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市場調查報告書

處理全球能源三難選擇問題的技術

Technologies Addressing Global Energy Trilema

出版商 Frost & Sullivan 商品編碼 931779
出版日期 內容資訊 英文 69 Pages
商品交期: 最快1-2個工作天內
價格
處理全球能源三難選擇問題的技術 Technologies Addressing Global Energy Trilema
出版日期: 2020年03月30日內容資訊: 英文 69 Pages
簡介

電力能源產業中的環境永續性問題、請求在不引起故障或停電下維持供應電力的能源安全問題,以及,以可再生能源系統增加競爭力之後必須從傳統的集中控制型電網進化成分散型且高能源效率的系統等,現在正面對必須引進新技術以解決問題的情況。

本報告集中討論了有可能處理全球電力產業在能源面臨的三難選擇,也就是能源安全、環境永續性,以及能源平等 (公平性、可獲取性) 問題的各種技術,並加入了針對最近的市場發展、引進新技術的準備情勢、法規措施及技術性性能指標的詳細分析。

第1章 執行摘要

  • 重點調查項目 - 可解決課題的技術
  • 調查範圍 - 關於課題與解決方案的預測
  • 分析架構 - Frost & Sullivan的核心價值
  • 調查方法

第2章 能源三難選擇 - 技術趨勢

  • 能源三難選擇 - 全球現象
  • 執行能源高效率化與智慧化左右了產業動態
  • 能源需求的提升與政策上的架構在處理能源轉型上發揮了重要功能
  • 能源三難選擇:三種特質 - 環境永續性
  • 能源三難選擇:三種特質 - 能源安全
  • 能源三難選擇:三種特質 - 能源平等 (公平性、可獲取性)
  • 有關能源安全的威脅,必須整合智慧技術

第3章 在能源三難選擇中,用於解決環境永續性問題的技術

  • 太陽能發電
    • 太陽能產業的進化
    • 太陽能發電發揮了長期規模下的彈性
    • 第三代太陽能發電技術使高競爭力的事業規劃變得確實
  • 生質能源
    • 生物資源的能源轉換過程的高度化發揮了確保技術多樣性的重要功能
    • 生物質處理工程在經濟且有效率地達成能源整合化發揮了極為重要的功能
    • 為了大規模引進,氣化技術確實有所影響
  • 二氧化碳捕獲與封存 (CCS)
    • 由於二氧化碳回收技術,綠色且永續的能源機製成為可能
    • 以產業整體進行二氧化碳回收,可以在全產業製程中抑制排放量
    • 藉由不斷持續研究開發二氧化碳捕獲與封存技術,可得到符合成本效益的有效性與高效率性

第4章 在能源三難選擇中,用於解決能源安全問題的技術

  • 分散型電力來源 (DER)
    • 運用分散型電力來源可以達成全球性的產消合一主義
    • 運用電力混合系統,關於成本及能源效率的技術性基準將有極大改變
    • 整合能源系統在大規模引進發揮了不可或缺的功能
    • 運用DER與有效率的能源管理,可以描繪出高效率且高競爭力的事業規劃
  • 能源儲存
    • 能源儲存技術在能源產業的所有業界發揮了重要功能
    • 由於提升電池能源密度及延長壽命,具備廣泛規模的彈性成為可能
    • 關於大規模引進公用產業規模,熱能源儲存技術擁有主要的廣大影響力
    • 機械式能源儲存也可能運用大規模能源儲存系統
    • 使用氫氣的能源儲存,將大幅改變性能及成本比較的基準
    • 能源儲存:技術比較

第5章 在能源三難選擇中,用於解決能源平等問題的技術

  • 能源管理系統提供雙向通訊網路
  • 以分散型電網基礎建設確保可靠性與集中管理型電網的獨立性

第6章 最近的市場發展

  • 氣體排放管制與提升效率的必要性促進了對研究開發的投資

第7章 主要的資金調集狀況

  • 資金調集有賴於公用產業界的支援,業界各家公司及研究機構因此能夠發展創新

第8章 分析家見解

  • 地政學的多元化與資源多元化影響了全球對於能源三難選擇的擔憂

第9章 COVID-19大流行對產業的影響

  • 以分散型的智慧電力系統應對COVID-19大流行對商業的影響

第10章 主要聯絡資訊

  • 業界主要聯絡資訊
  • 免責聲明
目錄
Product Code: D962

Diversifying Generation Portfolios in Conjunction with Effective Energy Management Solutions Can Drive Global Energy Transition

The rising population along with the rapid expansion of anthropogenic activities has infused concerns associated with the sustainability and optimization of natural resources worldwide. Perpetual increase in per capita energy consumption in conjunction with aging energy infrastructure has further added to the debate concerning the growth and future roadmap for energy companies and utilities. Moreover, stringent emission mandates in compliance with the 2015 Paris agreement coupled with increasing economic and technological competence from renewable energy systems have led to a paradigm shift from the conventional centralized grid mechanism towards a distributed and energy-efficient technological evolution. Change in electricity consumption, competence among emerging energy generation technologies, and regulatory implementations have compelled industry participants to adopt and implement technologies that ensure reliability and uninterrupted power supply. Besides, the rise in electric faults, blackouts and load shedding has further raised questions regarding energy security across the globe.

Henceforth, regulators and technology developers across the power industry have proposed ways to tackle circuitry failures on a larger scale through the introduction of micro-grids, decentralized generation systems and on-site renewable energy systems. The research study concentrated across technologies that address the basic challenges concerning energy trilemma (namely energy security, environmental sustainability, and energy equity) pertaining throughout the global power industry. Moreover, the study encompasses through recent developments, technology readiness levels, regulatory initiatives and various technology performance indicators ensuring a long-term, secure, and uninterrupted energy ecosystem.

Table of Contents

1.0 Executive Summary

  • 1.1. Research Focus - Enabling
  • 1.2. Research Scope - Foreseeing Challenges and Solutions
  • 1.3. Analysis Framework - Frost & Sullivan's Core Value
  • 1.4. Research Methodology

2.0 Energy Trilemma - Technology Trends

  • 2.1. Energy Trilemma - a Global Phenomenon
  • 2.2. Energy Efficiency and Smart Implementation to Influence Industry Dynamics
  • 2.3. Rising Energy Demand and Policy Framework Play a Pivotal Role in Addressing Energy Transition
  • 2.4. Energy Trilemma: The Three Dimensions - Environmental Sustainability
  • 2.5. Energy Trilemma: The Three Dimensions - Energy Security
  • 2.6. Energy Trilemma: The Three Dimensions - Energy Equity
  • 2.7. Smart Technology Integration ImposeSecurity Threats

3.0 Technologies Addressing Energy Trilemma "Environmental Sustainability

  • 3.1. Solar PV
  • 3.1.1. Evolution of the Solar Industry
  • 3.1.2. Solar PV to Witness Long-term Scalability
  • 3.1.2. Solar PV to Witness Long-term Scalability
  • 3.1.3. Third-generation Solar will Enable a Competitive Business Scenario
  • 3.1.3. Third-generation Solar will Enable a Competitive Business Scenario (continued)
  • 3.1.3. Third-generation Solar will Enable a Competitive Business Scenario (continued)
  • 3.1.3. Third-generation Solar will Enable a Competitive Business Scenario (continued)

3.2. Bioenergy

  • 3.2.1. Advanced Conversion Paths to Play a Major Role in Technological Diversity
  • 3.2.1. Advanced Conversion Paths to Play a Major Role in Technological Diversity
  • 3.2.2. Biomass Processing to Play a Pivotal Role in Achieving Economic & Efficient Integration
  • 3.2.3. Gasification to Positively Influence Large-scale Adoption

3.3. Carbon Capture & Storage (CCS)

  • 3.3.1. Carbon Capture Technologies to Enable a Clean & Sustainable Energy Mechanism
  • 3.3.2. Carbon Capture across Industries to Curb Overall Process Emissions
  • 3.3.3. Perpetual CCS Research & Development to Provide Cost Effectiveness & Efficiency

4.0 Technologies Addressing Energy Trilemma "Energy Security

  • 4.1. Distributed Energy Resources (DERs)
  • 4.1.1. Distributed Energy Resources to Enable Global Prosumerism
  • 4.1.2. Hybrid Systems to Redefine Technological Benchmarking in terms of Cost & Energy Efficiency
  • 4.1.3. Energy Systems Integration to Play a Vital Role in Large-scale Adoption
  • 4.1.3. Energy Systems Integration to Play a Vital Role in Large-scale Adoption (continued)
  • 4.1.4. DERs along with Effective Energy Management will Build an Efficient & Competitive Business Scenario

4.2. Energy Storage

  • 4.2.1. Storage to Play an Important Role across all the Energy Industry Verticals
  • 4.2.2. Batteries to Enable Wide Scalability through Improved Energy Density & Longevity
  • 4.2.3. Large Utility-scale Deployments to be Primarily Influenced by Thermal Energy Storage Technologies
  • 4.2.4. Mechanical Energy Storage to Support Large-scale Storage Systems
  • 4.2.5. Hydrogen Storage to Redefine Performance & Comparative Cost Benchmarking
  • 4.2.6. Energy Storage: Technology Comparison
  • 4.2.6. Energy Storage: Technology Comparison (continued)

5.0. Technologies Addressing Energy Trilemma "Energy Equity"

  • 5.1. Energy Management Systems to Provide a Two-way Communication Network
  • 5.2. Decentralized Grid Infrastructure to Ensure Reliability and Independence from Centralized Grid Networks

6.0 Recent Developments

  • 6.1. Emission Control & Efficiency Enhancement to Drive R&D Investments
  • 6.1. Emission Control & Efficiency Enhancement to Drive R&D Investments (continued)
  • 6.1. Emission Control & Efficiency Enhancement to Drive R&D Investments (continued)

7.0 Major Funding Landscape(2019 - 2020)

  • 7.1. Utility Aided Funding to Drive Innovations across Companies & Research Institutes
  • 7.1. Utility Aided Funding to Drive Innovations across Companies & Research Institutes (continued)
  • 7.1. Utility Aided Funding to Drive Innovations across Companies & Research Institutes (continued)

8.0 Analyst Insights

  • 8.1. Geopolitics & Resource Diversification to Impact the Global Trilemma Concerns
  • 8.1. Geopolitics & Resource Diversification to Impact the Global Trilemma Concerns (continued)

9.0 Industry Impact of COVID-19 Outbreak

  • 9.1. Decentralized and Smart Power Systems to Address Business Impact of COVID-19 Outbreak

10.0 Key Contacts

  • 10.1. Key Industry Contacts
  • 10.1. Key Industry Contacts (continued)
  • Legal Disclaimer