MAY 30, 2017 — Volvo Penta is launching a new engine and aftertreatment concept to comply with IMO Tier III standards. New emissions restrictions for vessels entering the Baltic Sea and North
MARCH 13, 2017 — Rotterdam headquartered Van Oord Dredging and Marine Contractors has ordered a new crane vessel that will be its first LNG fueled vessel. To be named Werkendam, the vessel
OCTOBER 19, 2016 — A new study details a number of potential pathways for the shipping industry to transition to a low carbon future. Called “Low Carbon Pathways 2050” the study was
“Legally, a ferry is the continuation or prolongation of a highway over a navigable stream.” This quote is from the first Transactions of the Society of Naval Architects and Marine Engineers (SNAME), published in 1893. Given the impact of ferries upon society, it should come as no surprise that they have been a topic of interest to many naval architects for many years. The Pacific Northwest region of the United States contains a mix of islands, rivers, peninsulas and lakes. Salt water and fresh water transportation routes have been a critical part of the economic development of the region beginning with the native peoples and continuing today. Since the arrival of the first settlers in the 1850’s, power-driven ferries have been a common sight, linking the various communities through the movement of goods and people.
What is a double-ended ferry and why choose this configuration? A double-ended ferry is one where vehicles are loaded on and off both ends of the vessel and the direction of travel switches so the bow becomes the stern. The greatest argument for a double-ended ferry is when the route is short such as a river crossing. The time to maneuver the vessel so it can back in to the dock becomes a significant portion of the overall time between departures. The maneuvering time also consumes additional fuel and imposes the risk, however small, of any maneuver going awry. Another advantage is that the vessel will have the same handling characteristics every time it enters or departs a terminal. With its propulsion at each end, the double-ended ferry has excellent stopping power and superior maneuverability, especially if using an azimuthing or cycloidal propulsion system. This all contributes to safety, a critical factor for any ferry.
The origins of Elliott Bay Design Group (EBDG) go back to the late 1920’s with the establishment of W.C. Nickum & Sons. The earliest ferry projects were to modify the double-ended ferries from the San Francisco Bay area that were made superfluous by the bridge building activities there in the 1930s. Since that time EBDG has worked on a wide variety of vessel sizes and propulsion types, to suit routes ranging from short river crossings to 20 nautical mile transits of exposed water.
The typical ferry we have designed has a V hull amidships with a narrow, flat of bottom at baseline. The side shell flares outboard with one or two knuckles between the heavy guard at the deck edge and the bottom. This configuration produces surfaces that are fully developable which facilitates construction. Typically, the waterline beam is 80% of the maximum beam. This shape provides excellent reserve buoyancy for damage stability and adds waterplane area as the vessel heels, thus improving intact stability. Where there is a draft limit, we increase the width of the flat of bottom. At the ends the waterline shape typically narrows to a fine entrance. Because the waterline beam decreases more quickly than the beam at deck, the effect is to create substantial sponsons. These are located sufficiently far above the bow wave to avoid increased wetted surface as the bow wave increases with speed. The shape of these sponsons also needs to consider wave slamming in rough weather, so a compromise is sometimes required between calm water resistance and speed in waves. The lower part of the hull at the ends is fitted with a skeg to support the shaftline (with traditional shafting on centerline) and to support the hull in dry dock. The skeg shape and volume are critical to the shape of the bow wave, hence we carefully consider the section area shape, including skegs. In more recent projects we have seen greater emphasis on reducing hull resistance, especially for ferries that operate on route lengths of greater than 2 nautical miles. Over the 40 to 50 year life of a ferry, small reductions in drag can result in significant fuel savings, and of increasing importance, lower emissions. Through the use of computational fluid dynamics we can find a balance between low resistance and ease of construction.
The double-ended ferry lends itself to a wide variety of propulsion configurations. Historically, these have ranged from steam-driven, side paddlewheels to a cable ferry powered by horses on a treadmill. In more recent times, we have seen the diesel engine become the dominant power source with a variety of means of putting the power into the water. Clearly, there is no preferred approach that works for every ferry. As designers, we look for the machinery configuration that meets the owner’s performance requirements with the best balance between reliability, maintainability, fuel efficiency and operability. This search typically takes the form of a propulsion study where we work with the owner to establish weighting criteria for the various aspects of the propulsion system. Typically, an owner will have strong opinions on what equipment and what configuration works well for his operation.
We are also seeing more clients interested in different forms of propulsion to reduce their overall energy consumption and thus reduce their environmental footprint. Owners are willing to trade off the simplicity and reliability of traditional geared diesel propulsion for reduced energy consumption through use of hybrid propulsion with electric drives, batteries for energy storage, and smart control systems. We are also seeing increased interest in alternative fuels such as liquefied natural gas, biofuels, and even hydrogen.
This year EBDG developed a physics-based simulation tool to evaluate different propulsion technologies for different sizes of ferries operating on different types of routes. This tool calculates hull resistance, weights, fuel requirements, and hull characteristics in an iterative fashion until the basic parameters of weight and buoyancy are in balance. The outputs from the tool are estimates of capital and operating costs as well as carbon emissions. We can now work with ferry operators to assess the economics of using technology to reduce environmental impacts.
So, what has 50 years taught us? First is that there always will be opportunities to improve the art of double-ended ferry design. Some recent trends include:
SEPTEMBER 6, 2016 — MAN Diesel & Turbo, Augsburg, Germany, reports that it recently delivered the 10,000th turbocharger from its TCR radial-type turbocharger series. The MAN TCR14 unit was produced for a
AUGUST 29, 2016 — Hoofddorp, Netherlands, headquartered C-Job Naval Architects reports that the Switijnk family, whose operations include Ameland Shipping B.V., has contracted it to develop a rotor sail equipped vessel design
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.
Tucked away in southwestern Finland is Salo, a town of about 50,000, where 40 percent of all the doors for large cruise ships are produced. Antti Marine’s production facility in Salo has produced a quarter of a million doors for 300 cruise ships in just over 20 years. It takes about 10 weeks to produce a typical order of 3,000 doors. They are supplied over a period of six months, as and when the ship’s cabins are built
“We are devoted to lean thinking,” says Commercial Director Markko Takkinen. “The production time of the doors is short, as we do not want them remain in storage here.”
Antti Marine specializes in what it calls ‘“tailored mass production”—necessary because on one cruise ship there may be 150 different types of doors.
Antti Marine is not the only Finnish marine company that benefits from many of the world’s large cruise ship fleet being built in Finland.
Cruise ships also have a lot of toilets and a need for a lot of waste management systems. Finnish headquartered Evac Group has just received its biggest cruise vessel contract ever: total waste management systems for four large cruise ships plus an option to outfit an additional six vessels. The initial four-vessel contract is valued at about EURO 30 million.
Each ship will have an Evac Cleansea wastewater treatment plan, allowing operation in Environmentally Sensitive Sea Areas (ESSAs) and Special Areas (SAs), dry and wet waste treatment systems, a bio sludge treatment unit, plus vacuum collecting systems and some 3,000 vacuum toilets.
Evac also supplies its products to a wide range of users ashore and afloat. So, too, does fire protection specialist Marioff Corporation Oy, but its roots are in the marine market and it last year launched a new generation Hi-Fog 3000 sprinkler series for marine applications that replaces earlier Hi-Fog 1000 and Hi-Fog 2000 sprinkler series.
“With the launch of this new generation of Hi-Fog 3000 sprinklers, we are offering to our marine customers enhanced Hi-Fog systems with faster activation, more efficient suppression and improved passenger and crew safety,” says John Hemgård, Director of Marine Business, Marioff Corporation Oy.
The Hi-Fog 3000 sprinkler series is designed, tested and type approved according to IMO Res.A800(19) as amended in IMO Res.MSC.265(84).
Another Finnish product that really took off after its widespread adoption is ABB’s Azipod. It’s become the propulsor of choice for cruise ships and ABB is currently delivering the complete electrical power plant and propulsion systems for two new 3,300 passenger cruise ships building at Germany’s Meyer Werft. The 20.5 MW Azipod XO propulsion unit for the first of the ships recently left the ABB factory in Helsinki.
ABB has delivered, or has on order, Azipod propulsion units for about 200 vessels
Each Azipod propulsion unit takes about two months for technicians to assemble at ABB’s Vuosaari plant. Across town at ABB’s Helsinki motors, generators and drives factory, the powerful synchronous motors at the system’s core take shape over six months.
COOPERATION AMONG STAKEHOLDERS
The major driver for marine engine designers is bringing engines into compliance with emissions requirements while keeping fuel consumption and maintenance costs under control.
A new pressurized EGR (exhaust gas recovery) economizer from Alfa Laval shows how Scandinavian maritime innovation often results from a cooperation between suppliers, university departments and shipowners. It also illustrates that, for some ships, EGR may be a better means of coming into compliance with new NOx limits than the better known SCR (selective catalytic reduction).
In a project supported by the Danish Energy-Technological Development and Demonstration Program (EUDP) and developed in cooperation with Aalborg University, the EGR economizer has been rigorously tested aboard the containership Maersk Cardiff.
“As a front-runner in the pursuit of green technologies, we were keen to see what the Aalborg EGR-HPE could do,” says Ole Christensen, Senior Machinery Specialist at A.P. Moller-Maersk. “But while we were enthusiastic about the boiler’s potential, we were also somewhat uncertain as how it would handle the physical realities of EGR. The temperatures are twice as high as those of traditional waste heat recovery, and the gas pressures are far greater.”
Those concerns disappeared when the boiler was brought online with the Maersk Cardiff’s two-stroke MAN B&W 6S80ME-C9 engine in November 2014. “Not only did the boiler survive,” says Christensen, “[but also] the results we have seen during testing are very promising.”
“EGR provides Tier III NOx compliance with a very compact footprint, but compliance itself is only part of the full potential,” says John Pedersen, Business Manager, Boilers, Combustion & Heaters at Alfa Laval. “Working closely with MAN Diesel & Turbo to optimize the EGR technology, we saw additional opportunities through our expertise in marine boilers.”
In the EGR process, around 30% of the exhaust gas is directed back into the engine, which reduces the combustion temperature and thus the production of NOx. Since only the remaining 70% of the gas reaches the traditional exhaust gas boiler after the turbocharger, waste heat recovery is reduced by 30% as well.
The Aalborg EGR-HPE is a revolutionary new economizer enclosed in a pressure casing that is placed in-line ahead of the pre-scrubber sprayers in the EGR circuit.
“By moving the break point for waste heat recovery from a medium engine load down to a low load, the Aalborg EGR-HPE enables even slower steaming,” says Pedersen. “That means fuel savings that quickly pay back the economizer, offset the EGR investment and lower CO2 emissions on top of the NOx reduction.”
Positioned ahead of the pre-scrubber spray jets, the Aalborg EGR-HPE has access to much higher temperatures than traditional exhaust gas boilers. It is integrated with the conventional waste heat recovery after the turbocharger by its steam drum, which is shared with the traditional exhaust gas boiler. With the output of the traditional economizer feeding into the shared drum, the Aalborg EGR-HPE produces extremely high-quality steam with a temperature of just above 400°C, bringing the waste heat recovery system to a much higher level of efficiency.
Using the Aalborg EGR-HPE in an integrated system allows waste heat recovery to occur at lower main engine loads than possible with a traditional waste heat recovery system in Tier III operation. This creates the possibility of even slower steaming.
“The EGR economizer makes waste heat recovery beneficial at far lower engine loads, down to around 30%” says Pedersen. “This means that vessels can steam even slower, with huge fuel savings as a result.”
DUAL FUEL
B&W in MAN-B&W stands for Burmeister & Wain and the Burmeister & Wain shipyard in Copenhagen built the Selandia, the world’s first successful diesel-powered oceangoing ship. That was in 1912.
More than a century later MAN Diesel & Turbo in Copenhagen is still on the cutting edge of diesel innovation.
One beneficiary of this is TOTE Maritime which opted for MAN Diesel & Turbo dual fuel technology for its two new Marlin Class, Jones Act containerships. Both of these ships have been delivered for operation between the U.S. and Puerto Rico, burning LNG as fuel and thereby meeting all U.S. SECA emissions requirement. Each is powered by the world’s first dual-fuel slow-speed engine, an MAN-B&W 8L70ME-GI, built in Korea by licensee Doosan Engine.
The technology in the ME-GI engines wasn’t just pulled out of a hat. It is a natural development of the MAN B&W low speed electronically controlled ME family of engines. The first testing of the GI principles was carried out in 1987 and MAN Diesel
& Turbo introduced its first two-stroke ME-GI dual fuel engine series in 2011, adding the ME-LGI engine series (which can burn liquid fuels such as methanol and ethanol) in 2013.
In theory, any ME engine can be converted into an ME-GI engine, but to be recognized by a classification society as “LNG ready” an ME engine equipped newbuild will have to be designed with provision for such things as the necessary LNG fuel tanks, piping and other ancillaries.
MEDIUM SPEEDS, TOO
LNG fueling has also proved an attraction for many operators of vessels with medium speed diesels who have to operate in emissions control area.
That trend sees Wärtsilä set to deliver the 100th Wärtsilä 34DF dual-fuel marine engine from the factory in early 2016. It is part of an order for three new large escort tugs under construction for Norwegian operator Østensjø Rederi by Spanish shipbuilder Astilleros Gondan. The tugs will operate at Statoil’s Melkøya terminal near Hammerfest in Norway.
“These 100 engines do not include those delivered for land-based energy generation applications,” says Lars Anderson, Vice President, Wärtsilä Marine Solutions.
“Within its power range, the Wärtsilä 34DF has become the workhorse of the marine industry, thanks to its superior reliability and lower operating costs. It is a highly efficient engine that is also making a notable contribution to environmental compliance,”
The Wärtsilä 34DF dual-fuel engine was upgraded in 2013 with a higher MCR (maximum continuous rating) and better efficiency than its earlier version, the first of which was delivered in 2010. The upgraded version has a power output range from 3,000 to 10,000 kW at 500 kW per cylinder.
ELIMINATE THE ENGINE?
Of course, if you can eliminate the engine and switch to battery power, that gets rid of emissions issues entirely. One area where this could be possible is in certain short range ferry operations and we have already noted the E-ferry way project under way in Denmark at Søby Værft AS.
Wärtsilä, too, is eyeing this niche. In January it launched a concept for a series of zero or low emission shuttle ferries. The concept has been developed in line with new Norwegian environmental regulations for ferries, and Wärtsilä says this regulatory trend is also evident in other countries.
The ferries are designed to run entirely on batteries or in a battery-engine hybrid configuration where the fuel options are liquefied natural gas (LNG) or biofuel.
In plug-in operation, the fuel consumption is reduced by 100 percent compared to conventional installations, and all local emissions are completely eliminated. With the plug-in hybrid configuration, emissions are reduced by up to 50 percent.
The concept features Wärtsilä’s new wireless inductive charging system, which offers major benefits for typical shuttle ferry operations involving 20,000 or more departures a year because of its time and energy savings. The system eliminates physical cable connections, thus reducing wear and tear and enabling charging to begin immediately when the vessel arrives at quay.
Wärtsilä has now signed an agreement with Cavotec SA to jointly develop a combined induction charging and automatic mooring concept. It would incorporate Wärtsilä’s wireless induction power transfer into a vacuum-based automated mooring technology in which remote controlled vacuum pads recessed into, or mounted on the quayside, moor and release vessels in seconds.
FILTER PROMISES TO CUT NOX
The Exilator, an environmental filter for smaller ships, able to reduce both sulfur, carbon monoxide, NOx and noise, has been successfully tested on a Danish Maritime Authority ship. The technology has been testing over a 12-month project phase followed by a three-month practical test of the concept on the Danish Maritime Authority’s ship Poul Løwenørn. The filter’s performance has been documented by the Danish Technological Institute, and the installation and mounting of the filter has been approved by LR.
The filter has been designed for ships with engines of up to 6 MW. Current regulations don’t require the cleaning of exhaust gas from smaller ships if they already sail on marine diesel with a maximum sulfur content of 0.1%. Still, developer Exilator ApS
believes that there is already a market for the filter, as it reduces soot pollution and NOx on the ship itself and also cuts engine noise considerably — particularly attractive in the yachting sector, or expedition vessels sailing in very sensitive nature areas.
According to the test from the Danish Technological Institute, the filter reduces soot particle emissions by 99,1%, carbon monoxide by 98% and NOx by 11%. Though those tests didn’t cover the filter’s noise reduction properties but the company expects a noise reduction up to 35 dB, including low frequency noise.
Financing for development and testing was secured through the Danish Growth Fund and investment & development company CapNova.
The filter works by catalytically incinerated the soot in the exhaust as soon the ship’s engines reach exhaust temperatures above 325 degrees C. Ash is accumulated in the filter, which means that the filters must be cleaned after about 5,000 operational hours, as part of the recycling process.
The filter requires that the ship uses marine gas oil with a maximum sulfur content of 0.1%. According the test, the filter improves the ship’s fuel consumption by around 1%.
The exhaust gas, after passing through the turbo charger, goes to a muffler that removes the deep resonance. Then comes the particle filter, which also serves as an oxidation catalyst, where the soot is captured and burned – and finally the gas is led through a reducing catalyst, which minimizes NOx and NO2, before being emitted into the atmosphere.
Development is now underway in a collaboration with DTU, the Technological Institute and an engine manufacturer aimed at increasing the filter’s NOx reduction from 11% to 40% in phase 1, and to 80% in the subsequent phase 2. When this is achieved, the filter will enable compliance with IMO Tier III NOx limits.
SCRUBBERS
Shipowners face no shortage of options if they decide to use exhaust gas scrubbers to cut sulfur emissions. Recent customers for Alfa Laval’s PureSOx exhaust gas cleaning systems include Buss Shipping, which is retrofitting hybrid PureSOx systems on two 1,025 TEU container feeder ships that operate exclusively in Emission Control Areas (ECAs). Since they frequent the low-alkalinity waters between Rotterdam and St. Petersburg, as well as ports like Hamburg with zero-discharge requirements, a scrubber with closed-loop mode was a necessity.
Each ship will receive a hybrid PureSOx system with multiple inlets, connecting the main engine and two auxiliary engines to one U-design scrubber. In contrast to earlier systems with multiple inlets, the inlets will now lead into a single scrubber jet section – an advance in construction that will make the scrubber even more compact.
“The PureSOx solution was well engineered and allowed a sophisticated integration of the scrubber system into our container feeder ships,” says Christoph Meier, Project Manager, Buss Shipping. “The custom construction let us avoid major modifications inside the vessel, which together with the pre-outfitting gave us a short installation time. All those factors contributed to a competitive price.”
Though there’s no doubt that scrubbers work, they also involve a substantial investment. That led Finland’s family-owned Langh Ship to develop a scrubber of its own, the decision was made a little easier by the fact that another family-owned company has 40 years’ experience in cleaning washing waters.
The resulting product was successfully tested over an extended period on one of Langth’s own ships, the M/S Laura, and received final class approval from GL in August 2014. All of Langh’s five vessels have now been fitted with the scrubber and last year a hybrid version was installed on Bore Shipping’s M/V Bore Song.
“It has lived up to our expectations: minimum sludge handling, very clean outgoing water and in that respect minimum impact on the environment,” said Jörgen Mansnerus, VP, Marine Management at Bore Ltd.
Scrubbers could become less expensive as the result of a pilot project developed by Norwegian University of Science and Technology (NTNU) researchers Carlos Dorao and Maria Fernandino.
Called the Lynx Separator, the technology now being examined for possible use in marine exhaust gas scrubbers was originally developed for use in the natural gas industry and involves using a steel sponge along with centrifugal force to remove the fluid from a gas stream, offering a brand new solution for the gas industry.
In the Lynx Separator, wet gas flows through the separator. A tubular metal sponge spins rapidly so the liquid is separated from the gas and thrown to the side and down, allowing dry gas to stream up to where it’s needed.
The Research Council of Norway’s Innovation Program MAROFF (Maritime activities and offshore operations) has now funded a pilot project to examine the possibility of applying the separator technology to cleaning ships’ exhaust emissions from ships andetheoretical calculations and testing show promising results
BALLAST WATER MANAGEMENT SYSTEMS
Another major focus of compliance concern for shipowners is, of course, ballast water management. Needless to say, most of the major players in the Scandinavian marine equipment sectors have horses in this race. It’s just to soon to pick any winners given the fact that no system has yet gained full U.S. Type Approval.
As this was written, Norway’s Optimarin was claiming to be on the brink of the coveted approval and was pleased when the U.S. Coast Guard told manufacturers of ultraviolet (UV) based BWMS that it will not accept the Most Probable Number (MPN) testing method in its approval process. The MPN methodology evaluates organisms on the basis of “viable/unviable,” with most UV systems depositing “unviable” organisms back into the water – meaning they are still alive but cannot reproduce. The USCG said that the FDA/CMFDA test, which judges life forms as “living/dead,” must be the standard for approval.
Optimarin says the decision is good news.
The Coast Guard has told UV system manufacturers that it will not accept the Most Probable Number (MPN) testing method in its approval process. The MPN methodology evaluates organisms on the basis of “viable/unviable,” with most UV systems depositing “unviable” organisms back into the water – meaning they are still alive but cannot reproduce.
“This is a clear indication to the industry that USCG wants absolute certainty with regard to standards – they do not want living organisms deposited in their territory,” comments Tore Andersen, Optimarin’s CEO. “MPN is acceptable for IMO, but that won’t be any consolation to shipowners with global fleets that want the flexibility of sailing in and out of U.S. waters.”
He says that Optimarin, which has over 20 years of industry experience and installed the world’s first commercial BWT system in 2000, is the only UV manufacturer that is currently within “touching distance” of USCG approval.
Its technology successfully satisied the FDA/CFMDA criteria during testing last year. Further tests in other water salinities are scheduled for spring 2016, after which point approval is expected later this year.
Andersen says the system’s power is the key to its efficacy. “Each of our system lamps has a 35 kW capacity, which is huge for a UV system. That power instantly kills invasive organisms and that’s exactly what USCG wants to see,” he says
JANUARY 21, 2016 — The Arleigh Burke-class guided missile destroyer USS Stockdale (DDG 106) left the pier at Coronado, CA, yesterday burning a fuel that’s a mixture of waste beef fat and
JANUARY 13, 2016 — Wärtsilä is launching a complete concept for a series of zero or low emission shuttle ferries. The concept has been developed in line with new Norwegian environmental regulations
