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Raytron Technical Review RESEARCH ARTICLE WP-06-10

Composite Conductors: Beyond Traditional Bimetals

RAYTRON Technical Team1

1RAYTRON Group, China

Published: March 2026 Version: 1.0
DOI: 10.1000/raytron.WP-06-10

1. Introduction

1.1 Beyond Bimetals

Diagram placeholder

MEDIA TODO
Figure fig1 Figure 1: Evolution from monometal to bimetal to composite structures
StructureLayersComplexity
Monometal1Simple
Bimetal2Moderate
Composite3+High

1.2 Why Composite Structures

GoalComposite Approach
Optimize multiple propertiesMultiple layers
Address specific needsTailored design
Achieve new performance levelsAdvanced architectures

2. Multi-Layer Structures

2.1 Three-Layer Conductors

ConfigurationPurpose
Cu-Ag-CuAg surface + Cu strength
Cu-Ni-CuNi barrier + Cu surfaces
Al-Cu-AgLightweight + conductivity + surface

2.2 Layer Functions

Diagram placeholder

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Figure fig2 Figure 2: Multi-layer conductor showing layer functions
LayerFunction
CoreMechanical properties
IntermediateBarrier, bond
SurfaceContact, corrosion

2.3 Examples

ConductorLayersApplication
Ag-Cu-Ag3Premium contacts
Cu-Ni-Cu3High-temp barrier
Al-Cu-Ag3Aerospace RF

3. Reinforced Conductors

3.1 Fiber Reinforcement

Fiber TypePurpose
Steel fibersStrength
Carbon fiberStrength + stiffness
Ceramic fiberHigh-temp strength

3.2 Composite Reinforced Aluminum Conductor (CRAC)

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Figure fig3 Figure 3: CRAC structure showing fiber reinforcement in aluminum matrix
ComponentFunction
Al matrixConductivity
Reinforcing fibersStrength
DesignOptimized sag

3.3 Advantages

PropertyReinforcedStandard
StrengthHigherLower
SagReducedHigher
TemperatureHigher capabilityStandard
WeightSimilarBaseline

4. Hybrid Designs

4.1 Mixed-Material Strands

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VIDEO TODO
Video 1: Hybrid conductor design and manufacturing process
Strand TypeMaterialFunction
Strength strandsSteel, compositeMechanical
Conductivity strandsAl, CuElectrical
CoreFiber, steelCentral support

4.2 Gap-Type Conductors

FeatureBenefit
Gap between layersTemperature independence
Steel coreHigh temperature capability
Al outerConductivity

4.3 HTLS (High Temperature Low Sag)

TypeTechnology
ACSSAnnealed Al on steel
TACSRThermal-resistant Al
ACCCComposite core
GAPGap-type design

5. Application Examples

5.1 High-Temperature Transmission

Diagram placeholder

MEDIA TODO
Figure fig4 Figure 4: High-temperature transmission conductor options
Conductor TypeMax TempApplication
ACSR100°CStandard
ACSS250°CHigh-capacity
ACCC180°CLow sag

5.2 Specialty RF

ApplicationComposite Solution
High-power RFAg-Cu-Ag for skin effect
Corrosive environmentsMulti-layer protection

5.3 Weight-Critical Applications

ApplicationComposite Design
AerospaceAl-Cu-Ag
UAVsComposite reinforced
SpaceOptimized materials

6. Conclusion

6.1 Summary

ApproachBenefitComplexity
Multi-layerOptimized propertiesHigher
ReinforcedEnhanced strengthModerate
HybridApplication-specificHigher

6.2 Design Philosophy

Composite conductors enable:

  • Property optimization beyond bimetals
  • Application-specific solutions
  • Performance breakthroughs

Trade-off: Higher complexity and cost

7. References

  1. CIGRE Technical Brochure 426. (2019). Conductors for High-Temperature Applications.
  2. IEEE 738. (2012). Calculation of Ampacity.
XU

Gaolei Xu

Senior Materials Scientist

Credentials & Honors

  • CTO, Raytron Group
  • Zhejiang Provincial High-level Talent Special Support Program - Young Talent
  • Shaoxing "Technology Vice President"
  • Shaoxing Science and Technology Commissioner
  • Member of National Technical Committee 243 on Heavy Metals (SAC/TC 243/SC2)

National Standards (Lead Author) View Official

Patents (Inventor) Search Patents

  • CN104959396A - Production Process of Copper Strip for Composite Contact Materials
  • CN106077125A - Production Process of Copper Profile for Magnetic Pole Coils
  • CN201410710206 - Conductive Material for High-speed Railway Traction Motors and Production Method
  • CN201310719717 - Method for Controlling Strip Shape of Copper Strip Blank by Continuous Extrusion
  • CN201310720126 - Device for Controlling Strip Shape of Copper Strip Blank by Continuous Extrusion
  • CN201310376884 - Five-in-one Copper Strip Edge Treatment Equipment for Transformers
  • CN201420184755 - Continuous Extrusion Die Flow Promotion Device
  • CN201320761640 - Continuous Extrusion Waste Cleaning Device

Areas of Expertise

Copper-Clad Aluminum (CCA) Technology Copper-Clad Steel (CCS) Manufacturing Bimetallic Composite Materials PV Ribbon for Solar Cells Battery Tab Materials for EV Applications Continuous Extrusion Technology

Selected Publications

  • Research and Application of Rolling Method for Manufacturing Metal Laminated Composites, Aluminum Processing Journal, 2008
  • Annealing Process Research of Copper-Aluminum Composite Strip
  • Research on Preparation Process of Copper/Aluminum Composite Strip for Cables
  • Interface Microstructure Evolution of Rolled Copper/Aluminum Composite Strip During Annealing

Mr. Xu Gaolei is a distinguished expert in non-ferrous metal processing with over 15 years of experience. He is recognized as a Young Talent under the Zhejiang Provincial High-level Talent Special Support Program. He leads R&D initiatives in bimetallic composite technologies and has contributed significantly to the standardization of copper and bimetallic materials in China.

Click standard/patent codes to view official documents

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