| ◆英語タイトル:Global Electric Ships Market Size study & Forecast, by Power Source (Fully Electric, Hybrid) by Power Output (Less than 75 kW, 75-745 kW, 746-7560 kW, More than 7560 kW), by Vessel Type (Commercial Vessel, Defense Vessel), by Level of Autonomy (Semi-Autonomous, Fully Autonomous) and Regional Analysis, 2022-2029
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 | ◆商品コード:BZW23MA179
◆発行会社(リサーチ会社):Bizwit Research & Consulting
◆発行日:2023年4月10日
◆ページ数:約200
◆レポート形式:英語 / PDF
◆納品方法:Eメール(受注後3営業日)
◆調査対象地域:アメリカ、カナダ、イギリス、ドイツ、フランス、スペイン、イタリア、中国、インド、日本、オーストラリア、韓国、ブラジル、メキシコ、
◆産業分野:船舶
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ビズウィットリサーチ社発行の本調査報告書によると、2021年にXXX億ドルであった世界の電気船舶市場規模が、予測期間中(2022年-2029年)にXX%以上成長すると見込まれています。本書は、電気船舶の世界市場を広く調査・分析し、エグゼクティブサマリー、市場定義・範囲、市場動向、産業分析、動力源別(完全電気式、ハイブリッド式)分析、出力別(75kW以下、75-745kW、746-7560kW、7560kW以上)分析、船舶種類別(商用船、防衛船)分析、自動レベル別(半自動型、完全自動型)分析、地域別(北米、ヨーロッパ、アジア太平洋、中南米、アメリカ、カナダ、イギリス、ドイツ、フランス、スペイン、イタリア、中国、インド、日本、オーストラリア、韓国、ブラジル、メキシコ、その他)分析、競争分析、調査プロセスなどの内容をまとめています。また、本書には、Kongsberg(Norway)、Leclanche(Switzerland)、Corvus Energy(Canada)、Echandia Marine Ab(Sweden)、Siemens(Germany)、Wartsila(Finland)、Vard(Part Of Fincantieri Spa)(Norway)、Norwegian Electric Systems(Norway)、General Dynamics Electric Boat(U.S.)、Man Energy Solutions Se(Germany)などの企業情報が含まれています。
・エグゼクティブサマリー
・市場定義・範囲
・市場動向
・産業分析
・リスク分析(新型コロナウイルス感染症の影響)
・世界の電気船舶市場規模:動力源別
- 完全電気式電気船舶の市場規模
- ハイブリッド式電気船舶の市場規模
・世界の電気船舶市場規模:出力別
- 75kW以下の電気船舶市場規模
- 75-745kWの電気船舶市場規模
- 746-7560kWの電気船舶市場規模
- 7560kW以上の電気船舶市場規模
・世界の電気船舶市場規模:船舶種類別
- 商用船の市場規模
- 防衛船の市場規模
・世界の電気船舶市場規模:自動レベル別
- 半自動型の市場規模
- 完全自動型の市場規模
・世界の電気船舶市場規模:地域別
- 北米の電気船舶市場規模
アメリカの電気船舶市場規模
カナダのの電気船舶市場規模
…
- ヨーロッパの電気船舶市場規模
イギリスの電気船舶市場規模
ドイツの電気船舶市場規模
フランスの電気船舶市場規模
…
- アジア太平洋の電気船舶市場規模
中国の電気船舶市場規模
インドの電気船舶市場規模
日本の電気船舶市場規模
…
- 中南米の電気船舶市場規模
ブラジルの電気船舶市場規模
メキシコの電気船舶市場規模
…
- その他地域の電気船舶市場規模
・競争分析
・調査プロセス |
Global Electric Ships Market is valued at approximately USD XXX billion in 2021 and is anticipated to grow with a healthy growth rate of more than XX% over the forecast period 2022-2029. Electric ships, as compared to traditional diesel engine ships, are driven by electricity. The electric motors on these ships are powered by a battery bank. A variety of battery banks, including lead-acid batteries, lithium-ion batteries, and fuel cells, can be utilized in an electric ship. The Electric Ships Market is expanding because of factors such as the enforcement of the 2020 global Sulphur cap and its beneficial environmental impact.
According to International Maritime Organization, in January 2020, adopted a global Sulphur cap, requiring ships operating outside of emission control areas (ECAs) to utilise low Sulphur fuels. Ships must use fuels with a Sulphur level of 0.5% or less, rather than the prior requirement of 3.5% or less. However, in comparison to the residual fuels used by most ships, the cost of complying with fuels is estimated to be approximately 50% higher. Additionally, the International Chamber of Shipping (ICS) estimates that the new laws will cost the industry a total of USD 50 billion, with an additional price increase. It is due to early uncertainties about the availability of compatible fuels. As a result, ship operators are probably going to increase their use of environmentally beneficial electric ships. It can also aid in the reduction of running costs. These reasons are expected to drive the growth of the electric ship market. Also, the growing use of fully electric passenger vessels and demand for zero-emission transportation will provide lucrative growth opportunities for the market during the forecast period. However, the modern battery technology & expensive capital may stifle market growth throughout the forecast period of 2022-2029.
The key regions considered for the Global Electric Ships Market study include Asia Pacific, North America, Europe, Latin America, and Rest of the World. In terms of revenue, Europe dominated the market owing to increased awareness of the implications of maritime emissions, notably in seaports such as Rotterdam and Hamburg. Furthermore, many government programs would encourage the use of electric vessels. Asia Pacific is expected to grow with the highest CAGR during the forecast period. According to the IMO, China, Japan, and South Korea produce more than 90% of the world’s ships, primarily big merchant vessels such as tankers and cargo ships. Recent regulatory developments, such as the global Sulphur cap, and voluntary initiatives by manufacturers, particularly in Japan and China, to increase electrification in large-sized vessels, are expected to influence market growth.
Major market player included in this report are:
Kongsberg (Norway)
Leclanche (Switzerland)
Corvus Energy (Canada)
Echandia Marine Ab (Sweden)
Siemens (Germany)
Wartsila (Finland)
Vard (Part Of Fincantieri Spa) (Norway)
Norwegian Electric Systems (Norway)
General Dynamics Electric Boat (U.S.)
Man Energy Solutions Se (Germany)
Recent Developments in the Market:
In September 2020, according to Amsterdam’s municipal public transportation provider, Corvus Energy has been given a contract by Holland Ship Electric to provide lithium-ion-based energy storage systems for 5 new ships being manufactured by Holland Shipyards Group for GVB.
In April 2019, Rolls-Royce Commercial Marine (RRCM) was acquired by Kongsberg from Rolls-Royce plc. It integrated it into its Kongsberg Maritime division. The acquisition will help the company’s expertise in the autonomous vessel and maritime digitalization technology.
Global Electric Ships Market Report Scope:
Historical Data 2019-2020-2021
Base Year for Estimation 2021
Forecast period 2022-2029
Report Coverage Revenue forecast, Company Ranking, Competitive Landscape, Growth factors, and Trends
Segments Covered Power Source, Power Output, Vessel Type, Level of Autonomy, Region
Regional Scope North America; Europe; Asia Pacific; Latin America; Rest of the World
Customization Scope Free report customization (equivalent up to 8 analyst’s working hours) with purchase. Addition or alteration to country, regional & segment scope*
The objective of the study is to define market sizes of different segments & countries in recent years and to forecast the values to the coming years. The report is designed to incorporate both qualitative and quantitative aspects of the industry within countries involved in the study.
The report also caters detailed information about the crucial aspects such as driving factors & challenges which will define the future growth of the market. Additionally, it also incorporates potential opportunities in micro markets for stakeholders to invest along with the detailed analysis of competitive landscape and product offerings of key players. The detailed segments and sub-segment of the market are explained below:
By Power Source:
Fully Electric
Hybrid
By Power Output:
Less than 75 kW
75-745 kW
746-7560 kW
More than 7560 kW
By Vessel Type:
Commercial Vessel
Defense Vessel
By Level of Autonomy:
Semi-Autonomous
Fully Autonomous
By Region:
North America
U.S.
Canada
Europe
UK
Germany
France
Spain
Italy
ROE
Asia Pacific
China
India
Japan
Australia
South Korea
RoAPAC
Latin America
Brazil
Mexico
Rest of the World
Chapter 1. Executive Summary
1.1. Market Snapshot
1.2. Global & Segmental Market Estimates & Forecasts, 2019-2029 (USD Billion)
1.2.1. Electric Ships Market, by Region, 2019-2029 (USD Billion)
1.2.2. Electric Ships Market, by Power Source, 2019-2029 (USD Billion)
1.2.3. Electric Ships Market, by Power Output, 2019-2029 (USD Billion)
1.2.4. Electric Ships Market, by Vessel Type, 2019-2029 (USD Billion)
1.2.5. Electric Ships Market, by Level of Autonomy, 2019-2029 (USD Billion)
1.3. Key Trends
1.4. Estimation Methodology
1.5. Research Assumption
Chapter 2. Global Electric Ships Market Definition and Scope
2.1. Objective of the Study
2.2. Market Definition & Scope
2.2.1. Scope of the Study
2.2.2. Industry Evolution
2.3. Years Considered for the Study
2.4. Currency Conversion Rates
Chapter 3. Global Electric Ships Market Dynamics
3.1. Electric Ships Market Impact Analysis (2019-2029)
3.1.1. Market Drivers
3.1.1.1. Enforcement of 2020 Global Sulphur Cap
3.1.1.2. Beneficial environmental impact
3.1.2. Market Challenges
3.1.2.1. Modern Battery Technology & Expensive Capital
3.1.3. Market Opportunities
3.1.3.1. Growing use of fully electric passenger vessels
3.1.3.2. Demand for zero-emission transportation
Chapter 4. Global Electric Ships Market Industry Analysis
4.1. Porter’s 5 Force Model
4.1.1. Bargaining Power of Suppliers
4.1.2. Bargaining Power of Buyers
4.1.3. Threat of New Entrants
4.1.4. Threat of Substitutes
4.1.5. Competitive Rivalry
4.2. Futuristic Approach to Porter’s 5 Force Model (2019-2029)
4.3. PEST Analysis
4.3.1. Political
4.3.2. Economical
4.3.3. Social
4.3.4. Technological
4.4. Investment Adoption Model
4.5. Analyst Recommendation & Conclusion
4.6. Top investment opportunity
4.7. Top winning strategies
Chapter 5. Risk Assessment: COVID-19 Impact
5.1. Assessment of the overall impact of COVID-19 on the industry
5.2. Pre COVID-19 and post COVID-19 Market scenario
Chapter 6. Global Electric Ships Market, by Power Source
6.1. Market Snapshot
6.2. Global Electric Ships Market by Power Source, Performance – Potential Analysis
6.3. Global Electric Ships Market Estimates & Forecasts by Power Source 2019-2029 (USD Billion)
6.4. Electric Ships Market, Sub Segment Analysis
6.4.1. Fully Electric
6.4.2. Hybrid
Chapter 7. Global Electric Ships Market, by Power Output
7.1. Market Snapshot
7.2. Global Electric Ships Market by Power Output, Performance – Potential Analysis
7.3. Global Electric Ships Market Estimates & Forecasts by Power Output 2019-2029 (USD Billion)
7.4. Electric Ships Market, Sub Segment Analysis
7.4.1. Less than 75 kW
7.4.2. 75-745 kW
7.4.3. 746-7560 kW
7.4.4. More than 7560 kW
Chapter 8. Global Electric Ships Market, by Vessel Type
8.1. Market Snapshot
8.2. Global Electric Ships Market by Vessel Type, Performance – Potential Analysis
8.3. Global Electric Ships Market Estimates & Forecasts by Vessel Type 2019-2029 (USD Billion)
8.4. Electric Ships Market, Sub Segment Analysis
8.4.1. Commercial Vessel
8.4.2. Defense Vessel
Chapter 9. Global Electric Ships Market, by Level of Autonomy
9.1. Market Snapshot
9.2. Global Electric Ships Market by Level of Autonomy, Performance – Potential Analysis
9.3. Global Electric Ships Market Estimates & Forecasts by Level of Autonomy 2019-2029 (USD Billion)
9.4. Electric Ships Market, Sub Segment Analysis
9.4.1. Semi-Autonomous
9.4.2. Fully Autonomous
Chapter 10. Global Electric Ships Market, Regional Analysis
10.1. Electric Ships Market, Regional Market Snapshot
10.2. North America Electric Ships Market
10.2.1. U.S. Electric Ships Market
10.2.1.1. Power Source breakdown estimates & forecasts, 2019-2029
10.2.1.2. Power Output breakdown estimates & forecasts, 2019-2029
10.2.1.3. Vessel Type breakdown estimates & forecasts, 2019-2029
10.2.1.4. Level of Autonomy breakdown estimates & forecasts, 2019-2029
10.2.2. Canada Electric Ships Market
10.3. Europe Electric Ships Market Snapshot
10.3.1. U.K. Electric Ships Market
10.3.2. Germany Electric Ships Market
10.3.3. France Electric Ships Market
10.3.4. Spain Electric Ships Market
10.3.5. Italy Electric Ships Market
10.3.6. Rest of Europe Electric Ships Market
10.4. Asia-Pacific Electric Ships Market Snapshot
10.4.1. China Electric Ships Market
10.4.2. India Electric Ships Market
10.4.3. Japan Electric Ships Market
10.4.4. Australia Electric Ships Market
10.4.5. South Korea Electric Ships Market
10.4.6. Rest of Asia Pacific Electric Ships Market
10.5. Latin America Electric Ships Market Snapshot
10.5.1. Brazil Electric Ships Market
10.5.2. Mexico Electric Ships Market
10.6. Rest of The World Electric Ships Market
Chapter 11. Competitive Intelligence
11.1. Top Market Strategies
11.2. Company Profiles
11.2.1. Kongsberg (Norway)
11.2.1.1. Key Information
11.2.1.2. Overview
11.2.1.3. Financial (Subject to Data Availability)
11.2.1.4. Product Summary
11.2.1.5. Recent Developments
11.2.2. Leclanche (Switzerland)
11.2.3. Corvus Energy (Canada)
11.2.4. Echandia Marine Ab (Sweden)
11.2.5. Siemens (Germany)
11.2.6. Wartsila (Finland)
11.2.7. Vard (Part of Fincantieri Spa) (Norway)
11.2.8. Norwegian Electric Systems (Norway)
11.2.9. General Dynamics Electric Boat (U.S.)
11.2.10. Man Energy Solutions Se (Germany)
Chapter 12. Research Process
12.1. Research Process
12.1.1. Data Mining
12.1.2. Analysis
12.1.3. Market Estimation
12.1.4. Validation
12.1.5. Publishing
12.2. Research Attributes
12.3. Research Assumption
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