FPC Prototype in Humanized Way

Quick FPC, Rigid-flex PCB prototype and PCB Assembly

Flex PCB Blog
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What is FPC
Special attention points for flexible circuit wiring
Multilayer PCB Stack-up Basics | PCB Knowledge
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FPCway: Specialized manufacturer of flexible printed circuit boards and rigid-flexible printed circuits
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Control Impedance Between Rigid PCB and Flex PCB
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Normal Flex PCB Specifications
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Flex PCB Boards and Connectors
About RA Copper and ED Copper
Introduction of Flexible PCB
5 Tips For Designing Flexible PCB
Advantages of FPC (Flexible PCB)
Evolution of the Flex Printed Circuit Board
Benefits of Using Flex Circuit Boards
Why Rigid-Flex PCBs are Economical?
Flexible PCB vs Rigid PCB
Development of Flexible printed circuit board (FPC) market
Traditional Manufacture Engineering of FPC Substrate
Development Trend of FPC Board
Flex PCB and the Manufacturing
About Flex PCB design
About Flex PCB and Assembly
How to Ensure Flex PCB Design Success
How to Select the Appropriate FPC Materials?
The Differences In Rigid PCB, Flex PCB and Rigid-Flex PCB
Flex-Rigid PCB Design Guidelines
Beneficials for Polyimide Flex PCB Boards
About Stiffener on Flex PCB FPC circuit Boards
About ENIG and ENEPIG
PCB Surface Finish Comparison
Copper Thickness for FPC Boards
Interconnect Solutions for Flexible Printed Circuits and Etched Foil Heaters
Advantages and Disadvantages of Rigid-Flex PCB
About FPC Plating Process
About EMI shield design for Flex Printed Circuit Board
PCB Assembly Blog
How to solve the problem of PCB warping deformation after welding large copper bar?
About PCB Assembly
QFP and BGA and the Development Trend in PCB assembly
Why some components need be baked before reflow soldering
About Flex PCB Assembly
Manual Soldering in SMT Assembly Manufacturing Process
BGA Components and BGA Assembly
Quick Understanding for PCB Assembly Process
About SMT Assembly (Surface Mount Technology)
About THT Assembly (Through-Hole Technology)
About Reflow Soldering
About_Wave_Soldering
PCB Assembly Inspections and Tests
Panel Requirements for PCB Assembly
About SMT (Surface Mount Technology)
FPC Research Blog
Preparation of FPC based on ultrasonic spraying method_4_Experimental Results
Preparation of FPC based on ultrasonic spraying method_3_Experimental Procedure
Preparation of FPC based on ultrasonic spraying method_2_Experimental Platform and Principle
Preparation of FPC based on ultrasonic spraying method_1_abstract
Research on Layout Design Method of Ultra-thin FPC_4_Analysis of Layout Design Methods
Research on Layout Design Method of Ultra-thin FPC_3_Analysis of Layout Design Methods
Research on Layout Design Method of Ultra-thin FPC_2_Analysis of Layout Design Methods
Research on Layout Design Method of Ultra-thin FPC_1_introduction
Research progress on polyimide FPC_2_the field of FPC
Research progress on polyimide FPC_1_Introduction
Analysis of Vibration Characteristics of FPCBs _4_Summary
Analysis of Vibration Characteristics of FPCBs _3_Finite Element Analysis
Analysis of Vibration Characteristics of FPCBs _2_Theory of Vibration Analysis
Analysis of Vibration Characteristics of FPCBs Under Random Vibration_1_Introduction
Design Methods for FPCBs_5_Practical Application
Design Methods for FPCBs_4_Electrical Circuit Design and Examples
Design Methods for FPCBs_3_Structure Design Method and Examples
Design Methods for FPCBs_2_Component Selection Methodology and Examples.
Research on Design Methods for FPCBs
Application of MPW technique for FPCBs _4_Summary
Application of MPW technique for FPCBs_3_Experimental results
Application of MPW technique for FPCBs_2_Experimental setup
Application of MPW technique for FPCBs_1_Principle of MPW
Application of FPCB in PC motherboards_4_ Results and discussion
Application of FPCB in PC motherboards_3_ Numerical analysis
Application of FPCB in PC_2_ Experimentation
Application of FPCB in PC motherboards
A Bus Planning Algorithm for FPC Design _4_Experimental result
A Bus Planning Algorithm for FPC Design _3_Proposed Algorithm
A Bus Planning Algorithm for FPC Design _2_Preliminaries
A Bus Planning Algorithm for FPC Design _1_Introduction

Printed circuit boards (PCBs) connect electrical components together using discrete wiring, resulting in a complete and functional unit. PCBs can be as simple as one or two layers of copper circuits, but are far more likely to have many layers of circuitry. The layers are necessary for the designer to "route" all of the circuits between the components-where one, two, or even eight layers of circuitry may not be enough to complete their design and make all of their connections. 

 

While all circuit boards perform the same basic function as a substrate for the electronic components, the design and materials of their construction are the key distinguishing points. Circuit boards are custom-tailored to their particular application. 

 

The three main types of PCBs are Rigid PCB, Flexible PCB (or FPC board), and Rigid-Flex PCB. We tried to provide a clearer understanding of the differences and similarities between each type of PCB Boards. 

 

Rigid PCB vs. Flex PCB 

 

The most notable difference between rigid PCBs and flex PCBs can be inferred from their names. Rigid PCBs are inflexible, while flex PCBs can be bent or otherwise shaped to fit inside the designated system. Flexible circuits, when designed correctly, can also be flexed for hundreds of thousands of cycles repeatedly without failure. The increased versatility of flex boards typically comes at a higher cost, but they are essential for applications with limited space requirements, such as consumer electronics, medical devices, space and automotive applications. 

 

Rigid circuit boards are very popular largely due to their low cost. In conventional electronics, and particularly in consumer electronics, with greater space availability, manufacturers can save significantly by using rigid circuit boards. However, flexible PCBs are beginning to siphon market share from rigid circuit boards due to their versatility, among other advantages, such as: 

 

Flexibility. Flexible circuits can be bent, folded, and even creased to fit the end application, giving the designer the ability to have the circuitry fit the device, rather than the end device being built around the electronics and circuit boards. Flexible circuits are ideal for wearable electronics, for example. 

 

Connectivity. Flexible circuits provide greater connectivity between other circuit boards, electronic components and the user interface in electronic packaging. They can even provide connectivity in dynamic flex applications where the flexible circuit needs to flex continuously over the life of the device, so they are used extensively in laptop computers, foldable electronics, and display connectivity. 

 

Reduced weight. A lower weight circuit board results in a lighter end product, which is essential in today's electronics market where small, lightweight devices are preferred by electronic device designers and consumers. Flexible circuits are ideal for unmanned vehicles and drones, due to their very light weight. 

 

Durability. While rigid PCBs are typically thicker and fairly strong, flex PCBs absorb shocks and vibrations much more effectively than rigid PCBs. This contributes directly to long-term reliability, product life and functionality. Flexible circuits are used extensively in medical electronics, missile guidance systems, weapons, satellite and other applications requiring excellent environmental survivability. 

 

Resistant. While rigid PCBs are at risk of damage or warping from heat, chemicals, or radiation, flex PCBs are much more resistant to these detrimental environments. This explains their wide application in today's automotive electronics. 

 

With the differences between rigid and flexible PCBs in mind, we will now compare these PCB types with their hybrid counterpart, the rigid-flex PCB. 

 

Rigid-Flex PCB vs. Rigid PCB and Flex PCB 

 

As its name suggests, the rigid-flex PCB is a hybrid of both rigid and flex PCBs, and features the great qualities of both while eliminating many of their individual limitations. A rigid-flex PCB incorporates flexible materials in conjunction with rigid materials by layering flexible circuit substrates inside of the rigid circuit board materials, ultimately combining the versatility of flexible circuits with the stability, strength and circuit routing densities of rigid PCBs. This hybridization opens up a spectrum of possibilities for much more complex and mechanically challenging designs. 

 

Rigid-flex PCBs are a means to streamline the electronic design, by eliminating flexible cables, connectors and discrete wiring. The electrical performance of a rigid flex PCB is enhanced compared to its counterparts, because the circuits are integral to the overall construction. All of the electrical and mechanical connections are internally contained within the rigid-flex PCB, providing the electronics designer with much improved service reliability and electrical performance. 

 

While they do typically arrive at a higher cost than their flex and rigid board counterparts, the reliability, weight reduction, strength and space-saving advantages of rigid-flex boards are often ideal in certain applications, and outperform any other electronic packaging techniques. Ultimately, rigid-flex PCBs provide the best benefits of rigid and flex PCBs in one solution. Applications where rigid flex PCBs excel are: 

 

High-reliability applications. If an assembly will be exposed to excessive or repeated shock, or high vibration environments, connectors with flexible cables are more likely to fail. Rigid flex PCBs provide great reliability even when subjected to extreme vibration and shock applications. 

 

High-density applications. Within a small enclosure, it’s sometimes impossible to accommodate all of the cables and connectors that an electronic PCB design would require. Rigid flex boards can fold into very small, and very thin profiles, offering substantial space savings in these instances. 

 

Five or more rigid boards. If your application will ultimately involve five or more rigid boards connected to one another with flex cables, an integrated rigid flex solutionis often the optimal and most cost-effective choice. We FPCway professional in PCB Manufacture and PCB Assembly for Flex PCB, Rigid-flex PCB and Rigid PCB. Feel free to contact us sales@fpcway.com for more information.

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  • Based in Shenzhen China, FPCway is professional at Flex PCB,
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