➢ Can AI Data Centers save the power grid? All methods for grid stabilization and monetization through VPP integration revealed! ➢ Survive the 2030 power demand explosion. New strategies deciphered with IEA and OCCTO data! ➢ The shock of sub-PUE 1.1. The paradigm shift in DC design brought by liquid cooling transition and waste heat valorization! ➢ Is “24/7 CFE” achievable? The core of advanced PPAs and decarbonization with hydrogen fuel cells! ➢ From SMR direct connection to microgrids. Detailed explanation of next-generation power source models to escape grid dependency! ➢ Next-generation UPS sells “inertia.” New demand response rewards from battery utilization! ➢ Fusion of watts and bits. Integrated control technology for IT, power, and cooling through digital twins! ➢ Seize opportunities in power and DC special zones. Public-private collaborative grid enhancement projects and investment focus!

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📘 Book Overview Title: AI Data Center and Power Grid Symbiosis Strategy – New Infrastructure Breaking Through Grid Bottlenecks (AI Data Center and Power Grid Symbiosis Strategy) Publication Date: April 27, 2026 Format: A4 size, softcover, 129 pages Price: Book only (paperback) 110,000 JPY (tax included) Set Price (Book + PDF version CD): Book + CD (PDF version) 176,000 JPY (tax included) ISBN: 978-4-910581-86-6 Edited and Published by: CMC Research Inc.

📝 Features of This Book Sub-PUE 1.1, complete transition to liquid cooling, UPS inertia provision—AI DC design has evolved this far. Systematically organizes implementation technologies for integrated power, cooling, and IT control, and grid cooperative operation. Who will win in the era of power shortages? A must-read report for the era of grid bottlenecks.

◎ Upon Publication The advancement of physical AI and generative AI has fundamentally reshaped the thermal density and power design of data centers (DCs). Power demands exceeding 100kW per rack have rendered traditional air-cooling methods obsolete, making a complete transition to liquid and immersion cooling inevitable. However, technical challenges are not limited to facility interiors. How to integrate the enormous power consumed by DCs and the “heat” discharged from them with the grid and local communities will be central to future design philosophy. Next-generation DCs will require “Grid-Aware” operation. Next-generation UPS, linked with large-capacity batteries, will evolve from mere backup power sources into devices that provide inertia to the grid. Furthermore, real-time integrated control of IT load and power/cooling facilities using digital twins is an essential technology for achieving extreme efficiency below PUE 1.1. Moreover, initiatives to return waste heat as a resource to regional heat supply and industrial processes will not only maximize energy circulation efficiency but also be key to increasing the social acceptance of DCs. This report delves into the depths of modularization and integration approaches to optimize the collaboration between watts (power) and bits (data). It analyzes in detail the technical specifications that should become standard by 2030, anticipating the mandatory implementation of WUE (Water Usage Effectiveness) and CUE (Carbon Usage Effectiveness), which are practical challenges. CMC Research Department

📖 Book Structure/Table of Contents Overview Part I: Dramatic Transformation of Power Demand by AI and Data Centers Chapter 1: Exponential Increase in Power Consumption due to AI Infrastructure 1. The “Power Wall” beyond the AI Bubble 2. Scaling Law Trade-offs and Stabilization of Inference Demand 3. Chain Reaction of Global “Power Demand Shock” 4. Constraints and the “Grid Capacity” Wall in Japan 5. Technical Challenges: Extreme Pursuit of PUE and Sustainability 6. Paradigm Shift in Cooling Technology: End of Air Cooling and Inevitability of Liquid and Immersion Cooling 6.1 Physical Limits of Air Cooling Systems (The Air Wall) 6.2 Two Major Trends in Liquid Cooling Technology: DLC and Immersion Cooling 7. Adoption Barriers in Japan and Potential for “Waste Heat Utilization” 8. ±400VHVDC Power Distribution Revolution: Core Infrastructure Supporting the 1MW Rack Era 8.1 Physical Collapse of “200V Distribution” and Reality of Loss Calculation 8.2 Overview of Standards and Trends of Promoting Forces 8.3 Intermediate Layer Strategy 8.4 Technical Challenges and Conformity to International Standards Chapter 2: 2030/2050 Power Demand Forecast from IEA/OCCTO Data 1. Introduction 2. IEA: Global DC Power Demand Comparable to Total Japanese Demand 3. OCCTO “FY2025 Supply Plan”: The Shock of 13-fold Increase in DC Demand 4. Grid Capacity Wall: Concentration in the Tokyo Metropolitan Area and Area-specific Critical Points 5. Scenario Analysis: The Shock of “197TWh” in 2050 References/Sources Chapter 3: Gigantification of AIDC and Grid Bottlenecks 1. Grid Connection Waiting Lists and Transformation of Location Strategies 2. Global

FACT BOX

  • Source: PR TIMES
  • Category: New Product
  • Organizations: IEA / OCCTO