Nacos Platinum gets a helicopter guidance plug in
SEPTEMBER 27, 2016 — Your helicopter pilot will now be able to land the Dom Perignon on your yacht more safely. Wärtsilä is using the upcoming Monaco Yacht Show to introduce helicopter
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Green technologies: The road to faster adoption
Leading shipowners and operators, gas suppliers, ports, class societies, and technologists gathered last month in London to announce a new cross-industry initiative aimed at accelerating the adoption of Liquefied Natural Gas (LNG) as a marine fuel. The initiative hopes to address the issues of LNG bunkering infrastructure, regulatory concerns, and the higher initial capital investment costs in building LNG-fueled vessels.
Called SEA/LNG, the initiative brings together participants from Carnival Corporation & plc, DNV GL, ENGIE, ENN, GE, GTT, Lloyd’s Register, Mitsubishi Corporation, NYK Line, Port of Rotterdam, Qatargas, Shell, TOTE Inc. and Wärtsilä.
The goal of the initiative explains TOTE Inc. Executive Vice President Peter Keller, who is serving as SEA\LNG’s Chairman, is to address “market barriers and help transform the use of LNG as a marine fuel into a global reality.”
When it comes to using LNG as a marine fuel, TOTE is all in. It’s committed about $500 million in capital investments to have its entire fleet to burn LNG. The U.S.-flag operator has built two 3,100 TEU LNG-fuelled containerships now in operation between the Port of Jacksonville, FL, and San Juan, PR, and is converting the two ORCA Class Roll-on/Roll-Off ships in its fleet to burn LNG. The first of those two is being converted at Singapore’s Keppel Shipyard this fall.
TOTE is not alone in adding dual-fuel and LNG-Ready tonnage to its oceangoing fleet in the U.S. Harvey Gulf International Marine, Crowley Maritime Corp., Matson Navigation, Kinder Morgan, and SEA VISTA/SEACOR all have vessels in operation or under construction that burn or could eventually burn LNG as a marine fuel. In all, there are 29 vessels that are designed or could be converted to burn LNG as shown in the accompanying table. This does not include inland and coastal vessels such as towboats or ferries.
The U.S. Maritime Administration, for example, is supporting the conversion of a towboat to burn LNG as fuel.
The use of LNG as a marine fuel has increased with Emission Control Areas (ECAs) coming into force in Northern Europe and North America under MARPOL Annex VI. LNG is relatively clean burning, containing virtually no sulfur content and it produces lower NOx and particulate matter in the combustion process than fuel oil and marine diesel oil.
A long-time, well-known proponent of LNG as a marine fuel, John Hatley, PE, Gas Initiatives Wärtsilä North America, sees gas as a compelling solution for box feeders, RO/RO vessels, ferries and cruise ships, product tankers, Great Lakes vessels, and ATBs on short coastal voyages that enter into ECAs.
LNG is therefore able to offer a fuel solution compliant with both current and anticipated future regulations.
The larger effect from Annex VI will come when the requirement to reduce sulfur content of marine fuels to 0.5% on a global basis effective 2020 or 2025 depending on the outcome of an IMO low sulfur fuel availability study to be completed in 2018. The issue for ship owners and operators is how to find alternatives to economically meet the low sulfur fuel mandate about to be imposed by MARPOL Annex VI.
However, while LNG is a competitive fuel relative to current alternatives, LNG infrastructure is needed in ports around the world to enable quick, safe and cost effective bunkering. In the U.S., the first LNG bunker transport barge with GTT Mark III Flex tank technology is under construction at Conrad Orange shipyard in Orange, TX, and expected to be delivered in early 2017. LNG bunkering infrastructure is far more advanced in Europe.
“Everybody is calling for alternatives to reduce environmental impacts says Philip Olivier, CEO of ENGIE Global LNG. “That’s why we have joined forces to actively promote LNG as a key fuel in maritime transport. LNG has the potential to take a 10% market share of global bunker demand by 2030. ENGIE will contribute to achieving this target.”
Tom Strang, Senior Vice President, Maritime Affairs, Carnival Corporation & plc, says, “By working together proactively across the whole marine LNG value chain we can make the transition to a lower emission marine sector a reality.”
Lauran Wetemans Shell’s general manager downstream LNG agrees. “To make the transition to LNG as a fuel happen it needs close collaboration with key players across the full value chain,” says, Wetemans. “SEA/LNG aims to promote the benefits and potential of LNG fuel, and create a level playing field for LNG with other fuels. It will complement the work being done by other organizations like the Society for Gas as a Marine Fuel.”
Leo Karistios, Gas Technology Lead, Lloyd’s Register, points out, “LNG fuelled shipping has mainly been for the visionaries and, until now, concentrated in specialist ship sectors: short sea shipping and ferries, mainly sailing between two fixed ports. We want to help drive the expansion of LNG as a marine fuel of choice, with not just more short sea and local ships burning gas, but also the deep sea trades.”
Timo Koponen, Vice President, Flow & Gas Solutions, Wärtsilä Marine Solutions, says his company will contribute “its vast experience and know-how in gas driven propulsion systems and the entire gas value chain” to the initiative. “By working together, we plan to overcome the challenges and speed the general acceptance of LNG. Having been a pioneer in the use of LNG as a marine fuel, and a developer of major technologies facilitating the adoption of LNG fuel, it is natural that Wärtsilä supports wholeheartedly the aims of the SEA/LNG coalition.”
Developing bulk carrier concept
Wärtsilä is also involved with an effort with class society ABS, Arista Shipping, Deltamarin, and GTT in the Project Forward joint development project (JDP) to develop a dry bulk carrier concept that employs LNG as fuel.
The goal is to develop a Kamsarmax bulk carrier design to be the first of this type suitable for worldwide services powered by LNG in compliance with the IMO’s Energy Efficiency Design Index 2025 standards, NOx Tier III and MARPOL Annex VI SOx emission levels. This landmark design will be the first LNG-fueled cargo ship capable of full-range operations.
“The long-term potential for LNG as a marine fuel is tremendous,” says ABS Vice President of Global Gas Solutions Patrick Janssens. “We see the near-term opportunities for larger vessels on fixed and known trade routes, but more opportunities will emerge as concepts mature and bunkering infrastructure expands. Environmental stewardship will continue to be a concern, and owners will be evaluating alternative fuel choices.”
“Project Forward represents a milestone for the shipping industry in bringing to the market a practical, achievable design for what are the workhorses of the shipping fleet,” says Arista Shipping Principal Alexander P. Panagopulos. “Our mission is to develop the next generation of energy efficient and environmentally friendly dry bulk cargo ships to be sustainable worldwide beyond 2030. It marks a number of ‘firsts’ and draws together the experience of a team of leaders in their field to make LNG powered shipping a reality on the high seas.”
Technical challenges in developing this design were considerable, as there is a need to carry a large volume of LNG (2,500 m3) – which corresponds to full-range operation and 40 days – in a type of ship where available space is limited and cargo space is at a premium.
ABS will provide Approval in Principle (AIP) for the concept, which is based on the highly optimized Deltamarin B.Delta 82 design, utilizing a GTT membrane LNG fuel tank. This design also could be applied to other bulk carrier sizes and serve as the basis for an LNG-fueled tanker. The concept features a Wärtsilä four-stroke, medium-speed engine without auxiliary generators, the first time this configuration has been applied to a vessel of this type, significantly simplifying the vessel’s engine room arrangement and contributing to lower capital expenditure.
Read more from our Green Technology & Sustainable Shipping section in our Digital Edition.
European marine technology: Intelligent innovation
“Orders are drying up. We are faced with an unimaginable situation at which our dock may soon be empty,” wrote Choi Kil Seon, Chairman of the world’s largest shipbuilder, Hyundai Heavy Industries, in a letter to employees this past March. Complacency had set in during the boom years of the 2000’s, he said, despite strenuous efforts to compete with Chinese shipbuilders.
His stark warning has been echoed around shipbuilding halls across Asia. Chinese shipbuilding is undergoing massive retrenchment with the closure of many second-tier shipyards and massive state aid for those still in business. Meanwhile, Japanese shipyards fear a slump that could prove worse than the crash that followed the 2008 financial crisis. Shipyard executives fear the worst as current projects come to an end and have no pipeline of business to speak of.
About 5,000 miles away, workers in the high-tech Kleven Shipyard just outside Ulsteinvik on Norway’s west coast may or may not be aware that their counterparts in Asia are staring into the abyss. And they would certainly not recognize the term complacency in any aspect of shipyard operation.
A combination of effective marketing, chunky investment in automation and robotics, clever use of the country’s export credit arrangements, and close cooperation with Rolls-Royce ship designers who work just across the fjord, has enabled the family-owned shipyard to build up an order book now potentially worth more than $1.8 billion.
Early in July, the yard announced its latest contract for the construction of two—with an option for an additional two—ice-strengthened expedition ships designed by Rolls-Royce (rendering pictured at right) for Norway’s Hurdigruten. Hurdigruten operates a fleet of cargo and passenger vessels around the country’s 15,700-mile coast. The order, worth billions of Norwegian krone, is the largest in Hurdigruten’s history and is a major coup for the shipyard and Rolls-Royce which, in addition to vessel design, will supply about $15 million of equipment for each ship.
Together with the yard’s existing 16-ship order book, Kleven now has work for the rest of this decade. Ships under construction include six anchor handlers for Maersk Offshore, four high-tech stern trawlers of Rolls-Royce design for German, French and Spanish owners, the world’s most advanced cable layer with the highest DP3 position-keeping for ABB, two Rolls-Royce design live fish carriers, a deep-sea mining vessel for de Beers, and two luxury megayachts for a New Zealand entrepreneur. Talk about a diverse order book.
How has the yard been able to buck the global trend, particularly in one of the most expensive parts of the world? Certainly the Norwegian Export Credit Guarantee Agency has played an important role by making attractive financing terms available for foreign owners and vessels to be deployed overseas. But the yard’s management has spent almost $60 million on upgrading yard facilities over the past five years.
The robotic welding process, using lasers, continues to evolve, with a vision control system recently installed and developed by the University of Trondheim. The automated process allows welding rates of more than 300 feet per hour transforming manual rates of a typical eight feet per hour. “This is how we believe we can stay ahead of our competition and be competitive on price,” said a yard representative recently.
However, while the Kleven story may be exceptional—other yards in Norway’s usually bustling Sunmøre region are wrestling the challenge of an unprecedented offshore downturn—the design and shipbuilding innovation evident in northern Europe still facilitates construction of some of the world’s most sophisticated vessels.
In a radius of just a few miles from Kleven, there are several Vard yards, now owned by Fincantieri, the Havyard and across the fjord, next door to Rolls-Royce is Ulstein. Between them, these shipbuilders have completed some of the most sophisticated vessels ever built. They include the latest generation seismic survey ships, light well intervention vessels, offshore construction vessels and ultra-sophisticated cable layers.
Norway is not alone, however, in blazing a shipbuilding innovation trail. Finnish ship designers have unmatched expertise in ice-class design and construction, likely to be in heavy demand as warming seas enable navigation through the Northern Sea Route. Presumably with this in mind, Russia’s United Shipbuilding Corporation completed the acquisition of what is now called Arctech Helsinki Shipyards at the end of 2014.
Sited adjacent to the ice model test basin now known as Aker Arctic Technology Inc, the Helsinki shipyard has undergone various changes in ownership over the years, but has always focused primarily on ice-class design and construction. More than 500 ships have been built since it was established 151 years ago and more than 60% of the icebreakers now in operation around the world were built there.
The Helsinki yard has pioneered a range of ice-class innovations over the years, often with others. These include ‘double-acting’ vessels, which can break ice by bow or stern, azimuthing propulsion for ice operation, heeling and air-bubbling systems, shallow-draft icebreaker designs for inland waterways and coastal seas, and nuclear-powered icebreakers.
The shipyard continues to innovate. In 2014, the shipyard delivered the first “oblique icebreaker” to Russia’s Federal Agency of Sea and River Transport. The Baltika has an asymmetric hull and three azimuthing thrusters with a total installed power of 9 MW. She can break ice ahead, astern or sideways and can open up a 160-foot channel in two-foot thick ice.
The shipyard’s most recent delivery is the first dual-fuelled icebreaker to be powered by LNG and diesel. The Polaris, with a bollard pull of 200 tonnes, is powered by two 6.5 MW stern Azipods and one 6 MW unit, all supplied by power and automation company ABB. She is the Finnish Transportation Agency’s eighth icebreaker.
Polaris will be powered by Wärtsilä’s dual-fuel engines capable of operating on both liquefied natural gas (LNG) and low sulfur diesel fuel. Wärtsilä’s scope of supply consists of one 8-cylinder Wärtsilä 20DF, two 9-cylinder Wärtsilä 34DF, and two 12-cylinder Wärtsilä 34DF engine. Additionally, Wärtsilä secured a five years maintenance agreement for all engines and generators including spare parts, remote online support, CBM monitoring and training services.
The EURO 123 million ($136 million) vessel, classed by Lloyd’s Register, also has an emergency response and oil spill recovery capability and completed sea trials successfully in June. Her 800 m3 of LNG storage will provide an endurance of up to 30 days when operating in the Gulf of Bothnia.
Norway has led the way in the development of gas-powered ships and Rolls-Royce has been one of the pioneers. Designed by NSK Ship Design, the gas-powered cargo ship M/S Høydal features a Bergen gas engine, Promas combined rudder and propeller, and a hybrid shaft generator from Rolls-Royce. The ship was built at Tersan Shipyard in Turkey and delivered to NSK Shipping. The DNV GL class Høydal transport fish feed manufactured by BioMar to the numerous salmon and trout farms of northern Norway.
Boaty McBoatface lives on
Rolls-Royce engineers are also designing the 128m polar research vessel RRS Sir David Attenborough, which will be built at Cammell Laird’s site in Birkenhead on Merseyside, England. As you might recall, the project drew worldwide attention and almost blew up the internet when the public overwhelmingly chose the name “Boaty McBoatface” for the £200 million vessel during a “Name Our Ship” campaign held by Britain’s Natural Environmental Research Council. The council saved face—pun somewhat intended—by choosing the fourth most popular name submitted, “Sir David Attenborough,” after the famous British naturalist.
NERC says a remotely operated vehicle used by the Sir David Attenborough in its research will be named Boaty McBoatface instead.
The project is the biggest commercial shipbuilding contract in Britain and one of the biggest for more than a generation. When delivered in 2019, the Sir David Attenborough will carry out oceanographic and other scientific work in both the Antarctic and Arctic as well as transporting supplies to Antarctic research stations.
The research vessel will be Polar Code 4 ice class, with an endurance for voyages up to 19,000 nautical miles, space for a total of 90 people and a large cargo capacity. The vessel is also designed to generate very low levels of underwater radiated noise and minimize the risk of pollution. Onboard laboratories will allow the prompt analysis of samples.
As part of its £30 million contract, Rolls-Royce will supply the diesel electric propulsion system which will include new Bergen B33:45 engines, two nine-cylinder and two six-cylinder engines, and two 4.5m diameter Rolls-Royce Controllable Pitch Propellers (CPP). The powerful, efficient and compact engines and strong propellers will be able to push the vessel through approximately one meter thick level ice with extremely low underwater radiated noise, avoiding interference with survey equipment or disturbing marine mammals and fish shoals.
According to Jørn Heltne, Rolls-Royce, Senior Vice President for Sales in Ship Design & Systems, Rolls-Royce will also deliver automation and control systems, including its Dynamic Positioning system and Unified Bridge.
Also, Rolls-Royce deck handling systems will support a wide range of tasks, such as towing scientific equipment for subsea acoustic survey equipment using up to 12,000m of wire, or deploying equipment over the side or through a moonpool to collect seawater and seabed samples at depths of up to 9,000m.
OEMs capitalize on new era of ‘smart shipping’
Rapid advances in satcom technology is finally enabling shipping to go digital and make the most of ship-shore connections. While a handful of companies have wired up their ships over the last few years—notably the world’s largest container line, Maersk, high-throughput broadband now facilitates 24/7 connectivity and introduces a new era of remote monitoring, diagnostics, predictive maintenance and shore-side support.
Other transport modes have been using these technologies for some time, but satellite coverage across the world’s oceans has remained a challenge. Many thousands of unconnected ships still provide manually prepared noon reports for managers ashore, an asset monitoring procedure which some from outside shipping can scarcely believe.
Rolls-Royce, through its TotalCare service, has been monitoring the performance of thousands of jet engines for years. Instead of signing service agreements and charging customers for call-outs, spare parts and attendance at unexpected breakdowns, the company’s “power-by-the-hour” concept is aimed at keeping planes in the air and avoiding any downtime.
Earlier this year, London-listed Inmarsat launched Fleet Xpress, a high-throughput broadband service available through its Global Xpress network on its latest satellite constellation. As well as enabling a completely new range of ship-shore connections including internet, email, social media and video conferencing, third party app providers can procure bandwidth on Fleet Xpress to provide their own “smart” services (see accompanying feature, “Fleet Xpress brings ‘smart’ ship tipping point,” for more details).
Systems similar to the Rolls-Royce TotalCare service are now being introduced in shipping. Wärtsilä recently paid EURO 43 million ($47.5 million) for Finnish energy management and analytics firm Eniram which has sensor and analytics equipment installed on about 270 vessels and a turnover of EURO 10 million ($11 million) in 2015. The Helsinki-based firm has established a sound track record in raising vessel efficiency by optimizing trim, engine load and speed, thereby saving fuel and cutting emissions.
The acquisition will strengthen the company’s recently launched Wärtsilä Genius service in which key components are monitored in real time, exceptions noted, and maintenance procedures optimized. A virtual service engineer will also be available as part of the service and the company plans to make more details available at this year’s SMM in September.
Competitor ABB is preparing to open its fourth “Integrated Operations Center” in the United States later this year, probably in Houston. The company has already opened a facility for its offshore clients in Billingstad, Norway, and two similar centers for shipping customers in Helsinki and Singapore.
A fifth center is also likely to be set up in China. By mid-year, ABB had established real-time connections between the centers and clients’ ships, enabling ABB personnel to track performance and provide shore-side support if necessary. Meanwhile Rolls-Royce Marine is also in the process of setting up connections to monitor its equipment in operation at sea.
Following a successful remote monitoring pilot project, Radio Holland recently struck a deal with China Navigation Company for the maintenance of its navcom equipment onboard the owner’s newbuild, multipurpose vessels and bulk carriers.
“The maintenance agreement with Radio Holland has been designed to dovetail with the end of the warranty period for our newbuildings,” says Martin Cresswell, Fleet Director, China Navigation Co. Pte., “and is a continuation of the excellent cooperation that we have built over the last few years. The agreement incorporates remote monitoring, which we believe will significantly reduce out of service periods, increasing operational safety.”
MAN Diesel’s largest two-stroke engine yet
Just this past June, China State Shipbuilding Corporation (CSSC) acquired Wärtsilä’s 30% shareholding in Winterthur Gas & Diesel Ltd. (WinGD). WinGD, Winterthur, Switzerland, will continue as an independent, international company to develop and innovate its two-stroke low-speed marine engine portfolio serving all merchant markets and customers worldwide.
WinGD was one of the earliest exponents of diesel technology. It started the development of large internal combustion engines in 1898 under the “Sulzer” name.
“With the transfer of the shares in WinGD from Wärtsilä Cooperation to CSSC, we will be able to establish even closer cooperation with one of the leading global shipbuilding conglomerate CSSC enabling us to accelerate the development of reliable, efficient and innovative two-stroke low-speed engines meeting the market demands of merchant shipping of the future. WinGD will continue to work with the Wärtsilä Corporation Service Network to serve our customers for after-sales support,” says Martin Wernli, CEO of WinGD.
In other news in the two-stroke diesels, this past May, the 19,437-TEU MSC Jade was delivered by Korea’s Daewoo Shipbuilding & Marine Engineering (DSME) with what is the largest and most powerful engine yet from MAN Diesel & Turbo. Built by Doosan Engine in Korea under license from MAN Diesel & Turbo, the MAN B&W 11G95ME-C9.5 two-stroke engine is rated at an impressive 75,570 kW (103,000 hp).
The G95 is a popular choice in the large containerships (9,000 to 21,000 TEU), with 68 sold in the segment since August 2013.
“We attribute the G95’s popularity in this segment to its ability to provide sufficient power for such vessels to reliably achieve their desired operating speed,” says Ole Grøne, Senior Vice President Low-Speed Sales and Promotions, MAN Diesel & Turbo. “Here, the G95’s rpm ensures that a propeller of optimal size can be employed, in turn delivering a low fuel-oil consumption for an optimal fuel economy.
Japan’s Mitsui Engineering & Shipbuilding, another MAN Diesel licensee, completed the world’s first ME-GIE ethane-operated two-stroke diesel engine. The Mitsui-MAN B&W 7G50ME-C9.5-GIE will be installed in the first of three 36,000 m3 liquefied ethane gas carriers being built by Sinopacific Offshore Engineering in China.
MAN Diesel & Turbo reports that ethane was chosen as fuel over HFO because of its competitive pricing as well as the significantly shorter bunkering time it entails. As a fuel, its emissions profile is also better than HFO, as it contains a small amount of sulphur, 15-20 lower CO2 and emits signficantly fewer particles during combustion. The ME-GI engine can also easily be converted to run on methane, if the operator desires.
Pioneering New Technologies
Soon, noon-day reporting from fallible human beings will be a thing of the past. From cradle to grave, a whole new approach to ship efficiency has been made possible by recent advances in IT and data processing. Now, a step change in “always-on” ship connectivity will allow maritime assets to be monitored and managed remotely right round the clock.
As we reported in “Shipping’s Space Age Future” (ML April 2016, p. 37), perhaps the most ambitious project on the go in Europe is the Rolls-Royce-led Advanced Autonomous Waterborne Applications Initiative (AAWAI) in which other maritime firms including DNV GL, Inmarsat, Deltamarin and NAPA are also involved. Other participants include top academics from various Finnish universities.
At a project update meeting recently in Helsinki, Rolls-Royce President – Marine, Mikael Makinen declared: “Autonomous shipping is the future of the maritime industry. As disruptive as the smart phone, the smart ship will revolutionize the landscape of ship design and operations.”
Delegates heard that the sensor technology is now sufficiently sound and commercially available so that algorithms required for robust decision-making—the vessel’s virtual captain—are not far away. Now the arrays of sensors are to be tested over the coming months on board Finferries’ 65-meter-long double-ended ferry, Stella.
“Some of the distinct goals of this project are to make a difference in marine safety and energy efficiency,” Päivi Haikkola, Manager, R&D, Deltamarin Ltd., told Marine Log. “We want to mitigate human error.”
Finferries and dry bulk shipping company ESL Shipping Oy are the first ship operators to join the project, which aims to explore ways in which to combine existing communication technologies as effectively as possible for autonomous ship control. Inmarsat’s involvement is key.
The London-listed communications company recently began the roll-out of its new Fleet Xpress service, seen by many as truly a light-bulb moment. Preparing the ground for rapid advances in smart ship operation and crew welfare, the new service now provides always-on high-speed broadband communication between maritime and offshore assets at sea, and shore-based managers. It is the first time that such a service has been available from a single operator.
Fleet Xpress will also facilitate cloud-based applications from third parties with smart systems to raise ship operating efficiency and improve the life-quality of seafarers. For the first time, big data can be used to improve asset management and maintenance.
IT advances have also facilitated a new approach to ship design. Model basins and testing tanks still have their place, of course, but thousands of relatively high-speed computational iterations can measure the relative benefits of small design changes in a way that has not been possible before.
Take the Finnish company Foreship, for example. Its capabilities in computational fluid dynamics (CFD) and the super-efficient hull forms which it has developed have propelled the company into a position as one of the top ship design consultants to global cruise lines, advising both on newbuilding plans, conversions and retrofits.
In a couple of months, the first of two 4,700 dwt “EcoCoaster” cargo ships is due for delivery to Finland’s Meriaura Group from the Royal Bodewes yard in the Netherlands. Foreship carried out extensive hull optimization work and, as a result, these vessels will burn only about half of the fuel compared to an existing vessel of similar size and class.
Foreship worked with both the owner and Aker Arctic Technology on the ships which will be able to run on biofuel or marine gasoil. Meriaura plans to have at least half of its fleet – currently about 20 ships – based on EcoCoaster designs by 2020. Since ordering the 4,700 dwt units, work has been carried out on larger designs.
Also hailing from Finland is progressive ship design firm Deltamarin. Now a subsidiary of Singapore-listed AVIC International Maritime Holdings Limited and ultimate Chinese ownership, the company’s range of super-efficient B.delta bulk carriers spanning a size range from 28,000 dwt to 210,000 dwt has caught the attention of long-established dry bulk owners including heavyweights such as Algoma, Canada Steamship, Cosco, Louis Dreyfus Armateurs and Oldendorff.
Of course the catalyst for taking a fresh look at the hull forms which had not changed for decades was the spike in bunker prices. But although the oil price collapse means today’s fuels cost only a fraction of prices two or three years ago, the search for improved economy has developed a momentum of its own, and nowhere is this more obvious than amongst leading propulsion companies, many of which are to be found in Europe.
While big low-speed diesel manufacturers like MAN Diesel & Turbo and Wärtsilä have made huge strides in raising the fuel efficiency of large engines, it is among some of the smaller niche machinery providers where true design innovation is to be found. Electrical power, energy storage and the growing popularity of azimuth thrusters are fiercely fought-after markets. ABB, Rolls-Royce, Steerprop, and Wärtsilä all feature in a market popular with operators of cruise ships, workboats, offshore support vessels and dynamically positioned offshore units of various types.
ABB, for example, recently won a European Marine Engineering Award for its Azipod D electric propulsion system with a power range from 1.6MW to 7MW. Launched last year, the latest Azipod was designed to allow its use on a wider range of ship types. It incorporates various innovative features including a new hybrid cooling system which contributes to a requirement for 25% less installed power and similar fuel savings.
The first cruise ship with Azipod D will be the 16,800 gt Scenic Eclipse being built by Uljanik shipyard in Croatia. The Scenic Eclipse (pictured above) is being built to Polar Class 6 and will operate in the summer waters of the Polar regions when it is delivered in 2018. The 228-passenger ship will have two 3MW Azipods installed.
Meanwhile, ABB recently announced a deal to supply a new electrical power system based on its Onboard DC Grid system for a hybrid car ferry in Norway. Initially the vessel, for Torghatten Trafikkselskap will operate as a hybrid with two battery packs contributing to peak demand. However, the 60-car, 250-passenger vessel can be easily modified to become fully electric in due course by adding 16 battery packs and a shore connection.
For the cruise ship and offshore vessel markets, Wärtsilä recently unveiled the Wärtsilä WTT-40 transverse thruster, which features a 4,000 kW power level and a 3,400 mm diameter controllable pitch propeller. The thruster complies with the U.S. EPA’s latest VGP2013 regulations. It also features integrated hydraulics to save machinery room space and installation and commissioning time in the shipyard.
Meanwhile, last year Steerprop Ltd. landed orders for a total of ten SP25D units to serve as main propulsion for three inland towboats being built for SCF Marine at C&C Marine & Repair, Belle Chasse, LA. The propulsors will be delivered this summer to the shipyard by Karl Senner, LLC., Kenner, LA, the North American distributor for Steerprop. These will be the largest and highest horsepower inland towboats equipped with Z-drives built in North America to date, according to Chris Senner of Karl Senner, LLC. He adds, “It is imperative to consider the harsh conditions of the inland waterways and select a unit suited for the environment, which is why we propose the equivalent of an ice-class rated unit.”
A new generation of much more fuel and operationally efficient newbuilds, however, does nothing for the tens of thousands of existing vessels built before the new wave of design innovation began. But there are a range of initiatives in progress focused on enhancing existing ship efficiency.
Germany’s Becker Marine Systems is a leading light in energy-efficient retrofits and appendages. The company recently signed a deal with Abu Dhabi’s Adnatco to fit some 20 vessels with Becker Mewis Ducts (pictured at right). Rudder modifications and Becker Twisted Fins are also generating a steady pipeline of sales.
Walter Bauer, Sales Director, concedes that sales volume has reduced. But he says that this is partly a result of the dire state of the bulk carrier market. Tanker business, he says, is holding up well.
But what to do with almost-obsolete panamax container ships? Owing to beam constraints, they are generally long and relatively thin, and were mostly built in an era of cheap fuel and fast sailing speeds. They are not particularly efficient from a box-carrying point of view, but are in dire straits today, competing with larger ships and lower slot costs. There are more than 800 such vessels in the world fleet today and well over half are less than 10 years old. They are likely to prove increasingly unpopular with charterers.
Cargo access specialist MacGregor is one of several companies which offers capacity increasing conversions for container ships. By slicing a vessel in half lengthways, a newly constructed midship section can be inserted and stack heights raised by lifting the navigation bridge.
In a similar project, the capacity of the 4,860 TEU MSC Geneva, owned by Reederei NSB, was increased to 6,300 TEU. The five-month widening project, undertaken in close cooperation with Hamburg’s Technology GmbH, was completed at Huaran Dadong Dockyard in China. Through its subsidiary NSB Marine Solutions, Reederei NSB is now offering to assist in similar projects for third parties.
Meyer Werft delivers Ovation of the Seas
APRIL 10, 2016 — Shipbuilder Meyer Werft formally handed over the 168,660-gt Ovation of the Seas to Royal Caribbean Cruises at a ceremony held in Bremen, Germany, on September 8. The third
A look at the best passenger ships of 2015
MV Veteran, 80m Ice Class Ferry
Delivered this past October by Damen Shipyards Galati, Romania, the RoPax ferry MV Veteran is built to handle the tough environment of the Arctic region. The 200-passenger vessel was designed to operate specifically in icy waters by a partnership comprised of Fleetway Inc., for the Government of Newfoundland and Labrador, and Denmark’s Knud E. Hansen.
The MV Veteran can handle 40 cm-thick floating ice at 4 knots, says Jan van Hogerwou, Damen Manager, North America. The ferry’s “rudders, hull and propellers have been strengthened and are outfitted with extra plate thickness for heavy winter conditions.”
Three MTU 16V 4000M23S engines generate 1,700 kWe, 400V, at 1,800 rev/min. The emergency genset is provided by one Volvo D16 engine generating 440 kWe 440V, at 1,800 rev/min. Its propulsion set is made up of two 1,600 kW Rolls-Royce azimuth thrusters, Electric Drive, and two 2,600 mm ice strength fixed pitch propellers.
And while the vessel was built in Romania, its very much a Canadian product, with several Canadian companies providing services for the vessel, with products including electrical equipment to fire-fighting systems.
MV Veteran has roll-on, roll-off capacity for 60 vehicles, is 80.9 m long with a beam of 17.2 m and can operate at a cruising speed of 14 knots.
The first in a two-vessel contract, the Veteran, and its sister ship the MV Legionnaire, are part of a large “lifeline” vessel replacement program being undertaken by the Provincial Government to modernize its fleet. The fleet transports over 900,000 passengers, 400,000 vehicles and 20,000 tonnes of freight with more than 50,000 arrivals and departures every year.
MV Veteran is class by ABS +A, Vehicle Passenger Ferry, Ice Class 1AA, Near Coastal, Voyage Class II, E, +AMS, HAB+, ACCU GP.
Product Director at Damen Ferries, Henk Grunstra, acknowledges that the Ice Class 1A Super certificate in the highest available for ferries. He also says the vessel has redundant systems in place for safe operation.
MV Veteran features 127 seats in the forward passenger lounge, 88 seats in the aft passenger lounge, 15 single crew cabins.
The Sally Fox, 105 ft fast ferry
Last April, a new foxy lady on the Puget Sound made her presence felt. Built by All American Marine, Bellingham, WA, the MV Sally Fox, is the first of two new ferries ordered by King County’s Marine Division. The vessel is also the first ferry to be built under the U.S. Coast Guard’s Sub-Chapter K rule, and delivered under the new 5A Space Performance Guidelines issued.
The 5A Space Performance Guidelines make it possible for a boat builder, such as All American Marine (AAM), to design and implement suitable structural fire protection in very low fire load spaces in the construction of weight-sensitive high-speed passenger vessels.
The 105 ft x 33 ft catamaran was designed by AAM, however, for its wave piercing hull design the builder called upon New Zealand-based naval architecture firm Teknicraft Design Ltd. The wave piercing hull design helps reduce drag and enhance passenger comfort.
Sally Fox is powered by twin Cummins QSK-50 tier II engines rated at 1,900 rev/min. The 250-passenger ferry operates at a service speed of 28 knots across the Puget Sound from Vashon Island to downtown Seattle.
Special attention was paid to each passenger deck’s layout in order to facilitate and streamline the boarding and disembarking process. Additionally, the new ferry features some green technologies, for example, instead of paint, the decks are covered with a peel-and-stick non-slip tread, while the exterior of the superstructure is wrapped in UV-stable vinyl.
Funded by federal grants, the new water taxi will replace the Melissa Ann, a 27 year old vessel leased to operate on the route since 2010. Its sister ferry, the MV Doc Maynard was delivered by AMM September 2015.
Baynes Sound Connector, Longest Cable Ferry
Next month, BC Ferries’ first ever cable ferry, the Baynes Sound Connector will make its long awaited debut and begin operations. Built by Seaspan’s Vancouver Shipyards, the 78.5 m ferry will accommodate 150 passengers and 50 vehicles on a 1,900 meter (about 1.9 km) route, making the ferry one of the longest cable ferries in the world.
Baynes Sound Connector will travel at a speed up to 8.5 knots between Buckley Bay and Denman Island. The ferry operates on one drive cable, and two guide cables along the route on the Baynes Sound Channel. Operator BC Ferries expects the cable ferry will help reduce operational costs, saving the company over $80 million over its expected 40-year service life; will have a smaller environmental footprint and lower fuel emissions.
While the news of the Baynes Sound Connector is exciting, the project was initially met with fears from the local community that felt a ferry operating on cables would be unsafe and wouldn’t be able to meet BC’s promise of a more efficient ferry on the run.
BC Ferries has stated that the ferry has been designed and built to safely operate in the Bayes Sound environment, which is a relatively low marine traffic area, and was tested in some of the worst weather conditions.
To further safety, it was recently announced that transit lights have been installed at both the Buckley Bay and Denman West terminals to secure safe passage for the cable ferry and other vessels in the area. A green light would indicate that the Baynes Sound Connector is docked at a terminal and boaters can safely cross the channel. A red light indicates the ferry is in transit, and it may not be safe for other vessels to cross the channels since the cables in operation may not be fully submerged.
Texelstroom, CNG Hybrid Ferry
Built by Spanish shipbuilder Construcciones Navales del Norte—La Naval, the 135m Texelstroom will offer its owner, Royal N.V. Texels Eigen Stoomboot Onderneming (TESO), a unique energy efficient vessel package that will combine a variety of green energy sources to help reduce its environmental impact when its delivered 1Q 2016.
The 1,750-passenger ferry is equipped with a hybrid propulsion system comprised of dual fuel (diesel/CNG) generating sets and a battery system, feeding the propulsion electric motors. The ferry is expected to operate mainly on the natural gas that will be storing two batteries of Compressed Natural Gas (CNG) bottles installed on the top deck.
The double-ended ferry was designed with two separate navigation bridges and two independent engine rooms. One engine room is fitted with two ABC diesel engines, each generating 2,000 kW of power; and the other engine room is fitted with two ABC dual fuel engines, also generating 2 x 2,000 kW. Each ship end will be fitted with two Rolls-Royce azimuth propeller.
The ferry, designed by La Naval in close cooperation with TESO and C-Job Naval Architects & Engineers, and classed by Lloyds’ Register, will also feature over 700 m2 of solar panels, helping the ship to be more sustainable. Additionally, according to LR, the ferry’s design is supported by the European Union’s “I.Transfer” program. The goal of the program is to make ferry transport accessible and sustainable.
The ferry will be ice class, featuring a strengthened hull to operate through winter ice, and will have a notation for Passenger and Crew Accommodation Comfort (PCAC) to ensure a safe and comfortable journey for passengers and crew.
Texelstroom will provide services in The Netherlands, between the island of Texel and the port of Den Helder. The ferry, which will also have capacity for 350 vehicles, will operate between 10 to 15 knots.
Ampere, Zero-emission Battery Powered Ferry
Norway was one of the first countries to embrace the move to alternative energies; the country was one of the earliest adopters of LNG as a marine fuel, and now it is the homebase for the world’s first battery powered electric car/passenger ferry. Built by Fjellstrand Shipyard, the 80 m long x 21 m wide Ampere produces zero emissions thanks to its Siemens’ BlueDrive PlusC electric propulsion system. The ferry does not use any fuel tanks or engines. Instead, it derives its power from its batteries which enable Norled to reduce its fuel costs by up to 60%, and save one million liters of fuel annually.
Ampere’s power system is made up of 224 Corvus Energy AT 6500 modules with a total capacity of 1.46MWH, an energy management system, a steering system, thruster control and an alarm system. The Energy Storage System (ESS) is split into four parts. Each of the vessel’s ends is fitted with a vessel mount and a shore power station—this enables and facilitates the rapid recharging of the batteries.
The innovative vessel is meant to be as environmentally friendly as possible, from the inside-out. Constructed from light-weight aluminum, the Ampere, weighs just half of what a conventional ferry would weigh. Its service life is double that of a steel hull ferry, and the vessel requires fewer drydock periods which help lower the vessel’s maintenance costs.
The Ampere is also equipped with LED lighting, high efficiency thrusters with feathering propellers from Rolls-Royce, and a HVAC system with extensive heat recovery. The ferry, which has passenger capacity for 350 and room for 120 cars, is classed by DNV-GL as 1A1- LC R4(nor), CF, C, BP, IOPP-A.
Mein Schiff 4, 99,500 grt cruise ship
Designed for the German premium-class cruise market, the 99,500 gt Mein Schiff 4 is the fourth in a series of cruise ships being built for TUI Cruises, a joint venture between TUI AG and Royal Caribbean.
Mein Schiff 4 was constructed using advanced and eco-friendly technologies according to ship builder Meyer Turku Shipyard, Finland. The ship was built to be as environmentally friendly as possible. Its expected to consume 30 percent less energy when compared to other ships its size. The cruise ship is also fitted with a combined exhaust after-treatment system, made up of a scrubber and a catalyzer, lowering sulfur emissions by as much as 99 percent, and NOx by 75 percent.
Engine power is provided by two Wartsila 12V46 diesel engines and two Wartsila 8L46F diesel engines.
The ship is 294m long x 36m wide, with an 8m draft. It features 1,253 cabins, and has capacity for 2,790 passengers and 1,030 crew members.
Mein Schiff 4’s initial itinerary included traveling through a variety of routes in the Baltic Sea to the Baltic States and in Northern Europe around Norway. This winter, the ship will travel to the Canary Islands making stops along Morocco and Mediera.
Mein Schiff 4 is classed by DNV-GL +1A1 Passenger Ship BIS Clean F(M) Fuel (991 kg/m3, -7°C, 380 cSt) LCS(DC) TMON. Sister ships Mein Schiff 5 and 6 will be completed and delivered by the Meyer Turku yard by 2017.
Samish, 144-Car Ferry
The second in a series of four Olympic Class ferries for Washington State Ferries, the 144-Car Samish, was named in honor of the region’s native Samish Indian Nation. It’s name means “giving people,” and Washington State Ferries is hoping to do just that, by giving back to the community with the addition of the Samish to its growing ferry fleet.
Delivered by Vigor Industrial, the new $126 million ferry, like its sister ship, the Tokitae, is based on the Olympic Class design by Seattle-based Guido Perla & Associates, Inc. The ferry measures 362 ft x 83 ft and has capacity for 144 cars and 1,500 passengers.
The Olympic Class, is built by a group of Washington-based companies—led by Vigor Industrial—offering the very best the state has to offer in design and production; and generating and supporting over 500 jobs in the Puget Sound.
Its superstructure was build by Whidbey Island, WA-based Nichols Brothers Boat Builders. Nichols built the superstructure for the Tokitae and will do the same for the third and fourth vessels in the series.
Olympic Class vessels were designed with passenger comfort in mind. The class provides wider lanes and more spaces for cars and trucks, additional comfort for passengers with two Americans with Disabilities Act-compliant (ADA compliant) elevators, an ADA-compliant car-deck restroom; flexible seating configurations; improved heating and ventilation; and wider stairwells and passageways.
Samish’s main propulsion is provided by two Electro-Motive Diesel (EMD) engines developing a total 6,000 hp, enabling the vessel to reach speeds up to 17 knots on its Anacortes to San Juan Islands route. Olympic Class ferries are also equipped with the latest emergency-evacuation and fire-suppression systems.
Samish and the other vessels in the Olympic Class also provide WSF with improved efficiency and better fuel consumption. Its hull design helps reduce wake, further improving fuel efficiency. The ships will replace the aging Evergreen State Class vessels which have been in operation since the 1950’s.
F.A. Gauthier, First LNG ferry for North America
Canada’s Société des Traversiers du Québec (STQ) is committed to a greener future. To that end the company invested in the construction of three LNG-fueled ferries in between 2014 and 2015, including the F.A. Gauthier, which was delivered to the operator this past summer.
Built by Italy’s Fincantieri Castellamare di Stabia shipyard, the F.A. Gauthier has the distinction of being the first LNG-fueled ferry to operate in North America. Classed by Lloyd’s Register, the ferry is fitted with an ultra compliant, low-emission, dual-fuel system from Wärtsilä.
Powered by four Wärtsilä 12v34D dual-fuel generating sets, meaning the ship can run on either Liquefied Natural Gas (LNG) or Marine Diesel Oil (MDO), the 133 m x 22 m ferry can reach a maximum speed of 20 knots on its Matane-Baie-Coreneau-Godbout route.
The ship is also equipped with Wärtsilä’s LNGPac system comprised of LNG bunkering, storage tanks, and handling equipment. Its fitted with two contra-rotating propellers, making the ferry exceptionally maneuverable.
The F.A. Gauthier’s hull is certified as Ice Class 1 and Propulsion Class 1, enabling the ship to break sea ice and handle adverse weather conditions on the Gulf of St. Lawrence. The ferry can carry 900 passengers and 180 vehicles on each trip, and is expected to transport more that 205,000 passengers and 118,000+ vehicles a year.
Viking Star, 48,000 grt cruise ship
Viking Ocean Cruises made its debut into the ocean going cruise market last year with the delivery of its highly anticipated 930 passenger Viking Star. The ship is the first of three cruise ships under construction at Fincantieri Marghera, Italy shipyard for the brand—which is a spin off of Viking River Cruises.
The goal for Viking Ocean Cruises was to bring the focus of cruising back to the destination. With that in mind, the brand decided to build a smaller passenger cruise ship, with a smarter design and providing guests with an enriching trip.
What makes the “small” cruise ship unique is that its engineered at a scale that enables the ship to have direct access into most ports, making embarkation and debarkation effectively easier and more efficient for guests. This lets passengers spend more time at each destination along the ship’s route.
The Viking Star’s design pays homage to the brand’s Nordic heritage, effectively immersing the passenger into local surroundings. Clean lines, woven textiles and light-wood help evoke the Viking spirit of discovery, according to the brand, and helps connect the passenger with nature.
The 228m long ship, which features 465 state room—each with its own veranda—has two pools, a main pool with a retractable roof, and a glass-backed infinity pool cantilevered off the stern; the ship also includes indoor-outdoor spaces for al fresco dining, large windows and skylights that further blur the light between inside and out, and a wrap-around promenade deck that pays homage to classic ocean liners.
Viking Star was also designed with the environment in mind. The ship is powered by energy-efficient hybrid engines, hydro-dynamically optimized streamlined hulls and bows for maximum fuel efficiency, onboard solar panels and equipment that minimizes exhaust pollution and meets the strictest environmental regulations.
Oscar B. 115 ft ferry, Wakiakum County
Wahkiakum County, Washington State is paying homage to one of the greatest skippers the country has ever had by naming the county’s newest ferry, the Oscar B, after him. Oscar Bergseng skippered the ferry, Wahkaikum, which was built in 1961, for 17 years.
Built by Nichols Brothers Boatbuilders, Freeland, WA, the 115 x 47 ft Oscar B is double the size of its predecessors, offering an expanded vehicle capacity.
The new ferry can carry 100 passengers and 23 cars between the Cathlamet, WA and Westport, OR terminals.
The ferry, designed by Seattle’s Elliott Bay Design Group, features a steel-hull, aluminum super-structure. Its power is provided by two state-of-the-art Cummins QLS diesel engines, each delivering 285 hp at 1,800 rev/min and couple to ZF Marine reversing reduction gears with two fixed-pitch propellers.
Oscar B meets all current U.S. Coast Guard requirements. Additionally, it features a hydraulic steering system, up-to-date electronics, a passenger lounge and ADA-accessible restrooms.
LNG fueled cement carrier enters service
After an extensive program of trials and tests, the 7,300 dwt vessel today departed Delfzijl on her first commercial voyage to Rostock where she will receive her first cement load.
With dimensions of 109,66 m x 14.99 m, M.V. Greenland is a dedicated cement carrier build for the joint venture JT cement, in which Erik Thun AB cooperates with KG Jebsen Cement from Norway.
The vessel is the first ever dry cargo ship with an LNG fueled propulsion system and LNG tanks integrated inside the hull. The unique design incorporates a pressurized LNG tank positioned in the foreship.
The vessel has a 6-cylinder Wärtsilä 34DF main engine, with Wärtsilä also supplying an enclosed Gas Valve Unit (GVU) for easier installation and additional engine room safety.
The cement cargo system consists of a fully automated cement loading and unloading system, based on fluidization of cement by means of compressed air. The cement can be loaded and unloaded fully enclosed through pipes and is thus dust-free.
The Best Ships of 2015
1. ISLA BELLA, WORLD’S FIRST LNG-FUELED CONTAINERSHIP (pictured above)
TOTE Maritime’s 3,100-TEU containership Isla Bella was due to set sail for San Juan, PR, on November 24, marking the first time a ship in a Jones Act liner service will burn Liquefied Natural Gas (LNG) as a marine fuel. When the 764-foot-long Isla Bella transited the Panama Canal back on October 30 on her way to the Port of Jacksonville, Panama Canal Administrator/CEO Jorge L. Quijano called her “a true engineering feat.”
Among the principal maritime stakeholders involved in the successful launch of the Isla Bella and her sister Perla del Caribe are: owner and operator TOTE, shipbuilder General Dynamics NASSCO, designer DSEC (Daewoo Shipbuilding and Marine Engineering’s ship design arm), engine licensee MAN Diesel & Turbo, classification society ABS, and regulator U.S. Coast Guard.
The two Marlin Class containerships were contracted by TOTE in December 2012 and are being built at a total cost of about $375 million.
The 764-ft Isla Bella is equipped with the world’s first dual-fuel slow-speed engine, an 8L70ME-GI built by Korea’s Doosan Engine, under license from MAN Diesel & Turbo. With a 3,100 TEU capacity, the LNG-powered Isla Bella reduces NOx emissions by 98 percent, SOx emissions by 97 percent and CO2 emissions by 76 percent. The technology makes the ship one of the world’s most environmentally friendly containerships afloat.
During LNG will allow the Marlin Class Isla Bella to be fully compliant with strict emissions regulations while operating in both the North American Emissions Control Area and the U.S. Caribbean ECA.
At the time of her delivery, Kevin Graney, Vice President and General Manager of General Dynamics NASSCO, said, “Successfully building and delivering the world’s first LNG-powered containership here in the United States for coastwise service demonstrates that commercial shipbuilders, and owners and operators, are leading the world in the introduction of cutting-edge, green technology in support of the Jones Act.”
The moment is bittersweet for TOTE as it unfolds within the shadow of the tragic loss of the SS El Faro with all hands aboard during Hurricane Joaquin on October 1. The ship’s crew of 28 and five Polish nationals onboard were lost. The U.S. Navy, working with the National Transportation Safety Board (NTSB), has located the ship in waters 15,000 feet deep near the Crooked Island in the Bahamas.
The Isla Bella will be joined by the Perla del Caribe in Puerto Rico cargo service in the first quarter of 2016.
2. OHIO, LNG-READY PRODUCT TANKER
The 330,000 bbl Ohio was became the first product tanker to be built with the future consideration for the future use of LNG as fuel when it was delivered earlier this year to Crowley Maritime Corp. by Aker Philadelphia Shipyard, Philadelphia, PA.
The Ohio received American Bureau of Shipping’s (ABS) LNG-Ready Level 1 approval, meaning Crowley has the option to convert the tanker to Liquefied Natural Gas (LNG) propulsion in the future.
The Ohio along with her three ships being built at Aker Philadelphia are based on a proven Hyundai Mipo Dockyards (HMD) design which incorporates numerous fuel efficiency features, flexible cargo capability, and a slow-speed diesel engine built under license from MAN Diesel & Turbo. The 600 feet long Ohio is capable of carrying crude oil or refined petroleum products.
Crowley’s Seattle-based, naval architecture and marine engineering subsidiary Jensen Maritime is providing construction management services for the product tankers. Jensen now has an on-site office and personnel at the Philadelphia shipyard to ensure strong working relationships with shipyard staff and a seamless construction and delivery program.
“We are excited to offer our customers cutting-edge technology available in these new tankers, which not only embraces operational excellence and top safety, but also offers the potential to be powered by environmentally friendly LNG in the future,” said Crowley’s Rob Grune, senior vice president and general manager, petroleum and chemical transportation. “Adding these new Jones Act tankers to our fleet allows us to continue providing our customers with diverse and modern equipment to transport their petroleum and chemical products in a safe and reliable manner.”
3. NEW MINI TANKER FOR NY HARBOR
Blount Boats, Inc., Warren, RI, delivered the Chandra B, a new mini-tanker for American Petroleum & Transport, Inc., Miller Place, NY. The 79 ft by 23 ft, double-hull bunkering tanker operates in New York Harbor and New Jersey supplying fuel to ferries, dinner boats, dredges, and other vessels.
Propulsion power for the tanker is supplied by two EPA Tier 3-compliant Cummins Model QSL9, six-cylinder diesel engines rated at 330 hp at 1,800 rev/min with ZF Model W325 marine hydraulic gears that will have 4.91:1 reduction ratio. The self-propelled Chandra B is equipped with a 50 hp Wesmar hydraulic bow thruster, providing it with enhanced maneuverability.
Designed by Farrell & Norton Naval Architects, Newcastle, ME, the Chandra B is built to USCG Subchapter “D” specifications and is less than 100 gross tons. Farrell & Norton also designed one of the tank barges in American Petroleum & Transport’s fleet. The double-hull Chandra B will replace the 1979-built single hull Capt. Log in American Petroleum & Transport’s fleet.
American Petroleum & Transport (APT) has had to retire all of its single-hull tankers because of OPA 90 regulations.
APT vessels crisscross New York Harbor delivering ultra low sulfur diesel to clients such as Circle Line, New York Water Taxi, Great Lakes Dredge & Dock, and Sterling Equipment, as well as for the auxiliary engines of larger ships. The Chandra B has cargo fuel tankage is designed to hold a capacity of 56,450 gallons.
4. SAKIGAKE, JAPAN’S FIRST LNG-POWERED TUG
This past year, NYK took delivery of Sakigake, Japan’s first LNG fueled tug. Built at NYK’s wholly owned subsidiary Keihin Dock Co’s Oppama shipyard, the 37.2 m x 10.2 m Sakigake is operated by Wing Maritime Service Corporation, mainly in the ports of Yokohama and Kawasaki. Wing Maritime also operates the hybrid tug Tsubasa.
The Sakigake is equipped with two Niigata 6L28AHX-DF dual-fuel engines, each developing 1,618 kW. Propulsion is supplied by two Niigata Z-Pellers.
The DF engines can burn either LNG or diesel oil. The environmental advantages of operating on LNG as compared with conventionally powered tugs that use marine diesel oil is Sakigake emits about 30 percent less CO2, 80 percent less NOx, and no SOx.
While the project posed several challenges—the relatively small size and limited amount of space on the tug, and the large variation in engine power—Keihin Dock was able to achieve the desired level of environmental performance while maintaining the same hull form and steering performance of existing tugs. Keihin Dock worked closely with both Niigata Power Systems and Air Water Plant & Engineering Inc. to develop equipment for supplying LNG.
The project was supported by subsidies from Japan’s Ministry of Economy, Trade and Industry and the Ministry of Land, Infrastructure and Transport. ClassNK also provided joint research support.
5. JS INEOS INSIGHT, FIRST ETHANE-POWERED SHIP
Emblazoned on the JS Ineos Insight’s hull is the phrase, “Shale Gas for Manufacturing.” Built specifically to transport shale gas from the U.S. to Europe, the JS Ineos Insight is the first of eight 180m x 26.6m ethane gas carriers built by China’s Sinopacific for Denmark’s Evergas.
Named on July 14, the JS Ineos Insight can not only carry ethane, LPG or LNG, but can also burn ethane, LNG and conventional diesel in its two Wartsila 50DF dual fuel engines.
The eight Ineos ships will transport over 800,000 tons of ethane gas at -90°C per annum across the Atlantic from the U.S. to Norway and Scotland.
Classed by Bureau Veritas, the Dragon vessels were originally designed as dual-fuel LNG/diesel-powered vessels, with two 1,000 m3 LNG tanks on deck powering two Wärtsilä 6L20 DF main engines with a total output of 2,112 kW and two shaft generators with a total output of 3,600 kW power. The vessels will initially transport ethane from the U.S, to the U.K. Ineos refineries, the ability to also burn ethane was added to allow use of the cargo gas as fuel.
At the christening of the JS Ineos Insight and the JS Ineos Ingenuity, Ineos Chairman Jim Ratcliffe says, “Today is a landmark day for both Ineos and Europe. We have seen how U.S. shale gas revolutionized U.S. manufacturing and we believe these huge ships will help do the same for Europe. Ineos together with Evergas has commissioned eight brand new ships, accessed hundreds of miles of new pipeline and built two enormous terminals to get U.S. Shale gas to Europe. The scale of the whole project is truly breathtaking.”
According to Bureau Veritas Business Development Manager Martial Claudepierre, the ability to burn ethane and LNG as fuel in the Dragon Class ships “is a major step forward in the use of clean fuels.” He says that BV worked with Evergas and the Danish Maritime Authority to verify and ensure that the use of ethane is at least as safe as required by the IGC and will not impair the engine compliance with MARPOL Annex VI.
According to Claudepierre, using ethane required extra engine room ventilation and additional gas detection, plus modifications to the main engines including a lower compression ratio, different turbocharger nozzles and de-rating of the engine to cope with the lower knocking resistance of ethane. “But,” he says, “The gains in not carrying an additional fuel and in environmental performance from being able to burn clean fuel throughout the voyage are significant.”
6. MARJORIE C, NEW JONES ACT CONRO
Capable of carrying up to 1,200 cars and 1,400 TEU of containers, the Combination Container and Roll-on/Roll-Off (ConRO) vessel Marjorie C entered Jones Act service this year between the U.S. West Coast and Hawaii.
Built by VT Halter Marine, Pascagoula, MS, the Marjorie C was engineered from a proven design by Grimaldi at Croatia’s Uljanik Shipyard. The 692 ft x 106 ft ConRO has a draft of 31 ft, deadweight of 21,132.5 metric tons, with nine decks. It has a stern ramp capacity of 350 metric tons. The ship has a service speed of 21.5 knots.
The vessel’s design incorporates the highest level of operating efficiencies as well as reduced environmental impacts. The sister vessel, Jean Anne, was Pasha Hawaii’s first Jones Act vessel and has been serving the Hawaii/Mainland trade since March 2005. The Marjorie C entered into service this past May.
The ship is named in honor of Pasha Hawaii’s President and CEO George Pasha, IV’s grandmother, Marjorie Catherine Ryan.
“After more than three and a half years of planning and construction, we are pleased to unveil a ship that has been designed to not only accommodate the varying needs of our customers, but a vessel that minimizes our carbon footprint through extensive fuel consumption efficiencies and other green technologies,” said Pasha Hawaii’s President and CEO, George Pasha, IV. “With the addition of the Marjorie C we can now offer customers increased service and capacity between the West Coast and Hawaii trade lane on vessels providing superior reliability and cargo protection.”
7. NEIL ARMSTRONG, FIRST OF NEW CLASS OF RESEARCH VESSELS
This past Halloween, the first-of-class oceanographic research vessel R/V Neil Armstrong (AGOR 27) set sail from Dakota Creek Industries, Anacortes, WA, to San Francisco, CA, on its inaugural voyage. As we went to press, the Neil Armstong was waiting its turn to pass through the Panama Canal on its way north to the Woods Hole Oceanographic Institute in Woods Hole, MA. The ship will be operated by the Woods Hole Oceanographic Institution under a charter party agreement with Office of Naval Research (ONR).
Designed by Guido Perla & Associates, Inc., Seattle, WA and owned by the U.S. Navy, Neil Armstrong is 238 ft x 50 ft with a depth of 22 ft and draft of 15 ft. The first of two research vessels, the Neil Armstrong has four main 1,400 kW diesel generators, two 876 kW propulsion motors, and two controllable pitch propellers. The ship has a sustained speed of 12 knots and maximum speed of 12.8 knots.
The ship was classed by ABS Under 90 meter rules A1, Circle E, AMS, ACCU, NIBS, Ice Class D0, UWILD, 46 CFR Subchapter U, SOLAS (Oceanographic Vessels), MARPOL.
The Neil Armstrong’s sister vessel, the R/V Sally Ride (AGOR 28), is also under construction at Dakota Creek Industries.
During acceptance trials, Mike Kosar, Program Manager for the Support Ships, Boats and Craft office within the Program Executive Office (PEO), Ships, says, “The results of these tests and the outstanding fit, finish and quality of the vessel, stand as a testament to the preparation and effort of our entire shipbuilding team. It reflects the exceptionalism of AGOR 27’s namesake, Neil Armstrong.”
Neil Armstrong Class AGORS incorporate the latest technologies, including high-efficiency diesel engines, emissions controls for stack gasses, and new information technology tools both for monitoring shipboard systems and for communicating with the world. These ships will provide scientists with the tools and capabilities to support ongoing research including in the Atlantic, western Pacific and Indian Ocean regions across a wide variety of missions.
The lab areas include the main lab of 1,023 ft2, the wet area of 398 ft2, computer area of 311 ft2, and staging area bay of 303 ft2.
Neil Armstrong will be capable of assisting with integrated, interdisciplinary, general purpose oceanographic research in coastal and deep ocean areas. The vessel will operate with a crew of 20 with accommodations for 24 scientists.
8. BARZAN, FIRST OF NEW CLASS OF GAS READY BOXSHIPS
Recently named in a ceremony at shipbuilder Hyundai Samho Heavy Industries’ Mokpo, South Korea, shipyard, Barzan is the first in a series of six 18,800 TEU containerships ordered by Dubai headquartered United Arab Shipping Company (UASC). It is the first vessel to receive classification society DNV GL’s new GAS READY notation. Her five sister ships and eleven 15,000 TEU vessels of UASC’s newest eco-ship generation, will also receive the notation.
The ships have been designed and constructed to enable a quick and cost efficient retrofit to LNG fueling at a later stage. The GAS READY notation, with nominators (D, S, MEc, AEi) demonstrates that the vessel is in compliance with the gas fueled notation rules, that structural reinforcements to support the fuel containment system (LNG tank) have been verified (S), that the main engines installed can be converted to dual fuel (MEc ) and that the auxiliary engines installed can be operated on gas (AEi).
“We believe that this vessel, as well as the rest of the vessels in our new building program, demonstrates our commitment to technical innovation and eco-effectiveness,” says Jørn Hinge, President and CEO of UASC. “For UASC, achieving optimum efficiency levels is not a single initiative or project, it is a strategy and an ongoing commitment, and we will continue to work with DNV GL on the remaining newbuild vessels that have the lowest levels of CO2 output in their class.”
As well as being LNG ready, Barzan and her sister vessels incorporate several innovative energy saving methods, including a Siemens’ Siship SGM environmentally friendly drive and power generation system.
The Waste Heat Recovery System (WHRS) converts thermal energy from the exhaust gas from the main engines into electrical power to maximize the efficiency of the system.
The Barzan was expected to have an EEDI (Energy Efficiency Design Index) value that is close to 50 per cent less than the 2025 limit set by IMO, with a CO2 output per TEU that is more than 60 per cent lower than a 13,500 TEU vessel delivered just three years ago.
Barzan has been constructed to DNV GL class rules with the notations: 1A1 Container Carrier DG-P Shore Power E0 NAUT-OC HMON (A1,C1,G4) CLEAN BWM-T BIS TMON NAUTICUS (Newbuilding) GAS READY (D, S, MEc, AEi).
9. CROWN POINT, NEW GENERATION GREEN TUG
Tidewater Transportation and Terminals, Vancouver, WA, recently took delivery of the Crown Point, the first in a series of three 102 ft x 38 ft towboats being built at Vigor Industrial in Portland, OR.
The three towboats are the first new vessels to be built for the Tidewater fleet in 30 years, and are critical for the company to meet the anticipated rising customer demand on the Columbia-Snake River system. “The launching of the Crown Point, and the forthcoming Granite Point and Ryan Point vessels, marks an important step for Tidewater,” says Marc Schwartz, Maintenance & Engineering Manager at Tidewater. The vessels will strengthen our fleet, as well as reinforce Tidewater’s commitment to our customers, community, and environment.”
Tidewater operates the largest barge transportation and terminal network on the Columbia-Snake River system. The Crown Point joins the company’s current fleet of 16 vessels and 160 barges. Tidewater transports a wide range of cargo among a network of ports, terminals and grain elevators throughout the entire Columbia-Snake River system, which stretches some 465 miles of waterways. We also operate five strategically located terminals and five pipelines with key intermodal connections to railroads, highways and other pipelines.
Designed by CT Marine, Naval Architects and Marine Engineers of Edgecomb, ME, the Crown Point is an environmentally friendly tug with EPA Tier 3 compliant diesel engines that reduce air emissions and improve fuel efficiency. Main propulsion is supplied by two Caterpillar 3516C EPA Tier 3 certified diesel engines producing 2,240 bhp, each at 1,600 rev/min. The engines drive two 92 in. x 100 in. fixed pitch, stainless steel propellers through CT28 Kort Nozzles capable of a service speed of 8 knots. Operating in the Columbia River Gorge high winds, extreme currents and swells can be considered normal piloting conditions. That’s why the Crown Pount abd her sister towboats are fitted with an enhanced steering system using four steering and four flanking rudders was designed. The towboat has a wheelhouse with exceptional all-round visibility through full height windows, leading edge navigation and communications equipment, and enhanced accommodations for the captain and crew.
“During the last year and a half, a great deal of effort went into designing, engineering and building a towboat that would meet or exceed performance parameters,” explains Bruce Reed, Tidewater COO and Vice President. “With crew endurance being a priority, we employed Noise Control Engineers, Billerica, MA to develop a sound and vibration control package for the vessel. By incorporating Christie and Grey vibration control mounts and comprehensive acoustic insulation, noise levels register at less than 60 decibels in the accommodations during vessel operation.”
Other equipment onboard the Crown Point includes two C7.1, Tier 3 generators, rated at 480v, 200 kW at 1,800 rev/min. The generators are controlled through an automatic transfer system that ensures the vessel will recover from a generator power loss in less than 30 seconds. Deck machinery includes seven Patterson WWP 65E-7.5, 65-ton electric deck winches, with pilothouse remote operation and local push button control stations on the main deck. Each winch has Samson 1 3/8” Turbo 75 Synthetic Line.
In order to use the newest technology and minimize power usage, variable frequency drives were used in all major rotating machinery applications and LED lighting was employed in both interior and exterior lighting applications. The vessel is fitted with a Kidde NOVEC 1230 fire suppression system. Centralized fire detection and alarms cover both the machinery spaces and accommodations.
10. MULTRATUG 28, A HYBRID TUG
This past year, Netherlands-based towage and salvage specialist Multraship took delivery of Multratug 28, a Damen ASD 2810 Hybrid tug built at Damen Shipyards Galaţi, in Romania, as part of a fleet expansion program.
Classed by Lloyd’s Register, the hybrid Multratug 28 is 28.67m x 10.43m, with a maximum draft of 4.9m. The propulsion system includes two MTU 16V4000M63R diesel engines with one MTU 12V 2000 M41B propulsion genset of 800 kvA, 440V-60Hz. The battery pack are two 120 kWh. Two Rolls Royce US205 azimuth thrusters provide propulsion. The tug has a bollard pull of 62 tons, diesel direct speed of 13 knots, diesel electric speed of 8 knots, and battery pack speed of 4 knots.
The ASD 2810 HYBRID is developed to save fuel by 30% and to reduce emissions by 50%. To achieve this the vessel is provided with a propulsion system that can operate diesel-direct, diesel-electric or fully-electric. Fully-electric sailing on the batteries, with zero emissions and extremely low noise levels, is possible for time periods of up to one hour at a speed of 4 knots.
In June 2014, the first Damen ASD 2810 Hybrid was delivered to Iskes Towage & Salvage. Being green does not mean sacrificing power, the Bernardus still has a bollard pull of 60 tonnes. The Bernardus operates in the Port of IJmuiden near Amsterdam, the Netherlands.
“This hybrid tug is a unique concept,” says Dinu Berariu, Project Manager at Damen Shipyards Galaţi. “It features a diesel-direct, diesel-electric and battery powered propulsion system. This hybrid configuration will enable Multraship to lower fuel costs by up to 30 percent and emissions by up to 60 percent.”
Headquartered in the harbor city of Terneuzen, Multraship operates in the ports around the Scheldt estuary, in Zeeland seaports and the Belgian ports of Ghent and Antwerp, as well as the Bulgarian port of Burgas on the Black Sea.
Multraship’s fleet expansion program stems from its increasing customer base in the offshore sectors as well as growing demand for harbor towage services.
11. VASCO DE GAMA, FIRST 18,000 TEU BOX SHIP FROM A CHINESE YARD
As we went to press, the world’s third largest containership company, CMA CGM Group, Marseilles, France, was closing in on the acquisition of Singapore-based NOL, the world’s fourth largest. It successful, privately held CMA CGM would leapfrog over MSC to become number two in the world.
A big part of CMA CGM’s success is its investments in larger, more energy efficient tonnage to improve pricing and economies of scale. An excellent example is the CMA CGM Vasco De Gama delivered this summer to CMA CGM by China State Shipbuilding Corporation (CSSC).
With a length of 399 m and breadth of 54 m, the 18,000 TEU vessel is the largest containership in the CMA CGM Group and is the first 18,000 TEU containership to be built by a Chinese shipyard. CSSC is also building two more of the giant box ships, the CMA CGM Zheng He and CMA CGM Benjamin Franklin.
Flying the U.K. flag, CMA CGM Vasco De Gama is equipped with the latest environmental technologies including a latest generation main engine, a twisted leading edge rudder with bulb from Germany’s Becker Marine Systems and an optimized hull design. These innovations decrease the vessel’s CO2 emissions by 10% compared to the previous vessel generation. With an estimated emission of 37g of CO2/km for each container carried, the giant containership provides one of the world’s greenest goods transportation options.
The ship’s environmental footprint meets the 2025 energy efficiency regulations.
CMA CGM Vasco De Gama calls at 11 different countries on CMA CGM Group’s French Asia Line (FAL) service between Europe and Asia.
CMA CGM is also building three 20,600 TEU containerships—the largest yet built—at Korea’s Hanjin Heavy Industries. Those three ships will each have full spade twisted rudders (TLKSR) from Becker Marine Systems and Becker Twisted Fins. Both Becker products will make a significant contribution to the vessel’s efficiency improvement.
12. ESVAGT FROUDE, SPECIALIZED WIND FARM VESSEL
As of September this past year, Denmark’s ESVAGT had new owners; 3i Infrastructure and AMP Capital acquired the shares of A.P. Møller-Maersk Group and ESE-Holding. While ESVAGT’s primary market will continue to be oil and gas support and standby rescue in the North Sea, the company is broadening its portfolio with a push into the offshore wind energy market.
This past summer, ESVAGT entered the offshore wind industry with the christening of the world’s first purpose-built Service Operation Vessels at Siemens AG in Rostock and Hamburg, Germany.
The Service Operation Vessels (SOV), Esvagt Froude and Esvagt Faraday are each 83.7m x 17.6m, with a draft of 6.5m. Both of the Danish-flag SOVs were built in Norway by Havyard Ship Technology and are based on a Havyard 832 SOV design. The SOVs both have diesel-electric propulsion and DC power systems, enabling optimized fuel and energy efficiency and crew comfort. The service speed is 14 knots.
The SOVs are essentially “service stations at sea,” offering technicians a safe, efficient platform for wind turbine maintenance. Using the ship’s DP system, the ship can connect to wind turbines via its Ampelmann A-type Walk-to-work hydraulic gangway system offering a stable, safe platform to connect to the wind turbine.
Each offers accommodations for 60 people. The vessels are designed to reduce the level of vibration and increase the level of comfort for everyone onboard.
“As a supplement to the “Walk-to-Work” gangway, we have equipped the Service Operation Vessels with the newly developed ESVAGT Safe Transfer Boats (STB 7 and STB 12),” says Søren Nørgaard Thomsen, Managing Director for ESVAGT. “They are designed in-house based on more than 20 years of experience in boat development and more than 100,000 boat transfers. These boats will in a safe manner provide the industry with additional efficiencies and cost reductions.”
Each of the ships carry ESVAGT STB 7B Safe Transfer Boat, ESVAGT STB 12A Safe Transport Boat, ESVAGT FRB 15C Fast Rescue Boat.
A third ESVAGT SOV is on order and under construction at Havyard for delivery in 2016. The third ESVAGT SOV will service the 400 MW Dudgeon Wind Farm off the East Coast of England in the fall of 2016.
The Best Passenger Ships of 2015
1. Veteran, 80m Ice Class Ferry, Government of Newfoundland and Labrador, Damen Galati
The Veteran is part of a large “lifeline” vessel replacement program being undertaken by the Provincial Government to modernize its fleet.
2. Sally Fox, 105 ft Fast Ferry, King County, All American Marine
Sally Fox is the first U.S. Coast Guard Sub-chapter “K” inspected passenger vessel built and delivered under new fire safety guidelines.
3. Baynes Sound Connector, Longest Cable Ferry, BC Ferries, Seaspan Vancouver Shipyards
BC Ferries’ cable ferry, the 150-passenger, 50-vehicle Baynes Sound Connector is the longest cable ferry in operation today.
4. Texelstroom, CNG Hybrid Ferry, TESO, LaNaval
The ferry will operate mainly on natural gas stored in two batteries of compressed natural gas (CNG) bottles installed on the top deck.
5. Ampere, Electric Ferry, Norled, Fjellstrand
Norled’s Ampere is the world’s first battery powered electric car and passenger ferry.
6. Mein Schiff 4, 99,500 grt Cruise Ship, TUI Cruises, Meyer Turku
Designed for the German premium-class cruise market, the 99,500 gt Mein Schiff 4 is 294 m long and 36 m wide and has a total of 1,253 cabins.
7. Samish, 144-Car Ferry, Washington State Ferries, Vigor Industrial
Designed by Seattle-based Guido Perla & Associates, Inc., the Samish is the second in the Olympic Class vessels being built for WSF. The 362 ft ferries have a capacity of 144 cars and 1,500 passengers.
8. F.A. Gauthier, First LNG Ferry for North America, STQ, Fincantieri
The ship’s integrated diesel electric propulsion system has four Wärtsilä 12V34DF dual-fuel generating sets. that can run on either LNG or MDO Gas – LNG) or marine diesel oil (MDO).
9. Viking Star, 48,000 grt Cruise Ship, Viking Ocean Cruises, Fincanitieri
The Viking Star is the first of the three 48,000 grt, 930 passenger cruise ships on order for the line at Fincantieri’s Marghera, Italy, shipyard.
10. Oscar B., 115 ft Ferry, Wakiakum County, Nichols Brothers Boat Builders
Designed by Seattle’s Elliott Bay Design Group the steel-hulled, aluminum superstructured vessel has been built for Wahkiakum County, Washington State as a replacement for the ferry Wahkiakum.
LNG fuel tanks installed in first Crowley ConRo
Another important milestone was marked last week, with the installation of three LNG fuel tanks in the first ship.
The double-walled, stainless steel tanks – which are 110 feet in length and 20.6 feet in diameter – weigh 225 metric tons and will hold more than enough LNG fuel for two round-trip voyages between the vessel’s future ports of call, Jacksonville, FL, and San Juan, Puerto Rico.
“While we are all excitedly watching these ships take shape, we are particularly proud of the role we, as a company, are playing to bring the most modern, technologically advanced and environmentally friendly ConRo ships in the world to the Jones Act market of Puerto Rico,” said Tom Crowley, company chairman and CEO. “There are no other ships of their kind being built anywhere else in the world today, and they are being constructed right here at home – in the United States of America. Having that shipbuilding capability here is essential to our national defense and an important reason we as a country need the Jones Act to be maintained and strengthened.”
Crowley’s two Jones Act ConRo ships, which will be named El Coquí (ko-kee) and Taíno (tahy-noh), are are scheduled for delivery second and fourth quarter 2017 respectively.
“It’s very impressive to see these new state-of-the-art Commitment Class ships take shape,” said John Hourihan, senior vice president and general manager, Puerto Rico services. “Seeing those LNG tanks being placed into El Coquí really resonates with me because we are setting a new standard for environmentally responsible shipping.”
The Commitment Class ships have been designed to maximize the carriage of 53-foot, 102-inch-wide containers, which offer the most cubic cargo capacity in the trade.
The ships will be 219.5 meters long, 32.3 meters wide , have a deep draft of 10 meters, and an approximate deadweight capacity of 26,500 metric tonnes. Cargo capacity will be approximately 2,400 TEUs (20-foot-equivalent-units), with additional space for nearly 400 vehicles in an enclosed Ro/Ro garage.
Each ship will be powered by an MAN B&W 8S70ME-GI8.2 main engine and three MAN 9L28/32DF auxiliary engines, all fueled by LNG .
The ship design is provided by Wartsila Ship Design in conjunction with Crowley subsidiary Jensen Maritime.
