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市場調查報告書
遠端控制微電網市場分析及預測:鄉村發電系統,小規模島嶼電網系統,產業用遠端控制採礦系統,及行動軍事微電網
Remote Microgrids - Village Power Systems, Weak Grid Island Systems, Industrial Remote Mine Systems, and Mobile Military Microgrids: Market Analysis and Forecasts
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遠端控制微電網市場分析及預測:鄉村發電系統,小規模島嶼電網系統,產業用遠端控制採礦系統,及行動軍事微電網 是由出版商Pike Research在2012年01月所出版的。
這份英文市場調查報告書包含84 Pages 價格從美金3900起跳。
全球遠隔發電系統數達到1,000,但大部分只有柴油發電,這些在技術上遠不及智慧電網。美國政府在阿富汗和伊拉克的軍事前線基地,設置著所謂的「行動微電網」。這些遠端控制微電網,因為沒有大型的供電網連接,為了能在24小時運作,能源儲存成為最大的需求。這些很多都是為了削減柴油燃料消費的一體化太陽能發電功能,這也成為促進遠端控制微電網市場今後的成長很大的因素。Pike Research預測全球遠端控制微電網市場發電容量,從2011年的349兆瓦(MW),2017年將以超過1.1千兆瓦特(GW)的規模擴大。
本報告提供全球遠端控制微電網所涵蓋的市場,鄉村發電系統,小規模島嶼電網系統,產業用遠端控制採礦系統,及行動軍事微電網等主要領域的市場機會分析,遠程亞太地區的微電網引進的市場問題,及需求因素檢討,技術及引進的問題評估,市場預測提供,再加上主要企業的資訊等,為您概述為以下內容。
第1章 摘要整理
第2章 市場問題
- 什麼是微電網?
- 遠端控制微電網:主要的定義與零件
- 分散發電
- 微儲存
- 變頻器,轉換器,及充電控制器
- 微電網「控制」系統
- 遠端控制微電網的商務案例:SWOT分析
- 現狀的遠端控制微電網的機會
- 發展中國家的人口增加模式
- 低收入者層的價值命題
- 島嶼的高柴油發電成本
- 成本持續降低的太陽能PV
- 行動微電網的軍事技術的發展
- NGO基金
- 安裝的問題
- 重視電網連接系統的微電網市場
- 交易條件不存在的主要新興市場
- 因地區而異的文化的商務次序
- 得到全面研究的經營模式的缺失
- AC vs DC電網結構
第3章 技術的問題
- 遠端控制微電網部門技術概要
- 微電網零件的成本詳細內容
- 遠端控制微電網的次級區分
- 鄉村發電系統
- 小規模島嶼電網系統
- 遠隔開採產業
- 行動軍事微電網
第4章 主要市場參與企業
- 公共事業
- Alaska Energy Authority
- BC Hydro
- 設計軟體供應商
- 專門硬體設備及系統廠商
- Nextek Power Systems
- OutBack Power Technologies
- Powercorp/ABB
- 東芝
- 國防委託業者
- General Electric
- NextEnergy
- 儲存創新者
- 產業用遠程礦山管理再生能源專賣業者
第5章 市場預測
- 遠端控制微電網市場概要
- 鄉村發電系統
- 實例分析:聯合國財團(UNF)
- 北美
- 南美
- 歐洲
- 亞太地區
- 全球其他地區
- 小規模島嶼電網系統
- 產業用遠端控制採礦系統
- 行動軍事微電網
第6章 企業目錄
第7章 縮寫及簡稱清單
第8章 目錄
第9章 圖表清單
第10章 調查範圍,資訊來源及調查手法,註解
Abstract
Remote power systems in all corners of the world number in the thousands, with
the vast majority being powered up by dumb, dirty diesel generation, hardly a
technology of relevance to the smart grid and fundamental networking
advantages of the microgrid platform. Nevertheless, once distributed renewable
energy generation (RDEG) is added to the mix, then these remote microgrids
begin to look like classic microgrids. The closest analogy to remote
microgrids funded by the U.S. government are the so-called “mobile
microgrids” deployed at military forward operating bases (FOBs) in
Afghanistan and Iraq, and other temporary or remote bases throughout the world.
Since these remote microgrids never connect to a larger grid and, therefore,
operate in an island mode on a 24/7 basis, a greater need exists for energy
storage versus other topologies. Many of these microgrids are designed to
reduce diesel fuel consumption by integration of solar photovoltaics, a
technology that is the primary driver for remote microgrids over the next 6
years. Pike Research forecasts that the global remote microgrid market will
expand from 349 megawatts (MW) of generation capacity in 2011 to over 1.1
gigawatts (GW) by 2017, an amount that equals or perhaps even surpasses all
other microgrid segments combined that are in the current planning stages or
have already been deployed.
This Pike Research report analyzes the global market opportunity for remote
microgrids in several key segments including village power systems, weak grid
island systems, industrial remote mine systems, and mobile military
microgrids. The study examines the market issues and demand drivers associated
with adoption of microgrids for remote applications, assesses technology and
implementation issues, and profiles the key industry players that are engaged
in this fast-growing market. Market forecasts, segmented by application and
world region, are provided for generation capacity and revenue growth through
2017.
Key Questions Addressed:
- Which technology components vital to grid-connected microgrids are
relevant or irrelevant to remote microgrids?
- Why is the remote microgrid application so commercially advanced?
- Beyond General Electric, which established companies are engaged in the
remote microgrid market?
- Who are the leading developers of remote microgrids?
- Unlike other microgrid markets, wind power is the dominant generation
source for remote microgrids. Why?
- Which two locations are the world's current wind/diesel remote microgrid
hot spots?
- Moving forward, why are solar photovoltaics (PV) the primary technology
driver behind this remote microgrid market?
Who needs this report?
- Microgrid and smart grid technology companies
- Microgrid project developers
- Solar PV and wind turbine manufacturers
- Large industrial power users
- Non-governmental organizations
- Military agencies
- Government agencies
- Investor community
Research Methodology
Pike Research's industry analysts utilize a variety of research sources in
preparing Research Reports. The key component of Pike Research's analysis is
primary research gained from phone and in-person interviews with industry
leaders including executives, engineers, and marketing professionals.
Analysts are diligent in ensuring that they speak with representatives from
every part of the value chain, including but not limited to technology
companies, utilities and other service providers, industry associations,
government agencies, and the investment community.
About Pike Research
Pike Research is a market research and consulting firm that provides in-depth
analysis of global clean technology markets. The company's research
methodology combines supply-side industry analysis, end-user primary research
and demand assessment, and deep examination of technology trends to provide a
comprehensive view of these industry sectors.
Report Statistics
- Publication Date: 1Q 2012
- Total Number of Pages: 84
- Total Number of Tables, Charts, Figures: 79
Table of Contents
1. Executive Summary
- 1.1. Remote Microgrids Market Overview
- 1.1.1. Remote Microgrids Market Segmentation
- 1.1.2. Remote Microgrids Landscape
- 1.2. Remote Microgrids Market Forecast
- 1.2.1. Remote Microgrid Capacity
- 1.2.2. Remote Microgrid Revenue
2. Market Issues
- 2.1. What Is a Microgrid?
- 2.1.1. Microgrid Application Overview
- 2.2. Remote Microgrids: Key Definitions and Components
- 2.2.1. Distributed Energy Generation
- 2.2.2. Micro Storage
- 2.2.3. Inverters, Converters, and Charge Controllers
- 2.2.4. Microgrid “Control” Systems
- 2.3. The Business Case for Remote Microgrids: SWOT Analysis
- 2.4. Current Remote Microgrid Opportunities
- 2.4.1. Population Growth Patterns in the Developing World
- 2.4.2. A Bottom of the Pyramid Value Proposition
- 2.4.3. High Cost of Diesel Power Generation on Islands
- 2.4.4. Declining Costs of Solar PV
- 2.4.5. Military Advances with Mobile Microgrids
- 2.4.6. NGO Funds
- 2.5. Implementation Issues
- 2.5.1. Microgrid Market Focused on Grid-Tied Systems
- 2.5.2. Lack of Commercial Terms in Key Emerging Markets
- 2.5.3. Cultural Business Protocols Vary by Geography
- 2.5.4. Lack of Fully Vetted Business Models
- 2.5.5. AC versus DC Grid Architectures
3. Technology Issues
- 3.1. Remote Microgrid Sector Technologies Overview
- 3.1.1. Wind and Solar Resources
- 3.1.2. Technology Upgrades
- 3.2. Microgrid Component Cost Breakdown
- 3.3. Remote Microgrid Subsegments
- 3.3.1. Village Power Systems
- 3.3.2. Weak Grid Island Systems
- 3.3.3. Remote Mining Operations
- 3.3.4. Mobile Military Microgrids
4. Key Industry Players
- 4.1. Utilities
- 4.1.1. Alaska Energy Authority
- 4.1.2. BC Hydro
- 4.2. Design Software Providers
- 4.3. Specialized Hardware and Systems Integrators
- 4.3.1. Nextek Power Systems
- 4.3.2. OutBack Power Technologies
- 4.3.3. Powercorp/ABB
- 4.3.4. Toshiba
- 4.4. Defense Contractors
- 4.4.1. General Electric
- 4.4.2. NextEnergy
- 4.5. Storage Innovators
- 4.5.1. Xtreme Power
- 4.5.2. ZBB Energy
- 4.6. Industrial Remote Mine Renewable Power Specialists
- 4.6.1. Remote Energy Solutions
5. Market Forecasts
- 5.1. Remote Microgrids Market Overview
- 5.1.1. Remote Microgrid Subsegments
- 5.1.2. Remote Microgrid Revenue Methodology
- 5.2. Village Power Systems
- 5.2.1. Case Study: United Nations Foundation
- 5.2.2. North America
- 5.2.3. Latin America
- 5.2.3.1. Case Study: Village Power Systems in Chile, South America
- 5.2.4. Europe
- 5.2.5. Asia Pacific
- 5.2.6. Rest of the World
- 5.3. Weak Grid Island Systems
- 5.3.1. North America
- 5.3.2. Latin America
- 5.3.3. Europe
- 5.3.4. Asia Pacific
- 5.3.5. Rest of the World
- 5.4. Industrial Remote Mine Systems
- 5.4.1. North America
- 5.4.2. Latin America
- 5.4.3. Europe
- 5.4.4. Asia Pacific
- 5.4.5. Rest of the World
- 5.5. Mobile Military Microgrids
6. Company Directory
7. Acronym and Abbreviation List
8. Table of Contents
9. Table of Charts and Figures
10. Scope of Study, Sources and Methodology, Notes
List of Charts and Figures
- Total Remote Microgrid Capacity, All Scenarios, World Markets: 2011-2017
- Total Remote Microgrid Revenue, All Scenarios, World Markets: 2011-2017
- Village Power Systems Capacity, All Scenarios, World Markets: 2011-2017
- Village Power Systems Revenue, All Scenarios, World Markets: 2011-2017
- Weak Grid Island Systems Capacity, All Scenarios, World Markets: 2011-2017
- Weak Grid Island Systems Revenue, All Scenarios, World Markets: 2011-2017
- Industrial Remote Mine Systems Capacity, All Scenarios, World Markets:
2011-2017
- Industrial Remote Mine Systems Revenue, All Scenarios, World Markets:
2011-2017
- Military Forward Operating Base Installations, World Markets: 2011-2017
- Mobile Military Microgrid Capacity, All Scenarios, United States: 2011-2017
- Mobile Military Microgrid Revenue, All Scenarios, United States: 2011-2017
- PQR Hierarchy
- Microgrid Market Shares Based on Capacity Size, World Markets: 2009
- Solar PV Market Displaying Exponential Growth, World Markets: 2000-2010
- Microgrid Market Shares per Generation Type, World Markets: 2009
- Long-Term Population Trends: 1950-2050
- Regional Remote Microgrid Opportunities: 1970-2030
- Topology of Remote Microgrid at Gaidouromantra, Kythos Island, Greece
- Solar PV and Diesel Generation Cost Crossover Point: 2001-2011
- Historical Price Trends for Solar PV: 1985-2011
- The History and Evolution of DC Distributed Power
- Low, Medium, and High Wind Penetration Microgrid Cost Factors in Alaska
- Daily Solar Radiation and Clearness Levels for Tropical Remote Microgrid
Sites
- Monthly Wind Speed Estimates for Tropical Remote Microgrid Sites
- Cost Breakdown for Alaska Wind-Diesel Remote Microgrids
- Load Profile for Tropical Village Power System in Developing World
- Alaska Industrial Development and Export Authority (AIDEA) Wind Diesel
Hybrid
- Remote Microgrid Projects
- Topology of Bella Coola Remote Microgrid
- DC Direct Coupling Microgrid Advantages
- OutBack Power Village Power Distribution Center
- PowerStore Flywheel Diagram
- Solar PV and Small Wind on Miyako Island, Japan
- REMUS System in Afghanistan
- EPRI's Cost Ranking of Major Storage Systems
- Relative Shares of Electric Power: OECD vs. Non-OECD Countries: 1990-2035
- IEA Solar PV Roadmap Scenarios: 2010-2050
- Solar PV End-Use Market Segments (Including Off-Grid): 2010-2050
- Ontario's Remote Northern Community Remote Microgrid Sites
- Topology of Huatacondo Project in Chile, South America
- Ross Island, Antarctica Weak Grid Island System
List of Tables
- SWOT Analysis for Remote Microgrids
- Alaska Energy Authority SWOT Analysis
- BC Hydro SWOT Analysis
- HOMER Energy SWOT Analysis
- Nextek Power Systems SWOT Analysis
- OutBack Power SWOT Analysis
- Powercorp/ABB SWOT Analysis
- Toshiba SWOT Analysis
- GE SWOT Analysis
- NextEnergy SWOT Analysis
- Xtreme Power SWOT Analysis
- Village Power Systems Capacity by Region, Base Scenario, World Markets:
2011-2017
- Village Power Systems Capacity by Region, Average Scenario, World Markets:
2011-2017
- Village Power Systems Capacity by Region, Aggressive Scenario, World
Markets: 2011-2017
- Village Power Systems Revenue by Region, Base Scenario, World Markets:
2011-2017
- Village Power Systems Revenue by Region, Average Scenario, World Markets:
2011-2017
- Village Power Systems Revenue by Region, Aggressive Scenario, World
Markets: 2011-2017
- Weak Grid Island Systems Capacity by Region, Base Scenario, World Markets:
2011-2017
- Weak Grid Island Systems Capacity by Region, Average Scenario, World
Markets: 2011-2017
- Weak Grid Island Systems Capacity by Region, Aggressive Scenario, World
Markets: 2011-2017
- Weak Grid Island Systems Revenue by Region, Base Scenario, World Markets:
2011-2017
- Weak Grid Island Systems Revenue by Region, Average Scenario, World
Markets: 2011-2017
- Weak Grid Island Systems Revenue by Region, Aggressive Scenario, World
Markets: 2011-2017
- Industrial Remote Mine Systems Capacity by Region, Base Scenario, World
Markets: 2011-2017
- Industrial Remote Mine Systems Capacity by Region, Average Scenario, World
Markets: 2011-2017
- Industrial Remote Mine Systems Capacity by Region, Aggressive Scenario,
World Markets: 2011-2017
- Industrial Remote Mine Systems Revenue by Region, Base Scenario, World
Markets: 2011-2017
- Industrial Remote Mine Systems Revenue by Region, Average Scenario, World
Markets: 2011-2017
- Industrial Remote Mine Systems Revenue by Region, Aggressive Scenario,
World Markets: 2011-2017
- Military Forward Operating Base Installations by Conflict Zone, World
Markets: 2011-2017
- Mobile Military Microgrid Capacity, All Scenarios, United States: 2011-2017
- Mobile Military Microgrid Revenue, All Scenarios, United States: 2011-2017
- Total Remote Microgrid Capacity by Region, Base Scenario, World Markets:
2011-2017
- Total Remote Microgrid Capacity by Region, Average Scenario, World
Markets: 2011-2017
- Total Remote Microgrid Capacity by Region, Aggressive Scenario, World
Markets: 2011-2017
- Total Remote Microgrid Revenue by Region, Base Scenario, World Markets:
2011-2017
- Total Remote Microgrid Revenue by Region, Average Scenario, World Markets:
2011-2017
- Total Remote Microgrid Revenue by Region, Aggressive Scenario, World
Markets: 2011-2017
遠距微電網的收益在2017年將達102億美元
2012年01月20日
日商環球訊息(股)有限公司開始販售由Pike Research所發行的調查報告「Remote Microgrids - Village Power Systems, Weak Grid Island Systems, Industrial Remote Mine Systems, and Mobile Military Microgrids: Market Analysis and Forecasts (遠端控制微電網市場分析及預測:鄉村發電系統,小規模島嶼電網系統,產業用遠端控制採礦系統,及行動軍事微電網)」。
全球的遠距發電系統數量達到數千個,不過幾乎為柴油發電,且沒有可活用智慧電網和微電網平台所具有基本網路優點的技術。
但是,如與可再生分散能源發電相結合,如此的遠距微電網也將會具有標準型微電網的特徵。
與太陽能發電機能一體化、削減柴油燃料消費的技術,在今後6年間將成為牽引遠距微電網成長的主要因素。
Pike Research的報告書預測,全球遠距微電網市場的發電容量,將從2011年的349百萬瓦(MW),於2017年擴大成超越1.1億瓦的規模。這與計劃階段或是已設置的微電網所合計發電容量相比較的話,將會是相同,甚至超越其上。
Pike Research預測,透過該發電容量的擴大,遠距微電網部門的收益將增加,並於2017年達到102億美元以上。
即使在全球經濟持續低迷下的保守預測,2017年的收益也將會達到45億美元。
資深分析師Peter Asmus表示,「全球的遠距微電網部門,在收益面為所有微電網部門中,最具吸引力的部門。」
「根據近期的調查,以及Pike Research的最新報告書,遠距微電網部門與過去的預測相比,為更穩固的市場,且由於太陽能PV價格的持續下滑,即使沒有政府的獎勵政策,也將會大幅成長。」
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