KR102591564B1 - Laser Soldering System - Google Patents

Abstract

The present invention relates to a laser soldering system that can prevent surface contamination or corrosion of a substrate by effectively removing flux components generated from solder paste during the laser soldering process.

Description

Laser Soldering System {Laser Soldering System}

The present invention relates to a laser soldering system. More specifically, the present invention relates to a laser soldering system that can prevent surface contamination or corrosion of the substrate by effectively removing flux components generated in solder paste during the laser soldering process.

Surface Mounted Technology (SMT) is a technology that mounts surface-mounted electronic components on the surface of a board and solders them. Among these soldering technologies, laser soldering is a non-contact method that uses laser light as a heat source to instantly raise the temperature to the solder melting point, making it advantageous for lead-free soldering processes that require high temperatures in local areas on the substrate.

Laser soldering technology applies a solder paste composed of alloy and flux to the soldering area of a semiconductor element to be mounted on a board, and then melts the solder paste by irradiating a laser to the soldering area of the board to create semiconductor terminals, etc. on the board. Can be soldered.

Meanwhile, during the radar soldering process, as the solder paste melts and cools rapidly again, the flux that has not yet been vaporized among the solder paste remains on the substrate. Among the components of the flux, rosin (resin) or an activator remains on the substrate. It remains and causes white turbidity, surface contamination, damage or corrosion.

To solve this problem, the process of removing the flux activator component was previously performed by heating the laser soldered board in a high temperature oven for several tens of minutes. However, this method removes the plating (TIN) layer through repeated heat treatment of the board. This caused soldering problems, such as the growth of the IMC layer.

Therefore, there is a need for a laser soldering system that can prevent surface contamination, damage, or corrosion of the substrate by effectively removing flux components remaining on the substrate during the laser soldering process.

The present invention aims to solve the problem of providing a laser soldering system that can prevent surface contamination or corrosion of the substrate by effectively removing flux components generated from solder paste during the laser soldering process.

In order to solve the above problem, the present invention provides a laser soldering system for soldering at least one semiconductor device to a substrate, using solder paste applied to solder the semiconductor device to the substrate. A laser irradiation unit that radiates a heating laser toward the semiconductor device and the substrate; A hot air supply unit that supplies hot air to the soldering area by the laser irradiation unit to vaporize flux components remaining around the semiconductor device and the substrate among the solder paste heated by the laser irradiation unit; and an intake unit for sucking in and discharging flux components vaporized by hot air supplied from the hot air supply unit.

Additionally, the hot air supply unit and the intake unit may be disposed with the laser irradiation unit interposed therebetween.

Here, the hot air nozzle of the hot air supply unit may be disposed inclined toward the soldering area.

Additionally, the intake duct of the intake unit may be disposed to be inclined downward toward the soldering area so that vaporized flux components are sucked in after hot air supplied from the hot air supply unit collides with the soldering area.

Additionally, the outlet cross-sectional area of the hot air nozzle of the hot air supply unit may be smaller than the inlet cross-sectional area of the intake duct of the intake unit.

Here, the flux components removed by the intake unit may include resin and activator.

And, the intake unit can perform intake at a negative pressure of 7 to 9 bar.

In addition, the hot air supply unit includes an inert gas supply unit for supplying an inert gas into the hot air supply unit; a heating unit for heating the inert gas supplied from the inert gas supply unit; It may include a compression unit for compressing the inert gas heated in the heating unit and discharging it to the outside of the hot air supply unit.

Here, the heating unit may heat the inert gas supplied from the non-flammable gas supply unit to maintain the temperature at 200 to 240 degrees Celsius.

Additionally, the hot air supply unit may generate hot air by discharging the inert gas compressed from the compression unit at a pneumatic pressure of 0.5 to 2.5 bar.

And, the substrate to be laser soldered may be a flexible printed circuit board (FPCB).

In order to effectively remove flux components that fail to vaporize during the soldering process and remain on the substrate, the laser soldering system according to the present invention supplies hot air to the soldering area of the substrate and simultaneously removes the flux components vaporized by the hot air by inhaling them. By being configured to do so, there is an effect of preventing surface contamination, damage, or corrosion of the substrate caused by the flux component.

Figure 1 shows the overall configuration of a laser soldering system according to the present invention.
Figure 2 shows a front view of a laser soldering system according to the invention.
Figure 3 shows a perspective view of a laser soldering system according to the invention.
Figure 4 shows test results for detecting flux in solder pastes according to comparative examples and examples.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure will be thorough and complete, and so that the spirit of the invention can be sufficiently conveyed to those skilled in the art. Like reference numerals refer to like elements throughout the specification.

Figure 1 shows the overall configuration of the laser soldering system according to the present invention, Figure 2 shows a front view of the laser soldering system according to the present invention, and Figure 3 shows a perspective view of the laser soldering system according to the present invention. .

As shown in FIGS. 1 to 3, the present invention provides a laser soldering system 1000 for soldering at least one semiconductor device 61 to a substrate 60, wherein the semiconductor device 61 is soldered to a substrate 60. ) A laser irradiation unit 100 that radiates a laser to heat the solder paste applied for soldering in the direction of the semiconductor element 61 and the substrate 60, among the solder paste heated by the laser irradiation unit. In order to vaporize the flux component 63 remaining around the semiconductor element 61 and the substrate 60, the hot air supply unit 200 supplies hot air to the soldering area by the laser irradiation unit and the hot air supplied from the hot air supply unit. It is configured to include an intake unit 300 for sucking in and discharging the vaporized flux component 63.

The laser irradiation unit 100, which constitutes the laser soldering system 1000 according to the present invention, irradiates a laser to the soldering area 60s of the substrate 60 in order to solder the semiconductor element 61 to the substrate 60, It is configured to solder the semiconductor device 61 on the substrate 60 by melting the solder paste applied in the soldering area 60s.

Here, the laser irradiation unit 100 may be configured to irradiate a laser downward from the top of the soldering area 60s of the substrate. The laser irradiation unit 100 is provided with a laser head 110 that radiates a laser beam, and the laser head 110 directs the laser beam downward to the area around the semiconductor element 61 within the soldering area 60s of the substrate. Laser soldering can be performed by irradiating the location where the solder paste is applied for several seconds.

In addition, the laser irradiation unit 100 is an inspection unit 130 that irradiates inspection light to check whether the laser beam from the laser head 110 is properly irradiated toward the solder paste applied to the soldering area 60s on the substrate. Can be additionally provided.

A soldering performing unit 600 may be provided in the lower area of the laser irradiation unit 100 to support the substrate 60 including the semiconductor element 61 to be soldered and perform laser soldering on the substrate 60. . The soldering performing unit 600 moves the soldering area 60s of the substrate to be placed in an area where the laser beam is irradiated downward by the laser irradiating unit 100, or moves the substrate 60 to the outside after the soldering process is completed. It may include a movable conveyor 610 for unloading.

Here, the substrate 60 soldered by the laser irradiation unit 100 may be a flexible printed circuit board (FPCB), which can be applied to a vehicle battery cell, etc. to implement a voltage sensing function. Additionally, the substrate 60 may be made of a polymer material such as polyethylene naphthalate (PEN) or polyimide (PI) in order to realize flexible performance.

The substrate 60 may be irradiated with a laser by the laser irradiation unit 100 and solder paste may be applied in advance to the area where the semiconductor device 61 is joined within the soldering area 60s of the substrate. The solder paste applied to the substrate 60 may be in the form of a cream that has a higher viscosity than a liquid.

This solder paste is a flux that facilitates soldering by removing alloy components made of metals such as lead (Pb), tin (Sn), silver (Ag), and copper (Cu) and the oxide film formed on the surface of the alloy. It is composed of (flux). The flux may be contained in an amount of 10 mass% or less, preferably 3 to 5 mass%, based on the total solder paste content.

In addition, the flux of the solder paste is rosin (resin, rosin), which is manufactured from pine rosin powder, and chlorine (Cl), fluorine (F), and bromine ( Solvents made of organic chemicals such as methyl alcohol (MA), isopropyl alcohol (IPA), ethanol, etc. to dissolve activators and flux solid components composed of halogen elements such as Br) It may be configured to include.

On the other hand, rosin, which constitutes the flux of solder paste, has a unique sticky property, so when rosin remains on the board, a polymer coating material is applied to the board to protect the board from moisture, gas, and other contamination after soldering. During conformal coating treatment, the flowability of the polymer coating material may be reduced and the adhesion between the polymer coating material and the substrate 60 may be worsened, resulting in contamination, corrosion, or damage to the substrate 60. This must be removed.

In addition, if the activator that constitutes the flux of the solder paste remains on the surface of the substrate 650 after soldering, the activator gradually turns white in the area of the substrate that comes into contact with moisture in the air, causing surface contamination, and the contact Since it causes oxidation corrosion of the substrate in this area, it must be removed.

The flux of solder paste has the characteristic of being removed naturally by vaporizing in the air when the temperature is gradually raised above about 150 degrees (°C). However, laser soldering is a method of intensively heating the solder paste by instantly irradiating a high-temperature laser beam of about 200 to 300 degrees (°C) from the laser irradiation unit 100 to the soldering area of the substrate, so the solder paste is heated during the laser soldering process. A separate process must be added to remove the flux component 63 generated as it fails to evaporate for a sufficient period of time and cools suddenly and remains on the substrate 60.

Therefore, conventionally, a baking method is used in which the soldered substrate 60 is heated in an oven at a temperature of 150°C or higher for several tens of minutes, thereby removing the flux component 63 remaining on the soldered substrate 60. ) was carried out by vaporizing it and blowing it into the air to remove it, but this method had the problem of causing thermal deformation, such as distortion or volume reduction, or cracking or melting on the substrate due to repeated high-temperature treatment of the substrate. .

Accordingly, the laser soldering system 1000 according to the present invention includes a hot air supply unit 200 for vaporizing the flux component 63 remaining on the substrate 60 by applying hot air to the soldering area 60s of the substrate 60. and an intake unit 300 for sucking in and discharging the flux component 63 vaporized by hot air to be disposed between the laser irradiation units 100, respectively, during soldering by the laser irradiation unit 100 or during soldering. It is configured to effectively remove the flux component 63 remaining around the semiconductor element 61 after completion.

In addition, the flux component 63 that is sucked in and removed by the intake unit 300 includes resin (rosin) and an activator, which causes the flux remaining in the soldering area 60s of the substrate after soldering. Surface contamination, damage, or corrosion of the substrate due to the flux component 63 can be prevented.

The hot air nozzle 210 of the hot air supply unit 200 constituting the laser soldering system 1000 may be disposed inclined toward the soldering area 60s of the substrate, and the intake duct 310 of the intake unit 300 It may be arranged to be inclined downward toward the soldering area (60s) so that the vaporized flux component is sucked in after the hot air supplied from the hot air nozzle (210) of the hot air supply unit (200) collides with the soldering area (60s) of the substrate. there is.

The intake unit 300 includes an intake duct 310 for intake of surrounding air containing flux components, and an intake pipe for transporting and discharging the gaseous flux component 63 that is connected to the intake duct to the outside. It may be configured to include (330).

Here, the intake unit 300 can perform intake at a negative pressure of 7 to 9 bar, and the intake unit 300 is connected to the intake pipe 330 and removes air around the soldering area 60s of the board. A vacuum unit (not shown) may be further provided to create a negative pressure environment by vacuuming.

The outlet cross-sectional area of the hot air nozzle 210 constituting the hot air supply unit 200 may be smaller than the inlet cross-sectional area of the intake duct 310 of the intake unit 300. As the outlet cross-sectional area of the hot air nozzle 210 of the hot air supply unit 200 is formed relatively small, the pressure of the hot air sprayed from the hot air nozzle 210 increases to force the flux component 63 in the direction of the intake unit 300. While it can be transported quickly, the inlet cross-sectional area of the intake duct 310 of the intake unit 300 is formed relatively large, so that a large amount of surrounding air of the vaporized flux component 63 can be smoothly absorbed and removed.

Referring to FIG. 1, the hot air supply unit 200 constituting the laser soldering system 1000 supplies inert gas such as nitrogen (N ₂ ), helium (He), and argon (Ar) into the hot air supply unit 200. an inert gas supply unit 220 for supplying, a heating unit 240 for heating the inert gas supplied from the inert gas supply unit, and compressing the inert gas heated in the heating unit to discharge it to the outside of the hot air supply unit. It may be configured to include a compression unit 260 for.

The hot air supply unit 200 includes a supply pipe 230 for transferring the inert gas supplied and heated by the inert gas supply unit 220 and the heating unit 240 into the hot air supply unit 220, and the supply pipe ( It may be configured to include a hot air nozzle 210 that generates hot air as the inert gas transported along 230) is discharged to the outside. Here, the hot air is composed of inert gases such as nitrogen (N ₂ ), helium (He), and argon (Ar) from the inert gas supply unit 220, so even if the hot air collides with the soldering area 60s of the substrate, the substrate ( 60) Deterioration of lead wetting due to oxidation can be prevented.

The concentration of the inert gas supplied from the inert gas supply unit 220 of the hot air supply unit 200 may be 5 to 7 ppm. In this way, when the concentration of the inert gas supplied from the inert gas supply unit 220 is 5 to 7 ppm, the hot air generated thereby sufficiently creates an inert gas atmosphere in the soldering area 60s of the substrate to prevent oxidation or corrosion, etc. can be prevented and at the same time, price competitiveness can be secured by minimizing the use of inert gas.

In addition, the heating unit 240 of the hot air supply unit 200 may heat the inert gas supplied from the inert gas supply unit 220 so that the temperature is maintained at 200 to 240 degrees (°C). When the temperature of the inert gas is less than 200°C, the temperature of the inert gas discharged to the outside of the hot air nozzle 210 of the hot air supply unit 200 decreases to less than about 150°C, and the flux component remaining in the substrate 60 On the other hand, if the temperature of the inert gas exceeds 240 ° C, it is heated above the heat resistance temperature of the polymer material constituting the substrate 60, and the substrate 60 is heated in the area where the hot air and the substrate contact. ) may cause melting or damage.

In addition, the hot air supply unit 200 may generate hot air by discharging the inert gas compressed from the compression unit 260 at a pneumatic pressure of 0.5 to 2.5 bar from the hot air nozzle 210. The hot air supply unit 200 generates hot air from the supplied and heated inert gas to vaporize the flux component 63 remaining around the semiconductor element 61 in the soldering area 60s of the substrate, and the vaporized flux component ( 63), together with the surrounding air, can eventually be sucked in and removed by the intake unit 300.

Figure 4 shows test results for detecting flux in solder pastes according to comparative examples and examples.

As shown in FIG. 4, the comparative examples and examples are laser soldering by applying the laser soldering system without the hot air supply unit 200 and the intake unit 300 and the laser soldering system 1000 of the present invention, respectively. After performing, the rosin detection reagent 65a and the activator detection reagent 65b are applied around the soldering area 60s of the substrate, and the state of the substrate 60 is captured and shown after a certain period of time.

Here, in the case of a comparative example applying a laser soldering device without the hot air supply unit 200 and the intake unit 300, the rosin detection reagent 65a and the activator detection reagent 65b are applied to the laser soldering treated substrate. It was confirmed that among the flux components (63) remaining in the soldering area (60s), a color change occurred in the detection reagent by reacting with rosin and an activator, respectively.

On the other hand, in the case of an embodiment in which the laser soldering system 1000 according to the present invention equipped with both the hot air supply unit 200 and the intake unit 300 is applied, the flux remaining in the soldering area 60s of the substrate after laser soldering The component is vaporized by the high-temperature hot air generated in the hot air supply unit 200 and is completely sucked in and removed by the intake unit 300, so that the rosin detection reagent 65a is applied to the flux of the solder paste in the soldering area 60s. ) and the reagent for detecting the activator (65b) were confirmed unreacted.

Although this specification has been described with reference to preferred embodiments of the present invention, those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims described below. It will be possible to implement it. Therefore, if the modified implementation basically includes the elements of the claims of the present invention, it should be considered to be included in the technical scope of the present invention.

1000: Laser soldering system
100: Laser irradiation unit
200: hot air supply unit
300: intake part

Claims (12)

In a laser soldering system for soldering at least one semiconductor device to a substrate,
A laser irradiation unit that radiates a laser to heat the solder paste applied to solder the semiconductor device to the substrate in the direction of the semiconductor device and the substrate;
A hot air supply unit that supplies hot air to the soldering area by the laser irradiation unit to vaporize flux components remaining around the semiconductor device and the substrate among the solder paste heated by the laser irradiation unit; and
An intake unit for sucking in and discharging flux components vaporized by hot air supplied from the hot air supply unit,
The hot air supply unit and the intake unit are disposed with the laser irradiation unit interposed, the hot air nozzles of the hot air supply unit are disposed inclined toward the soldering area at a position facing each other, and the intake duct of the intake unit is supplied from the hot air supply unit. After hot air collides with the soldering area, the soldering area is disposed at an angle downward so that vaporized flux components are sucked in,
The hot air supply unit generates hot air by heating an inert gas with a concentration of 5 to 7 ppm in the range of 200 to 240 degrees (°C) and then discharging the inert gas with a pneumatic pressure of 0.5 to 2.5 bar,
The outlet cross-sectional area of the hot air nozzle of the hot air supply unit is configured to be smaller than the inlet cross-sectional area of the intake duct of the intake unit, and the intake pressure by the intake unit is more than twice the air supply pressure by the hot air supply unit in the negative pressure range of 7 to 9 bar. Features a laser soldering system. delete delete delete delete According to paragraph 1,
A laser soldering system, wherein the flux components removed by the intake unit include resin and an activator. delete According to paragraph 1,
The hot air supply unit includes an inert gas supply unit for supplying an inert gas into the hot air supply unit; a heating unit for heating the inert gas supplied from the inert gas supply unit; and a compression unit for compressing the inert gas heated in the heating unit and discharging it to the outside of the hot air supply unit. delete delete delete According to paragraph 1,
A laser soldering system, wherein the substrate is a flexible printed circuit board (FPCB).