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Raytron Technical Review RESEARCH ARTICLE WP-07-11

Lightweight车辆电气系统

Lightweight Vehicle Electrical Systems

RAYTRON Technical Team1

1RAYTRON Group, China

发布日期: March 2026 版本: 1.0
DOI: 10.1000/raytron.WP-07-11

1. Introduction

1.1 Lightweighting Drivers

DriverImpact
Fuel efficiency~2% per 100 kg reduction
EV range~1% per 100 kg reduction
CO2 regulationsPenalties for weight
PerformanceBetter acceleration

1.2 Weight Targets

Vehicle TypeCurrent WeightTarget Reduction
ICE compact1200-1400 kg10-15%
ICE mid-size1500-1800 kg10-15%
EV1800-2500 kg15-20%

Chart placeholder

MEDIA TODO
Figure 1 Vehicle weight distribution showing electrical system contribution

2. Weight Reduction Imperative

2.1 EV Range Impact

Weight ReductionRange Increase
100 kg8-12 km
200 kg15-25 km
300 kg25-35 km

2.2 Cost Impact

FactorWeight vs Cost
Battery sizeWeight drives cost
StructureHeavier = more material
Fuel/EnergyWeight drives consumption

2.3 Regulatory Pressure

RegionCO2 TargetImplication
EU95 g/km by 2025Weight reduction needed
US49 MPG by 2026Weight reduction needed
ChinaNEV mandatesEV efficiency critical

3. Electrical System Weight

3.1 Weight Distribution

ComponentICE WeightEV Weight
Wiring harness30-50 kg50-80 kg
Battery cables-10-30 kg
Motors/actuators5-10 kg10-20 kg
Electronics5-10 kg10-15 kg
Total electrical40-70 kg80-145 kg

3.2 Wire Gauge Distribution

Gauge% of HarnessWeight Contribution
0.5 mm²30%20%
0.75 mm²25%20%
1.0 mm²20%20%
1.5 mm²+25%40%

3.3 High-Voltage Systems (EV)

ComponentWeight
HV cables15-30 kg
Connectors3-5 kg
Protection2-4 kg

Diagram placeholder

MEDIA TODO
Figure 2 EV high-voltage cable system weight breakdown

4. Lightweighting Strategies

4.1 Material Substitution

StrategyWeight SavingsCost Impact
Cu to CCA50-60%-15 to -25%
Cu to Al65%-20 to -30%
Optimized sizing10-20%Variable

4.2 Design Optimization

StrategyWeight Savings
Optimized routing5-10%
Integrated connectors5-10%
Topology optimization10-15%

4.3 System Integration

StrategyBenefit
Integrated modulesFewer wires
Zone architectureReduced length
Power over dataFewer conductors

5. Material Selection

5.1 Application Matrix

ApplicationRecommendedWeight Savings
Low-power signalCCA50-60%
Standard powerCCA50-60%
High-powerCCA (sized)40-50%
HV DC (EV)CCA or Al40-60%

5.2 Trade-off Analysis

FactorCuCCAAl
WeightHeavyLightLightest
CostHighModerateLow
TerminationEasyEasyDifficult
FlexibilityGoodGoodPoor

5.3 Implementation Priority

PriorityCircuit TypeApproach
1Low-current, long runsCCA maximum benefit
2High-current runsCCA with sizing
3Engine bayTemperature evaluation
4HV systemsApplication-specific

Diagram placeholder

MEDIA TODO
Figure 3 Material selection decision matrix for vehicle lightweighting

6. Conclusion

6.1 Summary

StrategyWeight Reduction
Material substitution40-60%
Design optimization10-20%
Combined approach50-70%

6.2 Implementation Approach

  1. Analyze current harness weight
  2. Identify substitution opportunities
  3. Size appropriately
  4. Validate performance
  5. Implement production

7. References

  1. ISO 6722. (2022). Automotive Wire Specifications.
  2. SAE J2954. (2020). Wire Harness Design.

FAQ

How much range improvement can lightweighting provide?

Each 100 kg weight reduction improves EV range by approximately 8-12 km. A 30 kg reduction in wiring weight could add 2.5-3.5 km range.

What is the best strategy for electrical system lightweighting?

Start with material substitution (Cu to CCA) for low-current circuits, optimize routing to reduce cable lengths, and implement zone architecture to minimize wire runs. Combined approach yields 50-70% weight reduction.

Should I use CCA or aluminum for vehicle lightweighting?

CCA is generally preferred over aluminum for automotive applications due to easier terminations, better flexibility, and compatibility with standard connectors. Aluminum may be considered for specific high-current applications.

What is the implementation priority for lightweighting?

Priority 1: Low-current, long runs (maximum benefit). Priority 2: High-current runs (CCA with sizing). Priority 3: Engine bay (temperature evaluation). Priority 4: HV systems (application-specific evaluation).

徐高磊

(Gaolei Xu)

资深材料科学家

资质荣誉

  • 锐创集团 CTO
  • 浙江省高层次人才特殊支持计划青年人才
  • 绍兴市"科技副总"
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  • 全国有色金属standards化技术委员会重金属分技术委员会(TC243/SC2)委员

国家standards(主要起草人) 查看官方

发明专利 检索专利

专业Section

CCA(CCA)技术 铜包钢(CCS)制造工艺 双金属复合材料 光伏焊带技术 电动汽车电池极耳材料 连续挤压技术

代表性论文

  • 轧制法制造金属层状复合材料的研究与Applications,《铝加工》2008年第3期
  • 铜铝复合带退火工艺的研究
  • 电缆用铜铝复合带制备工艺研究
  • 轧制铜/铝复合带材在退火过程中的界面组织演变

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