DOCSLIB.ORG

Abs Advisory on Decarbonization Applications for Power Generation and Propulsion Systems

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Abs Advisory on Decarbonization Applications for Power Generation and Propulsion Systems ABS ADVISORY ON DECARBONIZATION APPLICATIONS FOR POWER GENERATION AND PROPULSION SYSTEMS ABS | ADVISORY ON DECARBONIZATION APPLICATIONS FOR POWER GENERATION AND PROPULSION SYSTEMS | 01 © Andrey Sharpilo/Shutterstock OUR MISSION The mission of ABS is to serve the public interest as well as the needs of our members and clients by promoting the security of life and property and preserving the natural environment. HEALTH, SAFETY, QUALITY & ENVIRONMENTAL POLICY We will respond to the needs of our members and clients and the public by delivering quality service in support of our Mission that provides for the safety of life and property and the preservation of the marine environment. We are committed to continually improving the effectiveness of our HSQE performance and management system with the goal of preventing injury, ill health and pollution. We will comply with all applicable legal requirements as well as any additional requirements ABS subscribes to which relate to HSQE aspects, objectives and targets. Disclaimer: While ABS uses reasonable efforts to accurately describe and update the information in this Advisory, ABS makes no warranties or representations as to its accuracy, currency or completeness. ABS assumes no liability or responsibility for any errors or omissions in the content of this Advisory. To the extent permitted by applicable law, everything in this Advisory is provided “as is” without warranty of any kind, either expressed or implied, including, but not limited to, the implied warranties of merchantability, fitness for a particular purpose, or noninfringement. In no event will ABS be liable for any damages whatsoever, including special, indirect, consequential or incidental damages or damages for loss of profits, revenue or use, whether brought in contract or tort, arising out of or connected with this Advisory or the use or reliance upon any of the content or any information contained herein. —— TABLE OF CONTENTS 1 INTRODUCTION ......................................................................................................................................................................1 2 INTERNAL COMBUSTION ENGINES ................................................................................................................................4 2.1 Current Applications .........................................................................................................................................................................................................................................4 2.2 Support Equipment and Systems .......................................................................................................................................................................................................6 2.3 Fuel Options .................................................................................................................................................................................................................................................................9 2.4 Ship Design and Modifications ...........................................................................................................................................................................................................11 2.5 Regulatory Requirements ...........................................................................................................................................................................................................................11 2.6 Crew Training ..........................................................................................................................................................................................................................................................11 2.7 Safety ...................................................................................................................................................................................................................................................................................12 3 STEAM TURBINES ............................................................................................................................................................... 13 3.1 Current Applications .....................................................................................................................................................................................................................................13 3.2 Support Equipment and Systems ...................................................................................................................................................................................................18 3.3 Fuel Options ...............................................................................................................................................................................................................................................................19 3.4 Ship Design and Modifications ........................................................................................................................................................................................................20 3.5 Regulatory Requirements ........................................................................................................................................................................................................................20 3.6 Crew Training .........................................................................................................................................................................................................................................................20 3.7 Safety .................................................................................................................................................................................................................................................................................20 4 GAS TURBINES ..................................................................................................................................................................... 21 4.1 Current Applications .....................................................................................................................................................................................................................................21 4.2 Fuel Options ..............................................................................................................................................................................................................................................................23 4.3 Ship Design and Modifications .........................................................................................................................................................................................................24 4.4 Regulatory Requirements .........................................................................................................................................................................................................................25 4.5 Crew Training ..........................................................................................................................................................................................................................................................25 4.6 Safety ..................................................................................................................................................................................................................................................................................25 5 FUEL CELLS ......................................................................................................................................................................... 26 5.1 Current Applications ......................................................................................................................................................................................................................................26 5.2 Support Equipment and Systems ....................................................................................................................................................................................................28 5.3 Fuel Options .............................................................................................................................................................................................................................................................30 5.4 Ship Design and Modifications ..........................................................................................................................................................................................................31 5.5 Regulation Requirements ..........................................................................................................................................................................................................................31 5.6 Crew Training ........................................................................................................................................................................................................................................................32 5.7 Safety ..................................................................................................................................................................................................................................................................................32
Load more

Recommended publications
  • MARINE ENGINES Power &Propulsion Solutions Index
    MARINE ENGINES Power & propulsion solutions Ed. 2018/05 Ed. Index Power range ............................................ 3 Engine range ........................................... 5 Power generation ................................... 8 Marine solutions ..................................... 9 Hybrid systems ..................................... 11 References ............................................ 15 Overall data....... .................................... 18 Anglo Belgian Corporation (ABC) is one of Europe’s leading medium speed engine manufacturers. The company offers more than a century of expertise in ship propulsion. ABC was originally established in 1912 by a group of industri- alists, with participation of the inventor of the diesel engine, Rudolf Diesel himself. An important step in ABC’s history was the acquisition by OGEPAR (1985), a strong fi nancial holding with a large base in metal industry and engineering. Today, ABC has risen far above the standard of engine manufacturer. The company is constantly evolving, developing new solutions in the fi eld of marine propulsion, power generation and locomotive traction. Through innovative thinking, ABC aims to increase sustainability and supply reliable and effi cient products within a framework of ecological development. All engines are designed for heavy duty and continuous operation, straightforward applications and easy maintenance. ABC headquarters and production facility in Ghent, Belgium ABC engines, your * Polar cruise vessel equipped with: 2 x 12DZC @ 750 rpm partner at sea 2 x 6DZC @ 750 rpm For more than 100 years ABC has been supplying power The best quality indicators of our work and engines are solutions to all those who know that the engine is the heart those clients who have trusted us, since 4 generations, of their vessels. ABC engines stand for reliability and good with the installation of our engines in their ships, performance under the hardest and most demanding condi- showing this trust from father to son.
    [Show full text]
  • Security & Defence European
    a 7.90 D European & Security ES & Defence 4/2016 International Security and Defence Journal Protected Logistic Vehicles ISSN 1617-7983 • www.euro-sd.com • Naval Propulsion South Africa‘s Defence Exports Navies and shipbuilders are shifting to hybrid The South African defence industry has a remarkable breadth of capa- and integrated electric concepts. bilities and an even more remarkable depth in certain technologies. August 2016 Jamie Shea: NATO‘s Warsaw Summit Politics · Armed Forces · Procurement · Technology The backbone of every strong troop. Mercedes-Benz Defence Vehicles. When your mission is clear. When there’s no road for miles around. And when you need to give all you’ve got, your equipment needs to be the best. At times like these, we’re right by your side. Mercedes-Benz Defence Vehicles: armoured, highly capable off-road and logistics vehicles with payloads ranging from 0.5 to 110 t. Mobilising safety and efficiency: www.mercedes-benz.com/defence-vehicles Editorial EU Put to the Test What had long been regarded as inconceiv- The second main argument of the Brexit able became a reality on the morning of 23 campaigners was less about a “democratic June 2016. The British voted to leave the sense of citizenship” than of material self- European Union. The majority that voted for interest. Despite all the exception rulings "Brexit", at just over 52 percent, was slim, granted, the United Kingdom is among and a great deal smaller than the 67 percent the net contribution payers in the EU. This who voted to stay in the then EEC in 1975, money, it was suggested, could be put to but ignoring the majority vote is impossible.
    [Show full text]
  • Y ...Signature Redacted
    Modeling Brake Specific Fuel Consumption to Support Exploration of Doubly Fed Electric Machines in Naval Engineering Applications by Michael R. Rowles, Jr. B.E., Electrical Engineering, Naval Architecture, State University of New York, Maritime College, 2006 Submitted to the Department of Mechanical Engineering in Partial Fulfillment of the Requirements for the Degrees of Naval Engineer and Master of Science in Naval Architecture and Marine Engineering at the MASSACHUSETTS INSTITUTE OF TECHNOLOGY June 2016. 2016 Michael R. Rowles, Jr. All rights reserved. The author hereby grants to MIT permission to reproduce and to distribute publicly paper and electronic copies of this thesis document in whole or in part in any medium now known or hereafter c: A uth or ........................................... Signature redacted Department of Mechanical Engineering A may 22,k 2016 C ertified by ............................ Signature redacted .... Weston L. Gray, CDR, USN Associate Professor of the Practice, Naval Construction and Engineering redacted ..Thesis Reader Certified by .......... Signature Ll James L. Kirtley Professor of Electrical Engineering redacted Isis Supervisor Accepted by ............ SSignatu gnatu re ...................... Rohan Abeyaratne MASSACHUSETTS INSTITUTE Chairman, Committee on Graduate Students OF TECHNOLOGY Quentin Berg Professor of Mechanics Department of Mechanical Engineering JUN 02 2016 LIBRARIES ARCHIVES Modeling Brake Specific Fuel Consumption to Support Exploration of Doubly Fed Electric Machines in Naval Engineering Applications by Michael R. Rowles, Jr. Submitted to the Department of Mechanical Engineering on May 12, 2016 in Partial Fulfillment of the Requirements for Degrees of Naval Engineer and Master of Science in Mechanical Engineering Abstract The dynamic operational nature of naval power and propulsion requires Ship Design and Program Managers to design and select prime movers using a much more complex speed profile rather than typical of commercial vessels.
    [Show full text]
  • The ABB ETB (Electric Towboat) the US Inland River Market Is Ready For
    — WHITEPAPER The ABB ETB (Electric Towboat) The U.S. inland river market is ready for electric propulsion — The ABB ETB The U.S. inland river market 2 ABB ETB THE U.S. INLAND RIVER MARKET IS READY FOR ELECTRIC PROPULSION — Abstract ABB’s electric propulsion systems are available to help long- established towboat owners in the U.S. inland waterway market to solve some very modern challenges. Electric propulsion has proven itself among own- Authors: Edward Schwarz, Vice President, Sales, ers of many different vessel types. Now ABB’s New Build Sales; Richard Rozok, Technical Man- electric propulsion systems are available to help ager, Sales, New Build Sales. long-established towboat owners in the U.S. in- land waterway market to solve some very modern Edward Schwarz is responsible for business de- challenges. With regulators re-stricting emissions velopment and the development of new sales pro- from ships to EPA Tier 4 standards, diesel electric grams for ABB’s marine and ports business unit in propulsion offers owners a way to build compli- North America. With his long experience in the ant vessels operating on easier to meet Tier 3 marine propulsion market, Ed brings new con- main engines. cepts to unique vessel applications. ABB has taken the time to understand the de- Richard Rozok is responsible for developing new mands of this unique sector, creating solutions technical solutions for the North American new whose flexibility addresses new regulations, in- sales program. He brings proven technical exper- creasing CAPEX costs for new builds, the impera- tise and the ability to find practical and creative tive for lower OPEX costs and demand for greater solutions to solve vessel owner’s problems.
    [Show full text]
  • The Future in Warship Propulsion
    ELECTRICAL PROPULSION: THE FUTURE IN WARSHIP PROPULSION LCdr R.R.A. Sauvé JCSP 42 PCEMI 42 Service Paper Étude militaire Disclaimer Avertissement Opinions expressed remain those of the author and Les opinons exprimées n’engagent que leurs auteurs do not represent Department of National Defence or et ne reflètent aucunement des politiques du Canadian Forces policy. This paper may not be used Ministère de la Défense nationale ou des Forces without written permission. canadiennes. Ce papier ne peut être reproduit sans autorisation écrite. © Her Majesty the Queen in Right of Canada, as © Sa Majesté la Reine du Chef du Canada, représentée par represented by the Minister of National Defence, 2016. le ministre de la Défense nationale, 2016. CANADIAN FORCES COLLEGE – COLLÈGE DES FORCES CANADIENNES JCSP 42 – PCEMI 42 2015 – 2016 JCSP SERVICE PAPER – PCEMI ÉTUDE MILITAIRE ELECTRICAL PROPULSION: THE FUTURE IN WARSHIP PROPULSION LCdr R.R.A. Sauvé “This paper was written by a student “La présente étude a été rédigée par un attending the Canadian Forces College stagiaire du Collège des Forces in fulfilment of one of the requirements canadiennes pour satisfaire à l'une des of the Course of Studies. The paper is a exigences du cours. L'étude est un scholastic document, and thus contains document qui se rapporte au cours et facts and opinions, which the author contient donc des faits et des opinions alone considered appropriate and que seul l'auteur considère appropriés et correct for the subject. It does not convenables au sujet. Elle ne reflète pas necessarily reflect the policy or the nécessairement la politique ou l'opinion opinion of any agency, including the d'un organisme quelconque, y compris le Government of Canada and the gouvernement du Canada et le ministère Canadian Department of National de la Défense nationale du Canada.
    [Show full text]
  • High-Tech Electric Propulsion
    TORQEEDO TORQEEDO High-tech electric propulsion A rigorous focus on cutting-edge technology, R&D and new production processes, as well as optimizing performance, comfort, safety and economic features, has made one German supplier a key player in electric and hybrid marine technology WORDS: DR CHRISTOPH BALLIN hen Torqeedo’s founders, Dr Christoph Ballin and Dr Friedrich WBoebel, looked at solutions for electric propulsion systems for boats in 2004, they noted that existing products did not reflect the then state of technology, with the solutions coming from low-volume, high- price manufacturing starting points. This gap in the market prompted the creation of Torqeedo, a new player in the marine industry, focusing only on high-tech propulsion, combined with industrial R&D and manufacturing, to realize competitive price points while also providing revolutionary benefits. Despite being founded less than a decade ago, Torqeedo has already gathered critical global acclaim by being first to market with key innovations. For example, the company was the first to introduce brushless motors into marine propulsion. It was also the first to introduce lithium batteries to the marine industry on a broad scale and the first to integrate them into electric outboard designs. These critical breakthroughs, and many other high-tech innovations, have made Torqeedo one of the best-known brands in the field of marine electric propulsion. Located in Starnberg, near Munich, with sales offices in the USA, the UK, France and Spain, Torqeedo offers propulsion systems from 0.5kW through to 110kW, all developed according to the same ethos – superior technology with revolutionary benefits.
    [Show full text]
  • A Survey of Conventional and Unconventional Sub Marine Propulsion Systems
    UNCLASSIFIED AD NUMBER AD342338 CLASSIFICATION CHANGES TO: unclassified FROM: confidential LIMITATION CHANGES TO: Approved for public release, distribution unlimited FROM: Distribution: Further dissemination only as directed by Office of Naval Research, Attn: Code 429, Arlington, VA, 30 APR 1963, or higher DoD authority. AUTHORITY 31 Dec 1972 per document marking; ONR itr, 4 may 1977 THIS PAGE IS UNCLASSIFIED GENER AL DECL SCHEDULEASSIFICAT]ri INACCORDANCE WITH 0D0 5200.1-R & EXECUTIVE ORDER 11652 THI S DOC UMENT 1 ,toultjec" to Generni Declassification Schedule of xu.cutive C-der 11652-Automatically Downgraded att intervals-SYeats 9ECLASSIFIEO ON DECEMBER 31,_7Ii• BY uttanst Documentation Center Weie,.-e Supply Agency r :ieron Station V',gi i 22314 ADL DEFENSE DOUiMENIAION CENTER SCIENTIFIC AND fECHNICA I ii'*O9MATION CAMERON SIAPbDN, Al XANDP1;A. ViRGlN IA MWI NOTICE: When &g,-zrwwv or other &~~speoi- fica~tions or othcr Utita are used fo i jutrpose other than in compc-tion vith a. dY4M'*tcly related. gosvernmemt prood-e3ment operatiar, the U. S. Government thereby incuxs no re~ap. -ibility, nor any obligeaion vhatsoever3- and the ':eq,-ttthe Govern- ment may have :Vormujlated, fudýeý or L,,a -- y vay supplied the said dmvidngs, spec ftcekons,, or other dUta is not to 'be regarded by tpi-tit~1ion )r other- vise as in Pny m~anner lictensixng ~b~hh~'or any other person nor c~orporwtion, ovr corvey-',Pg any rights or perzission to mainufeactula, u,ý- oý Oe4 &a-y pa~tented. inrvziation that may tr aw &,y be xvelated thereto. Kil-30T-11G Va,, MATONMJ DEF'SITB OF 'CID" U3M9TEDf SUM~tE W1Tý 1VT'"TMEAIN- ING OF Tffl3 ESPIONAGE ,At~l "TJ"Ml8 U.
    [Show full text]
  • GE Marine Gas Turbine Propulsion for Frigates
    GE Marine Gas Turbines for Frigates March 2018 GE’s Marine Solutions One Neumann Way MD S156 Cincinnati, Ohio USA 45215 www.ge.com/marine GE Marine Gas Turbines for Frigates Introduction The important role of a frigate is to escort and protect other high value fleet and merchant ships the world over. Frigates operate independently and possess sufficient capabilities (i.e. anti-submarine, anti-ship and anti-air) to provide missions in maritime and wartime environments. With GE being the market leader in the supply of marine propulsion gas turbines and seeing the proliferation in the demand for frigates, we wanted to know how our gas turbines and product roadmap compared to the needs of frigates. Before we could answer that question, we needed to answer the following two questions: 1. What are propulsion trends for frigates? 2. What are key attributes or requirements, and how do they translate to gas turbine propulsion characteristics? The key attributes of a frigate were taken from the July 2017 United States Navy Future Guided Missile Frigate (FFG(X)) Request for Information (RFI). It is anticipated the attributes would be common to many of the world’s frigates. Frigate Propulsion Trends and GE LM2500 Family Gas Turbine Suitability GE performed an analysis of all the frigates built since 1960 excluding certain countries such as Russia and China. Classification of a ship as a frigate is a gray area as there is blending of smaller corvettes and larger destroyers. For this analysis, we used the Wikipedia listing of frigates. All of the following ship data was obtained from public information such as Wikipedia and IHS Jane’s Fighting Ships.
    [Show full text]
  • The Market for Gas Turbine Marine Engines
    The Market for Gas Turbine Marine Engines Product Code #F649 A Special Focused Market Segment Analysis by: Industrial & Marine Turbine Forecast - Gas & Steam Turbines Analysis 4 The Market for Gas Turbine Marine Engines 2010-2019 Table of Contents Executive Summary .................................................................................................................................................2 Introduction................................................................................................................................................................3 Methodology ..............................................................................................................................................................5 Trends and the Competitive Environment .........................................................................................................6 Manufacturers Review.............................................................................................................................................8 Russian Marine Gas Turbines .............................................................................................................................16 Market Statistics .....................................................................................................................................................17 Table 1 - The Market for Gas Turbine Marine Engines Unit Production by Headquarters/Company/Program 2010 - 2019 ................................................18 Table
    [Show full text]
  • UNIT-1 COAL BASED THERMAL POWER PLANTS PART-A 1. What Are the Types of Power Plants?
    ME6701 POWER PLANT ENGINEERING/ EEE DEPT/R SENTHI KUMAR VEL TECH HIGH TECH DR. RANGARAJAN DR.SAKUNTHALA ENGINEERING COLLEGE UNIT-1 COAL BASED THERMAL POWER PLANTS PART-A 1. What are the types of power plants? 1. Thermal Power Plant 2. Diesel Power Plant 3. Nuclear Power Plant 4. Hydel Power Plant 5. Steam Power Plant 6. Gas Power Plant 7. Wind Power Plant 8. Geo Thermal 9. Bio – Gas 10. M.H.D. Power Plant 2. What are the flow circuits of a thermal Power Plant? 1. Coal and ash circuits. 2. Air and Gas 3. Feed water and steam 4. Cooling and water circuits 3. List the different types of components (or) systems used in steam (or) thermal power plant? 1. Coal handling system. 2. Ash handling system. 3. Boiler 4. Prime mover 5. Draught system. a. Induced Draught b. Forced Draught 4.What are the merits of thermal power plants? 1.The unit capacity of thermal power plant is more. 2.The cost of unit decreases with the increase in unit capacity 3. Life of the plant is more (25-30 years) as compared to diesel plant (2-5 years) 4. Repair and maintenance cost is low when compared with diesel plant 5. Initial cost of the plant is less than nuclear plants 6. Suitable for varying load conditions. 5. What are the Demerits of thermal power plants? Demerits of thermal Power Plants: 1. Thermal plant are less efficient than diesel plants 2. Starting up the plant and brining into service takes more time 3. Cooling water required is more 4.
    [Show full text]
  • การพัฒนาของเรือรบรุ่นใหม่ และเทคโนโลยีระบบบูรณาการ the Evolution of Warships and Integrated Systems Technology ตอนจบ นาวาเอก คำรณ พิสณฑ์ยุทธการ
    บทความ การพัฒนาของเรือรบรุ่นใหม่ และเทคโนโลยีระบบบูรณาการ The Evolution of Warships and Integrated Systems Technology ตอนจบ นาวาเอก คำรณ พิสณฑ์ยุทธการ ารบูรณาการระบบต่าง ๆ ในเรือรบ ในขอบเขตจำกัดหรือสามารถฟื้นตัวกลับมารบได้ (Warship Integrated Systems) ในเวลาอันรวดเร็ว โดยพัฒนาทั้งในรูปแบบของการ กตามที่ได้กล่าวไปแล้วว่า การบูรณาการระบบต่าง ๆ พัฒนารูปร่างของเรือ (Shape) และภาพเงาร่าง บนเรือ มีจุดมุ่งหมายที่จะให้เกิดความมีประสิทธิภาพ (Signature) ของเรือ ระบบบูรณาการที่มีการนำมา ในการทำการรบทั้งในทางรุกและทางรับ โดยเน้น ใช้บนเรือแล้วในปัจจุบัน ประกอบไปด้วยระบบต่าง ๆ การพัฒนาระบบแบบบูรณาการไปที่หลักการ ๒ ดังนี้ ประการ คือ การพัฒนาระบบบูรณาการด้านขีด การบูรณาการระบบสะพานเดินเรือ (Integrated ความสามารถในการรบทางเรือสมัยใหม่ (Modern Bridge System : IBS) Warfighting Capabilities) และการพัฒนาระบบ การบูรณาการระบบอำนวยการรบ (Integrated บูรณาการด้านความอยู่รอดของเรือ (Survivability) Combat Management System : ICMS) ซึ่งแบ่งเป็น การป้องกันการยิงถูกเรือ (Hit Avoidance) การบูรณาการระบบบริหารจัดการระบบ ตามขั้นตอนการรบแต่ละขั้นตอน ความทนทานต่อ เรือต่าง ๆ (Integrated Platform Management ความเสียหายของเรือ (Damage Tolerance) ให้อยู่ System : IPMS) นาวิกศาสตร์ ปีที่ ๙๔ ฉบับที่ ๑๑ พฤศจิกายน ๒๕๕๔ ๐17 การบูรณาการระบบสื่อสาร (Integrated เป็นระบบแรกของเรือที่มีการพัฒนาให้เป็นระบบ Communication System : ICS) บูรณาการขึ้น โดยการนำแผนที่เดินเรือมาทำงาน การบูรณาการระบบเสากระโดงเรือ (Integrated ร่วมกับเรดาร์ ไยโรและเครื่องวัดความเร็วเรือ (Log) Mast System : IMS) สะพานเดินเรือของเรือรบรุ่นเก่า ๆ เครื่องมือเดินเรือ การบูรณาการระบบขับเคลื่อนของเรือ (Combined เรดาร์เดินเรือ
    [Show full text]
  • Division of Marine Engineering
    ΝATIONAL TECHNICAL UNIVERSITY OF ATHENS SCHOOL OF NAVAL ARCHITECTURE AND MARINE ENGINEERING DIVISION OF MARINE ENGINEERING DIPLOMA THESIS Techno-economic Evaluation of Various Energy Systems for LNG Carriers ANDRIANOS KONSTANTINOS ATHENS, JULY 2006 SUPERVISOR PROFESSOR: CH. FRANGOPOULOS Devoted to my family for their love, patience and support and especially to my beloved mother Aimilia S. Rakka- Andrianou who will live forever in our hearts. CONTENTS Foreword Acknowledgements 1. INTRODUCTION 1 2. LNG CARRIER PROPULSION PLANTS DESCRIPTION 3 2.1 Steam Turbine 3 2.1.1 General information-technological development 3 2.1.2 Conventional steam turbine propulsion plant 5 2.1.3 Advantages and drawbacks for a steam turbine propulsion plant installation 8 2.2 Gas Turbine 9 2.2.1 General information-technological development 9 2.2.1.1 Marine aero-derivative gas turbines manufacturers 10 2.2.1.2 Gas turbine myths and misunderstandings 12 2.2.1.3 Advantages of marine aero-derivative gas turbines 13 2.2.1.4 Disadvantages of marine aero-derivative gas turbines 15 2.2.1.5 Gas turbines for LNG carriers 16 2.2.2 Typical gas turbine propulsion plant 19 2.2.3 Advantages and drawbacks for a gas turbine propulsion plant installation 20 2.3 Combined Gas and Steam Turbine 21 2.3.1 General information-technological development 21 2.3.2 Typical combined gas and steam turbine propulsion plant 29 2.3.3 Advantages and drawbacks for a combined gas and steam turbine propulsion plant installation 31 2.4 Slow Speed Diesel Engine 33 2.4.1 General information-technological
    [Show full text]