Modular Industrial and Commercial Energy Storage System : The Tailored Energy Storage Solution for Obsolete Industrial Infrastructure

Ⅰ. Energy Pain Points and Retrofitting Needs in Aging Industrial Parks​

1. ​High Electricity Costs​
• Significant peak-valley price disparity (e.g., peak: ¥1.2/kWh vs. valley: ¥0.3/kWh), with peak-hour consumption accounting for over 40% of total costs.
• Insufficient transformer capacity, coupled with prohibitively high expansion costs (over ¥500,000 per unit upgrade).
2. ​Spatial and Equipment Limitations​
• Compact layout leaves no reserved space for energy storage, making traditional containerized energy storage systems unfeasible.
• Aging equipment with low efficiency and lack of real-time monitoring, resulting in 20%-30% higher energy intensity than advanced factories.
3. ​Poor Power Supply Stability​
• Unexpected blackouts cause production interruptions, incurring annual losses exceeding millions; inadequate backup energy storage capacity.
4. ​Carbon Pressure and Policy Drivers​
• High reliance on traditional energy sources triggers surging carbon tax costs (e.g., annual emissions >1,500 tons risk million-level fines).
• Government subsidies (e.g., ¥0.5/kWh for energy storage) incentivize upgrades.

​II. ICESS Core Solutions​

1. ​Modular Energy Storage System: Overcoming Spatial Constraints​
• Ultra-slim design: ≤90cm-wide modular units (e.g., SigenStack) embed into building gaps/equipment interlayers without foundation modifications.
• Distributed load-bearing: Single-unit weight <300kg; two-person installation adapts to structural limits of aging plants.
• Scalable capacity: From 100kW/200kWh to 10MW+ (supporting Li-ion, flow batteries, etc.).
2. ​Integrated PV-Storage-Charging: Dynamic Energy Optimization​

3.​Multi-Timescale Energy Storage Configuration​

​III. AI-Driven Smart Management Platform​

• Real-time monitoring: Integrates PV, storage, and charging pile data for dynamic "source-grid-load-storage" visualization.
• AI-powered scheduling: Prioritizes green energy consumption; automatically dispatches storage/grid power during shortages; adjusts non-urgent production lines/charging pile load.
• Carbon management: Auto-generates emission reports aligned with industry standards; supports carbon credit trading.
• Smart O&M: Proactive fault alerts (>95% accuracy); automated work orders; 50% higher maintenance efficiency.

​IV. Retrofitting Implementation Roadmap​

1. ​Spatial Assessment & Design​
• Use BIM scans to identify idle space (e.g., gaps ≥90cm can deploy 1MWh systems).
2. ​Phased Deployment​
• Phase 1: Modular storage + smart charging piles (commissioned in 3 months for basic peak-shaving).
• Phase 2: Expand rooftop PV + long-duration storage (e.g., retrofit abandoned hydrogen tanks for LH₂ storage).
3. ​Policy & Funding Coordination​
• Secure local subsidies and green loans.

​V. Benefit Analysis​

​VI. Case Study: Mannheim Energy Hub Transformation​
​Pain Point: An 8-hectare retired coal plant site with dense underground pipelines; zero available land for new large-scale storage.
​Solution:

• Maximized existing infrastructure: Integrated original grid access points to deploy 50MW/100MWh LFP storage (zero new land use).
• Space-optimized embedding: 30 ISO-standardized containerized units retrofitted into abandoned plant structures.
  ​Benefits:
• ​Scalability & Capacity: Annual peak-shaving = 200% of local peak load; 100MWh storage powers critical industries >2 hours.
• ​Environmental & Economic Returns:
• Annual CO₂ reduction: 7,500 tons (equivalent to 3M liters of fuel saved or 85+ hectares reforested).
• Annual revenue >€1.5M via electricity arbitrage & grid frequency regulation services.