TWM614050U - Automatic welding system and heating device thereof - Google Patents

Abstract

This creation is an automatic welding system and its heating device. It includes a heating device above a carrier, which includes an induction coil connected to a power supply, and a magnetic directional sleeve covering the periphery of the induction coil to align with the circuit board. Solder, when the power supply supplies power to the induction coil, the induction coil generates magnetic flux to guide the solder to generate an induced current. The magnetic directional sleeve provides a limited magnetic field range and narrows the range of induced current generated by the magnetic field to facilitate pointing to a small range of solder. A moving device is inserted in the induction coil to move the unsoldered electronic components. A control device is connected to and controls the heating device and the moving device to perform the above-mentioned preset actions. The heating device of this creation has high directivity and is matched with electromagnetic induction, which can enable a single electronic component to be desoldered or welded to a new electronic component, which can effectively improve the overall efficiency.

Description

Automatic welding system and heating device

This creation is about a technology involving welding, especially an automatic fusion welding system and its heating device.

With the increasing progress of semiconductor technology, in addition to improving the performance of electronic products such as smart phones or various sensors, semiconductor technology has also been reduced in size. When processing electronic components such as soldering or desoldering, you need to be more careful.

However, the manufacturers of these electronic products must test the electronic components in the electronic products, such as integrated circuits (ICs) before shipping. When the electronic components are damaged or incompletely connected to the circuit board, It is necessary to desolder its electronic components to remove or re-solder the electronic components.

In the past, when the electronic components on the circuit board were desoldered, the soldering tin of the electronic components was heated by directly holding the welding gun. After the solder has melted, the solder sucker is used to remove the solder from the electronic component, thereby removing the electronic component from the circuit board.

However, the temperature range generated by the traditional welding gun can reach 300 degrees Celsius to 1000 degrees Celsius, which is quite wide, and there is currently no effective way to control the temperature of the welding gun. Therefore, for temperature-sensitive electronic components, the temperature may be too high. The damage will undoubtedly increase the cost burden of manufacturers. In addition, the diameter of the heating tip of the welding gun is at least 1 centimeter (mm), which is completely unsuitable for integrated circuits as small as nanometers.

Therefore, the traditional manual desoldering method not only consumes manpower, but also takes a long time, has low accuracy, and cannot effectively control the desoldering temperature, making the overall efficiency relatively low.

In view of this, this author proposes an automatic welding system and its heating device to effectively overcome the above-mentioned problems in response to the lack of the above-mentioned conventional technology.

The main purpose of this creation is to provide an automatic welding system and its heating device, which has high magnetic directivity, and at the same time, with electromagnetic induction technology, it can only melt a single small area of solder for automatic welding or removal. Desoldering electronic components.

Another purpose of this creation is to provide an automatic welding system and its heating device. The magnetic directional sleeve has good magnetic permeability, which can effectively enhance the benefits of electromagnetic induction, and the high resistance of the magnetic directional sleeve can avoid the magnetic directional sleeve. The temperature of the barrel is too high to avoid the material embrittlement and loss of magnetism caused by the temperature of the magnetic directional sleeve.

In order to achieve the above-mentioned purpose, this creation is to provide an automatic welding system, which is suitable for heating the solder on the circuit board to remove the electronic components on the circuit board. The automatic welding system includes a carrier, a heating device, a moving device and a control device. The carrier can be used to carry circuit boards, and one side of the carrier is provided with a heating device. The heating device includes a power supply, an induction coil and a magnetic directional sleeve. The power supply is connected to the induction coil, and the magnetic directional sleeve covers the periphery of the induction coil, and the magnetic directional sleeve is aligned with the solder of the circuit board. When the power supply is supplied to the induction coil, the magnetic directional sleeve can concentrate the magnetic flux generated by the induction coil In the opening range of the front end of the magnetic directional sleeve, the magnet is guided to the solder to generate an induced current to heat the solder. The moving device penetrates the inner side of the induction coil to move the electronic components. The control device is connected to and controls the heating device and the moving device, and executes the above-mentioned preset actions.

In this embodiment, the carrier is set on a first mobile device, and the first mobile device is connected to and receives the control mobile carrier of the control device. The moving device is arranged on a second moving device, and the second moving device is connected to and receives the control moving and moving device of the control device.

In this embodiment, the heating device further includes a coaxial magnetic directional sleeve of the magnetic conductive sheet, and is located on the other side of the carrier relative to the heating device.

Another purpose of this creation is to provide an automatic welding system, which can automatically detect damaged electronic components, and automatically perform de-soldering and removal actions on the electronic components.

To achieve the above-mentioned purpose, in this embodiment, the automatic welding system further includes an image capturing device arranged on a third mobile device, and the image capturing device is connected to and receives the control of the control device. The image capturing device can capture the circuit board image and transmit it to the control device, so that the control device can identify the damaged electronic component based on the circuit board image, and the control device can capture the position information of the electronic component and the fixed direction information of the electronic component. The first moving device is controlled to move the stage according to the position information of the electronic component, so that the heating device and the moving device are aligned with the position of the damaged electronic component, so as to desolder the damaged electronic component.

Another purpose of this creation is to provide an automatic welding system that can weld back new electronic components, which can greatly improve the efficiency of chip yield detection and circuit board repair, and relatively improve the efficiency of shipments.

To achieve the above purpose, in this embodiment, the automatic welding system further includes a repair module, including an electronic component supply device, connected to the control device, to supply new electronic components. A component is connected to the control device for the camera. A component adjustment device is connected to the control device to receive the control of the control device to capture the new electronic component to the front of the lens of the component turning camera, to make the component turning camera to shoot the new electronic component, to generate a new electronic component image to the control device, and the control device to compare The image of the new electronic component and the fixed direction information of the electronic component are used to generate a direction adjustment signal to the component adjustment device according to the fixed direction information of the electronic component to adjust the direction of the new electronic component. A fourth moving device is connected to the control device to receive the control moving component adjustment device of the control device. The control device controls the fourth moving device according to the position information of the electronic component to install the new electronic component to the position of the damaged electronic component.

In this embodiment, the heating device further includes a magnetic conductive sheet arranged on the other side of the carrier relative to the heating device and coaxially magnetically directed to the sleeve.

In this embodiment, the automatic welding system further includes a distance sensor, adjacent to the heating device, and connected to the control device to receive the control measurement of the control device and the relative distance between the electronic component, and generate a distance information. When the distance information is less than a preset distance information, the control device controls the second mobile device to stop approaching the electronic component.

In this embodiment, the second moving device, the heating device and the moving device are arranged on the third moving device.

In this embodiment, the magnetic directional sleeve is an iron-based amorphous magnetic directional sleeve or a soft ferrite magnetic directional sleeve.

In this embodiment, the magnetic directional sleeve is a tapered magnetic directional sleeve, and the diameter of its tip is at least 2 millimeters (mm).

In this embodiment, the induction coil is a copper tube induction coil.

In this embodiment, the moving device is a vacuum suction nozzle.

In this embodiment, the induction coil is a spiral induction coil.

In this embodiment, the automatic welding system further includes an air jet device connected to the control device, the air jet device is connected to the nozzle tube of the transfer device, and the air jet device receives and controls the device to spray inert gas to the nozzle tube of the transfer device.

In addition, this creation further provides a heating device suitable for heating solder on a circuit board. The heating device includes a power supply, an induction coil and a magnetic directional sleeve. The power supply is connected to the induction coil. The magnetic directional sleeve covers the periphery of the induction coil. The magnetic directional sleeve is aligned with the solder on the circuit board. When the power supply is supplied to the induction coil, the magnetic directional sleeve concentrates the magnetic flux generated by the induction coil. Magnetic induction is generated to the solder to heat the solder for desoldering.

In this embodiment, the magnetic directional sleeve can be an iron-based amorphous magnetic directional sleeve or a soft ferrite magnetic directional sleeve.

In this embodiment, the magnetic directional sleeve is a tapered magnetic directional sleeve, and the diameter of the tip of the magnetic directional sleeve is at least 2 millimeters (mm).

In this embodiment, the induction coil is a copper tube induction coil.

In this embodiment, the heating device further includes a coaxial magnetic directional sleeve with a magnetic conductive sheet.

In this embodiment, the induction coil is a spiral induction coil.

In order to have a better understanding and understanding of the structural features of this creation and the effects achieved, I would like to provide a better embodiment diagram and detailed descriptions. The description is as follows.

First, the structure of the automatic welding system 1 of this creation will be explained. Please refer to the first to third figures. The automatic welding system 1 includes a machine 10 with a carrier 20, a heating device 30, a moving device 40, A control device 50, an image capturing device 60, a distance sensor 70, a repair module 80, and an air jet device 90. A plurality of waste barrels 12 are provided on the machine table 10 and in front of the carrier table 20 to contain damaged electronic components. The control device 50 can be a computer, which can be controlled by a programmable logic controller (PLC) to connect the carrier 20, the heating device 30, the moving device 40, the image capturing device 60, the distance sensor 70, The repair module 80 and the air-jet device 90, and control the operation of the stage 20, the heating device 30, the moving device 40, the image capturing device 60, the distance sensor 70, and the repair module 80.

Please continue to refer to the first to third figures. The carrier 20 is a platform for carrying a circuit board 22, and the circuit board 22 is a circuit board capable of soldering electronic components, such as a printed circuit board (PCB). The carrier 20 is arranged on a first moving device 24. The first moving device 24 includes an x-axis moving track 240 and a y-axis moving track 242. Through the control of the control device 50, the carrier 20 can be positioned on the x-axis and the y-axis. Move freely.

Please refer to the first to fifth figures together, the heating device 30 is arranged on one side of the stage 20. In this embodiment, the heating device 30 is located above the stage 20, and the heating device 30 is arranged on a third moving device. On 62, the third moving device 62 includes a z-axis moving track 620 to control the heating device 30 to move up and down relative to the carrier 20 above the carrier 20. As shown in FIG. 4 and FIG. 5, the heating device 30 includes a power supply 32, an induction coil 34 and a magnetic directional sleeve 36. The power supply 32 is connected to the control device 50, and the power supply 32 receives the control of the control device 50. The induction coil 34 is connected to the power supply 32. In this embodiment, the induction coil 34 is a spiral induction coil made of copper tube induction coil. The magnetic directional sleeve 36 covers the induction coil 34, and the magnetic directional sleeve 36 is a tapered magnetic directional sleeve. The tip of the tapered magnetic directional sleeve is aligned with the solder on the circuit board 22. When the power supply 32 supplies power to the induction coil 34 At this time, the magnetic directional sleeve 36 can concentrate the magnetic flux generated by the induction coil 34 to conduct magnetism to the solder to generate electromagnetic induction, so as to heat the solder to melt the solder. In this embodiment, the diameter of the tip opening of the tapered magnetic pointing sleeve is at least 2 millimeters (mm). Of course, the diameter of the tip opening can be changed with the heating target range, and not only the above-mentioned at least 2 millimeters (mm) limit. The design of the tapered magnetic directional sleeve 36 can accurately align the solder heating on one of the micron-sized solder holes in the circuit board 20 to concentrate and limit the magnetic flux range of the induction coil 34, which can improve the accuracy of solder alignment . In addition, the magnetic directional sleeve 36 is made of an iron-based amorphous magnetic directional sleeve or a soft ferrite magnetic directional sleeve with high resistivity and high magnetic permeability. Ferrite materials, as long as the permeability is between 1500μ and 2500μ, can effectively improve the benefits of electromagnetic induction, and use iron-based amorphous magnetic directional sleeves or soft ferrite magnetic directional sleeves and other high-resistance materials , It can prevent the temperature of the magnetic direction sleeve 36 from being too high, and the maximum working temperature is only 160 degrees Celsius, which can prevent the electronic components from being damaged due to the high temperature.

Please continue to refer to the fourth and fifth diagrams. The moving device 40 is inserted inside the induction coil 34. The moving device 40 may be a vacuum suction nozzle, which includes a suction nozzle tube 44, and the moving device 40 provides moving electronic components. As shown in the figure, the moving device 40 is disposed on the second moving device 31, and the second moving device 31 includes a z-axis moving track 310 to control the moving device 40 to move above the carrier 20 relative to the carrier 20 to move up and down. In this embodiment, a buffer spring 42 is provided on the transfer device 40. When the electronic component touches the transfer device 40 due to the thermal expansion of the heating device 30, the buffer spring 42 can give a buffering effect to avoid the transfer device 40. The electronic components are pressed strongly, causing damage to the electronic components.

Please refer to the third figure, in which the nozzle tube 44 of the transfer device 40 is further connected to the air-jet device 90. In the unillustrated embodiment, the air-jet device 90 can be installed on one side of the power supply 32, and the air-jet device 90 The air port is connected to the suction nozzle tube 44 of the transfer device 40, so that the air jet device 90 receives the control of the control device 50 to spray inert gas to the suction nozzle tube 44 of the transfer device 40.

Please continue to refer to the third to fifth figures, the image capturing device 60 can be a camera. The image capturing device 60 is connected to and receives the control of the control device 50, and the image capturing device 60 and the heating device 30 are set together on a third moving device 62, and the third moving device 62 receives the control of the control device 50 to make the image capturing device 60 moves up and down on the z-axis above the stage 20. In addition, in this embodiment, the second mobile device 31 is also provided on the third mobile device 62.

The distance sensor 70 is arranged adjacent to the heating device 30, and the distance sensor 70 is also arranged on the third mobile device 62, and is connected to the control device 50 to receive the control measurement of the control device 50 and the relative distance between the electronic components, and generate A distance information. When the distance information is less than a preset distance information, such as less than 100 micrometers (µm), the control device 50 controls the third moving device 62 to stop the heating device 30 from approaching the electronic component.

Please refer back to the first to third figures. The repair module 80 includes an electronic component supply device 82, a component alignment camera 84, a component adjustment device 86, and a fourth moving device 88. The electronic component supply device 82 is connected to the control device 50 to receive the control of the control device 50 to supply new electronic components. The component turning camera 84 is a photographing device, and is connected to the control device 50 to receive the control of the control device 50 to perform photographing. The component adjustment device 86 is a steerable vacuum nozzle. The component adjustment device 86 is connected to the control device 50 to receive the control of the control device 50 to capture new electronic components to the front of the lens of the component correction camera 84, so that the component correction camera 84 captures the new electronics The component generates a new electronic component image to the control device 50, and the control device 50 compares the new electronic component image to adjust the direction of the new electronic component to match the direction required for installing the new electronic component. The fourth moving device 88 is disposed on the machine 10 and connected to the control device 50 to receive the control moving component adjustment device 86 of the control device 50. The fourth moving device 88 includes an x-axis moving track 880 to provide the component adjustment device 86 for The movement in the x-axis causes the control device 50 to control the fourth moving device 88 to install the new electronic component to the position of the damaged electronic component.

The above embodiment is used for the desoldering of printed circuit board (Printed circuit board, PCB), but when the circuit board is a flexible and lightweight polyester (PET) substrate, it cannot be produced by the heating device 30 of this embodiment. Magnetic heating. At this time, a magnetic conductive sheet (not shown in the figure) can be provided on the other side of the carrier 20 relative to the heating device 30, that is, under the carrier 20. In this embodiment, the magnetic conductive sheet is fixed on the machine table 10 and is coaxially magnetically directed to the sleeve 36 to forcibly guide the magnetic lines of force through the electronic components to heat the solder. The rest of the structure is the same as the above embodiment, so the description will not be repeated.

After describing the structure of the automatic welding system 1 of this embodiment, in order to enable a better understanding of the automatic welding system 1, continue to explain the use status of the automatic welding system 1 of this embodiment and how to achieve the de-soldering and move the electronic components. Or solder back the new electronic components for automatic repair.

Please continue to refer to the first to fifth figures to illustrate the state of the automatic welding system 1 in the process of unsoldering. First, the control device 50 controls the first moving device 24 to move the stage 20 to a position below the image capturing device 60.

Then the control device 50 controls the z-axis moving track 620 of the third moving device 62 to adjust the image capturing device 60 to move up and down relative to the stage 20, thereby adjusting the focal length of the image capturing device 60, and the control device 50 can control the image capturing The device 60 captures the circuit board image of the circuit board 22 on the carrier 20, and the image capturing device 60 transmits the circuit board image to the control device 50, so that the control device 50 can identify the damaged electronic components according to the circuit board image, and the control device 50 can capture Take the electronic component position information and the electronic component fixing direction information of the damaged electronic component.

The control device 50 then controls the first moving device 24 to adjust the position of the stage 20 according to the position information of the electronic component so that the heating device 30 is aligned with the damaged electronic component. At this time, the control device 50 can control the third moving device 62 The z-axis moving track 620 moves the heating device 30 downward to approach the damaged electronic components. Since the third mobile device 62 is provided with a distance sensor 70, the distance sensor 70 can continuously detect the relative distance to the electronic component and generate distance information. When the distance information is less than a preset distance information such as 500 microns ( When um) or less and 0 micrometer (um) or more, the control device controls the third moving device 62 to stop the heating device 30 from approaching the electronic components. At this time, the control device 50 controls the power supply 32 of the heating device 30 to generate electricity, so that the induction coil 34 generates a high-frequency magnetic field and emits electromagnetic waves. At the same time, it is matched with the magnetic directional sleeve 36 to generate induced current with the conductive magnetic solder on the electronic component , Such as tin solder produces electromagnetic induction, so that the solder is heated and melted.

Finally, the control device 50 controls the second moving device 31, and the moving and transporting device 40 picks up the de-soldering damaged electronic components, and moves to the waste bucket 12 on the machine 10 to discard the damaged electronic components to complete the desoldering work. .

In addition, the automatic welding system 1 can also automatically weld back new electronic components for repair. When the electronic components are soldered back, the control device 50 controls the electronic component supply device 82 of the repair module to supply new electronic components. Then the control device 50 controls the fourth moving device 88 to move the component adjustment device 86 to the electronic component supply device 82 to capture the new electronic component to the front of the lens of the component realignment camera 84, and provide the component realignment camera 84 to photograph the new electronic component. A new electronic component image is generated to the control device 50. The control device 50 compares the image of the new electronic component with the fixed direction information of the electronic component to generate a direction adjustment signal to the component adjustment device 86 according to the fixed direction information of the electronic component to adjust the direction of the new electronic component. To put it simply, the direction of the new electronic component will be adjusted so that the direction of the new electronic component is the same as the installation direction of the damaged electronic component. Finally, the control device 50 controls the x-axis moving track 880 of the fourth moving device 88 according to the electronic component position information to move the component adjusting device 86. The control device 50 then controls the first moving device 24 and moves the stage 20 according to the electronic component position information. The y-axis position of the new electronic component is installed to the position of the damaged electronic component, and the third moving device 62 is controlled to move the heating device 30 close to the solder of the new electronic component for soldering to complete the repair action. While installing new electronic components, the control device 50 also controls the jet device 90 to jet inert gas, such as jetting nitrogen to the nozzle tube 44 of the transfer device 40, so that the nitrogen gas is discharged from the nozzle tube 44 to stabilize the environment for installing electronic components.

In summary, this creation can automatically detect damaged electronic components, and automatically unsolder and remove the electronic components. At the same time, new electronic components can be soldered back, which can greatly improve chip yield detection and The efficiency of circuit board repair has also improved the efficiency of shipments. In addition, the heating device of this invention has high magnetic directivity, and with electromagnetic induction technology, it can melt only a single small area of solder for soldering or automatically remove unsoldered electronic components. In particular, the magnetic directional sleeve has good permeability, which can effectively enhance the benefits of electromagnetic induction, and the high resistance can prevent the magnetic directional sleeve from overheating, and prevent the magnetic directional sleeve from being affected by temperature and causing material embrittlement and loss of magnetism.

Only the above are only the preferred embodiments of this creation, and they are not used to limit the scope of implementation of this creation. Therefore, all equivalent changes or modifications made in accordance with the characteristics and spirit of the application scope of this creation shall be included in the scope of patent application of this creation.

1: Automatic welding system 10: Machine 12: Waste barrel 20: Stage 22: circuit board 24: The first mobile device 240: x-axis moving track 242: Y-axis movement track 30: heating device 31: The second mobile device 310: z-axis moving track 32: power supply 34: induction coil 36: Magnetic pointing sleeve 40: moving device 42: buffer spring 44: Nozzle tube 50: control device 60: Capture device 62: The third mobile device 620: z-axis moving track 70: Distance sensor 80: repair module 82: Electronic component supply device 84: The component is turned into the camera 86: Component adjustment device 88: The fourth mobile device 880: x-axis moving track 90: Jet device

The first picture is a three-dimensional view of this creative automatic welding system. The second picture is a side view of the automatic welding system for this creation. The third picture is the block diagram of this creative automatic welding system. The fourth picture is a three-dimensional view of this creative heating device. The fifth picture is a cross-sectional view of the heating device of this creation.

1: Automatic welding system

10: Machine

12: Waste barrel

24: The first mobile device

30: heating device

31: The second mobile device

40: moving device

50: control device

60: Capture device

62: The third mobile device

70: Distance sensor

80: repair module

Claims (19)

An automatic welding system suitable for heating solder on a circuit board to remove electronic components on the circuit board. The automatic welding system includes: a carrier to carry the circuit board; and a heating device arranged on the circuit board. On one side of the carrier, the heating device includes: a power supply; an induction coil connected to the power supply; and a magnetic directional sleeve covering the induction coil, and the magnetic directional sleeve is aligned with the circuit board Solder, when the power supply is supplied to the induction coil, the magnetic directional sleeve concentrates the magnetic flux generated by the induction coil to conduct magnetism to the solder to generate electromagnetic induction to heat the solder; a moving device penetrates the induction coil The inner side of the coil is used to move the electronic component; and a control device that connects and controls the heating device and the moving device, and executes the above-mentioned control of the heating device to supply power to the induction coil and control the moving device to move the electronic The action of the component. The automatic welding system according to claim 1, wherein the carrier is arranged on a first moving device, and the first moving device is connected to and receives the control of the control device to move the carrier; wherein the moving device is arranged On a second mobile device, the second mobile device is connected to and receives the control of the control device to move the moving device. The automatic welding system according to claim 2, further comprising: a third mobile device connected to and receiving the control of the control device; and An image capturing device is arranged on the third mobile device, and the image capturing device is connected to and receives the control of the control device. The image capturing device can capture the circuit board to obtain a circuit board image and transmit the circuit board Image to the control device; wherein the control device recognizes the damaged electronic component based on the circuit board image; the control device recognizes the electronic component position information and the electronic component fixing direction information of the damaged electronic component; the control device According to the position information of the electronic component, the first moving device is controlled to move the carrier, so that the heating device and the moving device are aligned with the position of the damaged electronic component, so as to desolder the damaged electronic component. The automatic welding system described in claim 3 further includes a repair module, including: an electronic component supply device connected to the control device to supply new electronic components; a component turning camera connected to the control device; and a component The adjustment device is connected to the control device to receive the control of the control device and capture the new electronic component to the front of the lens of the component-turning camera. The control device controls the component-turning camera to photograph the new electronic component, and generate a new electronic component The control device for the image of the electronic component, the control device compares the image of the electronic component with the fixed direction information of the electronic component to generate a direction adjustment signal to the component adjustment device to adjust the new electronic component according to the fixed direction information of the electronic component The steering; and a fourth moving device connected to the control device and the component adjusting device to receive the control of the control device to move the component adjusting device, the control device controlling the fourth moving device according to the position information of the electronic component , Install the new electronic component to the location where the electronic component was damaged. The automatic welding system according to claim 3, wherein the second moving device, the heating device and the moving device are arranged on the third moving device. The automatic welding system according to claim 3, further comprising a distance sensor arranged on the third moving device, arranged adjacent to the heating device, and connected to the control device to receive the control of the control device, and The relative distance between the distance sensor and the electronic component is measured to generate distance information. When the distance information is less than a preset distance information, the control device controls the third moving device to stop the heating device from approaching the electronic component. element. The automatic welding system according to claim 1, wherein the heating device further includes a magnetic conductive sheet arranged on the other side of the carrier relative to the heating device, and the magnetic conductive sheet is coaxial with the magnetic directional sleeve. The automatic welding system according to claim 1, wherein the magnetic directional sleeve is an iron-based amorphous magnetic directional sleeve or a soft ferrite magnetic directional sleeve. The automatic welding system according to claim 1, wherein the magnetic directional sleeve is a tapered magnetic directional sleeve, and the diameter of the tip is at least 2 millimeters (mm). The automatic welding system according to claim 1, wherein the induction coil is a copper tube induction coil. The automatic welding system according to claim 1, wherein the moving device is a vacuum suction nozzle, which includes a suction nozzle tube. The automatic welding system according to claim 1, wherein the induction coil is a spiral induction coil. The automatic welding system according to claim 11, further comprising an air jet device connected to the control device, the air jet device communicates with the nozzle tube of the transfer device, and the air jet device receives the control device to spray inert gas to the nozzle tube . A heating device suitable for heating solder on a circuit board. The heating device includes: a power supply; an induction coil connected to the power supply; and a magnetic directional sleeve covering the periphery of the induction coil and a pair of magnetic directional sleeves When the solder on the circuit board is quasi, when the power supply is supplied to the induction coil, the magnetic directional sleeve concentrates the magnetic flux generated by the induction coil to conduct magnetism to the solder to generate electromagnetic induction to heat the solder. The heating device according to claim 14, wherein the magnetic directional sleeve is an iron-based amorphous magnetic directional sleeve or a soft ferrite magnetic directional sleeve. The heating device according to claim 14, wherein the magnetic directional sleeve is a tapered magnetic directional sleeve, and the diameter of the tip can be at least 2 millimeters (mm). The heating device according to claim 14, wherein the induction coil is a copper tube induction coil. The heating device according to claim 14, further comprising a magnetic conductive sheet arranged coaxially with the magnetic directional sleeve. The heating device according to claim 14, wherein the induction coil is a spiral induction coil.

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