PCB reflow technology is an obvious trend in the development of PCB. Basically, traditional PCB inserts can also be reflowed, which is commonly referred to as through-hole reflow soldering. The advantage is that all welding points can be completed at the same time to minimize the production cost.
In the development of PCB, an obvious trend is reflow soldering technology. Basically, traditional inserts can also be reflowed, which is commonly referred to as through-hole reflow soldering. The advantage is that all welding points can be completed at the same time to minimize the production cost. However, the application of reflow soldering is limited by the temperature sensing element, whether it is an insert or SMD. People turn their attention to welding. In many applications, selective welding is used after reflow welding. This is a very effective way
Process characteristics of selective welding
The process characteristics of selective welding can be understood by comparing with wave soldering. The most obvious difference between the two is that the lower part of the PCB is completely immersed in the liquid solder in wave soldering, while in selective soldering, only some specific areas are in contact with the solder wave. Because PCB itself is a bad heat conduction medium, it will not heat and melt the solder joints of adjacent components and PCB areas during welding. Flux must also be pre coated before welding. Compared with wave soldering, the flux is only applied to the lower part of the PCB to be welded, not the entire PCB. In addition, selective welding is only applicable to the welding of plug-in components. Selective welding is a new method, and a thorough understanding of the selective welding process and equipment is necessary for successful welding.
Process of selective welding
Typical selective welding processes include: flux spraying, PCB preheating, dip welding and drag welding.
Preheating process
Flux coating process
Flux coating process plays an important role in selective welding. During welding heating and at the end of welding, the flux shall have enough activity to prevent bridging and PCB oxidation. Flux spraying The X/Y manipulator carries the PCB through the upper part of the flux nozzle, and the flux is sprayed to the PCB to be welded position. Flux has a variety of ways, including single nozzle spray, micropore spray, and synchronous multi-point/pattern spray. The most important thing for microwave peak selection welding after reflow welding sequence is accurate spraying of flux. The micro hole spray type will never contaminate the area outside the solder joint. The minimum flux spot pattern diameter of micro spot spraying is greater than 2mm, so the position accuracy of the flux sprayed and deposited on the PCB is ± 0.5mm, which can ensure that the flux always covers the welded part. The tolerance of the amount of sprayed flux is provided by the supplier. The technical specification should specify the amount of flux used, and it is generally recommended that the 100% safety tolerance range.
welding technology
There are two different selective welding processes: PCB drag welding process and dip welding process.
The selective drag welding process is completed on a single small tip solder wave. Drag welding process is suitable for welding in very close space on PCB. For example, for individual solder joints or pins, a single row of pins can be used for drag welding. The PCB moves on the solder wave of the solder tip at different speeds and angles to achieve the best welding quality. To ensure the stability of the welding process, the inner diameter of the welding nozzle is less than 6mm. After the flow direction of solder solution is determined, the welding nozzle is installed and optimized in different directions for different welding needs. The manipulator can approach the solder wave from different directions, i.e. 0 °~12 ° at different angles, so users can weld various devices on electronic components. For most devices, it is recommended that the tilt angle be 10 °.
Compared with the immersion welding process, the solder solution of the drag welding process and the movement of the PCB board make the heat conversion efficiency in welding better than that of the immersion welding process. However, the heat needed to form the weld connection is transferred by the solder wave, but the quality of the solder wave of a single nozzle is small. Only the temperature of the solder wave is relatively high can it meet the requirements of the drag welding process. For example, the soldering temperature is 275 ℃~300 ℃, and the pulling speed is generally acceptable, which is 10 mm/s~25 mm/s. Nitrogen is supplied in the welding area to prevent solder wave oxidation. Solder wave eliminates oxidation, so that the drag welding process can avoid bridging defects. This advantage increases the stability and reliability of the drag welding process.
The machine has the characteristics of high precision and high flexibility. The system designed with module structure can be customized completely according to the special production requirements of customers, and can be upgraded to meet the needs of future production development. The movement radius of the manipulator can cover the flux nozzle, preheating and solder nozzle, so the same equipment can complete different welding processes. The unique synchronous manufacturing process of the machine can greatly shorten the single board manufacturing process cycle. The ability of the manipulator makes this selective welding have the characteristics of high precision and high quality welding. Firstly, the highly stable precise positioning capability of the manipulator (± 0.05mm) ensures the repetition and consistency of the parameter height of each plate production; Secondly, the 5-dimensional motion of the manipulator enables the PCB to contact the tin surface at any optimized angle and orientation to obtain the best welding quality. The tin wave height measuring needle installed on the manipulator splint device is made of titanium alloy. Under the program control, the tin wave height can be measured regularly. The tin wave height can be controlled by adjusting the speed of the tin pump to ensure process stability.
Despite the above advantages, the single nozzle solder wave drag welding process also has shortcomings: the welding time is the longest among the three processes of flux spraying, preheating and welding. And because the solder joints are dragged one by one, the welding time will increase significantly with the increase of the number of solder joints, and the welding efficiency cannot be compared with the traditional wave soldering process. However, the situation is changing. The design of multiple welding nozzles can maximize the output. For example, the use of double welding nozzles can double the output, and the flux can also be designed as double nozzles.
The immersion selective soldering system has multiple solder tips and is designed one-to-one with PCB solder joints. Although it is less flexible than the manipulator type, its output is equivalent to the traditional wave soldering equipment, and its cost is lower than the manipulator type. According to the size of PCB, single board or multiple boards can be transferred in parallel, and all solder joints will be sprayed, preheated and welded in parallel at the same time. However, due to the different distribution of solder joints on different PCBs, special solder tips need to be made for different PCBs. The size of the welding nozzle should be as large as possible to ensure the stability of the welding process without affecting the adjacent components on the PCB. This is important and difficult for design engineers, because the stability of the process may depend on it.
The immersion selective welding process can be used to weld 0.7mm~10mm solder joints. The welding process of short pins and small size pads is more stable, and the possibility of bridging is also small. The distance between adjacent solder joint edges, devices and welding nozzles should be greater than 5mm. The main purpose of preheating in the selective welding process is not to reduce the thermal stress, but to remove the solvent pre drying flux, so that the flux has the correct viscosity before entering the solder wavefront. During welding, the influence of the heat carried by preheating on the welding quality is not a key factor. The PCB material thickness, device package specification and flux type determine the preheating temperature setting. In selective welding, there are different theoretical explanations for preheating: some process engineers believe that PCB should be preheated before flux spraying; Another view is that welding is carried out directly without preheating. Users can arrange PCB process flow of selective welding according to specific conditions.