Technical Solutions
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Six-Level Energy Efficiency Adaptive Synchronous Rectification Drive System
By adopting adaptive synchronous rectification technology, the system drastically reduces the power loss of power switch transistors during the conduction and switching processes. It can significantly lower the typical temperature rise of the synchronous rectification section compared with the conventional asynchronous rectification solution, effectively alleviating the local hot spot issue. This not only enhances the system's continuous operation capability in high-temperature environments, but
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Algorithm Platform for Mitigating Aging of Charger Components under High-Temperature Operating Conditions
The platform continuously collects the electro-thermal stress parameters of devices and dynamically optimizes their operating voltage and current trajectories based on the life prediction model, thereby reducing the annual failure rate of power devices at high temperatures and achieving active life management.
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High-Rate Charging Temperature Rise Prediction and Protection System
With a built-in thermal coupling model and real-time monitoring algorithm, the system continuously collects data of key temperature rise points and predicts the heat flow distribution. It then dynamically adjusts the output power at the millisecond level, narrows the temperature rise deviation under extreme operating conditions, and fundamentally ensures high energy efficiency and thermal safety.
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Graphene Patch Thermal Resistance Calculation Platform for High-Power Adapters
Through accurate calculation and simulation of the interfacial thermal resistance between core heat-generating devices and graphene heat-dissipating patches, the platform not only optimizes the design efficiency of the heat dissipation structure from the source, but also accurately predicts the hot spot temperature and steady-state distribution under different power loads, maximizing the power density and current output capacity within the safety threshold.
CATEGORIES
NEWs
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Six-Level Energy Efficiency Adaptive Synchronous Rectification Drive System
By adopting adaptive synchronous rectification technology, the system drastically reduces the power loss of power switch transistors during the conduction and switching processes. It can significantly lower the typical temperature rise of the synchronous rectification section compared with the conventional asynchronous rectification solution, effectively alleviating the local hot spot issue. This not only enhances the system's continuous operation capability in high-temperature environments, but
-
Algorithm Platform for Mitigating Aging of Charger Components under High-Temperature Operating Conditions
The platform continuously collects the electro-thermal stress parameters of devices and dynamically optimizes their operating voltage and current trajectories based on the life prediction model, thereby reducing the annual failure rate of power devices at high temperatures and achieving active life management.
-
High-Rate Charging Temperature Rise Prediction and Protection System
With a built-in thermal coupling model and real-time monitoring algorithm, the system continuously collects data of key temperature rise points and predicts the heat flow distribution. It then dynamically adjusts the output power at the millisecond level, narrows the temperature rise deviation under extreme operating conditions, and fundamentally ensures high energy efficiency and thermal safety.
-
Graphene Patch Thermal Resistance Calculation Platform for High-Power Adapters
Through accurate calculation and simulation of the interfacial thermal resistance between core heat-generating devices and graphene heat-dissipating patches, the platform not only optimizes the design efficiency of the heat dissipation structure from the source, but also accurately predicts the hot spot temperature and steady-state distribution under different power loads, maximizing the power density and current output capacity within the safety threshold.
Copyright © 2026-2027 Shenzhen Dipinle Technology Co., Ltd.
Copyright © 2026-2027 Shenzhen Dipinle Technology Co., Ltd.
