Highlighted Capability about Flex Rigid Flex PCB in RAYPCB

What is a Flex-Rigid PCB?

A flex-rigid PCB, also known as a rigid-flex circuit board, combines flexible and rigid board technologies into a single circuit board. Flex-rigid PCBs consist of multiple layers of flexible PCB (Flex PCB) substrate attached to one or more rigid PCB sections.

The flexible parts of the board can be folded or bent to fit the available space or shape requirements. The rigid areas of the board provide structural support and dimensional stability for components. This hybrid design enables the creation of PCBs with 3D configurations for use in applications with limited space or unique form factor requirements.

Key Advantages of Flex-Rigid PCBs

Flex-rigid PCBs offer several advantages over traditional rigid PCBs:

1. Reduced size and weight
2. Enhanced reliability due to elimination of connectors between flex and rigid sections
3. Improved signal integrity from shorter signal paths
4. Design freedom and flexibility to fit uniquely shaped enclosures
5. Simplified assembly since flexible and rigid sections are fabricated together
6. Cost savings from reduction in number of PCBs, connectors, and assembly steps

RAYPCB’s Flex-Rigid PCB Capabilities

RAYPCB is a leading manufacturer of advanced PCBs, including flex-rigid boards. With state-of-the-art equipment and extensive experience, RAYPCB offers comprehensive flex-rigid PCB Solutions to meet the most demanding requirements.

Materials and Layer Counts

RAYPCB supports a wide range of materials and layer counts for flex-rigid PCBs:

Feature	Capability
Flex PCB Materials	Polyimide (PI), Liquid Crystal Polymer (LCP)
Rigid PCB Materials	FR-4, High Tg FR-4, Rogers, Aluminium
Flex Layer Count	1-6 layers
Rigid Layer Count	2-16 layers
Hybrid Layer Count	Up to 22 layers total

RAYPCB’s material options enable the creation of flex-rigid PCBs suitable for various environmental conditions and performance requirements. The supported layer counts provide design flexibility for simple to complex circuits.

Minimum Feature Sizes

RAYPCB can manufacture flex-rigid PCBs with fine features for high-density designs:

Feature	Minimum Size
Flex PCB Trace Width/Spacing	3/3 mil
Rigid PCB Trace Width/Spacing	3/3 mil
Flex PCB Hole Size	8 mil
Rigid PCB Hole Size	8 mil
Flex PCB Outline Tolerance	±5 mil
Rigid PCB Outline Tolerance	±5 mil

With these capabilities, RAYPCB can produce flex-rigid PCBs with high-density interconnects and fine-pitch components. The tight tolerances ensure accurate and reliable manufacturing.

Rigid-Flex Bending and Folding

RAYPCB’s flex-rigid PCBs support various bending and folding configurations:

• Flex-to-install (bend once for installation)
• Dynamic flex (repeated bending during use)
• 180° folds
• 90° folds
• U-shaped folds
• Custom angles and shapes

The flexible sections of the PCB can be designed to accommodate the specific bending and folding requirements of the application. RAYPCB’s engineers can provide guidance on bend radius limitations and design best practices to ensure reliability.

Stiffeners and Shielding

To enhance the mechanical stability and electromagnetic shielding of flex-rigid PCBs, RAYPCB offers the following options:

• FR-4 stiffeners
• Aluminium stiffeners
• Copper shielding
• Conductive adhesives

Stiffeners can be added to the flexible sections to provide additional support and prevent excessive bending. Shielding options help to reduce electromagnetic interference (EMI) and improve signal integrity.

Surface Finishes and Soldermask

RAYPCB supports a variety of surface finishes and soldermask options for flex-rigid PCBs:

Feature	Options
Surface Finish	ENIG, Immersion Silver, Immersion Tin, OSP
Soldermask	LPI, Flex Ink
Soldermask Color	Green, Black, White, Blue, Red, Yellow

The choice of surface finish and soldermask depends on the specific requirements of the application, such as environmental conditions, solderability, and cosmetic appearance.

Controlled Impedance

For high-speed and RF applications, RAYPCB can fabricate flex-rigid PCBs with controlled impedance traces:

• Single-ended impedance: 50Ω, 75Ω, 100Ω
• Differential impedance: 90Ω, 100Ω, 120Ω
• Impedance tolerance: ±10%

Controlled impedance traces help to maintain signal integrity and reduce reflections in high-speed circuits. RAYPCB’s experience and advanced manufacturing processes ensure accurate and consistent impedance control.

Flex-Rigid PCB Design Considerations

When designing a flex-rigid PCB, there are several key factors to consider:

Bend Radius and Bend Cycle Requirements

The minimum bend radius and the expected number of bend cycles are critical parameters in flex-rigid PCB design. The bend radius should be as large as possible to minimize stress on the conductors and insulation. Repeated bending can cause fatigue and ultimately lead to failure.

RAYPCB recommends the following minimum bend radii:

Flex Layer Count	Minimum Bend Radius
1-2 layers	6x thickness
3-4 layers	8x thickness
5-6 layers	10x thickness

For dynamic flex applications, it is essential to use materials and designs that can withstand the expected number of bend cycles. RAYPCB can assist in selecting the appropriate materials and design techniques to meet the bend cycle requirements.

Panelization and Routing

Proper panelization and routing are essential for the successful manufacturing of flex-rigid PCBs. The panelization layout should consider the following:

• Rigid-to-flex transition areas
• Bend regions and bend directions
• Component placement and clearances
• Assembly and testing requirements

RAYPCB’s engineers can provide guidance on panelization and routing best practices to ensure manufacturability and reliability.

Component Selection and Placement

Component selection and placement are critical for flex-rigid PCBs, especially in the flexible regions. Components should be selected based on their ability to withstand the expected mechanical stresses and environmental conditions.

Some guidelines for component placement on flex-rigid PCBs include:

• Place components on rigid sections whenever possible
• Avoid placing components near bend regions
• Use low-profile and flexible component packages when necessary
• Consider the effects of component placement on the overall flexibility of the board

RAYPCB can provide recommendations on component selection and placement to optimize the performance and reliability of the flex-rigid PCB.

Flex-Rigid PCB Applications

Flex-rigid PCBs are used in a wide range of applications across various industries, including:

• Aerospace and defense
• Automotive
• Medical devices
• Consumer electronics
• Industrial equipment
• Wearable technology

Some specific examples of flex-rigid PCB applications include:

• Aerospace: Avionics, satellite systems, space vehicles
• Automotive: Infotainment systems, dashboard electronics, sensors
• Medical: Implantable devices, surgical instruments, wearable health monitors
• Consumer electronics: Smartphones, laptops, gaming devices
• Industrial: Robotics, automation systems, test and measurement equipment
• Wearables: Smartwatches, fitness trackers, AR/VR headsets

The unique capabilities of flex-rigid PCBs make them an ideal solution for applications that require high density, reliability, and flexibility in a compact form factor.

RAYPCB’s Flex-Rigid PCB Manufacturing Process

RAYPCB’s flex-rigid PCB manufacturing process follows a series of carefully controlled steps to ensure the highest quality and reliability:

1. Material selection and preparation
2. Inner layer processing
3. Lamination
4. Drilling and hole plating
5. Outer layer processing
6. Surface finish application
7. Soldermask and silkscreen
8. Routing and profiling
9. Electrical testing
10. Final inspection and packaging

Throughout the manufacturing process, RAYPCB employs strict quality control measures and advanced process controls to maintain consistency and adherence to customer specifications.

Frequently Asked Questions (FAQ)

1. What are the main advantages of using flex-rigid PCBs?

Flex-rigid PCBs offer several advantages, including reduced size and weight, enhanced reliability, improved signal integrity, design flexibility, simplified assembly, and cost savings due to the reduction in the number of PCBs, connectors, and assembly steps.

2. What materials does RAYPCB support for flex-rigid PCBs?

RAYPCB supports a wide range of materials for flex-rigid PCBs, including polyimide (PI) and liquid crystal polymer (LCP) for the flexible sections, and FR-4, high Tg FR-4, Rogers, and aluminum for the rigid sections.

3. What is the maximum number of layers that RAYPCB can manufacture for flex-rigid PCBs?

RAYPCB can manufacture flex-rigid PCBs with up to 6 flexible layers and 16 rigid layers, with a total combined layer count of up to 22 layers.

4. Can RAYPCB produce flex-rigid PCBs with controlled impedance?

Yes, RAYPCB can fabricate flex-rigid PCBs with controlled impedance traces for high-speed and RF applications. Supported impedance values include 50Ω, 75Ω, and 100Ω for single-ended traces, and 90Ω, 100Ω, and 120Ω for differential traces, with an impedance tolerance of ±10%.

5. What industries commonly use flex-rigid PCBs?

Flex-rigid PCBs are used in a wide range of industries, including aerospace and defense, automotive, medical devices, consumer electronics, industrial equipment, and wearable technology. They are particularly well-suited for applications that require high density, reliability, and flexibility in a compact form factor.

Conclusion

Flex-rigid PCBs offer a unique combination of flexibility and robustness, making them an ideal solution for a wide range of applications that demand high performance in challenging environments. With their extensive capabilities and experience, RAYPCB is well-positioned to provide state-of-the-art flex-rigid PCB solutions to meet the most demanding customer requirements.

By partnering with RAYPCB for flex-rigid PCB design and manufacturing, customers can benefit from advanced technology, expert support, and a commitment to quality and reliability. As the demand for compact, high-performance electronics continues to grow, flex-rigid PCBs are poised to play an increasingly important role in shaping the future of electronic packaging and interconnect solutions.