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Factors Affecting the Electrical Conductivity of Carbon Fiber Composites

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Introduction

Carbon Fiber Type: The type of carbon fiber used significantly impacts the electrical conductivity due to variations in the Crystalline Structure and arrangement of carbon atoms.

Fiber Volume Fraction: Increasing the volume fraction of conductive fibers within the composite enhances conductivity by providing more paths for electricity.

Fiber Orientation: Aligning carbon fibers in the same direction increases conductivity compared to randomly oriented fibers.

Matrix Material: The choice of matrix material, such as Conductive Polymers or fillers, plays a crucial role in determining the composite's conductivity.

Manufacturing Process: The method used to fabricate the composites, such as Pultrusion or Roll-Wrapping, affects factors like fiber alignment and resin content, impacting conductivity.

Additives and Fillers: Introducing conductive additives like Carbon Nanotubes or Graphene can significantly enhance the composite's conductivity.

Carbon Fiber Type

PAN-based Carbon Fibers: These fibers are known for their high strength and stiffness, making them suitable for applications requiring high mechanical performance.

Pitch-based Carbon Fibers: These fibers offer high thermal and electrical conductivity, making them ideal for applications requiring efficient heat and electricity transfer.

Crystalline Structure: The arrangement of carbon atoms within the fibers affects their conductivity, with more ordered structures generally providing better conductivity.

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Figure 1: Carbon fiber. Image Source: http://www.bing.com/images/search

Fiber Volume Fraction

Higher Volume Fraction: Increasing the volume fraction of conductive fibers within the composite enhances conductivity by providing more paths for electricity.

Conductive Pathways: A higher volume of fibers creates more conductive pathways, similar to adding more highways in a city, resulting in elevated conductivity.

Fiber Orientation

Aligned Fibers: Aligning carbon fibers in the same direction creates a 'superhighway' for electricity, markedly increasing conductivity.

Random Orientation: Randomly oriented fibers result in lower conductivity compared to aligned fibers.

Manufacturing Importance: Proper fiber orientation during the manufacturing process is essential for maximizing conductivity.

Matrix Material

Conductive Polymers: Utilizing conductive polymers in the matrix material can enhance the overall conductivity of the composite.

Conductive Fillers: Integrating conductive fillers like carbon nanotubes or graphene into the matrix further improves conductivity.

Insulating Pathways: Replacing insulating pathways within the matrix with conductive ones significantly boosts the composite's conductivity.

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Figure 2: Carbon Fibre Composites box.Image Source: Matrix

Manufacturing Process

Pultrusion: This method involves pulling carbon fiber rovings through a heated die, ensuring uniformity in structure and mechanical properties.

Roll-Wrapping: This technique involves wrapping continuous carbon fiber prepreg around a mandrel, offering versatility in design and exceptional strength-to-weight ratios.

Process Impact: The manufacturing process influences factors like fiber alignment and resin content, which in turn impact the final conductivity of the composite material.

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Figure 3: Fiber composites manufacturing process.Image Source: Formlabs

Additives and Fillers

Carbon Nanotubes: Introducing carbon nanotubes into the composite matrix can significantly enhance its conductivity.

Graphene: Graphene serves as a conductive pathway within the composite, facilitating electron flow and augmenting overall conductivity.

Selection and Incorporation: Careful selection and incorporation of these additives are essential to tailor the conductivity of the composite according to specific application requirements.

Applications and Implications

Aerospace and Defense: Used for electromagnetic shielding and lightning strike protection in aircraft and defense systems.

Automotive: Electric and hybrid vehicles utilize conductive carbon fiber composites to dissipate static electricity and enhance safety in onboard electronics.

Renewable Energy: Applied in wind turbine blades and solar panels to facilitate efficient energy transfer and dissipation.

Sensors and Structural Health Monitoring: Carbon fiber tubes with tailored conductivity capabilities serve as versatile sensors for detecting pressure, strain, and temperature variations.

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Figure 4: Application of polymer based carbon fiber composites.