表紙:市場データ - ユーティリティ規模・長期間のエネルギー貯蔵 - フロー/溶融塩/リチウムイオン/その他の高度電池、CAES、揚水発電、P2G:世界市場の分析と予測
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1005576

市場データ - ユーティリティ規模・長期間のエネルギー貯蔵 - フロー/溶融塩/リチウムイオン/その他の高度電池、CAES、揚水発電、P2G:世界市場の分析と予測

Market Data - Utility-Scale Long Duration Energy Storage - Flow, Molten Salt, Lithium Ion, and Other Advanced Batteries, Compressed Air Energy Storage, Pumped Hydro Storage, and Power-to-Gas: Global Market Analysis and Forecasts

出版日: | 発行: Guidehouse Insights (formerly Navigant Research) | ページ情報: 英文 35 Pages; 43 Tables, Charts & Figures | 納期: 即納可能 即納可能とは

価格
価格表記: USDを日本円(税抜)に換算
本日の銀行送金レート: 1USD=114.82円
市場データ - ユーティリティ規模・長期間のエネルギー貯蔵 - フロー/溶融塩/リチウムイオン/その他の高度電池、CAES、揚水発電、P2G:世界市場の分析と予測
出版日: 2021年05月03日
発行: Guidehouse Insights (formerly Navigant Research)
ページ情報: 英文 35 Pages; 43 Tables, Charts & Figures
納期: 即納可能 即納可能とは
  • 全表示
  • 概要
  • 図表
  • 目次
概要

据置型エネルギー貯蔵設備は、未来の脱炭素型電力網で重要な役割を果たすと考えられています。各国政府の政策や、ユーティリティ事業者の調達目標、監督官庁の活動といった要因により、より高レベルのUES (ユーティリティ規模のエネルギー貯蔵) の導入が進むと考えられています。また、電力容量のより大きいプロジェクトの計画も世界各地で進められています。

一方で、エネルギー貯蔵のどの要素が今後求められるのかについては、ほとんど合意がありません。特に、各々の電力網サービス・用途にとって最もコスト効率的なエネルギー貯蔵方法や放電期間については、その傾向が強くなっています。それでも、各国政府やユーティリティ企業が再生可能エネルギー発電向けに巨大な電力貯蔵設備の導入を計画しているため、将来の電力網には現状とは異なる、より幅広い種類のエネルギー貯蔵設備が必要となるでしょう。

当レポートでは、世界の長期エネルギー貯蔵の技術・市場動向について分析し、エネルギー貯蔵技術の概略や主な用途/サービス内容、各種技術の利点と欠点、市場の促進・抑制要因、全体的な市場規模の動向見通し (2021年~2030年)、技術別・用途別・放電時間別および地域別 (全7地域) の詳細動向、主要企業のプロファイルと主力製品/サービスの概要、といった情報を取りまとめてお届けいたします。

目次

第1章 エグゼクティブサマリー

第2章 市場の課題

  • 長期貯蔵用途
    • 再生可能エネルギーへのエネルギーシフト
    • 送電・配電資産の最適化
    • 予備容量
    • 弾力性とマイクログリッド
  • 市場の促進要因
    • 再生可能エネルギーの成長
    • 政府の支援
    • 競合技術の制約条件
  • 市場の抑制要因
  • 技術動向
    • CAES (圧縮空気エネルギー貯蔵)
    • フロー電池
    • ハイブリッドESS (エネルギー貯留装置)
    • LAES (液体空気エネルギー貯蔵)
    • 溶融塩電池
    • その他の高度なバッテリー
    • パワーツーガス (P2G:Power-to-Gas)
    • 揚水発電 (PHS)
    • 熱エネルギー貯蔵 (TES)

第3章 市場予測

  • 分析手法と前提条件
    • 新型コロナウイルス感染症 (COVID-19) 感染拡大の影響
  • 技術別の予測
  • 用途別の予測
  • 放電期間別の予測

第4章 結論・提言

第5章 頭字語・略語の一覧

第6章 目次

第7章 図表一覧

第8章 分析範囲・情報源・分析手法・注記

図表

LIST OF CHARTS AND FIGURES

  • Annual Installed Long Duration Energy Storage Capacity by Region, All Applicable Technologies, Durations, and Applications, World Markets: 2021-2030
  • Utility-Scale ESS CAPEX Assumptions by Technology, World Market Averages: 2020-2029
  • Annual Installed Long Duration Energy Storage Capacity by Technology, All Applications and Durations, World Markets: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application, All Applicable Technologies and Durations, World Markets: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Duration, All Applicable Technologies and Applications, World Markets: 2021-2030

LIST OF TABLES

  • Utility-Scale ESS CAPEX Assumptions by Technology, World Market Averages: 2020-2029
  • Annual Installed Long Duration Energy Storage Capacity by Region, All Applicable Technologies, Durations, and Applications, World Markets: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology, All Durations and Applications, World Markets: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application, All Durations and Applicable Technologies, World Markets: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Duration, All Applications and Applicable Technologies, World Markets: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Region, All Applicable Technologies, Durations, and Applications, World Markets: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Technology, All Durations and Applications, World Markets: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application, All Durations and Applicable Technologies, World Markets: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Duration, All Applications and Applicable Technologies, World Markets: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application and Duration, All Applicable Technologies, North America: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology and Duration, All Applications, North America: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application and Duration, All Applicable Technologies, North America: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Technology and Duration, All Applications, North America: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application and Duration, All Applicable Technologies, Western Europe: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology and Duration, All Applications, Western Europe: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application and Duration, All Applicable Technologies, Western Europe: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Technology and Duration, All Applications, Western Europe: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application and Duration, All Applicable Technologies, Eastern Europe: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology and Duration, All Applications, Eastern Europe: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application and Duration, All Applicable Technologies, Eastern Europe: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Technology and Duration, All Applications, Eastern Europe: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application and Duration, All Applicable Technologies, Asia Pacific: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology and Duration, All Applications, Asia Pacific: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application and Duration, All Applicable Technologies, Asia Pacific: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Technology and Duration, All Applications, Asia Pacific: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application and Duration, All Applicable Technologies, Latin America: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology and Duration, All Applications, Latin America: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application and Duration, All Applicable Technologies, Latin America: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Technology and Duration, All Applications, Latin America: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application and Duration, All Applicable Technologies, Middle East: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology and Duration, All Applications, Middle East: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application and Duration, All Applicable Technologies, Middle East: 2021-2030
  • Annual Long Duration Storage Deployment Revenue by Technology and Duration, All Applications, Middle East: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Application and Duration, All Applicable Technologies, Africa: 2021-2030
  • Annual Installed Long Duration Energy Storage Capacity by Technology and Duration, All Applications, Africa: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Application and Duration, All Applicable Technologies, Africa: 2021-2030
  • Annual Long Duration Energy Storage Deployment Revenue by Technology and Duration, All Applications, Africa: 2021-2030
  • Long Duration Energy Storage Application Details
目次
Product Code: MD-ULDS-21

Stationary energy storage is projected to play a major role in future decarbonized electricity grids around the world. Government policies, utility procurement targets, and regulatory bodies have begun to forecast greater levels of utility-scale energy storage (UES) deployments, with project sizes of larger power capacity also being planned around the world.

Simultaneously, there is little agreement on which attributes of energy storage will be required and valued over time, specifically the energy capacity or duration of energy storage that could be cost-effective for certain electricity grid services and applications. Nevertheless, as governments' and utilities' plans to deploy substantial amounts of new renewable energy generation mount, future electricity grids will likely require different types of energy storage than those being deployed as of this report's writing-particularly for long duration challenges and seasonal capacity challenges.

This ‘Guidehouse Insights report ’ examines the long duration energy storage market in seven major geographic regions, presenting a 10-year forecast and market sizing from 2021 through 2030. The report provides forecasts for the long duration storage market segmented by technology, application, and discharge duration. Covered technologies include flow batteries, compressed air energy storage (CAES), molten salt batteries, pumped hydro storage (PHS), power-to-gas (P2G), Li-ion batteries, and other advanced batteries. Applications included in the forecasts consist of capacity and reserves, transmission and distribution (T&D) asset optimization, solar energy shifting, and wind energy shifting. All forecasts are also segmented by duration for each region, technology, and application.

KEY QUESTIONS ADDRESSED:

  • What is driving demand for long duration energy storage?
  • What applications and grid services will long duration storage provide?
  • What is holding back the adoption of long duration energy storage?
  • Which technologies are suited for which long duration applications?
  • Which long duration technologies are expected to be the most widely deployed over the coming 10 years?
  • What are the advantages and disadvantages of each long duration energy storage technology?
  • Which companies are the leading developers of long duration energy storage?

WHO NEEDS THIS REPORT:

  • Advanced battery OEMs
  • Inverter and other balance-of-system vendors
  • Government and regulatory agencies
  • Nongovernmental organizations
  • IoT companies
  • Energy storage hardware vendors and technology firms
  • Renewable energy development financing companies
  • Smart grid controls and software companies
  • Utilities
  • Investor community

Table of Contents

1. Executive Summary

  • 1.1 Market Overview
  • 1.2 Market Forecasts

2. Market Issues

  • 2.1 Applications for Long Duration Storage
    • 2.1.1 Renewables Energy Shifting
    • 2.1.2 Transmission and Distribution Asset Optimization
    • 2.1.3 Reserve Capacity
    • 2.1.4 Resiliency and Microgrids
  • 2.2 Market Drivers
    • 2.2.1 Renewable Energy Growth
    • 2.2.2 Government Support
    • 2.2.3 Limitations of Competing Technologies
  • 2.3 Market Barriers
  • 2.4 Technology Trends
    • 2.4.1 CAES
    • 2.4.2 Flow Batteries
      • 2.4.2.1 VRFBs
      • 2.4.2.2 Zinc Bromide Batteries
      • 2.4.2.3 Iron Electrolyte Batteries
        • 2.4.2.3.1 ESS Inc. Case Study
      • 2.4.2.4 Other Flow Battery Technologies
    • 2.4.3 Hybrid ESSs
    • 2.4.4 LAES
    • 2.4.5 Molten Salt Batteries
    • 2.4.6 Other Advanced Batteries
    • 2.4.7 Power-to-Gas
    • 2.4.8 PHS
    • 2.4.9 Thermal Energy Storage

3. Market Forecasts

  • 3.1 Methodology and Assumptions
    • 3.1.1 Coronavirus Pandemic Impacts
  • 3.2 Forecasts by Technology
  • 3.3 Forecasts by Application
  • 3.4 Forecasts by Duration

4. Conclusions and Recommendations

5. Acronym and Abbreviation List

6. Table of Contents

7. Table of Charts and Figures

8. Scope of Study, Sources and Methodology, Notes