清潔能源微電網市場預測-全球清潔能源微電網部署預測（2022-2031）

在極端天氣、地震和野火等世界各地電網面臨的威脅日益增加的情況下，微電網提供的彈性預計將提供非凡的價值。

本報告調查全球清潔能源微電網市場，並提供預測期內的市場預測和商業模式等信息。

目錄

第 1 章執行摘要

• 微電網清潔能源
• 全球視野

第二章市場概述

• 市場定義
• 用於微電網的清潔能源 DER 選項
• 清潔能源微電網配置
• 市場促進因素
  • 降低儲能成本
  • 微電網控制器功能升級
  • 模塊化微電網的推進
  • 遠程微電網推動柴油補償
• 市場壁壘
  • 在微電網中引入可再生能源的問題
  • 對複原力的價值缺乏共識
  • 需要簡化互連程序
  • 控制器性能、成本、兼容性
• 為微電網選擇清潔能源 DER 選項的標準

第三章市場預測

• 調查方法
• 全球市場概覽
  • 清潔能源微電網容量預測
  • 清潔能源微電網支出預測
  • 清潔能源微電網容量：按清潔能源構成
  • 清潔能源微電網支出：按商業模式分類
• 區域市場概況
  • 北美
  • 歐洲
  • 亞太地區
  • 拉丁美洲
  • 中東/非洲

第 4 章結論/建議

第5章首字母縮略語列表

第6章目錄

第 7 章圖表

第八章調查範圍、來源及調查方法、備忘

In response to emerging threats to power grids globally-extreme weather events, earthquakes, and wildfires-the resiliency that microgrids provide offers special value. Microgrids can enable the integration of mixed asset fleets of distributed energy resources (DER) at the distribution grid, so they can subsequently be controlled as an ensemble. DER can be aggregated and used optimally through the microgrid platform, which allows for enhanced energy resiliency and reliability.

However, not all microgrids are powered by clean energy. Previously, diesel-based generators were deployed as assets for providing backup power supply and ensuring power reliability, as were other fossil fuel sources such as propane and kerosene. While these generator types provide reliability, they do not contribute to carbon reduction. Reducing carbon emissions while ensuring energy resilience requires clean energy microgrids.

This Guidehouse Insights report provides a market forecast of the global deployment of clean energy microgrids over the period 2022-2031. Clean energy microgrids are segmented based on their composition into 50%-clean energy microgrids-assets that leverage the natural gas infrastructure for delivering power, such as microturbines and fuel cells-and 100%-clean energy microgrids, which deliver power via solar, wind, and storage. Guidehouse Insights further reports on the business models that are used for deploying the clean energy microgrids over the forecast period.

KEY QUESTIONS ADDRESSED:

• What is driving the adoption of clean energy microgrids?

• What market barriers are clean energy microgrids facing?

• What are the key criteria for the selection and deployment of DER in clean energy microgrids?

• How does the clean energy microgrid market vary by region?

• What is the expected clean energy microgrid deployment capacity and spending in 2031?

• How many clean energy microgrids will depend on natural gas infrastructure in 2031?

• Which business models are expected to account for most of clean energy microgrid deployment in 2031?

WHO NEEDS THIS REPORT:

• Manufacturers of DER technologies
• Energy storage vendors
• Solar PV companies
• Microgrid developers
• Microgrid integrators
• Utilities
• Regulators
• University researchers
• Investor community

Table of Contents

1. Executive Summary

• 1.1. Clean Energy Resources for Microgrids
• 1.2. Global Outlook

2. Market Overview

• 2.1. Market Definition
• 2.2. Clean Energy DER Options for Microgrids
• 2.3. Clean Energy Microgrid Configurations
• 2.4. Market Drivers
  • 2.4.1. Energy Storage Cost Reduction
  • 2.4.2. Upgrades Made to Microgrid Controller Functionality
  • 2.4.3. Impetus for Modular Microgrids
  • 2.4.4. Remote Microgrids Facilitating Diesel Offsets
• 2.5. Market Barriers
  • 2.5.1. Complications with Renewable Energy Deployment in Microgrids
  • 2.5.2. Lack of Consensus on the Value of Resiliency
  • 2.5.3. Need for Streamlined Interconnection Procedures
  • 2.5.4. Controller Performance, Costs, and Compatibility
• 2.6. Selection Criteria of Clean Energy DER Options for Microgrids

3. Market Forecasts

• 3.1. Methodology
• 3.2. Global Market Overview
  • 3.2.1. Clean Energy Microgrid Capacity Forecast
  • 3.2.2. Clean Energy Microgrid Spending Forecast
  • 3.2.3. Clean Energy Microgrid Capacity by Clean Energy Composition
  • 3.2.4. Clean Energy Microgrid Spending by Business Model
• 3.3. Regional Market Overview
  • 3.3.1. North America
  • 3.3.2. Europe
  • 3.3.3. Asia Pacific
  • 3.3.4. Latin America
  • 3.3.5. Middle East and Africa

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

LIST OF CHARTS AND FIGURES

• Clean Energy Microgrids Capacity by Region, World Markets: 2022-2031
• Clean Energy Microgrids Spending by Region, World Markets: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, World Markets: 2022-2031
• Clean Energy Microgrid Spending by Business Model, World Markets: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, North America: 2022-2031
• Clean Energy Microgrid Spending by Business Model, North America: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Europe: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Europe: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Asia Pacific: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Asia Pacific: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Latin America: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Latin America: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Middle East & Africa: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Middle East & Africa: 2022-2031
• Sample DER Assets for Microgrids with Point of Common Coupling
• Technology Maturation Index for DER

LIST OF TABLES

• Clean Energy Microgrids Capacity by Region, World Markets: 2022-2031
• Clean Energy Microgrids Spending by Region, World Markets: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, World Markets: 2022-2031
• Clean Energy Microgrid Spending by Percentage Clean, World Markets: 2022-2031
• Clean Energy Microgrid Capacity by Business Model, World Markets: 2022-2031
• Clean Energy Microgrid Spending by Business Model, World Markets: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, North America: 2022-2031
• Clean Energy Microgrid Spending by Percentage Clean, North America: 2022-2031
• Clean Energy Microgrid Capacity by Business Model, North America: 2022-2031
• Clean Energy Microgrid Spending by Business Model, North America: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Europe: 2022-2031
• Clean Energy Microgrid Spending by Percentage Clean, Europe: 2022-2031
• Clean Energy Microgrid Capacity by Business Model, Europe: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Europe: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Asia Pacific: 2022-2031
• Clean Energy Microgrid Spending by Percentage Clean, Asia Pacific: 2022-2031
• Clean Energy Microgrid Capacity by Business Model, Asia Pacific: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Asia Pacific: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Latin America: 2022-2031
• Clean Energy Microgrid Spending by Percentage Clean, Latin America: 2022-2031
• Clean Energy Microgrid Capacity by Business Model, Latin America: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Latin America: 2022-2031
• Clean Energy Microgrid Capacity by Percentage Clean, Middle East & Africa: 2022-2031
• Clean Energy Microgrid Spending by Percentage Clean, Middle East & Africa: 2022-2031
• Clean Energy Microgrid Capacity by Business Model, Middle East & Africa: 2022-2031
• Clean Energy Microgrid Spending by Business Model, Middle East & Africa: 2022-2031
• Biomass Steam Turbine SWOT Analysis
• Energy Storage SWOT Analysis
• Fuel Cell SWOT Analysis
• Hydro SWOT Analysis
• Solar PV SWOT Analysis
• Wind SWOT Analysis
• Microturbine SWOT Analysis
• Natural Gas Genset SWOT Analysis