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800V EV Main Inverter

Electric Vehicle Powertrain Solution

800V EV Main Inverter Solution

Application: Electric Vehicles Technology: SiC MOSFET Voltage: 800V Platform Efficiency: >98%

Automotive Grade ✓

Next-Generation EV Powertrain

Revolutionary 800V electric vehicle main inverter solution leveraging CRRC Times Electric's advanced SiC MOSFET technology to deliver unprecedented efficiency, power density, and ultra-fast charging capability for next-generation electric vehicles.

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Ultra-Fast Charging

Enable 350kW+ charging speeds

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High Efficiency

>98% system efficiency achieved

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Power Density

50% size reduction vs Silicon

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Solution Overview

The 800V EV main inverter solution represents a paradigm shift in electric vehicle powertrain technology. By leveraging CRRC Times Electric's state-of-the-art SiC MOSFET modules, this solution enables automakers to achieve unprecedented performance metrics while meeting the stringent requirements of next-generation electric vehicles.

Key Benefits

Extended Range: Higher efficiency translates to 15-20% increase in driving range
Ultra-Fast Charging: 800V architecture enables 350kW+ DC fast charging
Reduced Weight: 50% lighter than equivalent Silicon-based systems
Compact Design: Higher power density enables smaller vehicle packaging
Cost Effective: Reduced cooling requirements lower total system cost
Future Ready: Scalable architecture for next-generation battery technologies

Target Applications

🚗 Premium EVs

🏁 Performance Vehicles

🚐 Commercial Vehicles

🚛 Electric Trucks

🚌 Electric Buses

⚡ Fast Charging Networks

Market Advantages

This solution addresses critical market needs in the rapidly evolving EV landscape:

Meeting consumer demand for faster charging and longer range
Enabling automakers to differentiate through superior performance
Reducing total cost of ownership through improved efficiency
Supporting global emissions reduction initiatives
Future-proofing investments in EV technology

System Architecture

Power Electronics Architecture

The 800V main inverter solution employs a three-phase, two-level voltage source inverter (VSI) topology optimized for SiC MOSFET operation:

Inverter Topology

Configuration: Three-phase, six-switch topology
Switching Frequency: 20-50 kHz (adjustable based on application)
Control Method: Space Vector PWM (SVPWM) for optimal harmonic performance
Dead Time: Optimized for SiC characteristics (<200ns typical)

Thermal Management

Cooling Method: Liquid cooling with optimized cold plate design
Thermal Interface: High-performance thermal interface materials
Temperature Monitoring: Integrated temperature sensors for each module
Derating Strategy: Intelligent power derating based on thermal conditions

Control System Architecture

Component	Function	Key Features
Main Controller	System control and coordination	Automotive-grade MCU, functional safety
Gate Drivers	SiC MOSFET gate control	Isolated drivers, fault protection
Current Sensors	Phase current measurement	High accuracy, low latency
Voltage Sensors	DC bus voltage monitoring	High voltage isolation
Position Sensor	Motor rotor position	Resolver or encoder interface

Safety and Protection

Functional Safety: ASIL-D compliance for critical functions
Overcurrent Protection: Hardware and software current limiting
Overvoltage Protection: Active clamping and monitoring
Thermal Protection: Multi-level thermal management
Isolation Monitoring: Continuous insulation resistance monitoring
Fault Diagnostics: Comprehensive fault detection and reporting

EMC and EMI Considerations

Optimized PCB layout for minimal loop inductance
Integrated EMI filter design
Shielding strategy for high-frequency noise suppression
Common-mode current management
Compliance with automotive EMC standards (CISPR 25)

Key Components

Primary Power Modules

Bill of Materials (BOM)

Component	Part Number	Quantity	Function	Key Specifications
SiC MOSFET Module	T-SiC-M1200	6	Main switching devices	1200V, 50A, 16mΩ
SiC Diode	T-SiCSBD-A1200	6	Anti-parallel diodes	1200V, 40A, Zero Qrr
Gate Driver IC	Recommended Partner	6	Gate drive control	Isolated, 15V/-5V output
DC Link Capacitor	Film Capacitor Bank	1	Energy storage	1000V, 500μF, Low ESR
Current Sensor	Hall Effect Sensor	3	Phase current measurement	±300A, 1% accuracy
Cooling System	Liquid Cold Plate	1	Thermal management	Optimized for SiC modules

Supporting Components

EMI Filter: Common-mode and differential-mode filtering
DC Link Precharge: Soft-start circuitry for capacitor charging
Contactors: High-voltage isolation switches
Fuses: Semiconductor protection fuses
Busbars: Low-inductance power distribution
Enclosure: IP67 rated housing with EMI shielding

Design Guidelines

Minimize parasitic inductance in power loop (<10nH)
Use symmetrical gate drive circuits for all phases
Implement temperature balancing across modules
Ensure adequate isolation distances (>8mm creepage)
Design for worst-case operating conditions

Performance Specifications

System Performance

Parameter	Value	Units	Conditions
Maximum Power	200	kW	Continuous at 25°C coolant
Peak Power	400	kW	30 seconds maximum
DC Bus Voltage	400-800	V	Operating range
Output Frequency	0-300	Hz	Motor dependent
Efficiency	>98	%	Rated power, 50°C
Power Density	15	kW/L	Including cooling
Switching Frequency	20-50	kHz	Configurable

Efficiency Characteristics

The SiC-based solution delivers superior efficiency across the entire operating range:

Peak Efficiency: >98.5% at rated power
Low Load Efficiency: >95% at 10% rated power
Efficiency Map: High efficiency across wide speed/torque range
Temperature Coefficient: <0.1%/°C efficiency degradation

Thermal Performance

Parameter	Value	Units	Notes
Junction Temperature	-40 to +175	°C	SiC MOSFET operating range
Coolant Temperature	-20 to +70	°C	System operating range
Thermal Resistance	0.08	K/W	Junction to coolant
Heat Dissipation	3-4	kW	At rated power

Dynamic Performance

Torque Response: <1ms for step changes
Speed Regulation: ±0.1% at steady state
Current Control Bandwidth: >1kHz
Overload Capability: 200% for 30 seconds
Regenerative Braking: Full power capability

Reliability Metrics

MTBF: >100,000 hours (automotive duty cycle)
Operating Life: 15+ years typical
Power Cycling: >500,000 cycles (ΔTj = 100K)
Vibration Resistance: 20g peak (5-2000Hz)
Shock Resistance: 50g, 11ms duration

Environmental Compliance

Protection Rating: IP67 (dust and water resistant)
Operating Altitude: Up to 3000m above sea level
Humidity: 95% RH non-condensing
Salt Spray: 96 hours (ISO 9227)
RoHS Compliance: Lead-free and environmentally friendly

Design Resources & Support

📄 Solution Documentation

Comprehensive design documentation and technical resources

Complete Solution Guide (PDF) Design Checklist (PDF) Bill of Materials (Excel)

🔧 Design Tools & Calculators

Engineering tools for system design and optimization

Thermal Design Calculator Efficiency Calculator EMI Design Guide

📐 Reference Designs

Proven reference designs and schematics

Circuit Schematics PCB Layout Guidelines 3D Mechanical Model

🧪 Test Reports & Validation

Comprehensive testing and validation documentation

Performance Test Report EMC Test Report Reliability Analysis

Engineering Support Services

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Custom Design Support

Tailored solutions for specific vehicle requirements

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Simulation & Modeling

Advanced simulation support for system optimization

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Prototyping Support

Rapid prototyping and proof-of-concept development

Training & Certification

SiC Technology Training: Comprehensive courses on SiC device characteristics
Design Workshops: Hands-on workshops for inverter design
Safety Training: High-voltage safety and functional safety training
Certification Programs: Professional certification in EV powertrain design

Development Timeline

Phase	Duration	Key Activities	Deliverables
Requirements Definition	2-4 weeks	System specifications, performance targets	Requirements document
Design & Simulation	6-8 weeks	Circuit design, thermal simulation, EMC analysis	Design package, simulation results
Prototyping	8-12 weeks	PCB fabrication, assembly, initial testing	Functional prototype
Validation & Testing	6-10 weeks	Performance testing, EMC testing, reliability testing	Test reports, certification
Production Support	Ongoing	Manufacturing support, quality assurance	Production documentation

Get Started

Ready to implement the 800V EV main inverter solution in your next project?

Schedule Consultation Access Technical Support

FAE

LiTong EV Solutions Team

Our Field Application Engineers specialize in electric vehicle powertrain solutions using CRRC Times Electric SiC technology. Contact our team for expert consultation and design support.