Rigid PCB
Your projects deserve the best—Magellan Circuits delivers premium Rigid PCBs crafted for precision, reliability, and performance. With 20+ years of expertise, you can count on us for cost-effective solutions tailored to your needs.
High-Quality Rigid PCB Manufacturer
Magellan Circuits, located in Shanghai, China, with more than 20 years Rigid PCB fabrication experience, specializes in producing high-precision printed circuit boards. Our 28,000 square meter facility enables us to provide professional, reliable, and efficient services to high-tech enterprises worldwide. With certifications including but not limited to ISO 9001, UL, ISO 14001, ISO/TS 16949:2009, OHSAS 18001, and IATF 16949:2016, we guarantee top-quality and durable products.
Rigid PCB Fabrication Capability
At Magellan Circuits, we offer a wide range of Rigid PCBs known for their superior quality and durability. Our rigid PCBs are designed to meet the diverse needs of various industries, ensuring robust performance and reliability. Whether you need single-layer or multi-layer rigid PCBs, we provide customized solutions that meet your specific requirements.
Board Parameters for Rigid PCB
| Feature | Standard | Advanced |
|---|---|---|
| Material | FR2, CEM-1, CEM-3, FR4 (Standard/Halogen Free/High Performance),Contact Us for more. | Contact us |
| Layer Count | 1-30 | 1-40 |
| Min Board Thickness | .012'' (0.30 mm) | .008'' (0.20 mm) |
| Max Board Thickness | .158'' (4 mm) | .393'' (10 mm) |
| Min Dielectric Layer Thickness | .002'' (0.05 mm) | .001''(0.025 mm) |
| Maximum Delivery Size | 24'' x 20'' (609 mm x 508 mm) | 47'' x 22'' (1204 mm X 560 mm) |
|
Inner Layer Min Trace Width and Clearance |
.002'' (.05 mm) | .002'' (.05 mm) |
|
Outer Layer Min Trace Width and Clearance |
.002'' (.05 mm) | .002'' (.05 mm) |
| Alignment Tolerance Between Layers | .002'' (.05 mm) | .001''(.025 mm) |
| Min Mechanical Drilling | .006'' (0.15 mm) | .004''(.10 mm) |
| Through Hole Aspect Ratio | 10:1 | 12:1 |
| Finished Hole Diameter Tolerance(PTH) | ± .003'' (± 0.076 mm) | ± .002'' (± 0.05 mm) |
| Finished Hole Diameter Tolerance(NPTH) | ± .0015'' (± 0.0375 mm) | ± .001'' (± 0.025 mm) |
| Max Outer Layer Copper Thickness | 6 oz | 120 oz |
| Max Inner Layer Copper Thickness | 4 oz | 6 oz |
| Impedance Control Tolerance | ± 10% | ± 5% |
| Plated Through Hole Copper Filling | No | No |
| Through-Hole Copper Paste Plugging | Yes | Yes |
| Via-in-Pad | Yes | Yes |
| Laser Direct Imaging | Yes | Yes |
| Solder Mask Via Plugging IPC4761 Type 6 | Yes | Yes |
| Resin Via Plugging IPC4761 Type 6 | Yes | Yes |
| Resin Via Plugging IPC4761 Type 7 | Yes | Yes |
Surface Finish Parameters for Rigid PCB
| Feature | Standard | Advanced |
|---|---|---|
| Immersion Gold | Yes | Yes |
| Gold Finger | Yes | Yes |
| OSP | Yes | Yes |
| Immersion Silver | Yes | Yes |
| Leaded HASL | Yes | Yes |
| Lead-Free HASL | Yes | Yes |
| ENIG | Yes | Yes |
| Immersion Tin | Yes | Yes |
| Gold Finger + OSP | Yes | Yes |
| Gold Finger + Lead-Free HASL | Yes | Yes |
| OSP + Immersion Gold | Yes | Yes |
| Immersion Silver + Gold Finger | Yes | Yes |
| Immersion Tin + Gold Finger | Yes | Yes |
| ENEPIG | Yes | Yes |
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What are Rigid PCBs?
Rigid PCBs, or Rigid Printed Circuit Boards, are the most common type of PCBs and the most widely used in electronic or electrical devices. Unlike flexible PCBs, rigid PCBs are made from a solid substrate material that maintains the shape of the board over time. The primary material used in rigid PCBs is FR-4, a composite made of woven glass epoxy material with a flame-resistant resin binder.
Rigid PCBs are known for their durability and strength, making them suitable for use in a wide range of applications, from consumer electronics to industrial machinery. They are used in devices where the board must retain its shape during the device’s entire lifespan.
Why Choose Rigid PCBs?
Rigid PCBs provide a stable and reliable platform for electronic components, ensuring consistent performance over time. The rigidity of the board prevents bending and flexing that could otherwise damage the circuit and compromise functionality. This makes them ideal for applications requiring high reliability, such as medical devices and aerospace systems.
Rigid PCBs are designed to withstand harsh conditions, including high temperatures and mechanical stress. The solid construction of these boards means they can handle significant physical and environmental stress without degrading. This durability is crucial especially for industrial equipment and automotive applications where the PCB must perform reliably under tough conditions.
Rigid PCBs can be manufactured using established processes and materials, ensuring high quality and consistency in production. The manufacturing techniques for rigid PCBs are well-developed, allowing for efficient production at scale. This results in cost-effective manufacturing processes that benefit both the manufacturer and the end-user.
Due to their widespread use and established manufacturing processes, rigid PCBs can be produced cost-effectively. This makes them an economical choice for many applications, particularly in consumer electronics and telecommunications, where cost efficiency is critical.
Rigid PCBs can support a high density of components, making them ideal for complex and compact electronic devices. This is particularly important in applications like smartphones, computers, and other high-tech devices where space is limited but performance cannot be compromised.
With their robust design and high-quality materials, rigid PCBs offer excellent electrical performance and signal integrity. They are essential for high-speed and high-frequency applications, such as advanced driver-assistance systems (ADAS) in automotive and networking equipment in telecommunications. The controlled impedance and reduced signal loss contribute to the superior performance of rigid PCBs in these demanding applications.
Rigid PCB Applications
Rigid PCBs are widely used in several industries due to their durability, stability, and ability to support complex circuitry. Here are some key applications:
- Smartphones and Tablets: Used for the main circuitry due to their compact design and high reliability.
- Computers and Laptops: Essential for motherboards and other internal components.
- Home Appliances: Found in devices like TVs, microwaves, and washing machines where durability is critical.
- Engine Control Units (ECUs): Required for robust and stable performance in high-temperature environments.
- Infotainment Systems: Provide the backbone for audio and video processing circuits.
- Advanced Driver-Assistance Systems (ADAS): Used in safety systems like collision detection and lane departure warning systems.
- Navigation and Control Systems: Necessary for reliable operation in extreme conditions.
- Communication Systems: Used in satellite and aircraft communication systems due to their stability and reliability.
- Diagnostic Equipment: Found in MRI machines, CT scanners, and other diagnostic tools that require precise and reliable operation.
- Monitoring Devices: Used in patient monitoring systems for critical and accurate readings.
- Machinery Controls: Essential for controlling complex machinery and automation systems.
- Power Supplies: Used in industrial power supply units due to their ability to handle high power loads.
- Networking Equipment: Found in routers, switches, and servers where high-speed data transmission is crucial.
- Base Stations: Used in mobile communication base stations to ensure stable and reliable operation.
- Solar Power Systems: Used in solar inverters and control systems for reliable energy conversion.
- Wind Turbines: Found in control units of wind turbines for efficient and stable energy generation.
FAQ
Materials:
- Rigid PCBs: Made from solid materials like FR4, providing stability and support.
- Flexible PCBs: Made from polyimide, allowing them to bend and flex while maintaining durability.
Bendability:
- Rigid PCBs: Inflexible and maintain their shape.
- Flexible PCBs: Can bend, twist, and fold, fitting into compact or irregular spaces.
Weight and Space Efficiency:
- Rigid PCBs: Heavier and occupy more space.
- Flexible PCBs: Lighter and occupy less space, ideal for compact designs and applications requiring weight reduction.
- Flexibility: Lack of flexibility limits use in applications needing bending or fitting into irregular shapes.
- Durability Under Stress: More susceptible to mechanical stress, shocks, and vibrations compared to flexible PCBs.
- Weight and Space Efficiency: Heavier and occupy more space, which is a disadvantage in weight-sensitive and space-constrained applications.
- Thermal Management: Challenges with heat dissipation, especially in applications that are not only compact but also high-power.
- Complexity in Assembly: Requires additional connectors and wiring when using multiple boards, increasing complexity and cost.
FR4: This is the most common material, made from woven fiberglass cloth and epoxy resin. It provides excellent mechanical strength and electrical insulation.
Copper Foil: Thin sheets of copper laminated onto the PCB’s insulating layers, creating the conductive pathways for electrical signals.
Prepreg: Semi-cured (B-stage) glass-epoxy material used as an insulating layer between the copper layers. It offers mechanical strength and electrical insulation.
Core: Fully cured (C-stage) glass-epoxy material with copper laminated on both sides, forming the inner layers of the PCB and providing additional structural stability.
Cyanate Ester Resins: Known for excellent electrical properties and thermal stability. Often blended with other resins to enhance performance.
Flame Retardants: Incorporated into epoxy resins to reduce flammability. Common examples include bromine compounds, though newer, halogen-free alternatives are also used due to environmental concerns.
Glass Cloth: Woven fiberglass provides reinforcement, adding mechanical and thermal durability to the dielectric material.
- Delamination:
Layers of the PCB can separate due to poor bonding or high thermal stress. To prevent this, use high-quality prepreg materials, ensure proper lamination processes, and control the thermal profiles during soldering. - Plating Voids:
Incomplete copper plating inside vias can cause electrical failures. To avoid this, clean holes thoroughly before plating, use optimized plating parameters, and perform regular inspections during the plating process. - Misregistration:
Misaligned layers can cause circuit connections to be off. Prevent this by using precise alignment tools and techniques during layering and lamination, and tightly control the mechanical movement of layers during manufacturing. - Insufficient Solder Mask Clearance:
Not enough clearance between the solder mask and pads can lead to solder bridging and short circuits. Follow proper design rules and regularly check for adequate clearance to prevent this issue. - Warping and Bowing:
Uneven cooling or stresses during manufacturing can cause the PCB to warp or bow. Use balanced copper distribution, appropriate cooling techniques, and ensure uniform material properties across the PCB to reduce this risk. - Conductive Anodic Filament (CAF) Formation:
CAF is caused by electrochemical migration along the glass fibers in the PCB. Prevent this by using materials with high CAF resistance, ensuring proper curing of the resin system, and maintaining a clean manufacturing environment. - Solderability Issues:
Weak solder joints can result from poor solderability. Mitigate this by using high-quality surface finishes, controlling oxidation levels of the pads, and ensuring correct application of solder paste.
Following testing methods, applied at various stages of the PCB manufacturing process, ensure the quality and reliability of rigid PCBs, helping to identify and address potential issues before the boards are used in final products.
1. Visual Inspection:
Immediately after the fabrication process, human operators or Automated Optical Inspection (AOI) machines perform a visual inspection to identify any visible defects in the PCB’s surface and patterns, ensuring pattern integrity, consistency, and dimensions.
2. Cross-Section Analysis:
After fabrication, this method involves cutting and polishing the PCB to examine internal structures like the quality of plating, presence of cracks, and layer alignment. It is crucial for evaluating the integrity of vias and internal connections.
3. Electrical Testing:
Following cleaning, electrical tests ensure all circuits are functioning correctly. This includes continuity tests to check for open or short circuits and impedance tests for controlled impedance traces. Dielectric constant (Dk) and dissipation factor (DF) are measured at different frequencies to verify the board’s electrical properties.
4. Thermal Cycling:
After electrical testing, thermal cycling tests the PCB’s ability to withstand temperature changes. The board is repeatedly heated and cooled to detect potential issues like copper barrel cracking and delamination, ensuring it can endure operational thermal stresses.
5. Solderability Testing:
Performed after the surface finish is applied and before assembly, this test evaluates the quality of the PCB’s surface finish to ensure it can form reliable solder joints. The test checks the PCB pads’ ability to accept solder and form strong connections.
6. Ionic Contamination Testing:
After cleaning and before final inspection, this test measures the levels of ionic materials left on the PCB, which can cause corrosion and electrical leakage over time. Ensuring low contamination levels is essential for the long-term reliability of the board.
7. Peel Strength Testing:
Conducted post-fabrication and before final inspection, peel strength tests measure the adhesion of copper layers to the PCB substrate. This ensures that the copper will not delaminate during use, expressed in pounds per square inch.
8. Flammability Testing:
Typically performed after fabrication and often by certified labs like UL, this test determines the PCB’s ability to resist catching fire. Common ratings like UL 94V-0 indicate that the material will self-extinguish quickly if ignited.
Ensuring the reliability of rigid PCBs is critical in electronic design and manufacturing. Implementing robust quality control processes throughout the production cycle helps identify and rectify defects early, ensuring high performance and longevity of the final product. Here are the key quality control processes in PCB manufacturing:
Material Selection:
- Use high Tg (glass transition temperature) materials like Tg170 for higher thermal stability and reliability, especially for PCBs with BGA components or more than six layers.
- Choose materials with low CTE (coefficient of thermal expansion) to minimize stress and potential delamination during thermal cycling.
Design Considerations:
- Layer Stackup: Proper layer stackup is crucial. For multilayer PCBs, ensure a balanced stackup to avoid warping. Use symmetrical layer designs to distribute stress evenly across the board.
- Via Structures: Implement the use of microvias and avoid stacking them. Use staggered via configurations to enhance mechanical strength and reliability.
Manufacturing Process Controls:
- Controlled Impedance: For high-frequency applications, ensure the correct impedance control by careful design and material selection. This helps maintain signal integrity and reduces the risk of failures due to impedance mismatches.
- Plating and Finishing: Ensure proper copper plating thickness, especially in vias, to prevent cracking and improve the overall mechanical robustness of the PCB.
Inspection and Testing:
- Automated Optical Inspection (AOI): Utilize AOI to consistently check for pattern integrity and dimensional accuracy, reducing the likelihood of defects slipping through manual inspection processes.
- Microsectioning: Regularly perform microsectioning to inspect internal layer connections and ensure proper lamination and via integrity.
Thermal Management:
- Thermal Cycling Tests: Conduct thermal cycling tests to evaluate the PCB’s performance under different thermal conditions. This helps identify potential issues with material expansion and contraction, which can lead to delamination or cracking.
- Heat Dissipation: Design the PCB to enhance heat dissipation. Place heat-generating components appropriately and use thermal vias and heatsinks where necessary to manage the thermal load.
Environmental Protection:
- Conformal Coatings: Apply conformal coatings to protect the PCB from moisture, dust, and other environmental contaminants. This is especially important for PCBs used in harsh environments.
- Proper Packaging: Ensure that the final assembly is well-protected against mechanical shocks and vibrations. Use appropriate packaging materials to cushion and protect the PCB during shipping and handling.
Reliability Testing:
- Highly Accelerated Life Testing (HALT): Implement HALT to uncover potential weaknesses by exposing the PCB to extreme thermal, mechanical, and electrical stress conditions. This helps improve the robustness of the design.
- Daisy-Chain Testing: Use daisy-chain testing for via reliability. This method helps in identifying weak interconnections, particularly in high-density interconnect (HDI) designs.
Ensuring that a PCB design meets industry standards involves a series of steps to verify and optimize the design for performance, reliability, and manufacturability. The following factors are to be considered when doing PCB design:
1.Follow IPC Standards:
The Institute for Interconnecting and Packaging Electronic Circuits (IPC) provides comprehensive standards for PCB design, manufacturing, and testing. Key standards include IPC-2221 for general PCB design and IPC-2222 for rigid PCB design. Adhering to these standards ensures your design meets widely accepted criteria.
2.Accurate Schematic Design:
Start with a complete and accurate schematic diagram. A well-organized schematic with clear signal flow and detailed notes facilitates a smoother PCB design process, ensuring signals flow logically and that critical components are properly placed.
3.Use Design Checklists:
Employ design checklists to verify that all aspects of the PCB meet necessary specifications. This includes but is not limited to correct hole diameters, appropriate pad sizes, proper component spacing, and adherence to clearance rules. Regular checklist reviews help catch errors early in the design process.
4.Conduct Design Rule Checks (DRC):
Perform automated design rule checks to ensure the PCB layout adheres to manufacturing capabilities and industry standards. DRCs identify potential issues such as spacing violations, incorrect trace widths, and other design flaws before production begins.
5.Thermal Analysis:
Conduct thermal analysis to ensure the PCB can handle operational heat. This involves simulating and evaluating the thermal performance of the PCB to prevent overheating and ensure reliable operation under expected temperature ranges.
6.Signal Integrity Analysis:
Perform signal integrity analysis to ensure proper impedance and minimize electromagnetic interference (EMI). This analysis helps maintain the quality of signal transmission, reducing the risk of signal degradation and ensuring reliable communication between components.
7.Power Integrity Analysis:
Ensure a stable power distribution network (PDN) by performing power integrity analysis. This involves modeling and simulation to verify that power delivery to all components meets requirements, minimizing noise and voltage drops.
8.Prototyping and Testing:
Create prototypes and conduct thorough testing to identify any issues in the design. This includes functional testing, performance testing, environmental testing, and compliance testing to relevant standards. Testing prototypes helps ensure the final design meets all performance and reliability requirements.
9.Collaboration with Fabricators:
Work closely with PCB fabricators throughout the design process. Their feedback on material selection, stackup configuration, and manufacturability can help refine the design to meet industry standards and improve the overall quality of the final product.
Quality control processes in PCB manufacturing are crucial to ensure the reliability and performance of the final product. The processes involve several steps, each designed to identify and rectify potential issues. Here is an overview of the key quality control processes:
Incoming Material Inspection:
- Raw materials such as copper-clad laminates and prepreg are inspected upon arrival. The inspection includes checking supplier certifications and conducting sampling tests for physical properties and cosmetic defects.
In-Process Inspection:
- Automated Optical Inspection (AOI): Used to verify pattern integrity, consistency, and dimensions. AOI provides a more consistent evaluation compared to manual visual inspections.
- Microsectioning: Involves taking a cross-sectional view of the PCB to inspect internal layers and ensure proper construction and interconnection.
Electrical Testing:
- Flying Probe Test: Used for low to medium volume production to test the electrical connectivity of the PCB.
- Bed of Nails Test: Suitable for high volume production, providing thorough testing of electrical connections across the board.
- Daisy-Chain Testing: For microvias and high-density interconnects (HDI), test coupons are used to evaluate the reliability of vias and connections under accelerated thermal cycling conditions.
Visual and Mechanical Inspection:
- Final inspection involves checking the mechanical dimensions, hole sizes, solder mask quality, and overall appearance. For high-reliability PCBs, a cross-section coupon is taken and stress-tested to check for cracking and correct plating thickness.
Environmental and Reliability Testing:
- Thermal Cycling: PCBs are subjected to thermal cycling to simulate the effects of soldering and rework processes. This helps identify potential issues related to base material degradation, copper dissolution, and delamination.
- Accelerated Life Testing: Includes tests like Highly Accelerated Thermal Shock (HATS) to evaluate the long-term reliability of the PCB under extreme conditions.
Final Quality Conformance Inspection:
- Verifies that the final product meets specified acceptability criteria. The inspections are defined by industry standards or customer requirements and often include reliability testing to ensure the PCB can withstand the intended operational environment.
Nonconforming Material Review:
- If a PCB does not meet the required standards, it is reviewed by a Material Review Board (MRB). The MRB determines whether the nonconforming PCB can be repaired, reworked, or scrapped. The goal is to eliminate the cause of discrepancies and prevent recurrence.
