I. Project Background & Core Requirements
Ensuring Continuity in Teaching:
The solution covers key areas such as multimedia classrooms, laboratories, and data centers. It enables seamless switching in the event of a power outage, preventing class interruptions and loss of research data.
Protecting Equipment:
Effectively mitigates the risks of damage caused by voltage fluctuations and power surges, ensuring long-term stable operation of precision instruments and teaching equipment.
Reducing Maintenance Costs:
Intelligent charge-discharge strategies extend battery lifespan. Combined with time-of-use electricity pricing, the solution helps reduce energy expenses and is suitable for education scenarios with limited budgets.
II. Intelligent Power Supply Architecture
- Tiered Power Supply Protection
Critical equipment such as data centers and research platforms maintain stable operation even during grid failures, avoiding data loss or class disruption.
- Smart Load Management
Integrated AI prediction module analyzes power usage trends and automatically switches between UPS and grid modes.
High-priority areas (e.g., teaching zones) are always ensured stable power supply.
Non-critical areas (e.g., overnight server rooms) enter deep sleep mode, achieving energy savings of over 40%.
- Flexible Scalability
Supports modular expansion using lead-acid or lithium battery units, adapting to the growth of classes or construction of new teaching buildings.
Preconfigured photovoltaic input ports allow integration with solar energy systems for green power consumption.
III. Custom Design for Campus Scenarios
- Seamless Deployment Experience
UPS main units are installed in power distribution rooms and integrated with campus ventilation and interior design.
All cables use flame-retardant materials and are routed through ceiling ducts, ensuring both safety and aesthetics.
- Multi-Layered Safety Mechanisms
Battery systems include hydrogen concentration monitoring and forced ventilation to eliminate fire risks.
Grounding resistance is controlled within ≤1Ω, meeting IEC 62305 Class II lightning protection standards.
- Phased Implementation Strategy
Phase I: Prioritizes coverage for the data center and core laboratory buildings.
Phase II: Extends to teaching buildings, gymnasiums, and dormitories, with construction scheduled during holidays to minimize disruptions.
IV. Integration of Industry-Education & Service Assurance
- Collaborative Innovation with Academia
Jointly develop UPS visualization teaching modules with partner universities, converting real-time operation data into teaching content to enhance practical learning.
Build campus microgrid training platforms to cultivate talents in renewable energy and power system maintenance.
- Reliable Service Assurance
Provide high-standard maintenance service for three years, including annual battery health checks and system inspections.
Offer regular training and emergency drills for teachers and administrative staff to strengthen campus response capabilities in power-related incidents.
- Phased Implementation Strategy
Phase I: Prioritizes coverage for the data center and core laboratory buildings.
Phase II: Extends to teaching buildings, gymnasiums, and dormitories, with construction scheduled during holidays to minimize disruptions.
Project Summary
This solution is centered on zero-interruption teaching, high safety and reliability, and energy-efficient sustainability. With a tiered intelligent power architecture, seamless system integration, and flexible scalability, it safeguards power supply for educational and research applications. By integrating industry and education resources with comprehensive support services, the solution accelerates the development of digital campuses and empowers the modernization of education in the new era.
