3 Selection of Microwave Printed Boards 3.1 Copper foil type and thickness selection 3.2 Environmental Adaptability Selection 3.3 Machinability selection 5.1 Double-sided microwave printed board manufacturing without metallized holes: 5.2 Double-sided microwave PCB manufacturing with metallized holes: 5.3 Multilayer Microwave PCB Manufacturing: (Slightly)
The choice of microwave printed board substrate should first consider its dielectric properties, but at the same time must also consider the surface copper foil type and thickness, environmental adaptability, processability and other factors, of course, there are costs.
At present, the most commonly used copper foil thickness is 35μm and 18μm. The thinner the copper foil, the easier it is to obtain high picture precision, so a high-precision microwave pattern should use copper foil no larger than 18 μm. If a 35 [mu]m copper foil is used, excessively high pattern accuracy deteriorates the processability, and the defective product rate inevitably increases.
Studies have shown that copper foil types also have an effect on the accuracy of the graphics. Current copper foil types include rolled copper foil and electrolytic copper foil. Rolled copper foils are more suitable for producing high-precision patterns than electrolytic copper foils. Therefore, when ordering materials, you may consider selecting a rolled-up copper foil substrate board.
Existing microwave substrates have no problem with the standard ambient temperature range of -55°C to +125°C. However, two considerations should also be considered. One is whether or not the pores affect the choice of substrate. For microwave plates that require through-hole metallization, the larger the coefficient of thermal expansion of the Z-axis of the substrate, the higher the thermal expansion coefficient of the substrate. The greater the possibility of fracture, so under the premise of meeting the dielectric properties, Z should choose the substrate with a small thermal expansion coefficient (see Table 1 to Table 4); Second, the impact of humidity on the choice of substrate, substrate The resin itself has low water absorption, but after adding the reinforcing material, its overall water absorption increases, and it will affect the dielectric properties when used in a high-humidity environment. Therefore, the material with small water absorption should be selected when selecting the material (see the table A to Table 4), or take structural measures to protect.
As design requirements continue to increase, some microwave printed board substrates have aluminum backings. The appearance of such aluminum-lined substrates brings additional pressure on the manufacturing process, the graphic production process is complicated, the shape processing is complicated, and the production cycle is lengthened. Therefore, if possible, the aluminum-lined substrate is not used as much as possible. The substrate of the board.
As the ROGERS company's TMM series of microwave printed board substrate, is composed of ceramic powder filled thermosetting resin. Among them, the TMM10 substrate filled with more ceramic powder, the performance of the more brittle, to the graphics manufacturing and shape processing process is very difficult, easy to defect or the formation of internal cracks, the relatively low yield. At present, the method of laser cutting is used for the profile processing of the TMM10 plate, which has high cost, low efficiency and long production period. Therefore, where possible, consideration may be given to selecting RT/Duroid series substrate boards that ROGERS meets the corresponding dielectric properties.
4 Structural Design
Due to the increasingly complex shape of the microwave board, and the high dimensional accuracy required, the number of the same type of production is very large and it is necessary to apply the numerically controlled milling technology. Therefore, the characteristics of numerical control processing should be fully taken into account in the design of microwave plates. The internal angles of all processing sites should be designed as rounded corners to facilitate one-step forming. If it is really necessary to have a right angle, it can also be designed in the form of b in Figure 1, which is also convenient for processing.
The structural design of the microwave plate should also not pursue excessive accuracy because the non-metallic material has a large tendency of dimensional deformation, and the microwave plate cannot be required to be processed with precision of metal parts. The high-precision requirements of the form factor may largely be due to the fact that when the microstrip line is in contact with the profile, the deviation of the profile will affect the length of the microstrip line, thereby affecting the microwave performance. In fact, with reference to the foreign code design, the microstrip line edge should be kept 0.2mm from the edge of the plate edge, so as to avoid the effect of shape processing deviation.
5 Microwave Printed Board Manufacturing Process
Microwave printed boards are different from ordinary single and double-sided boards and multilayer boards. They not only play the role of structural components and connectors, but also more importantly function as signal transmission lines.
The manufacture of microwave printed boards is due to the number of microwave printed board layers, the characteristics of microwave printed board raw materials, metallized hole manufacturing requirements, final surface coating methods, line design features, manufacturing line accuracy requirements, manufacturing equipment and advanced medicine. Factors such as sex and other factors, the manufacturing process will be adjusted according to specific requirements. The patterned electroplated nickel gold process is subdivided into a positive electroplating process for patterned nickel electroplating and a negative electroplating process for electroplated nickel gold.
Therefore, the manufacturing process flow adopted for different types of microwave printed boards and their processing requirements are also different. The following is a brief description:
(1) The pattern surface is a silver/tin alloy (omitted)
(2) The pattern surface is electroplated nickel gold (positive plate process flow) (slightly)
(3) The pattern surface is electroplated nickel gold (negative plate process flow) (slightly)
(1) The pattern surface is a silver/tin alloy (omitted)
(2) The pattern surface is electroplated nickel gold (positive plate process flow) (slightly)
5.4 Process Description
(1) When the circuit pattern is interconnected, the plated nickel-gold plating process can be selected;
(2) In order to increase the manufacturing pass rate of microwave printed boards, the negative plating process flow of patterned nickel-gold plating is used as far as possible. Because of the positive electroplating process using electroplated nickel gold, if the operation is not properly controlled, there will be quality problems with nickel-plated gold plating.
(3) Microwave plate of ROGERS company brand RT/duroid 6010 substrate, due to the pattern after etching, line edge “long hair†phenomenon will occur, leading to product scrap, the positive plating process of using graphic nickel-plated gold plating ;
(4) When the manufacturing precision of the circuit is within ±0.02mm, the wet film manufacturing process shall be used in the corresponding places of each process;
(5) When the manufacturing precision of the circuit is more than ± 0.03mm, the dry film (or wet film) process can be used in the corresponding parts of each process;
(6) For tetrafluoroethylene microwave plates, such as ROGERS company RT/duroid 5880, RT/duroid 5870, ULTRALAM2000, RT/duroid 6010, etc., in the hole metallurgy, sodium naphthalene solution or plasma can be used for the treatment. The TMM10, TMM10i, RO4003, and RO4350 do not require activation pretreatment.
5 Conclusion
The manufacture of microwave printed boards is progressing towards the processing direction of FR-4 ordinary rigid printed boards. More and more rigid printed board manufacturing processes and technologies are being applied to the processing of microwave printed boards. The specific performance in the manufacture of multi-layer printed circuit boards, circuit manufacturing precision of the subtle, three-dimensional numerical control processing and surface coating diversification.
In addition, with the further increase of the types of microwave printed circuit board substrates and the continuous improvement of design requirements, we are required to further optimize the existing microwave PCB manufacturing process and keep pace with the times to meet the growing requirements of microwave PCB manufacturing. .
Source: The 14th Institute of China Electronics Technology Group Corporation Yang Weisheng
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