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海軍用推進装置の世界市場 (2024~2034年)

Global Naval Propulsion Market 2024-2034

出版日: | 発行: Aviation & Defense Market Reports (A&D) | ページ情報: 英文 150+ Pages | 納期: 3営業日

価格
価格表記: USDを日本円(税抜)に換算
本日の銀行送金レート: 1USD=147.72円
海軍用推進装置の世界市場 (2024~2034年)
出版日: 2024年07月10日
発行: Aviation & Defense Market Reports (A&D)
ページ情報: 英文 150+ Pages
納期: 3営業日
  • 全表示
  • 概要
  • 図表
  • 目次
概要

世界の海軍用推進装置市場は、2024年に254億2,000万米ドルと推定され、予測期間中 (2024~2034年) に1.99%の年間平均成長率 (CAGR) で拡大し、2034年までに309億7,000万米ドルに成長すると予測されています。

Global Naval Propulsion Market-IMG1

世界の海軍用推進装置市場の概要

海軍用推進システムは、船舶が世界の海を航行し、軍事力を投射し、任務を遂行し、海上安全を確保するための重要な動力源です。海軍用推進技術の進化は、世界の海軍艦隊の能力と作戦効果を形成する上で重要な役割を果たしてきました。伝統的な蒸気エンジンから先進的な原子炉や環境的に持続可能なオプションに至るまで、海軍用推進技術は、近代的な海軍作戦の要求を満たすために大きな進歩を遂げてきました。

世界の海軍用推進装置市場における技術の影響

蒸気推進は、19世紀から20世紀初頭にかけて初期の艦艇の動力源となり、海軍作戦において歴史的な重要性を持っています。当初は石炭を燃料とし、後に石油を燃料とした蒸気推進システムは、帆船に比べて航続距離の延長と高速化を実現し、海軍の能力を大幅に向上させました。ガスタービンは20世紀半ばに、蒸気推進よりも優れた出力重量比、効率の向上、メンテナンス要件の低減を実現し、海軍用推進装置に革命をもたらしました。広く採用されたガスタービンは、艦艇の高速化と機動性の向上を可能にし、作戦効果を高めました。

原子力推進は、海軍技術における記念碑的な進歩であり、1954年の米国によるUSSノーチラスの進水で初めて実証されました。原子力艦艇は原子炉を利用し、頻繁な燃料補給を必要とせず、事実上無制限の航続距離と耐久性を提供します。この技術は、潜水艦や航空母艦の世界の運用を可能にし、海軍作戦における強力な資産としての役割を果たしています。最新の潜水艦では、ディーゼル発電機やガスタービンと電気モーターを統合した電気推進システムがますます普及しています。このシステム構成は、より静かな動作、ステルス性能の向上、運用効率の向上を実現し、潜水艦が長時間の任務を隠密裏に遂行することを可能にします。

ハイブリッド燃料と代替燃料は、環境の持続可能性の目標と化石燃料への依存度の低減に後押しされ、海軍用推進装置における革新の重要な分野として浮上してきました。液化天然ガス (LNG) や燃料電池のような技術は、海軍の即応性を確保しつつ、二酸化炭素排出量と運用コストを最小限に抑えることを目指し、従来の燃料に代わる実行可能な技術として研究されています。これらの進歩は、技術がいかに海軍艦艇の操縦、運用、そして世界な舞台での力発揮を再定義し続けているかを明確に示しています。蒸気推進の歴史的意義から、原子力および電気推進システムの変革的能力に至るまで、それぞれの技術革新は、現代の海上作戦における海軍の能力、効率、持続可能性の向上に貢献してきました。

世界の海軍用推進装置市場の主な促進要因

海軍用推進市場の主な促進要因:

いくつかの要因が、先進的な海軍用推進システムの開発と採用を推進し、世界中の現代海軍の能力と戦略目標を形成しています。

海軍用推進システム開発の中核にあるのは軍事能力の強化です。これらのシステムは、速度、耐久性、作戦範囲などの主要な軍事能力を強化する上で極めて重要です。現代の海軍は、船舶の性能を向上させるだけでなく、多様な海洋環境における応答性と任務の有効性を高める推進技術を優先しています。

技術革新は、海軍用推進システムの進歩において極めて重要な役割を果たしています。継続的な研究開発は、高効率、低排出、信頼性の向上を目指しています。材料科学、数値流体力学、パワーエレクトロニクスにおける革新は、推進技術の進化に大きく貢献し、海軍が技術進歩の最前線に立ち続けることを確実にしています。

戦略的優位性を維持し、海洋権益を守るために、海軍大国は最先端の推進システムに投資することが戦略的重要性から求められています。これらの技術により、海軍は世界な戦力投射、遠征作戦の支援、人道的任務への参加を可能にし、国家安全保障と国際的影響力を強化することができます。

海軍の活動には柔軟性が不可欠であり、多用途性、急加速、機動性、静粛性を備えた推進システムが要求されます。これらの特性は、海上でダイナミックに進化する脅威に効果的に対応し、戦闘活動から平和維持活動、災害救援活動まで幅広い任務プロファイルをサポートするために不可欠です。

環境への配慮は、海軍用推進システムの選択にますます影響を及ぼしています。海上活動が環境に与える影響に対する認識が高まるにつれ、海軍はよりクリーンで持続可能な推進技術の採用を余儀なくされています。規制要件と国際協定は、エネルギー効率の高いソリューションと代替燃料の統合を推進し、二酸化炭素排出量の削減と海軍活動に伴う海洋汚染の軽減を目指しています。

世界の海軍用推進装置市場の地域別動向

海軍用推進技術および戦略は、地政学的力学、運用ニーズ、技術能力の影響を受け、地域間で大きな多様性を示しています。

北米は、特に原子力空母と原子力潜水艦の開発で顕著なように、海軍用推進装置の革新でリードしています。米国は、長期の耐久性と運用能力のために原子炉技術の進歩に重点を置いています。さらに、ガスタービンシステムの最適化と代替燃料の研究は、海軍の効率と持続可能性を高めるための重要な重点分野です。欧州は、エネルギー効率の高い推進システムとハイブリッド電気技術を海軍艦隊に優先的に導入しています。英国、フランス、ドイツなどの国々は、排出量の削減と再生可能エネルギー源の艦艇への統合に取り組んでいます。この戦略的アプローチは、海上防衛能力を強化すると同時に、作戦の持続可能性を高めることを目的としています。

中国、インド、日本などのアジア太平洋諸国は、自国の艦隊を近代化し、地域の海上支配力を主張するために、先進的な海軍用推進技術に多額の投資を行っています。原子力潜水艦は、ガスタービン推進の研究や自前の電気推進システムの開発と並んで、重要な焦点となっています。これらの努力は、広大な海洋領土における海軍の戦力投射能力の強化に向けたものです。イスラエル、サウジアラビア、アラブ首長国連邦などの中東諸国は、先進推進システムによる海軍能力の強化を優先しています。効率的なガスタービンエンジンによる艦隊の近代化や、潜水艦の原子力推進の実現可能性を探るための投資が行われています。これらのイニシアチブは、海洋安全保障を強化し、この地域における強固な防衛態勢を維持することを目的としています。

世界のその他の地域には、ラテンアメリカ、アフリカ、オセアニアの新興海軍大国が含まれ、それぞれが海軍用推進装置への独自のアプローチを追求しています。これらの地域は、ディーゼル電気潜水艦の利用から、海軍の即応性、海上安全保障、災害対応能力の強化を目的としたハイブリッド推進システムの採用まで幅広いです。これらの戦略は、運用上のニーズと経済的制約および技術の進歩とのバランスを取る努力を反映しています。

海軍用推進装置の主要プログラム

Fluor Corporationは、完全子会社であるFluor Marine Propulsion, LLCとの契約を海軍省から延長されたことを発表しました。この契約延長は、エネルギー省国家核安全保障局と海軍省が共同で管理する海軍原子炉プログラムの一環です。ニューヨーク、ペンシルバニア、アイダホにある複数の海軍原子力研究所 (NNL) での海軍原子力推進工事に関わるものです。この1年間のオプションは11億6,000万米ドルで、コスト・プラス・フィーの取り決めとなっています。

BWX Technologiesは、米国海軍原子力推進プログラムの下で約3億米ドルの契約を獲得したことを発表しました。この契約は海軍原子炉燃料の製造に関するもので、テネシー州アーウィンを拠点とするBWXT社の子会社Nuclear Fuel Services, Inc.が受注しました。契約条件に基づき、Nuclear Fuel Servicesは海軍原子炉プログラム専用の燃料を製造・納入します。BWXT社の燃料と原子炉は、オハイオ級、バージニア級、シーウルフ級、ロサンゼルス級を含む米国海軍のさまざまなクラスの潜水艦や、ニミッツ級、フォード級航空母艦の動力源として不可欠です。さらに、BWXT社の燃料と原子炉は、海軍の将来のコロンビア級潜水艦をサポートします。燃料の製造が完了すると、燃料はバージニア州リンチバーグ近郊にあるBWXT社の施設に運ばれ、そこでBWXT社が製造する海軍用原子炉への最終的な取り付けが行われます。現在開発中の潜水艦用原子炉は、艦船の全寿命にわたって稼働することを目的としていますが、航空母艦用の原子炉は、艦船の耐用期間中に1回の燃料補給を行うことを目的として設計されています。

当レポートでは、世界の海軍用推進装置市場について分析し、全体的な市場規模の動向見通しや、地域別・国別の詳細動向、主要技術の概略、市場機会などを調査しております。

目次

海軍用推進装置市場:レポートの定義

海軍用推進装置市場の内訳

  • 地域別
  • プラットフォーム別
  • 種類別

海軍用推進装置市場の分析 (今後10年間)

海軍用推進装置市場のマーケットテクノロジー

世界の海軍用推進装置市場の予測

海軍用推進装置市場:地域別の動向と予測

  • 北米
    • 促進・抑制要因、課題
    • PEST分析
    • 市場予測とシナリオ分析
    • 主要企業
    • サプライヤー階層の情勢
    • 企業のベンチマーク
  • 欧州
  • 中東
  • アジア太平洋
  • 南米

海軍用推進装置市場:国別分析

  • 米国
    • 防衛計画
    • 最新動向
    • 特許
    • この市場における現在の技術成熟レベル
    • 市場予測とシナリオ分析
  • カナダ
  • イタリア
  • フランス
  • ドイツ
  • オランダ
  • ベルギー
  • スペイン
  • スウェーデン
  • ギリシャ
  • オーストラリア
  • 南アフリカ
  • インド
  • 中国
  • ロシア
  • 韓国
  • 日本
  • マレーシア
  • シンガポール
  • ブラジル

海軍用推進装置市場:市場機会マトリックス

海軍用推進装置市場:調査に関する専門家の見解

結論

Aviation and Defense Market Reportsについて

図表

List of Tables

  • Table 1: 10 Year Market Outlook, 2024-2034
  • Table 2: Drivers, Impact Analysis, North America
  • Table 3: Restraints, Impact Analysis, North America
  • Table 4: Challenges, Impact Analysis, North America
  • Table 5: Drivers, Impact Analysis, Europe
  • Table 6: Restraints, Impact Analysis, Europe
  • Table 7: Challenges, Impact Analysis, Europe
  • Table 8: Drivers, Impact Analysis, Middle East
  • Table 9: Restraints, Impact Analysis, Middle East
  • Table 10: Challenges, Impact Analysis, Middle East
  • Table 11: Drivers, Impact Analysis, APAC
  • Table 12: Restraints, Impact Analysis, APAC
  • Table 13: Challenges, Impact Analysis, APAC
  • Table 14: Drivers, Impact Analysis, South America
  • Table 15: Restraints, Impact Analysis, South America
  • Table 16: Challenges, Impact Analysis, South America
  • Table 17: Scenario Analysis, Scenario 1, By Region, 2024-2034
  • Table 18: Scenario Analysis, Scenario 1, By Platform, 2024-2034
  • Table 19: Scenario Analysis, Scenario 1, By Type, 2024-2034
  • Table 20: Scenario Analysis, Scenario 2, By Region, 2024-2034
  • Table 21: Scenario Analysis, Scenario 2, By Platform, 2024-2034
  • Table 22: Scenario Analysis, Scenario 2, By Type, 2024-2034

List of Figures

  • Figure 1: Global Naval Propulsion Market Forecast, 2024-2034
  • Figure 2: Global Naval Propulsion Market Forecast, By Region, 2024-2034
  • Figure 3: Global Naval Propulsion Market Forecast, By Platform, 2024-2034
  • Figure 4: Global Naval Propulsion Market Forecast, By Type, 2024-2034
  • Figure 5: North America, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 6: Europe, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 7: Middle East, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 8: APAC, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 9: South America, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 10: United States, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 11: United States, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 12: Canada, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 13: Canada, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 14: Italy, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 15: Italy, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 16: France, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 17: France, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 18: Germany, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 19: Germany, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 20: Netherlands, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 21: Netherlands, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 22: Belgium, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 23: Belgium, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 24: Spain, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 25: Spain, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 26: Sweden, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 27: Sweden, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 28: Brazil, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 29: Brazil, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 30: Australia, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 31: Australia, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 32: India, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 33: India, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 34: China, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 35: China, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 36: Saudi Arabia, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 37: Saudi Arabia, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 38: South Korea, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 39: South Korea, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 40: Japan, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 41: Japan, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 42: Malaysia, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 43: Malaysia, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 44: Singapore, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 45: Singapore, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 46: United Kingdom, Naval Propulsion Market, Technology Maturation, 2024-2034
  • Figure 47: United Kingdom, Naval Propulsion Market, Market Forecast, 2024-2034
  • Figure 48: Opportunity Analysis, Naval Propulsion Market, By Region (Cumulative Market), 2024-2034
  • Figure 49: Opportunity Analysis, Naval Propulsion Market, By Region (CAGR), 2024-2034
  • Figure 50: Opportunity Analysis, Naval Propulsion Market, By Platform (Cumulative Market), 2024-2034
  • Figure 51: Opportunity Analysis, Naval Propulsion Market, By Platform (CAGR), 2024-2034
  • Figure 52: Opportunity Analysis, Naval Propulsion Market, By Type (Cumulative Market), 2024-2034
  • Figure 53: Opportunity Analysis, Naval Propulsion Market, By Type (CAGR), 2024-2034
  • Figure 54: Scenario Analysis, Naval Propulsion Market, Cumulative Market, 2024-2034
  • Figure 55: Scenario Analysis, Naval Propulsion Market, Global Market, 2024-2034
  • Figure 56: Scenario 1, Naval Propulsion Market, Total Market, 2024-2034
  • Figure 57: Scenario 1, Naval Propulsion Market, By Region, 2024-2034
  • Figure 58: Scenario 1, Naval Propulsion Market, By Platform, 2024-2034
  • Figure 59: Scenario 1, Naval Propulsion Market, By Type, 2024-2034
  • Figure 60: Scenario 2, Naval Propulsion Market, Total Market, 2024-2034
  • Figure 61: Scenario 2, Naval Propulsion Market, By Region, 2024-2034
  • Figure 62: Scenario 2, Naval Propulsion Market, By Platform, 2024-2034
  • Figure 63: Scenario 2, Naval Propulsion Market, By Type, 2024-2034
  • Figure 64: Company Benchmark, Naval Propulsion Market, 2024-2034
目次
Product Code: AND064

The Global Naval Propulsion market is estimated at USD 25.42 billion in 2024, projected to grow to USD 30.97 billion by 2034 at a Compound Annual Growth Rate (CAGR) of 1.99% over the forecast period 2024-2034.

Global Naval Propulsion Market - IMG1

Introduction to Naval Propulsion Market

Naval propulsion systems are the critical power sources that enable ships to navigate through the world's oceans, projecting military power, conducting missions, and ensuring maritime security. The evolution of naval propulsion technology has been instrumental in shaping the capabilities and operational effectiveness of naval fleets globally. From traditional steam engines to advanced nuclear reactors and environmentally sustainable options, naval propulsion has undergone significant advancements to meet the demands of modern naval operations.

Technology Impact in Naval Propulsion Market:

The impact of technology on naval propulsion has fundamentally transformed the capabilities and operational dynamics of modern naval fleets. Several key technological advancements have played pivotal roles in this evolution:

Steam Propulsion has a historical significance in naval operations, powering early vessels during the 19th and early 20th centuries. Initially fueled by coal and later oil, steam propulsion systems provided extended range and higher speeds compared to sail-powered ships, thereby significantly enhancing naval capabilities. Gas Turbines revolutionized naval propulsion during the mid-20th century by offering superior power-to-weight ratios, enhanced efficiency, and reduced maintenance requirements over steam propulsion. Widely adopted, gas turbines enabled naval vessels to achieve faster speeds and greater maneuverability, thus enhancing their operational effectiveness.

Nuclear Propulsion represents a monumental advancement in naval technology, first demonstrated with the launch of the USS Nautilus by the United States in 1954. Nuclear-powered naval vessels utilize nuclear reactors to provide virtually unlimited operational range and endurance without the need for frequent refueling. This technology has empowered submarines and aircraft carriers to operate globally, serving as formidable assets in naval operations. Electric Propulsion Systems are increasingly prevalent in modern submarines, integrating diesel generators or gas turbines with electric motors. This system configuration offers quieter operation, improved stealth capabilities, and enhanced operational efficiency, enabling submarines to conduct extended-duration missions covertly.

Hybrid and Alternative Fuels have emerged as critical areas of innovation in naval propulsion, driven by environmental sustainability goals and reduced reliance on fossil fuels. Technologies such as liquefied natural gas (LNG) and fuel cells are being explored as viable alternatives to conventional fuels, aiming to minimize carbon emissions and operational costs while ensuring naval readiness. These advancements underscore how technology continues to redefine how naval vessels maneuver, operate, and project power on the global stage. From the historical significance of steam propulsion to the transformative capabilities of nuclear and electric propulsion systems, each innovation has contributed to enhancing naval capabilities, efficiency, and sustainability in modern maritime operations.

Key Drivers in Naval Propulsion Market:

Several factors converge to drive the development and adoption of advanced naval propulsion systems, shaping the capabilities and strategic objectives of modern navies worldwide.

Military Capability Enhancement lies at the core of naval propulsion system development. These systems are pivotal in enhancing key military capabilities such as speed, endurance, and operational range. Modern navies prioritize propulsion technologies that not only improve vessel performance but also enhance responsiveness and mission effectiveness across diverse maritime environments.

Technological Innovation plays a crucial role in advancing naval propulsion systems. Continuous research and development efforts aim to achieve higher efficiency, lower emissions, and increased reliability. Innovations in materials science, computational fluid dynamics, and power electronics contribute significantly to the evolution of propulsion technologies, ensuring navies stay at the forefront of technological advancements.

Strategic Imperatives drive naval powers to invest in cutting-edge propulsion systems to maintain strategic superiority and safeguard maritime interests. These technologies enable navies to project power globally, support expeditionary operations, and participate in humanitarian missions, thereby bolstering national security and international influence.

Operational Flexibility is critical for naval operations, demanding propulsion systems that offer versatility, rapid acceleration, maneuverability, and silent operation. These attributes are essential for responding effectively to dynamic and evolving threats at sea, supporting a wide range of mission profiles from combat operations to peacekeeping and disaster relief efforts.

Environmental Considerations are increasingly influencing naval propulsion system choices. With heightened awareness of the environmental impact of maritime operations, navies are compelled to adopt cleaner and more sustainable propulsion technologies. Regulatory requirements and international agreements drive the integration of energy-efficient solutions and alternative fuels, aiming to mitigate carbon footprints and reduce marine pollution associated with naval activities.

Regional Trends in Naval Propulsion Market:

Naval propulsion technologies and strategies exhibit significant diversity across regions, influenced by geopolitical dynamics, operational needs, and technological capabilities.

North America leads in naval propulsion innovation, particularly evident in its development of nuclear-powered aircraft carriers and submarines. The United States places emphasis on advancing nuclear reactor technology for extended endurance and operational capabilities. Additionally, optimization of gas turbine systems and research into alternative fuels are key areas of focus to enhance naval efficiency and sustainability. Europe prioritizes energy-efficient propulsion systems and hybrid electric technologies within its naval fleets. Nations such as the United Kingdom, France, and Germany are committed to reducing emissions and integrating renewable energy sources into their vessels. This strategic approach aims to enhance operational sustainability while bolstering maritime defense capabilities.

Asia-Pacific nations like China, India, and Japan are investing heavily in advanced naval propulsion technologies to modernize their fleets and assert regional maritime dominance. Nuclear-powered submarines represent a significant focus, alongside research into gas turbine propulsion and the development of indigenous electric propulsion systems. These efforts are geared towards strengthening naval power projection capabilities across vast oceanic territories. Middle Eastern countries including Israel, Saudi Arabia, and the United Arab Emirates prioritize enhancing naval capabilities through advanced propulsion systems. Investments are directed towards modernizing fleets with efficient gas turbine engines and exploring the feasibility of nuclear propulsion for submarines. These initiatives aim to bolster maritime security and maintain a robust defense posture in the region.

Rest of the World encompasses emerging naval powers in Latin America, Africa, and Oceania, each pursuing tailored approaches to naval propulsion. These regions range from utilizing diesel-electric submarines to adopting hybrid propulsion systems aimed at enhancing naval readiness, maritime security, and disaster response capabilities. Their strategies reflect efforts to balance operational needs with economic constraints and technological advancements.

Key Naval Propulsion Program:

Fluor Corporation has announced the extension of its contract with Fluor Marine Propulsion, LLC, a wholly-owned subsidiary, by the Department of the Navy . This contract extension is part of the Naval Reactors program, jointly managed by the Department of Energy's National Nuclear Security Administration and the Department of the Navy. It involves Naval Nuclear Propulsion work at several Navy Nuclear Laboratory (NNL) sites located in New York, Pennsylvania, and Idaho. The one-year option, valued at $1.16 billion, is structured as a cost-plus-fixed-fee arrangement.

BWX Technologies, Inc. has announced the award of a contract under the U.S. Naval Nuclear Propulsion Program valued at approximately $300 million. This contract is for the manufacturing of naval nuclear reactor fuel and has been awarded to BWXT's subsidiary, Nuclear Fuel Services, Inc., based in Erwin, Tennessee. Under the terms of the contract, Nuclear Fuel Services will produce and deliver fuel specifically for the Naval Reactors Program. BWXT's fuel and reactors are integral to powering various classes of U.S. Navy submarines including Ohio, Virginia, Seawolf, and Los Angeles classes, as well as the Nimitz and Ford class aircraft carriers. Additionally, BWXT's fuel and reactors will support the Navy's future Columbia-class submarines. Upon completion of fuel production, the fuel is transported to BWXT's facility near Lynchburg, Virginia, where it undergoes final installation into the naval reactors manufactured by BWXT. The reactors designed for submarines currently under development are intended to operate for the entire lifespan of the ship, while those for aircraft carriers are designed for a single refueling during the ship's service life.

Table of Contents

Naval Propulsion Market Report Definition

Naval Propulsion Market Segmentation

By Region

By Platforms

By Type

Naval Propulsion Market Analysis for next 10 Years

The 10-year naval propulsion market analysis would give a detailed overview of naval propulsion market growth, changing dynamics, technology adoption overviews and the overall market attractiveness is covered in this chapter.

Market Technologies of Naval Propulsion Market

This segment covers the top 10 technologies that is expected to impact this market and the possible implications these technologies would have on the overall market.

Global Naval Propulsion Market Forecast

The 10-year Naval Propulsion Market forecast of this market is covered in detailed across the segments which are mentioned above.

Regional Naval Propulsion Market Trends & Forecast

The regional naval propulsion market trends, drivers, restraints and Challenges of this market, the Political, Economic, Social and Technology aspects are covered in this segment. The market forecast and scenario analysis across regions are also covered in detailed in this segment. The last part of the regional analysis includes profiling of the key companies, supplier landscape and company benchmarking. The current market size is estimated based on the normal scenario.

North America

Drivers, Restraints and Challenges

PEST

Market Forecast & Scenario Analysis

Key Companies

Supplier Tier Landscape

Company Benchmarking

Europe

Middle East

APAC

South America

Country Analysis of Naval Propulsion Market

This chapter deals with the key defense programs in this market, it also covers the latest news and patents which have been filed in this market. Country level 10 year market forecast and scenario analysis are also covered in this chapter.

US

Defense Programs

Latest News

Patents

Current levels of technology maturation in this market

Market Forecast & Scenario Analysis

Canada

Italy

France

Germany

Netherlands

Belgium

Spain

Sweden

Greece

Australia

South Africa

India

China

Russia

South Korea

Japan

Malaysia

Singapore

Brazil

Opportunity Matrix for Naval Propulsion Market

The opportunity matrix helps the readers understand the high opportunity segments in this market.

Expert Opinions on Naval Propulsion Market Report

Hear from our experts their opinion of the possible analysis for this market.

Conclusions

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