S-polarized and is blocked by the P-transparent polarizer 300, thereby preventing the melting laser beam 502 from reaching the region other than the selective emitter on the substrate.

On the contrary, if the polarizer 300 is designed to transmit S-polarized light and reflect P-polarized light, if the light emitted from the laser emitting unit 100 is S-polarized light and the light converted by the light converting unit 200 is P-polarized light, the P-polarized light cannot pass through the polarizer 300 and cannot reach the substrate when the light converting unit 200 is powered on, and if the controller controls the light converting unit 200 to be powered off, the S-polarized light emitted from the laser emitting unit 100 is S-polarized light after passing through the laser emitting unit 100, and can pass through the polarized light to reach the melting laser emitter 500 and finally be emitted to the set selective emitter region on the substrate.

In the above case, when power is supplied to the optical conversion unit 200 to polarize the optical conversion unit 200, the polarization of the laser beam of the optical conversion unit 200 is effective at a high level, and when power is not supplied to the optical conversion unit 200, the polarization of the laser beam passing through the polarization conversion unit 200 is effective at a low level.

In the present invention, the optical path can be cut off or released quickly and accurately by opening and closing the optical conversion part 200 by the controller, and the energy loss of the laser is small, however, in order to cope with various conditions that may occur in the manufacturing process, in an example of the present invention, the manufacturing apparatus 1 further includes a light blocking part 800 and a driving device, and the driving device drives the light blocking part 800 to operate to cut off or release the laser beam between the laser emitting part 100 and the optical conversion part 200. Unlike the optical disconnection between the light conversion unit 200 and the controller, the light blocking member 800 according to the present invention is mechanically disconnected from the driving device. The light blocking member 800 is disposed between the light conversion part 200 and the laser emitting part 100, and moves between a position outside the optical path and a position on the optical path by the driving means, thereby cutting off the laser beam or releasing the laser beam. The driving device can be any power source which can drive the light-blocking component 800 to linearly move or rotate from the position outside the light path to the set position on the light path, such as a rotary motor, a screw motor and the like. It should be noted that the installation form of the light blocking member 800 and the driving device is not limited in the present invention, in this embodiment, the base 801 of the light blocking member is installed on the frame body 700, and is provided with a through hole for allowing the laser beam to pass through, and the light blocking member 800 blocks the through hole under the action of the driving device to cut off or release the laser beam.

The beam expanding part 400 of the present invention may be any suitable form of beam expander, and in one example of the present invention, the beam expanding part 400 includes a zoom beam expander. The zoom beam expander is disposed between the polarizer 300 and the fusion laser emitter 500, and the zoom beam expander can automatically adjust a relative distance between the internal lenses, thereby changing a diameter of the laser beam emitted from the zoom beam expander and incident into the fusion laser emitter 500. Generally, the spot size of the laser beam (L) becomes smaller as the diameter of the laser beam incident to the laser emitting portion 100 becomes larger, and the spot size of the laser beam becomes larger as the diameter of the laser beam incident to the laser emitting portion 100 becomes smaller.

As shown in fig. 3 to 4, in an example of the present invention, the frame body 700 is provided with two parallel first vertical plates 701 and second vertical plates 702, and both ends of the laser emitting portion 100, the light conversion portion 200, the polarizer 300, the beam expanding portion 400, and the base 501 of the melting laser emitter are mounted on the first vertical plate 701 and the second vertical plate 702 through adjusting slots 710. The adjustable clamping slot 710 comprises: the card slot comprises a card slot body 711, a damping part 712 and at least two adjusting bodies 713, wherein the damping part 712 is installed in the card slot of the card slot body 711, the base is installed in the damping part 712 in a positioning mode, and the at least two adjusting bodies 713 are pressed on the base in an abutting mode from top to bottom. The damping member 712 is made of a material with a certain hardness and shock absorption capacity, such as polyurethane, and when the optical path needs to be adjusted, the corresponding adjusting bodies 713 are screwed to change the inclination of the base, so as to adjust the optical path. The adjusting body 713 of the invention is easy to select a damping bolt, and the influence of vibration on the base can be greatly reduced through the matching of the damping bolt and the damping part 712. However, in an example of the present invention, a groove is provided on the base at a position corresponding to the adjusting body 713, a damping plate 714 is installed in the groove, the adjusting body 713 is a common bolt, the common bolt is threadedly installed on the slot body 711, and an end of the common bolt abuts against the damping plate 714. This structure can also play a role in shock absorption.

In consideration of the temperature sensitivity of the optical components, the housing 600 in this embodiment is provided with a cooling air inlet 605 and an outlet 606, and cooling air flows in from the cooling air inlet 605 and flows out through the outlet 606, thereby cooling each component in the housing 600. In consideration of cooling sufficiency, in the embodiment, the cooling air inlet 605 and the cooling air outlet 606 are respectively located at two sides of the first vertical plate 701 and the second vertical plate 702, and the air flow enters the box body 600 and is uniformly distributed into the frame body 700 from the side to cool each component, so that adverse effects of the air flow on the light path can be prevented.

In order to obtain a stable melting laser beam 502, as an example of the present invention, the manufacturing apparatus 1 for forming a selective emitter on a substrate in the present embodiment further includes a cold air supply device (not shown, which may be configured externally), a temperature sensor 900 is installed in the box 600, the temperature sensor 900 is electrically connected to the controller, and the controller is electrically connected to a control system of the cold air supply device. When the temperature fed back by the temperature sensor 900 exceeds the standard, the controller controls the cool air supply device to either lower the temperature or increase the air volume so that the temperature inside the cabinet 600 is lowered to be within a proper range. Considering that the laser emitting portion 100 is relatively high in temperature and sensitive to temperature, the temperature sensor 900 is installed inside the frame body 700 near the laser emitting portion 100.

While the line width of the laser beam is generally wide when the substrate is irradiated with the pulsed laser beam, in the present embodiment, the laser emitting portion 100 emits the continuous wave laser beam or the quasi-continuous wave laser beam having a line width relatively narrower than that of the pulsed laser beam, and the line width of the laser beam irradiated on the substrate is 10 μm or more and 20 μm or less.

In summary, the manufacturing apparatus for forming the selective emitter on the substrate of the present invention can form the selective emitter without a mask, thereby improving the production yield and significantly saving the maintenance cost of the apparatus. In addition, the manufacturing device for forming the selective emitter on the substrate integrally realizes the on-off of the laser beam through the light conversion part, the polarizer and the controller, not only can control the laser beam to be transmitted with higher efficiency, but also can filter out a part of stray light through the polarizer, can ensure that the quality of the laser beam irradiated on the substrate is uniform and stable, improves the reliability of the selective emitter, and has higher utilization value and use significance.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Many modifications may be made to the present invention without departing from the spirit or scope of the general inventive concept, and it will be apparent to those skilled in the art that changes and modifications may be made to the above-described embodiments without departing from the spirit or scope of the invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (8)

1. A manufacturing apparatus for forming a selective emitter on a substrate, comprising:

a laser emitting section that emits a continuous wave or quasi-continuous wave laser beam;

a light conversion portion that converts the laser beam into a corresponding first or second polarization;

a polarizer that allows one of the laser beam that is not polarized and the laser beam that is polarized to transmit therethrough, while blocking the other;

a beam expanding section expanding the laser beam transmitted through the polarizer to a set multiple;

a melting laser emitter that receives the expanded laser beam and emits a melting laser beam to a set position on the substrate;

a controller electrically connected to the light conversion part;

the cooling air inlet and the cooling air outlet are formed in the box body;

the frame body is clamped between the damping strips in the box body and connected with the damping strips through damping bolts;

the laser emitter, the light conversion part, the polarizer, the beam expansion part and the base of the melting laser emitter are all mounted on the frame body, and the controller controls the light conversion part to be opened or closed, so that the melting laser beam is closed when reaching the region except the preset selective emitter and is opened when reaching the preset selective emitter region.

2. The manufacturing apparatus according to claim 1, further comprising a light blocking member and a driving device, wherein the driving device drives the light blocking member to act so as to cut off or release the laser beam between the laser emitting portion and the light converting portion.

3. The manufacturing apparatus according to claim 1, wherein the melting laser emitter includes a scanning galvanometer and a condenser lens.

4. The manufacturing apparatus according to claim 1, wherein the beam expanding portion includes a zoom beam expander.

5. The manufacturing device according to claim 1, wherein the frame body is provided with two parallel first vertical plates and second vertical plates, and the two ends of the base of the laser emitting portion, the light conversion portion, the polarizer, the beam expansion portion, and the melting laser emitter are mounted on the first vertical plates and the second vertical plates through adjustable clamping grooves.

6. The manufacturing apparatus of claim 5, wherein said adjustable clamping slot comprises: the damping piece is installed in the clamping groove of the clamping groove body, the base is located in the damping piece, and the at least two adjusting bodies are pressed against and pressed on the base from top to bottom.

7. The manufacturing device according to claim 6, wherein a groove is formed in the base at a position corresponding to the adjusting body, a damping plate is installed in the groove, the adjusting body is installed on the clamping groove body in a threaded connection mode, and an end portion of the adjusting body abuts against the damping plate.

8. The manufacturing apparatus according to claim 1, wherein a line width of the melting laser beam is larger than 10 μm and smaller than 20 μm.

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