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市场调查报告书

可再生储存混合动力厂:混合太阳能与储存及应用-全球市场分析和预测

Renewables plus Storage Hybrid Power Plants - Hybrid Solar plus Storage and Storage plus Applications: Global Market Analysis and Forecasts

出版商 Guidehouse Insights (formerly Navigant Research) 商品编码 1016639
出版日期 内容资讯 英文 43 Pages; 29 Tables, Charts & Figures
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价格
可再生储存混合动力厂:混合太阳能与储存及应用-全球市场分析和预测 Renewables plus Storage Hybrid Power Plants - Hybrid Solar plus Storage and Storage plus Applications: Global Market Analysis and Forecasts
出版日期: 2021年06月29日内容资讯: 英文 43 Pages; 29 Tables, Charts & Figures
简介

存储是一种允许将可用能源用于其他场合的技术,尤其是在最需要或具有高价值的情况下。锂离子电池是全球新项目的默认技术,预计到2021年将占新项目容量的85%。

电池供电的储能系统 (BESS) 为电网和客户提供一组可互换的服务。将储能系统战略性地整合到电网中,可以更有效地利用其他电网资源,推迟成本高昂的升级和投资,并扩大电网运营范围。此外,可以通过储存电力来满足以前由火力发电厂满足的需求。

将大规模可再生能源与 BESS 相结合,缓解了可再生能源是一种间歇性资源的传统挑战。结合BESS,可调度可再生能源以提供电网容量和频率调整和运行准备等辅助服务。

本报告探讨了全球可再生能源和储能混合发电厂市场,并提供有关市场规模和预测、增长和制约因素、技术问题以及 COVID-19 大流行影响的信息。我是。

目录

第 1 章执行摘要

  • 市场介绍
  • 市场预测

第 2 章市场问题

  • 市场增长因素
    • 储电采购协议价格下降
    • 取消化石燃料发电厂
    • 公益事业规划问题
  • 市场壁垒
    • 预测
    • 市场宽松和实物税预扣
    • 市场进入和调度软件
    • 容量认证
    • 提供的参数
    • 互连
    • 资源规划
  • 存储和应用
    • 减少和传输拥塞
    • 能源价格套利
    • 可再生能源输出
    • 产能市场和资源充足率
    • 辅助服务
    • 远程微电网

第三章技术问题

  • 可再生能源混合系统配置
  • Solar Plus 存储
    • 交直流耦合
    • 著名的风能和储能项目
  • 新型多技术可再生混合动力系统
  • 用于存储的可再生能源和储能技术
    • 液流电池
    • PHS 和 CAES
    • 蓄热
    • P2G

第 4 章市场预测

  • 调查方法和先决条件
    • 冠状病毒大流行的影响
  • 按地区预测
  • 技术与时期预测

第 5 章结论/建议

第 6 章缩写列表

第七章目录

第8章图表

第 9 章调查范围、来源和调查方法、注释

目录
Product Code: MF-UBP-21

Energy storage technologies are capable of capturing usable energy for use at another time, particularly when it is most needed or more valuable. Deploying energy storage technologies is one solution for improving grid flexibility and facilitating large amounts of intermittent renewable energy onto the grid. Multiple energy storage technologies are available in the market with a wide range of power ratings, storage capacities, response times, efficiencies, capital costs, and scalability. However, lithium ion (Li-ion) batteries have become the default technology for new projects globally, projected to account for 85% of new project capacity in megawatts in 2021.

Battery energy storage systems (BESSs) provide an interchangeable array of grid and customer services. Integrating energy storage strategically across the electricity system can result in more efficient utilization of other grid resources, defer more costly upgrades or investments, and increase the range of operational possibilities for the electric system. In addition, storage can scale to address needs previously met by thermal power plants. The pairing of large-scale renewable resources with BESSs mitigates the previous challenge of renewables being intermittent resources. When paired with BESSs, renewables can be dispatched to provide grid capacity and ancillary services such as frequency regulation and operating reserves.

This ‘Guidehouse Insights report ’ provides global forecasts for annual deployments of new utility-scale renewables plus storage projects in terms of power capacity (megawatts) and energy capacity (megawatt-hours). These forecasts are segmented by region and technology. Additional insight is provided through the technology pricing forecasts that are included in this report. All forecasts cover a 10-year period from 2021 to 2030. Forecasts provided in this report have been revised from 2020 projections to account for new projects in the regional pipeline and expected disruptions from the coronavirus pandemic.

KEY QUESTIONS ADDRESSED:

  • What is driving the growth of renewables plus storage hybrid power plants?
  • What new regulatory policies are increasing renewables plus storage hybrid power plant opportunities?
  • How do the economics of renewables plus storage hybrid power plants vary by country and region?
  • What new markets are opening up for renewables plus storage hybrid power plant technologies?
  • How are market participation models and government policies improving the bankability of renewables plus storage hybrid power plants?
  • What is the long-term potential of renewables plus storage hybrid power plants in an evolving electric power industry?
  • How is the emergence of new hybrid configurations changing the energy storage plus renewables landscape?
  • What are the market forecasts, in capacity and revenue, for renewables plus storage hybrid power plants through 2030?

WHO NEEDS THIS REPORT:

  • Advanced battery OEMs
  • Inverter and other balance of system vendors
  • Government and regulatory agencies
  • Non-governmental organizations
  • IoT companies
  • Energy storage integrators
  • Battery storage aggregators
  • Solar PV OEMs
  • Wind turbine OEMs
  • Energy storage integrators
  • Energy storage hardware vendors and technology firms
  • Energy storage developers and independent power producers
  • Engineering, procurement, and construction (EPC) firms
  • Renewable energy development financing companies
  • Smart grid controls and software companies
  • Utilities
  • Investor community

Table of Contents

1. Executive Summary

  • 1.1. Market Introduction
  • 1.2. Market Forecasts

2. Market Issues

  • 2.1. Market Drivers
    • 2.1.1. Storage plus Power Purchase Agreement Price Declines
    • 2.1.2. Fossil Fuel Power Plant Retirements
    • 2.1.3. Utility Planning Challenges
  • 2.2. Market Barriers
    • 2.2.1. Forecasting
    • 2.2.2. Market Mitigation and Physical Withholding
    • 2.2.3. Market Participation and Scheduling Software
    • 2.2.4. Capacity Accreditation
    • 2.2.5. Offer Parameters
    • 2.2.6. Interconnection
    • 2.2.7. Resource Planning
  • 2.3. Storage plus Applications
    • 2.3.1. Curtailment and Transmission Congestion
    • 2.3.2. Energy Price Arbitrage
    • 2.3.3. Renewables Output
    • 2.3.4. Capacity Markets and Resource Adequacy
    • 2.3.5. Ancillary Services
    • 2.3.6. Remote Microgrids

3. Technology Issues

  • 3.1. Renewable Energy Hybrid System Configurations
  • 3.2. Solar plus Storage
    • 3.2.1. AC Coupling versus DC Coupling
      • 3.2.1.1. AC Coupling Advantages
        • 3.2.1.1.1. Flexibility
        • 3.2.1.1.2. Retrofits
      • 3.2.1.2. DC Coupling Advantages
        • 3.2.1.2.1. Efficiency
        • 3.2.1.2.2. Inverter Load Ratio
        • 3.2.1.2.3. Low Voltage (Low Power) Harvesting. 3.3. Wind plus Storage
    • 3.3.1. Notable Wind plus Storage Projects
  • 3.4. Emerging Multi-Technology Renewable Hybrid Systems
  • 3.5. Energy Storage Technologies for Renewables plus Storage
    • 3.5.1. Flow Batteries
    • 3.5.2. PHS and CAES
    • 3.5.3. Thermal Energy Storage
    • 3.5.4. P2G

4. Market Forecasts

  • 4.1. Methodology and Assumptions
    • 4.1.1. Coronavirus Pandemic Impacts
  • 4.2. Forecasts by Region
  • 4.3. Forecasts by Technology and Duration

5. Conclusions and Recommendations

6. Acronym and Abbreviation List

7. Table of Contents

8. Table of Charts and Figures

9. Scope of Study, Sources, and Methodology, Notes

LIST OF CHARTS AND FIGURES

  • Annual Installed Renewables plus Storage Hybrid Power Plants Power Capacity by Region, World Markets: 2021-2030
  • Utility-Scale ESS CAPEX Assumptions by Technology, World Market Averages: 2020-2029
  • Annual Installed Utility-Scale Solar PV plus Storage Hybrid/Colocated ESS Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Wind plus Storage Hybrid/Colocated ESS Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Renewables plus Storage Hybrid/Colocated ESS Energy Capacity by Generation Type, World Markets: 2021-2030
  • AC-Coupled System
  • DC-Coupled System
  • AC-Coupled Utility System
  • The Complexity of AC-Coupled and DC-Coupled Energy Storage before the California Public Utilities Commission's Net Energy Metering Decision
  • Emerging Multi-Technology Renewable Hybrid System Design
  • Max Bögl Wind AG Pilot Project in Gaildorf, Germany
  • Tractebel Offshore Hydrogen Production Concept

LIST OF TABLES

  • Utility-Scale ESS CAPEX Assumptions by Technology, World Market Averages: 2020-2029
  • Utility-Scale Li-Ion Battery plus Solar PV System Pricing by Component, 75 MW/AC; 20 MW/80 MWh System, World Market Averages: 2020-2029
  • Annual Installed Utility-Scale Solar PV Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Wind Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed UES Power Capacity by Region, All Technologies and Application Segments, World Markets: 2021-2030
  • Annual Installed UES Energy Capacity by Region, All Technologies and Application Segments, World Markets: 2021-2030
  • Annual Solar PV Deployment Revenue by Region, World Markets: 2021-2030
  • Annual Wind Deployment Revenue by Region, World Markets: 2021-2030
  • Annual Installed UES Deployment Revenue by Region, All Technologies and Application Segments, World Markets: 2021-2030
  • Annual Installed Utility-Scale Solar PV plus Storage Hybrid/Colocated Combined Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Solar PV plus Storage Hybrid/Colocated Solar PV Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Solar PV plus Storage Hybrid/Colocated ESS Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Solar PV plus Storage Hybrid/Colocated ESS Energy Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Wind plus Storage Hybrid/Colocated Combined Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Wind plus Storage Hybrid/Colocated Wind Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Wind plus Storage Hybrid/Colocated ESS Power Capacity by Region, World Markets: 2021-2030
  • Annual Installed Utility-Scale Wind plus Storage Hybrid/Colocated ESS Energy Capacity by Region, World Markets: 2021-2030