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Combining Industrial Design Aesthetics And Function
The synergy of technology, market, users, and aesthetics creates smarter, safer, more beautiful, and more diverse electric mobility tools. Deep insights into user needs, innovative fusion of technology and aesthetics, and a service model combining platformization and customization ultimately achieve a balance between high aesthetics, high performance, and high cost-effectiveness. Strong industrial design capabilities enable Yologo to provide more refined, attractive, and practical products, enhancing brand competitiveness.
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Development Capabilities Of Electronic Control Systems
The core of electronic control system development capabilities lies in achieving intelligence, efficiency, and safety, involving the selection and algorithm optimization of the main control chip MCU (such as BMS and VCU design), performance matching of power devices and auxiliary devices (high frequency, low loss), and the assurance of vehicle functional safety and information security.
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High-efficiency And Intelligent Motor
Based on the vehicle's electronic control system, precise decoupled control of current and torque is achieved, resulting in smooth and highly efficient power output. A permanent magnet synchronous motor is employed, utilizing meticulous design, high-permeability materials, and a high-performance FOC controller algorithm, along with integrated intelligent sensing, energy management, and control.
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Battery & BMS
High-energy-density NCM lithium batteries prioritize safety, long battery life, and high power output. They integrate advanced materials and intelligent management systems to achieve a balance between high safety and high energy density. Capable of withstanding high-rate discharge, they incorporate thermal management systems and boast long lifespans and high cycle lifespans.
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Strength And Vibration Testing
By simulating bumps and high-speed vibrations in a real road environment using a vibration test bench (vibration testing machine), the fatigue life, structural stiffness, stress in key components, and dynamic response of the bicycle frame under cyclic loading are evaluated to ensure that it can withstand long-term use without breakage or failure, thus guaranteeing riding safety.