Danish design firm helps speed wind farm installation
JANUARY 24, 2017 — Two months ahead of schedule, the first of 67 Siemens 6 MW wind turbines has started started supplying the German electrical grid with energy from the Veja Mate
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Lloyd’s Register’s Mark Darley discusses the challenges facing the industry
ML: Tell us a bit about your background. How did you get started in the marine business?
MD: Originally from the UK, my introduction to the Marine world can be traced back to growing up and learning to sail in my early teens—as well as the influence of my father, a mechanical engineer. To complement my understanding of science and engineering, and my sailing hobby, by the time I was University age, I chose to undertake a Naval Architecture and Offshore engineering degree. A graduate of both the Lloyds Register (LR) internship program and Lloyds Register Graduate training scheme, I have been fortunate, but also driven to obtain a diverse understanding of the global supply chain and Marine business as a whole over the 16 years I have worked for LR. Having held a variety of roles across our business and areas of operations—from London, Dubai, South Africa, South East Asia and now the Americas—each role has been an incredible professional and personal learning experience, and has given me a broad view of our clients, their challenges, the global interconnected nature of our Marine business as well as the place and importance of Lloyd’s Register both now and as we look to the future.
ML: You’ve worked with Lloyd’s Register in Europe, the Middle East and Asia. Are the challenges for a classification society any different in Americas than the rest of the world?
MD: Irrespective of geography, at Lloyd’s Register our primary aim is about helping to shape the future of shipping, while delivering solutions today – helping clients and stakeholders make the best commercial decisions based on the best technical insight. Over the years this has seen an evolution in how and what all Classification societies view as their part in the industry, from core classification to industry and individual client advisors. Clearly irrespective of geography, many of our client challenges are similar and I think one thing my global experience has taught me is that there are many synergies between geographies, segments, and clients that enable us in the Americas to be agile and expedite the best solutions for our clients.
In the Americas specifically, we operate across 14 countries and it’s important that we have both the right existing as well as future resource and knowledge base to address the challenges of our client bases as markets, ship segments, energy and social economic policies impact their operations and future strategic direction across those countries. Looking at the future of our services across the Americas, therefore, we have recently made enhancements to how we serve and work with our client bases across the region. Outside of our core Classification business and surveyors on ships, this ranges from working with the Royal Canadian Navy to developing a Regulatory regime for Naval Safety and their shipbuilding program to developing new propulsion configurations with our GE COGES (COmbined Gas turbine Electric and Steam) Joint Industry Project for LNG and ULCS construction right across the spectrum to helping understand small scale and inland waterways LNG solutions in the Gulf, South and Central America. While the challenges may be geographically unique, and different markets may require different solutions, our aim has always been to provide solutions and aid decision making for our industry.
ML: What are the biggest challenges faced by vessel operators today? Complying with stricter environmental regulations? Cybersecurity? Crew training?
MD: As you know these are very interesting times for the Marine Industry as a whole and inherent stakeholders there-in. Interestingly with the downturn in many sectors, we are seeing the emergence of an industry that, while remaining the enabler of world trade, is more open to drive innovation, offering interesting, dynamic technical solutions and careers as we search for answers to questions about the future of Marine and Offshore. The solutions to many of the challenges faced by owners today are also increasingly coming from other industries or providers not traditionally known within Marine. Aside from the ongoing regulatory changes, we are working with many owner/operators and shipyards across the world in so many areas. Sensors, data and robotics could drive safer, autonomous operations and surveys; new fuels are going to emerge to help lower greenhouse gases as well as improve local air emissions; new software tools will be developed to improve vessel design and safety oversight while also optimizing performance outcomes; and a new cyber enabled shipping that will see the development of things that we can’t predict and possibly lead to a significant and exponential disruption in the industry. We are also seeing the increasing challenge of obsolesce in newer and newer assets as well as a shift in firstly attracting then maintaining and training next generation crews.
These are very technological, challenging yet interesting and visionary times for Marine and Offshore.
ML: How do you see class evolving over the next decade? What challenges does your organization face in the years ahead?
MD: The role and place of Class societies has markedly changed over the last decade and looking forward the pace of industry change and technological advancement means we are already scenario planning for what may be needed in the next decades. It’s critical we understand and address these changes not only in terms of future core surveying capabilities and technologies but importantly to remain relevant and agile in maintaining our technology leadership and aims as an industry advisor. We often say “We are our people” and as someone who’s worked across the globe I have seen first-hand the breadth of our global knowledge base, connection and industry expectations. Ensuring we adapt to these changing needs is vital as well as ensuring we continue to invest either time or capital in understanding and shaping technology impacts to our own business with the agility to redefine what we do. To this aim we’ve working closer with industry visionaries many of whom reside in the Americas both historical marine companies but increasingly from outside of Marine. Real world solutions to industry challenges such as our joint venture project with Siemens, Dresser-Rand, Waller Marine and Conrad are examples of greater cross-industry collaboration in meeting tomorrow’s challenges.
Ulstein delivers X-Stern wind farm SOV
JUNE 23, 2016 — Bernard Schulte Offshore today took delivery of the first of two 88 m x 18 m wind farm service operation vessels ordered from Norway’s Ulstein Verft in 2015.
Tugs & Barges: Evolving with the market
Engineering company GTT has more than 50 years’ experience in the design of membrane cargo containment systems, but one project underway right now in Orange, TX, is quite unique. That’s because it’s the first Liquefied Natural Gas (LNG) bunker transport barge in the United States.
One of 118 GTT projects currently underway worldwide, the tank barge is taking shape at Conrad Orange shipyard, Aziz Bamik, General Manager of GTT North America, told delegates at Marine Log Tugs & Barges 2016 Conference & Expo held last month in Seattle. While Conrad has decades of experience building all types of tank barges—dirty oil, products, chemicals, and LPG—this is the first time that it is building a vessel with one of GTT’s Mark III Flex membrane tank technology. Following a certification process, Conrad signed a license agreement with GTT back in January 2015 to construct the Mark III Flex.
Designed to operate in inland waterways, bays, harbors, and U.S. coastal waters, the new 2,200 m3 tank barge will be used to refuel TOTE’s two 3,100-TEU LNG-powered containerships. The barge will travel about a mile from its mooring facility to fuel the two Orca Class containerships, which operate out of the Port of Jacksonville, FL to San Juan, PR. The barge is designed not as an Articulated Tug Barge unit, but rather to be towed by hawser wire, pushed or maneuvered by hip, says Bamik.
In anticipation of increasing demand for LNG as a marine fuel, Bamik also mentioned to the conference audience that GTT North America was working with Conrad on a larger Articulated Tug Barge unit that will have a capacity of 4,800 m3, with two GTT Mark III Flex Cargo Containment System tanks. The 319 ft x 62 ft barge would have cold LNG delivery with onboard reliquefaction.
COMING DEMAND FOR LNG
The interest in LNG as a marine fuel seems to have waned in the U.S. with the drop in the price of oil. As of today, five vessels burn LNG as fuel in the Jones Act market. Besides TOTE’s two containerships, the Harvey Power, the third in a series of six dual fuel Platform Supply Vessels for Harvey Gulf International Marine, New Orleans, recently entered service in the Gulf of Mexico under charter for Shell. Next year, Crowley Maritime will take delivery of two Commitment Class Container Roll-on/Roll-Off (CONRO) ships for Puerto Rico. Those are being classed by DNV GL. All the other Jones Act LNG fuelled vessels are being built to ABS class.
Additional LNG Ready classed tonnage delivered or being built by General Dynamics NASSCO in San Diego and Philly Shipyard Inc. in Philadelphia could grow the LNG-fueled Jones Act fleet if converted in the future. TOTE is also converting its two Orcas Class RO/RO ships for Alaska service in Singapore.
Globally, there are about 77 gas-fueled vessels in operation and another 79 confirmed newbuildings as of March 2016, according to Anthony Teo, Technology and LNG Business Development Manager, North America, DNV GL. “There are about another 50 LNG Ready vessels have been contracted,” Teo told delegates. He said that DNV GL estimates there will be 360 LNG fuelled vessels in operation by 2020.
The widespread adoption of LNG as a fuel, Teo pointed out, was is being hindered by the lack of gas fuel bunkering facilities in ports.
A panel of naval architects, liquefied natural gas reliquefaction technology providers, and regulators discussed more in-depth the current hurdles hindering the expansion of the adoption of LNG as a marine fuel for the tugs and towboats in the Jones Act market.
Panelist Rafael Riva, Marine Business Development Manager, ECA, Lloyd’s Register pointed out that the technology was well proven in Europe. The first LNG tugs, for example, were built in Turkish shipyard Sanmar for Norway’s Bukser og Berging AS and have been in service for Statoil AS since 2014. The DNV GL class tugs are equipped with lean burn gas engines from Rolls-Royce and Rolls-Royce azimuthing thrusters.
The LNG powered propulsion systems does require more space. The Shearer Group’s Engineering Manager Joshua Sebastian, PE, mentioned the complexities of integrating the necessary fuel tank, piping, and control systems required to burn LNG on the smaller towboat platform. Sebastian’s company, naval architectural firm The Shearer Group, has been contracted for the conversion of a 65-foot-long conventional diesel-powered towboat to burn LNG.
LNG-powered tugs also require small volumes of fuel with a dedicated delivery solution. Fueling can be accomplished either via tanker trucks, shore LNG storage tanks, portable gas fuel tanks or ship to ship or barge to ship transfer.
Panelist John Dwyer, Officer in Charge, Marine Inspection/Chief, Inspection Division at USCG Sector Puget Sound, provided the regulatory view on the development of LNG as a marine fuel in the U.S.
The U.S. Coast Guard has issued a number of policy letters and guidance on the design and operation of ships using LNG as a marine fuel, as well as ships and facilities transferring LNG as fuel. The U.S. Coast Guard has addressed designs and facilities on a case-by-case basis.
Waller Marine’s Beau Berthelot pointed out that his company has worked on a number of refueling solutions. Waller Marine, for example, has been granted an Agreement in Principle (AIP) by ABS for a new liquefied natural gas (LNG) and regasification articulated tug barge concept. The vessel has the ability to load LNG from existing LNG terminals, liquefaction facilities or traditional LNG carriers and transport the LNG to existing tanks, traditional LNG carriers, trucks or marine vessels using LNG as a fuel. The barge also is equipped for regasification of LNG directly to a pipeline or to a power plant. An additional feature will be the use of natural gas as a fuel in the dual fuel engines of the tug to drive the tug-barge unit.
The benefit of the LNG Articulated Tug and Barge Regas Vessel (ATB RV) is that it allows LNG to be moved and delivered more efficiently on a small-scale basis in locations where large LNG infrastructure would be cumbersome, costly and time consuming.
Another possible solution for small footprint applications mentioned by panelists David Grucza, Director, Drilling and Marine U.S., Siemens, and Michael Walhof, Sales Director, Distributed LNG Solutions, Dresser-Rand, a Siemens company, was Dresser-Rand’s LNGo system is a modularized, portable natural gas liquefaction plant. This point-of-use production plant is a standardized product made up of four packaged skids: a power module, compressor module, process module and a conditioning module. The natural gas consumed powers the unit and is also used as the process refrigerant to eliminate complexity and maintenance.
SHIPYARDS CONTINUE TO BE BUSY
Meanwhile, U.S. shipyards continue to book orders for conventionally powered harbor tugs and Articulated Tug Barge (ATB) units. The continued orders for ATBs, in particular, are in response to transport refined products in the U.S.
Just last month, Gunderson Marine, Portland, OR, secured an order to build two 82,000 bbl, 430 foot-long oceangoing tank barges for Harley Marine Services, Inc., Seattle. The tank barges will be part of an ATB unit.
Gunderson last built a barge for Harley Marine in 2009. Construction on the barges will begin this year, with delivery of both vessels set for the second half of 2017.
As of press time, Harley Marine Services was negotiating with a Gulf Coast shipyard for the construction of the ATB tugs that would be coupled to the tank barges being built by Gunderson.
Over the past nine months, Gunderson Marine has delivered two 578 ft ATB oceangoing barges for chemical and oil service for Kirby Offshore Marine.
For its tank barges, Kirby Offshore Marine took delivery of two 10,000 hp ATB tugs from Nichols Brothers Boat Builders, Whidbey Island, WA. Speaking at Marine Log Tugs & Barges 2016, Nichols Brothers Boat Builders President & CEO Gavin Higgins said that ATBs enjoy several cost advantages over coastal tankers when it comes to moving refined products. Crew costs are far less, nine crew vs. 18 crew. Additionally, ATBs are more ship shape, offering speed advantages over towed tank barges.
The shipyard has also signed a contract with Kirby for two line haul tugs, as well as two 8,000 hp ATB tugs based on a design by naval architect Robert Hill of Ocean Tug & Barge Engineering. The companion tank barges are being built by Vigor.
FINCANTIERI BAY SHIPBUILDING
Fincantieri Marine Group’s Fincantieri Bay Shipbuilding (FBS), Sturgeon Bay, WI, has delivered the Articulated Tug Barge unit (ATB) Barbara Carol Ann Moran and the 110,000-barrel ocean tank barge Louisiana to Moran Towing Corporation, New Canaan, CT.
The 5,300-HP, 121-foot ATB tug Barbara Carol Ann Moran is certified ABS Class +A-1 Towing Service, +AMS, and is equipped with state-of-the-art navigation and communications technology. The Louisiana is 468 ft x 78 ft.
The ATB unit will work the East Coast of the United States and the Gulf of Mexico.
This is the shipyard’s third delivery to Moran under a 2014 contract, with a tank barge delivered in May of 2015, and another ATB—the tug Leigh Ann Moran and tank barge Mississippi—delivered December 1, 2015.
VANE BROTHERS SERIES AT ST. JOHNS
Vane Brothers, Baltimore, MD, continues to invest in new tonnage. It has a long running newbuild program at Chesapeake Shipbuilding in Salisbury, MD, where it is constructing a series of 3,000 hp ATB tugs and has now added the second of eight 4,200 horsepower tugboats from St. Johns Ship Building, Palatka, FL.
The new tug, Hudson, is the second of Vane’s Elizabeth Anne Class, under construction at St. Johns Ship Building. Lead vessel of the class, the Elizabeth Anne, was delivered in January, while the third in the series, the Baltimore, is set for completion this summer.
The new tug will be paired with the Double Skin 601, the first in a new series of 55,000 bbl barges and will be followed later this year by the Double Skin 602, both built by the Conrad Deepwater South Shipyard in Amelia, LA.
“Our ongoing fleet construction program ensures that we have state-of-the-art equipment available to service all of our customers’ needs with the utmost safety and efficiency,” says Vane Brothers President C. Duff Hughes.
Designed by Frank Basile, P.E., of Entech Designs, LLC, Vane Brothers’ Elizabeth Anne Class tugboats are close cousins to the Basile-designed Patapsco Class tugboats, 15 of which were produced between 2004 and 2009.
Measuring 100 feet long and 34 feet wide, with a hull depth of 15 feet, the model bow Hudson is powered by two Caterpillar 3516 Tier 3 engines, each generating 2,100 horsepower at 1,600 rev/min. Two John Deere PowerTech 4045, 99 kW generators deliver service power to the boat, while a third John Deere 4045 teamed with an Allison transmission drives the chain-driven Intercon DD200 towing winch. The Elizabeth Anne also has Reintjes marine gears supplied by Karl Senner, LLC, Kenner, LA.
The Hudson features the latest in solid-state, Simrad electronics and handsomely appointed, mahogany upper and lower pilothouses, as well as spacious accommodations for up to seven crew members.
Meanwhile, the Double Skin 601 is configured and outfitted in a nearly identical fashion to the most recent 55,000 bbl Vane Brothers barges that were delivered in 2015 by Indiana-based Jeffboat Shipyard. Like them, the Double Skin 601 is equipped with an 8,600 BTU thermal fluid heating system, vapor control system and cargo tanks coated with International Interline 994 Epoxy Novolac. However, the Double Skin 601 has a raised forecastle bow design, which provides additional reserve buoyancy.
The DS-601 and its sister, the DS-602, are both fitted with two fixed boom pedestal cranes each, Model F1-65, with a 65-foot boom length supplied by Techcrane International, Covington, LA.
Primarily tasked with towing petroleum barges engaged in the North Atlantic coastwise trade, the Hudson has joined the Elizabeth Anne among more than 20 vessels that are part of Vane’s Delta Fleet, based in Philadelphia. The DS-601 is also a new Delta Fleet member.
NEW TUG FOR SEA VISTA
In early April, BAE Systems Southeast Shipyards, Mobile, AL, launched the first of two 12,000 hp ATB tugs for Sea-Vista ATB, LLC.
One of the interesting features of the tug M/V Sea Power is that it has two independently controlled and operated hydro-dynamic Van der Velden Barke rudders. Independent Proportional Steering will allow the rudders to be actuated either independently or synchronized. The rudders were supplied by Dutch company Van der Velden Marine Systems (VDVMS) in conjunction with its U.S. representative Ships Machinery International, Inc. (SMI).
Van der Velden says that tank tests showed that rudder design was extremely effective for this type of vessel. This ATB tug will have enhanced maneuverability and excellent course keeping stability. The efficiency provided by this high technology rudder solution will result in significant savings over the life of the vessel.
The 43m x 14m ATB tug, with a draft of 6.75m, is designed by Seattle-based Guido Perla and Associates, Inc. (GPA). The tug’s power is supplied by two 4,640 kW main engines and three 250 kW main generators, with a standby emergency generator of 150 kW. The vessel uses a pin connector system between the tug and the barge and fully complies with ABS Under 90 m Rules, Maltese Cross A1 AMS ACCU Towing Vessel, SOLAS, USCG Subchapter I.
“We are pleased that our client selected this state of the art rudder system for their new vessel,” said SMI Vice President Arthur Dewey, and “we are confident that their faith in Van der Velden rudders will be rewarded over the long haul.” Van der Velden reports that the Sea Power is the only vessel of its kind in the U.S. at present time.
The tug will have exceptional maneuverability, with two independently controlled and operated hydrodynamic Van der Velden Barke rudders. Independent Proportional Steering will allow the rudders to be actuated either independently or synchronized.
Van der Velden has done a lot of work to facilitate the installation of these rudders into a hull and worked closely with Guido Perla Associates Inc. and BAE Systems to assure a smooth transition from initial design to final installation.
GPAI Chairman Guido Perla commented, “Van der Velden provided excellent technical support and on time delivery of design documents that helped us develop the engineering and design for the installation of their steering system. Their coordination with our staff was prompt and to the point. We appreciated their support.”
Van der Velden says that the key driver behind the Barke rudder is its innovative and sophisticated progressive high lift design, offering unsurpassed maneuvering and course-keeping performance, as well as smooth operational comfort. The progressively operating flap linkage system is contained in a fully enclosed, grease-lubricated Barke housing. This results in minimum wear on the linkage components and eliminates the problems caused by contact with floating objects.
Another set of Barke high-lift rudders will be installed on a second ATB tug before this summer.
BARGE FOR PROVPORT
Conrad Shipyard, Amelia, LA, recently delivered a 300-foot long x 72-foot wide rake/box barge with a deck rating of over 6,000 pounds per square foot to ProvPort, Providence, RI, according to naval architect JMS Naval Architects, Mystic, CT. The crane barge design allows for the easy loading and unloading of cargo from ships to the dock or from ship to ship.
JMS Naval Architects, Mystic, CT, engineered and designed the crane barge for the State of Rhode Island that will be used for stevedoring operations at ProvPort Inc.
ProvPort is a nonprofit public-private partnership, formed in 1994, which owns and operates the municipal port of the City of Providence, RI. ProvPort is New England’s premier deep-water multimodal facility for international trade and domestic distribution and one of the busiest ports in America’s northeast.
JMS designed the barge to carry and operate the facility’s 440-ton Liebherr LHM 550 mobile harbor cranes. The barge is ABS classed A1 with notation “Deck Barge,” uninspected and unmanned. JMS also created the technical specification documents to utilize for the solicitation of shipyard bids and provided owner’s representative services during the construction of the barge at Conrad Industries.
The contract was funded by the State of Rhode Island’s Transportation Investments Generating Economic Recovery (TIGER) II grant program award managed by the Rhode Island Commerce Corporation. The grant was created by Congress in the 2010 Transportation Appropriations Act and allowed the purchase and installation of the barge and two high performance harbor cranes. The new stevedoring equipment will modernize and enhance the port’s ability to continue its existing bulk material operations while expanding its capabilities to accommodate container operations; thus alleviating demand on the Port of Boston—the only existing container port in New England. The new crane barge will be critical for the port which has relied on 30-year-old rented crane barges that have been prone to breakdowns and have been out service for prolonged periods. The crane barges are estimated to remove on average 1,000 trucks per week off the northeast corridor highway system—one of the most congested in the country.
NEW HARBOR TUGS FOR BAYDELTA, MCALLISTER
Jensen Maritime, Seattle, is designing tractor tugs for both U.S. East Coast and West operators. One is for Vessel Chartering LLC, a wholly owned dividsion of BayDelta Navigation. The new tug is powered by a pair of 3,385-horsepower Caterpillar 3516 EPA Tier 4 engines and is the third tugboat designed by Jensen Maritime with engines meeting EPA Tier 4 requirement.
The tug was designed without ballast tanks, eliminating the need for ballast water discharge and therefore ballast water treatment systems. To maintain proper trim, the vessel will transfer fuel, as necessary.
The tug is being built by JT Marine Inc. shipyard in Vancouver, WA, for delivery in second quarter 2017.
Jointly developed by Vessel Chartering and Jensen, the 110-ft x 40 ft tug has the ship assist and escort capabilities of smaller harbor tugs, while delivering the improved towing performance and increased range of larger ocean-going tugs.
The design offers the flexibility to support ship escorts, assists and towing, with the escort capability being enhanced to provide support for assisting the large, 18,000 TEU containerships expected to make an increasing number of West Coast port calls.
With an electrically powered, double drum tow winch aft by Rapp USA and an electrically powered hawser winch forward by Markey Machinery as deck machinery, the vessel will be capable of a 93-to-95 short-ton bollard pull. Both winches’ electrical power will remove any chance of a hydraulic oil spill on deck.
The tug is designed to carry up to 123,000 gallons of fuel, 4,300 gallons of fresh water, and up to 4,500 gallons of urea, which is used in the main engine exhaust Selective Catalyst Reduction (SCR) treatment system used to meet EPA Tier 4 emissions requirements.
On the East Coast, McAllister Towing, New York, NY, has contracted with Horizon Shipbuilding, Inc., Bayou La Batre, AL, to build it two new 100 ft x 40 ft new escort tugs.
The tugs will be powered by 3516E EPA Tier 4-compliant Caterpillar engines with Schottel SRP4000FP propulsion units producing 6,770 hp and 80 metric tons bollard pull.
The tugs will be the 31st and 32nd tractors and the first Tier IV tugs in McAllister’s fleet.
They will be ABS classed Maltese Cross A-1 Towing, Escort Service, FiFi 1 and Maltese Cross AMS.
The hull has been designed by Jensen Maritime for enhanced ship docking abilities in addition to direct and indirect escorting and the tugs have been designed and simulator tested to assist new Post-Panamax and Ultra-Large Vessels.
Towing machinery will include a Markey asymmetric render-recover winch on the bow and a Markey tow winch with a spool capacity of 2,500 ft of 2¼ in wire on the stern.
MARCON BROKER FOR NEW DESIGN TUG
Purple Water Ltd. has appointed Marcon International, Inc., Coupeville, WA, as exclusive broker to handle the shipyard licensing for construction of an innovative new tug in the Americas.
Called the Giano tug, the compact double-ended tug has a high displacement tunnel hull form, two large structural keels and a straight-line controllable pitch thruster configuration designed and built solely for ship handing.
With intuitive in-line handling controls, the tug can produce 55 tonnes (70 tonnes) of bollard thrust and pull in all directions at full power with true 360 degree maneuverability, while maintaining a 0 degree list – plus a side-stepping speed of 7 knots – from full ahead to full speed sideways in 10 seconds.
The tug works equally well from the bow or stern and is fitted with 75 tonne escort winches fore and aft.
The design is claimed to has the highest stability numbers of any escort tug afloat, not only in its own 24 m compact class, but also compared with the 32 m escort terminal class.
Two separate engine rooms, a separate generator room and a double hull with integral “W” heavy duty fendering and patented underwater fenders provide a high level of safety, and allow the tug the unique capacity to side thrust and push at full power without listing, while assisting vessels in confined spaces
The Gianotug design is patented over 40 countries.
After four years of research and development, the first tug of this class, is now available in Italy for shipowners and shipyards interested in licensing and building the design to inspect and experience a “hands-on” demonstration of the tug’s capabilities.
Built by Chinese shipbuilder Guangdong Bonny Fair Heavy Industry, the 25.75 m x 13.02 m x 5.20 m depth / 5.30 m Giano is powered by twin 1,678 kW CAT 3512C-HD diesels developing a total power of 4,562 HP at 1,800 RPM.
A Schottel SRP-3000 azimuthing drive with a controllable pitch prop is mounted in a straight line at each end, with the tunnel hull specifically designed to eliminate propeller interference.
Topside access and ultra-short shaft lines allow for main engine removal in a few hours.
The U.K. flagged Giano is classed LR +100A1, Escort Tug, FiFi-1 (2,400 cu.m/h) with water spray, Unrestricted – MCA WB Area 1 (up to 150 miles from safe haven). While this first vessel has a 55 tonnes bollard pull, the unified design allows for both 55 tonnes and 70 tonnes bollard pull versions to be built.
Ulstein starts sea trials of X-Stern SOV
JUNE 10, 2015 — Ulstein Verft reports that the first vessel equipped with its innovative X -Stern left its Ulsteinvik, Norway, shipyard for sea trials on Tuesday. The 88 m vessel, Ulstein
Waller Marine gets FEED contract for 400 MW FPP
FEBRUARY 25, 2016 — Waller Marine, Inc., (WMI), Houston, TX, has been contracted by Vires Energy Corporation of the Philippines to produce the Front End Engineering Design (FEED) of a nominal 400
The Nordic Influence
Shipping is a crucial contributor to the economies of the Nordic countries—Denmark, Finland, Norway, and Sweden—and the industry continues to be a magnet to attract bright young talent. The region’s ship operators maintain an edge over competitors from lower cost areas by investing in newer tonnage that can be operated efficiently and they are ready to take advantage of every benefit than can be reaped from advances in technology. And, in today’s regulatory climate, it doesn’t hurt that the ecologically conscious Nordic countries are an incubator for green technology.
If we take a look at the numbers of ships controlled from Scandinavia countries published by UNCTAD, the statistics can be misleading. While Finland doesn’t make UNCTAD’s cut of the top 35 shipping nations, the Finnish Shipowners Association says its membership consists of 21 companies operating 101 ships.
What these numbers don’t show is the number of ships chartered in by the region’s shipowners or their strengths in some key sectors. The obvious example of this is Maersk Group. It is the world’s second largest shipowner in terms of its owned fleet (720 vessels totaling 25.5 million gt) but the largest in terms of number of ships controlled (767 vessels totaling 31.7 million gt).
As of the third quarter of last year, the average age of ships in the Norwegian fleet of foreign-going vessels (under Norwegian and other flags) was 10.9 years. Indicating how Norwegians keep the fleet fresh: In the first nine month of last year, 57 newbuildings totaling 2.09 million dwt were added along with 38 pre-owned vessels totaling 818,000 dwt. Equally significantly, disposals and losses totaled 126 ships and 2,.29 million dwt.
The Danish fleet is also young, in gross tonnage terms, 31.9% is under five years old, 28.7% is 5-9 years old, 23% is 10-14 years old, 12.2% is 15-19 years old and just 4.1% is 20 years old or more.
Keeping fleets young means ordering ships. Breaking down 2015 world newbuilding orders by owner’s country of domicile, we find Norway coming in at number 8, ordering 188 vessels totaling 8.7 million dwt and Denmark in the 11th place placing orders for 131 ships totaling 7.2 million tons.
PARTNERING WITH SUPPLIERS
Wherever ships are built—and whoever is buying them—a large percentage of their value is likely to be equipment produced by companies based in the Nordic region, who benefit from a willingness by the region’s shipowners to partner in trialing of equipment aboard ship in real life, working conditions.
Historically, this loop used to also include shipyards, but with the shift of shipbuilding to Asia, this is less the case today. Last year’s Danish Maritime Days included a workshop on “Lack of yard presence in innovation supply chain — How can we as an industry enable improved technology uptake through earlier involvement with the yards?”
Nobody in the room had an instant answer. But there were anecdotal references to the dangers of sharing information too readily with Asian shipyards that see nothing wrong with putting one shipowner’s bright ideas into competitors’ ships.
What remains of the region’s shipbuilding industry is mostly focused on smaller, specialized tonnage, but it retains much of the infrastructure of earlier days including, the intellectual property found in classification societies, design houses, research institutions, model basins and similar facilities—creating ships on the drawing board, the computer and in models that will eventually come to life in full-scale steel in Asia.
Meantime, of course, some yards remain very much in business and winning orders.
DENMARK: MOVING BEYOND
With shipbuilding migrating to lower cost countries, the shipyard capacity in the region has shrunk considerably. For example, there are only a handful of yards in Denmark.
One of those is Fayard A/S in Munkebo. Located on the Odense fjord, it is a large, primarily ship repair, facility whose slogan is “Speed is all—Quality is everything.” It has four large graving docks, all served by high capacity cranes, and a 700 m working berth.
Dry Dock 3, measuring 315/415 m in length and 90 m in width, is the largest dock and is capable of undertaking simultaneous construction work on a variety of ships. Dry docks 1 and 2, may be smaller in size but are 280/303 m lengths and 44/45 m widths and are used for repair and maintenance work on ships. Dry docks 4, measuring 145 m x 30 m x 8 m, is primarily used for smaller vessels. Docks 1, 2 and 4 have modern dock gates and pumping systems that allow the yard to start working on a vessel with 3-4 hours of arrival. The dock gates open or close in just four minutes.
Karstensens Skibsvaerft A/S in Skagen currently has a labor force of around 250, and can build vessels up to 135 m in length. While most are fishing vessels, the yard has been building three Knud Rasmussen-class of offshore patrol vessels, the third of which is near completion using a hull built at Poland’s CRIST shipyard last April.
Orskov Yard A/S in Frederikshavn converts and repairs all types of vessels in facilities that include two graving docks two floating dry docks with a capacity of up to 215 m x 34 m. The yard employs 230 people and cooperates closely with a wide range of subcontractors to provide all-round, one-stop solutions.
Søby Værft AS in Søby Ærø offers ship repair services using three graving docks with capacities up to 115 m x 24 m x 6 m. It also undertakes newbuildings and one project it is getting set for is the EU-supported E-ferry project, aimed at bringing into service a 4.2 mWh battery capacity electrically powered, ICE class B, single ended, drive-through RO/RO passenger ferry with one continuous main deck for trailers and cars. It will use state-of-the-art electric only systems with an automated high power charging system.
The initial aim is to demonstrate an energy efficient and emission free ferry for passengers and vehicles in an operational viable setup on the Soeby-Fynshav and Soeby-Faaborg connections in the Danish part of the Baltic Sea. The longer term aim is to see 10 more E-ferries in operation in Europe and worldwide every year, reaching a total of 100 or more by 2030— saving 100,000-300,000 tonnes of CO2 annually.
SWEDEN: WHERE DID THE YARDS GO?
The Nordic country with the fewest surviving shipyards is Sweden, where the once gigantic industry has shrunk to the point that it apparently no longer supports a national shipbuilding association—so statistics on it are hard to come by.
Newbuilding is pretty much confined to Saab Kockums naval shipbuilding activities and a handful of small yards involved in smaller tonnage.
Two large repair facilities are still operational. Oresund Dry Docks, in Landskrona on the Øresund Strait beween Denmark and Sweden has facilities that include a 195 m x 35 m graving dock and a 165 m x 28 m floating dock. Damen Oskarshamnsvarvet, on the west coast, has facilities that include an 80 m x 15 m floating dock. Activities at Damen Shiprepair Götaverken in Gothenburg ended in 2014, due to “the depressed situation of the Scandinavian shipping market, the increased number of Baltic repair docks and the appreciation of the Swedish Krona (SEK).
Though Gothenburg no longer has a shipyard, it still has one of Europe’s best known towing tanks, operated by SSPA Sweden AB.
SSPA has the capability to perform most kinds of model testing in its facilities: the towing tank, the large cavitation tunnel and the seakeeping and maneuvering basin – Maritime Dynamics Laboratory, (MDL). Wind tunnel tests can be performed at external test facilities.
All test facilities at SSPA are designed for performing tests with large models, which have many advantages as scale effects are reduced and more reliable measurements can be performed.
NORWAY, HANGING IN THERE
For those interested in the preservation of Norwegian shipbuilding capability, a big question in the months ahead will be whether the Vard Group, a Fincantieri company, can continue to keep five Norwegian shipyards alive based on its previously successful strategy of supplying primarily the offshore oil and gas sector with specialized vessels designed and fitted out in Norway using hulls built in Romania.
In addition to its Norwegian yards, Vard has two yards in Romania, two in Brazil and one in Vietnam. Vard’s biggest recent headaches have included well-documented problems with its Brazilian activities and it has said that these are under review.
Outside of Brazil, Vard’s problems are those shared by all shipbuilders historically dependent on the oil and gas sector—getting enough orders to keep capacity occupied and diversifying into other sectors.
Its most recent order came in November and was for design and construction of what was described only as “one offshore vessel for an undisclosed international customer.” It is being designed by Vard Design in Ålesund, Norway. The hull will be constructed at Vard Braila in Romania and outfitting and delivery is scheduled from Vard Langsten in Norway in 2017.
That order followed contracts worth a total $100 million for the design and construction of two offshore subsea construction vessels for Dubai-based Topaz Energy and Marine. The hulls will be constructed at Vard Tulcea in Romania, with delivery scheduled from Vard Brattvaag in Norway.
In the fisheries sector, Vard last year secured an order from Brevik AS of Norway for a coastal fishing vessel, but, for this vessel, Vard Braila in Romania will undertake all stages of production.
Another fisheries order came from a Canadian client and was for a 79 m stern trawler of Rolls-Royce NVC 374 design. Vard Braila will build the hull and the vessel will be fitted out at Vard Aukra in Norway in the fourth quarter of 2016.
Thus far, Vard has either not been looking at the offshore wind sector or has been keeping very quiet about it. That’s not the case with other Norwegian shipbuilders.
A significant current project currently under way at the Ulstein shipyard is the fitting out of the first of two innovative offshore wind industry Service Operation Vessels (SOV) being built for Germany’s Bernhard Schulte Offshore GmbH that will be Ulstein’s first for the offshore wind industry — and the first to feature its innovative X-Stern which allows a vessel to be positioned with the stern faced towards the weather instead of the bow.
The hull of the first X-Stern SOV hull arrived at Ulstein’s Ulsteinvik shipyard in January and is scheduled for sea trials starting late spring. Starting this summer, the vessel will work at the Gemini wind farm in the Netherlands for Siemens Wind Power Service.
A project underway at Fjellstrand AS is another pointer to the growing attraction of offshore wind service opportunities in a depressed oil and gas market. It is converting a platform supply vessel it delivered only in April of last year into a wind farm support vessel.
Havyard Group established its credentials in the offshore wind sector with the delivery last February of the first of three Havyard 803 SOVs to Denmark’s Esvagt. In addition, Havyard has an order from Esvagt for aa design and equipment package for a Havyard 931 CCV crew change vessel that will be built at Spanish shipyard Astilleros Zamakona.
Late last year, Esvagt ordered a further Havyard SOV, aimed at a new niche for vessels of this kind, smaller wind farms. This Havyard 831 design is described as compact and efficient, but with ample capacity to transport service personnel and equipment. The first Havyard 831is also being built outside Norway, at the Cemre shipyard in Turkey.
Though design and equipment deals are obviously profitable for Havyard, that leaves shipyard capacity to be filled and another sector where it has been successful is the design and construction of large fish carriers. Last November Havyard was able to fill a gap in production of these vessels by using the covered building dock at its Leirvik shipyard for refit and refurbishment of two Faroese fishing trawlers.
Kleven, operates two shipyards—Myklebust Verft and Kleven Verft—and its orderbook includes a deep sea minerals exploration vessel and several fisheries vessel in among the AHTs and OCVs.
A recent contract came from Sølvtrans and is for delivery of a live fish carrier vessel for Myklebust Verft. This is Kleven’s second order from Sølvtrans for this type of vessel, both of which are being built to to Rolls-Royce NVC 387 design.
While ship designs are part of the stock in trade at Ulstein, Vard and Havyard, Kleven’s orderbook is pretty much a portfolio for Norwegian specialist ship design firms. The deep sea minerals vessel, which is on order for De Beers Marine Namibia, is being built to MT 6022 design from Marin Teknikk. This design is well proven in the offshore construction segment, but the De Beers ship will include a wide range of tailor made equipment and features.
A large pelagic midwater trawler/ purse seiner that Kleven is building for Gitte Henning AS in Skagen, Denmark, is based on a design from another well known independent design house, Salt Ship Design, which in October had 16 vessels of its design under construction at Norwegian and foreign shipyards.
“Unlike the current offshore market, fisheries and fish farming are doing very well and these segments represents an increasingly important market for Salt,” it said.
In addition to the independent design houses and shipyard design divisions, Norway is also the home of Rolls-Royce’s and Wärtsilä’s Ship Design divisions, which have absorbed various independents over the years. Having a ship design department makes all sorts of sense for both of them, as a ship design is the envelope for, quite literally, a boatload of equipment and systems.
FINLAND, BACK FROM THE BRINK?
In Finland, thanks largely to government support —including diplomatic efforts— a large part of the shipbuilding industry has emerged from the ashes of what was STX Finland.
Most importantly, with a lot of Finnish Government coaxing, Germany’s Meyer Werft has acquired the Turku shipyard, enabling it to continue as one of the world’s premier cruise ship yards.
Shipbuilding has also returned to the Rauma shipyard after STX announced its closure in 2013, with the site being sold to the local municipality. The shipyard reopened as Rauma Marine Constructions Oy (RMC) the following year and in December 2015 reported that it was to “receive a major infusion of capital for further growth from the government backed Finnish Industry Investment Ltd, and two investment companies, Finda and a fund managed by Taaleritehdas. That news came the day after the Finnish Ministry of Defense issued a Request For Information to kick off a long planned plan to build four new corvette size vessels.
The Rauma shipyard also has considerable expertise in the area of icebreaking vessels — which keeps what is now Arctech Helsinki Shipyard from having a monopoly in that area. When STX Finland ’s troubles threatened the survival of the Helsinki yard, Russia’s United Shipbuilding Company took a 50% stake in and subsequently took total ownership control and the yard’s orderbook primarily includes advanced icebreaking tonnage for Russian projects, though an icebreaker for the Finnish Transportation Authority is currently fitting out.
The other repository of Finnish icebreaking knowhow is ice-going vessel design and engineering specialist Aker Arctic, whose capabilities include ice model testing. Its largest shareholder is Finnish Industry Investment, which is also major stakeholder in the reborn Rauma yard.
First X-Stern hull arrives at Ulstein Verft
JANUARY 6, 2016 — The hull of the first of two innovative offshore wind industry Service Operation Vessels (SOV) arrived at Ulstein’s Ulsteinvik shipyard, Norway, January 3, from Poland. The vessels are
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.
Team aims to speed availability of LNG as marine fuel
The team, led by Siemens Drilling and Marine, Dresser-Rand and Lloyd’s Register, aims to provide an end-to-end solution, encompassing the entire supply chain, that will remove obstacles that can hold back wide-spread adoption of natural gas as the marine fuel of choice.
“Our integrated solution, encompassing the entire supply chain of LNG including gas-fueled marine propulsion systems, will remove the chicken-and-egg hurdle from the LNG-equation,” says David Grucza, Siemens Drilling and Marine. “This is a disruptive concept for the maritime industry, and the technology exists for immediate adoption. This joint solution is not limited geographically, and we stand ready to support the marine industry globally, although our initial focus is on deploying U.S. shale gas.”
The initial end-to-end solution offered to the North American inland and coastal waterways community comprises the following elements
- LNGo liquefaction barge;
- LNG bunkering barge (C-Type tanks with up to 2,500 cu.m capacity); and
- 4,200 or higher horsepower river pushboat.
It has been designed and engineered by Waller Marine Inc. (WMI) and the Shearer Group Inc. (TSGI), respectively, and will be constructed by Conrad Industries shipyard in Texas.
“Together, the team brings a holistic answer to the LNG marine fuel question of what comes first – the bunkering station or the engine?” says David Waller, President, Waller Marine, Inc. “The innovative solution to this industry hurdle includes the entire supply chain from liquefaction, LNG bunkering and design, all while meeting EPA and USCG compliance and providing smart, sustainable, lower greenhouse gas alternative fuels to operators.”
“Lloyd’s Register is well placed to support a new fleet of gas-fueled ships – and help them to operate safely and efficiently,” says Mark Darley, Americas Regional Marine Manager and President of Lloyd’s Register North America (LRNA). “Our expertise and leadership in gas technology and operations – from gas carriers to LNG bunkering and gas as a marine fuel – helps lead to the best decisions based on the best, independent, technical insight.”
Lloyd’s Register has established clear standards describing different levels of readiness to use natural gas as a marine fuel. Lloyd’s Register also provides training on the key practical aspects of modern LNG carriage by sea and risk management services to support safe LNG bunkering.
Siemens AG (Berlin and Munich) is active in more than 200 countries, focusing on the areas of electrification, automation and digitalization. One of the world’s largest producers of energy-efficient, resource-saving technologies, Siemens is No. 1 in offshore wind turbine construction, a leading supplier of gas and steam turbines for power generation, a major provider of power transmission solutions and a pioneer in infrastructure solutions.
Dresser-Rand, a Siemens Business, is among the largest suppliers of rotating equipment solutions to the worldwide oil, gas, petrochemical, and process industries.
Lloyd’s Register (LR) is the leading classification society in the gas carrier market – both for LNG and LPG – and is also taking a leadership role in the international development of gas as a marine fuel.
Waller Marine, Inc. is a global leader in the design of Floating Gas to Liquids (GTL), Floating Power Generation and Floating Liquefaction (LNG) and is is a licensed engineering firm with EPC capabilities.
Conrad Industries Inc. specializes in the construction, conversion and repair of a wide variety of marine vessels for commercial and governmental customers and the fabrication of modular components of offshore drilling rigs and floating, production, storage and offloading vessels.It has been awarded a contract to build a 2,200 cu.m. LNG bunkering barge — the first in the U.S.
The Shearer Group, Inc., founded in 2010, provides naval architecture, marine engineering, marine surveying and professional engineer services to clients in the inland and offshore marine industries.