Since 2015, our development of wearable heating technology has focused on the structural engineering of heated gloves, integrating thermal systems, control electronics, and material science into a unified modular architecture.
The system is designed to support OEM and ODM manufacturing requirements across outdoor, consumer, and industrial cold-protection applications.
Its foundation is built on four integrated domains: heating generation, temperature regulation, material structure, and safety control.
🧠 Engineering Foundation
The technology platform is based on three core engineering domains that define the performance and scalability of the system:
Flexible carbon-based heating structures provide stable thermal output while maintaining mechanical flexibility suitable for wearable applications.
An embedded MCU control architecture regulates temperature behavior through multi-level control logic and real-time feedback adjustment.
A low-temperature power management system ensures stable energy delivery while maintaining operational safety under extended usage conditions.
These subsystems are designed to operate as a unified architecture rather than independent components.
🔧 Heating System Architectures
Ultra-Thin Liner Heating Architecture (JHG41)
This system is designed for inner-layer thermal integration within multi-layer cold protection systems.
The heating structure is embedded within a flexible textile base, allowing direct contact with the hand while maintaining compatibility with external protective layers.
It is optimized for low-power operation and stable thermal output under layered wearing conditions.
The structure maintains flexibility to support natural hand movement without introducing rigidity.
This architecture is typically integrated into modular cold-weather systems rather than used as a standalone heavy protection solution.
Dual Heating Architecture (JHG43)
This system distributes thermal output across both the palm and dorsal side of the hand, creating a balanced heat field around the entire hand surface.
Temperature behavior is regulated through an MCU-based control system that adjusts output dynamically based on real-time feedback conditions.
The heating response is designed for rapid activation and stable long-duration performance under variable outdoor environments.
The outer structure is designed for independent use without additional layering requirements.
This architecture is widely applied in commercial-grade outdoor and daily-use heating products.
Industrial Heavy-Duty Heating Architecture (JHG42)
This system is engineered for operation in extreme cold environments and high-intensity usage conditions.
The outer layer integrates reinforced natural and synthetic materials designed to withstand abrasion, moisture, and mechanical stress.
Thermal regulation is optimized for low-temperature stability, ensuring continuous operation in harsh environments.
Protection mechanisms are integrated to prevent overheating and electrical instability during prolonged use.
This architecture is primarily used in industrial protection systems and extreme outdoor operational environments.
⚙️ System-Level Engineering Modules
The heating system is supported by a flexible carbon-based thermal generation layer designed for consistent heat distribution across wearable surfaces.
Temperature regulation is managed through an embedded MCU control system capable of multi-level adjustment, continuous monitoring, and safety intervention under abnormal conditions.
Power delivery is designed for compatibility with both lithium battery systems and external power sources, allowing configuration flexibility based on application requirements.
Safety mechanisms are embedded at multiple levels, including current regulation, thermal limitation, and circuit protection to ensure operational stability.
The entire architecture is designed to be configurable at production level, allowing adaptation of thermal output, material selection, structural design, and external form factor.
🔗 System-Level Product Architecture
The JHG41 system represents a lightweight internal thermal layer designed for integration into multi-layer protective systems.
The JHG43 system represents a balanced dual-surface heating architecture optimized for commercial applications.
The JHG42 system represents a reinforced industrial-grade architecture designed for extreme environmental conditions.
Together, these three architectures form a continuous thermal product system covering lightweight, commercial, and industrial application ranges.
🏭 System Perspective
The competitiveness of wearable heating technology is determined by the integration of thermal generation, intelligent regulation, and material engineering within a scalable manufacturing framework.
Through modular system design, different product configurations can be derived from a unified engineering platform while maintaining consistency in performance and production scalability.
This approach enables adaptation across multiple market segments without requiring fundamental changes to the core thermal architecture.