Shift

Category: Hybrid Ferry

  • Ship.Energy Q&A: Leading the Charge

    Ship.Energy Q&A: Leading the Charge

    Published In Ship.Energy on October 1, 2020. Link to the article can be found here.

    By Lesley Bankes-Hughes | Publishing Director, Petrospot Limited

    ‘In the future, every commercial vessel will have a battery room’’ says Sterling PBES CEO, Brent Perry.

    In this Q&A with ship.energy, Brent Perry discusses the retrofit potential of Energy Storage Systems, lifecycle costs, payback times – and also explains how the technology is evolving to enable new applications – perhaps as a containerised solution or a microgrid, or for a new type of vessel

    Is progress on the industry uptake of electric/hybrid vessels happening as Sterling PBES had envisaged? There seems to be an increasingly-held view that this technology is primarily appropriate for smaller vessels and/or those engaged on shorter, scheduled routes but that it will not have application for larger oceangoing vessels – do you agree with this viewpoint?

    Over the past few years, smaller vessels and those engaged on shorter, scheduled routes have certainly been the primary beneficiaries of Energy Storage System (ESS) technology. Their size and capabilities have made electrification relatively simple, while owners have seen rapid return on investment (ROI) from electrification.

    The operational benefits of energy storage have also traditionally been most pronounced in these markets. For passenger vessels, reduced vibrations and noise have clear benefits to passenger experience, while any near shore vessels are more exposed to national legislation and political or social pressure on greenhouse emissions and air pollution. This is changing as the industry comes under greater scrutiny from regulators and the public.

    Where these segments are the greatest beneficiaries of ESS technology today, we are seeing larger vessels to take advantage of li-ion ESS systems in the coming years. New fuels with lower energy densities than traditional bunker fuels (ammonia, hydrogen, methanol) are expected to become commonplace over the next few years, and energy storage represents a particular efficiency benefit for these vessels in balancing the power output of any given fuel source.

    What is the potential for the ESS retrofit market? Are there onboard installation challenges and also financial implications for this market versus newbuilds?

    We believe that, where not all future vessels will be fully-electric, all future vessels will have a battery room and an ESS. For hybrid systems, an ESS’s infrastructure would not need to be changed if the other fuel used is at a later date. This means that an ESS can via retrofit, future proof a vessel now, cost effectively.

    Historically, retrofit challenges have existed for ESS’s. Systems require some electrical infrastructure, and most systems require a specific footprint that can pose a challenge. New innovations are changing this, such as our new self-contained CanPower microgrid unit which can add energy storage to virtually any vessel. The system is simply, easily and inexpensively located on the top deck or other exterior location, and only requires a connection to the vessels electrical grid via a fixed connection or a plug in to function.

    What are the vessel design challenges associated with the use of ESS?

    It really depends on what you’re looking to do with an ESS. Adding a microgrid can be relatively simple, with a containerised system like our CanPower microgrid solutions being entirely self-contained and only requiring a minimal footprint and using existing infrastructure. With more challenging applications, existing type approval standards are there to apply to meet the expectations.

    Holistic design of the entirety of an ESS and its surroundings is vital to ensure safety and operability. Minimising the footprint and size of a system can have a huge impact, and good design has huge benefits here. In the event of an accident, this holistic principle is even more important; designers need to be sure that toxic gasses would be vented into safe areas, and electronic control systems are fully integrated into a vessel’s other safety systems.

    ESS manufacturers need to offer system integrators and naval architects expert support to overcome these challenges. At Sterling PBES, we take an active role in the design and installation of systems to provide seamless support to ensure efficiency, operability and safety.

    Is there anything that the shipping sector can learn from the experiences of the automotive sector in relation to electric/hybrid technology?

    If you look at the history of hybrid and electric cars, you can see how quickly electrification takes hold. At one point, electric and hybrid cars were seen as fringe and had little take up for decades, but when the technology caught up to the ambitions, we saw a sea change. Even Ferrari now make hybrid cars, and a lot of countries are planning to phase out conventional engine vehicles over the next two decades.

    In the maritime industry, energy storage has been proven as a technology – especially for smaller vessels. We are currently seeing a similar change, as shipowners and other stakeholders take notice of the cost and emissions benefits of li-ion energy storage.

    Could you comment on lifecycle costs/challenges of ESS in the context of a 25-30-year average lifespan of a vessel?

    For most near shore vessels today, the fuel cost savings associated with energy storage represent a fast ROI that remains high throughout a vessel’s lifespan. However, this does not always tell the full story. A conventional ship engine would be expected to survive the normal lifespan of a ship without full replacement, while the useable lifespan of li-ion cells has historically meant full system re-builds are required every five to ten years.

    Innovations like Sterling PBES’ CellSwap technology are changing this, though. CellSwap allows for individual li-ion cells to be replaced without removing the vital system infrastructure, meaning that a shipowner can take advantage of ever improving cell technologies without building in heavy redundancy into a system to improve its lifespan. At the same time, it makes replacing cells simpler than engine maintenance while bringing costs roughly in line with what you may see in a conventional vessel. Life cycle cost of electricity will be in the $0.05-0.06/kWh range.

    Is standard contractual documentation in place for the operation of hybrid/electric vessels, i.e. charter party agreements?

    Sterling PBES offers full financing options, either based on lease to own models or system cost sharing models where the customer pays for the system out of usage and service for the ESS.  Today this is a viable option for all qualified clients and can involve total vessel finance or ESS system finance.

    What is the payback period in terms of investing in hybrid vessels, and is financing available to owners for these vessels (subsidies, bank loans, other investment funds)?

    Payback times really depend on a huge number of factors, including the size and purpose of a vessel, its average fuel costs, and where it is operating. We have seen some passenger vessels see a return on their investment within a year, while it is a longer-term investment for some other vessels.

    Obviously, it is really important for companies to be open and honest in this space and we are committed to calculating these times honestly for our partners. As cell technology and energy density improves, it is important that the energy storage industry acts honestly and builds trust with the industry on payback times.

    In terms of finance, we have seen end users engage with ESG investors and other green funds and initiatives. ESG is rapidly growing as an area for finance, and sustainable electrification fits perfectly with the ethos and mandate of this rapidly growing source of finance.

    For fossil-fuelled vessels, there is a growing call for ‘well to wake’ emissions to be considered. How does this ‘measurement’ of emissions apply to ESS, in terms of production processes and also the disposal of lithium-ion batteries?

    It is true that building and disposing of energy storage systems represents some environmental impact. Mining the materials needed, constructing and installing whole systems, and disposing of the heavy metals included in the cells can have emissions and ecological impacts. These are significantly fewer than with any other type of system.

    At Sterling PBES, we are able to recycle and reuse 96% of the heavy metal content in the cells we use and use recycled material wherever possible. The materials are returned to ESS grade quality for true recycling.

    At the same time, innovations like our CellSwap system mean that the infrastructure of an ESS does not need to be removed, disposed of, and replaced every time a system’s cells need replacing. This even further cuts the environmental impact of our systems, while also cutting costs, and is a philosophy the industry will need to implement as ‘well to wake’ issues are highlighted.

    In your discussions with potential purchasers of electric vessels, what are the main questions they are asking of you in relation to the technology.

    The market is very interested in where the historic limitations of ESS technology are changing, especially from the operational side. People want to know if you can use it in new, novel applications – perhaps as a containerised solution or a microgrid, or for a new type of vessel – in a cost efficient and safe way.

    How do you see the electric/hybrid vessel sector developing over the next 10-20 years?

    In the future, every commercial vessel will have a battery room. The technology has been proven from cost, operability and environmental perspective, while ESS technology will be a vital part of enabling new fuels as the industry prepares for a zero-carbon future.

  • Startup Battery Solution Reduces Fuel Dependence in the Maritime Industry

    Startup Battery Solution Reduces Fuel Dependence in the Maritime Industry

    Published In Port of Seattle on October 19, 2020. Link to the article can be found here.

    By Omie Drawhorn | Marketing & Communications Project Manager, Port of Seattle

    Washington Maritime Blue, the Port of Seattle, and WeWork Labs have partnered to launch Washington’s first maritime accelerator to help maritime companies innovate and grow. New ideas in one of the most traditional sectors in Washington are critical for a thriving economy and to protect our planet, precious natural resources, and ocean life.

    Washington Maritime Blue and the Port are partnering again to launch the next cohort of the Maritime Blue Innovation Accelerator. Applications for the new cohort are open through Nov. 20.

    This series showcases the 11 companies participating in the inaugural cohort. These companies worked for four months out of WeWork Labs’ Seattle location with mentors and advisers to help navigate challenges. In April, the startups shared their innovative solutions in a Virtual Showcase.

    The maritime industry is responsible for 90 percent of goods delivered in the world but the technology powering the industry has not really changed in 100 years. Most commercial vessels use diesel fuel for almost all operations, which comes with fuel costs, maintenance down time, and impacts on the environment.

    Until now. A Vancouver-based startup has developed a cost-saving, energy efficient way to keep the industry moving into the future. Sterling Plan B Energy Solutions (Sterling PBES) has built a high-powered lithium ion battery used to hybridize or electrify any industrial equipment, powering everything from small cities to commercial vessels.

    Led by a team of seasoned maritime industry experts, Sterling PBES has been building marine energy storage systems since 2009 and is focused on helping the maritime industry lower or eliminate its dependence on fossil fuels by using electrical power.

    Electric ferry Aurora

    An electrifying solution

    Sterling PBES developed the CanPower Microgrid, an independent, containerized battery room that fits within standard-sized shipping containers 20 to 53 feet in length. A 40-foot shipping container of PBES batteries can power a ferry or a small community. Its liquid cooling system optimizes the battery’s lifetime, performance, and safety.

    The battery system can be stored on the top deck or other exterior location of a vessel and it connects to the vessel’s electrical grid through a fixed connection or a plug in. The battery can be charged in as little as six minutes depending on available shore power. The battery can also be easily swapped out, allowing the vessel to continue on to the next destination where another battery will be waiting. The batteries on shore are then recharged and on standby for the next use.

    CanPower is in final development, but the startup has been marketing the technology to potential clients with strong success.

    “We are seeing a huge demand for CanPower, with sales closing despite still being in the final engineering stage,” said Grant Brown, Vice President of Marketing and Brand at Sterling PBES.

    High speed passenger ferries currently being built in Washington state are candidates for the technology. Normally, it takes 20 to 30 minutes to charge a large electric battery – if high capacity shore power is available. With this system, the battery can be taken off the vessel, and replaced with a freshly charged one in a fraction of the time, just like the battery in a power tool.

    “We are also finding a lot of interest from tugboat operators, who want to run a zero emissions ship. It costs a lot to provide high power electricity to a large battery charger; the disruption to city streets and the build of electrical infrastructure means it’s often cheaper to simply buy extra batteries for the ship. With river cruise ships and ships with similar situations, there are predetermined stop points; while they are offloading passengers, they can drop a new battery on the ship. This technology will change the direction for the shipping industry.”

    Installing batteries on the electric ferry.

    A greener industry

    Brown said Pacific Northwest companies are showing a greater interest in reducing emissions, but the maritime industry as a whole has been slow to shift ways of thinking.

    “The maritime industry is extremely conservative. Companies are looking for something reliable and safe for their ships. The industry is risk averse, however saving money is a pretty compelling argument. With environmental regulations coming into effect, battery technology is at the intersection of all those things.”

    Sterling PBES’s battery technology has proven itself to be safe and reliable, and the economic benefits are clear. Despite upfront costs, in many cases the battery system pays for itself in under three years and provides savings for at least 10 years.

    “Hybrid battery systems provide 25 percent or better fuel savings on any ship. It’s a really significant way to reduce emissions. It’s reliable, safe, quiet, and better for the crew. There are no fumes, vibrations, or noise, and companies save a lot of money on fuel, while environmental requirements are satisfied 100 percent.”

    Ferry ForSea batteries in shipping container.

    Maritime Accelerator

    Brown applied for the Maritime Accelerator cohort to meet likeminded people in the maritime community.

    “I hoped to spend time rubbing shoulders with organizations like the Port of Seattle and Washington State Ferries, mostly to get a handle on how to develop and bring products to market that meet their needs. Rather than sitting in an isolated bubble inventing products we hope people would like, we wanted to look at what the market actually requires. CanPower is a result of those conversations.”

    In the program, Brown connected with people from all corners of the industry, sharing experiences with companies that recycle fishing nets, make fish jerky, or build consumer-oriented battery powered small boats.

    “We wouldn’t normally have direct contact with those types of groups; having these contacts broadens our breadth of knowledge on how to develop products that are more inclusive of different disciplines,” he said.

    Brown said the Accelerator helps to infuse new ideas and innovation into a traditional industry.

    “The maritime industry has been sort of on its own; it’s somewhat of an isolated bubble unto itself. The injection of new ideas into the maritime industry helps propel it forward so it doesn’t get left behind. It helps us stays relevant and current. The industry benefits from new ways of thinking. A lot of participants in the accelerator are quite young, and they’ve grown up in different eras than those sitting with power in the industry.”

    Connecting robot to ship for battery charging

    Next steps

    In the coming months, Sterling PBES will continue rolling out innovations on their new CanPower product, and work through a redesign of the main battery component.

    “We’re trying to lower costs and increase the ability to broaden our supply chain,” he said.

    They are also looking at entering into adjacent markets to the maritime industry.

    “We are looking at providing power for port equipment, refrigeration systems and remote communities. We are looking at providing energy storage with wind or solar systems for places like Puerto Rico or small islands in the Pacific Northwest.”

    Brown said his time in the Accelerator program opened his eyes to different processes and business practices that have been beneficial as Sterling PBES continues to grow.

    “We are thankful we were included, and we’ll take the lessons and tools that we learned with our company as we grow, and hopefully we will be able to offer some experience and perspective to new cohorts going forward” he said.

    PBES battery installation

  • Advances in Battery Safety and Technology: Energy Storage Safety; Lessons Learned in Practical Application

    Advances in Battery Safety and Technology: Energy Storage Safety; Lessons Learned in Practical Application

    Published In Energetica India on October 9, 2020 by News Bureau. Link to the article can be found here.

    By Brent Perry | CEO, Sterling PBES

    Battery technology has evolved very quickly, but the lithium-ion energy storage industry is still relatively young. As of today, there are few commercial systems that can claim to have been in operation for more than 10 years.  Despite this, the economic and environmental advantages of battery storage have meant that there are now hundreds of systems operating around the worldBattery technology has evolved very quickly, but the lithium-ion energy storage industry is still relatively young. As of today, there are few commercial systems that can claim to have been in operation for more than 10 years.  Despite this, the economic and environmental advantages of battery storage have meant that there are now hundreds of systems operating around the world.

    In 2009, I was a part of the group that produced the first lithium batteries for industrial applications. These were designed to demonstrate the principal that Megawatt scale Energy Storage Systems (ESS) could deliver real commercial value; at the time, there were a lot of doubters. Today, we have evolved not only performance, but also safety, integration, cost and risk management to much more predictable levels. The data obtained from constant commercial use continues to provide valuable information that allows us to continuously improve our systems. 

    This data and experience have led to significant improvements in battery design resulting in improved safety, system life, risk reduction and overall performance. The improved performance of modern industrial batteries has also changed the market. Lower system cost means more and more renewable energy installations are now finding true ROI from energy storage.

    Safety

    One critical weakness from the lithium-ion battery industry is fire safety, with the main concern being how to provide a cost-effective system while maintaining operational safety. This challenge was at the top of our minds in every design decision, and we addressed with our patented CellCoolTM cooling system. A cooling system so effective, it removes the risk of thermal runaway. 

    The principal is very simple; reduce the temperature of the cells at a faster rate than the cell increases in temperature. No matter how hard you work them, with CellCool a Sterling PBES battery will not achieve the temperature required to go into thermal runaway.  We worked in cooperation with regulators to develop safety tests designed to demonstrate that the batteries are inherently safe. 

    Even in these very demanding tests, we have proven success. Our CellCool system is able to prevent thermal runaway, making every system safer to operate.  This is done with an inherently simple liquid cooling system and cannot be achieved with air cooling systems due to the inefficiency of heat to air transfer. 

    Safety has other considerations as well. We designed a Battery Management System (BMS) that is inherently focussed on protecting the facility, the battery system and the cells.  This is done at its core by monitoring the voltage and temperature of every individual cell in the system, and then balancing the performance within safe operating parameters. 

    Another critical element of safety in design has been the inclusion of contactors in the individual battery modules. We are building DC voltage systems that range from 300-1500VDC, therefore the risk of personal injury in transportation, installation and service have high potential. For example, a 1500 VDC arc flash can permanently disable a technician.  By adding contactors in the individual battery modules, we eliminate voltage at the terminals until the system is fully engaged and the BMS can confirm that all cables are correctly installed. There is no voltage or power to the terminals as long as the contactor is open. Contactors also reduce the risk by isolating the modules as single units no matter how large the overall system size. The element of crew safety of our technicians and the operation staff cannot be overstated in terms of benefit to our customers. Instead of relying on specially qualified technologists, we can now train the customer’s engineers to do maintenance. This design decision was not free, but it is the right way to go to improve overall safety and reduce costs for our customers.

    Cost

    Another critical part of the design of a battery is not the actual battery itself, but the space the battery operates in. The added costs of necessary safety systems can be significant. Most battery suppliers off-load these safety measures onto other contractors and by not including them in the quoted price of the battery. These add-on systems are critical to the performance and safety of a battery and are therefore included in every Sterling PBES system deployed.

    Another benefit of liquid cooling is the ability to predict the lifespan of our systems. Air cooled batteries are dependent on the ambient temperature to manage the overall life of a lithium battery. Even a small increase in battery room temperature has a significant reduction in calendar life.  In contrast, liquid cooling maintains the temperature of the cells at a fixed range eliminating the impact of ambient temperature on lifespan.

    Size and Cost

    The other significant feature of any system is the percentage of energy available on a continuous basis. On air-cooled designs, the continuous rating is about 70%. This means that if 1MW of energy is required, a battery of 1.4MWh of capacity will operate at 1MW load – a larger, heavier system that is significantly more costly to install and maintain.  If we assumed that the battery system cost $100/kWh, then a 1.4MWh battery adds $140,000 to the capital cost of the system.

    With Sterling PBES CellCool, the battery can operate at an average continuous rate of 300%. A 1MWh system can now be met with a 350kWh battery; much smaller, much lighter, and much less costly to install, with only a $35,000 budget needed.

    Sustainability

    A battery that can last for ten years is a pretty amazing thing, but it will likely not match the lifespan of the power generation system it is supporting. This equates to battery system replacement every five or ten years.  In analyzing a system, our engineers realized that the most significant reason for ESS replacement was the fact the cells will age with time and use.

    With Sterling PBES CellSwapTM the cells of a battery module are able to be replaced within 30 minutes.  Cell swap means that the battery system life span is now the same as that of the power generation system.  With this inclusion, the design of the battery system is now in line with market requirements.

    Recycling will have an increasingly prominent role in decision making in coming years. This is part of the benefit of a cell swap; we can recycle the lithium cells at a very low cost because only the cells are replaced – the other hardware is reused. While often overlooked, it is necessary for any company that uses ESS in commercial operations to include this operational expenditure in their impact analysis.

    Where to next?  Commercial needs will continue to drive improvements. Gone are the days when a battery was a fire and forget proposition. They are now an integral part of the overall system design and can provide significant ROI when deployed thoughtfully and with care. Modern batteries can provide safe, reliable service for decades and, when integrated correctly, reduce the system size and cost of any renewable grid energy system.

     

  • Letting coastal communities breathe; why aren’t there more electric ferries?

    Letting coastal communities breathe; why aren’t there more electric ferries?

    The electrification of the shipping industry has historically been seen as an unrealistic pipe dream with little to no serious recognition of the concept, conjuring images of a one-stop solution fleet filled with sleek fullyelectric oceangoing vessels carrying vast amounts of tonnage across the globeWhile energy storage technology is developing and scaling quickly, fully-electric oceangoing cargo vessels are not viable with today’s battery technology. Yet, they are proven and highly cost effective solutions for passenger vessels and ferries today.  

    The passenger sector seems to have recognised the boons of hybrid and battery-powered vessels, and has begun to adopt such systems for an increasing number of vessels globally. But, why are there not more electric ferries?  

    When we think about fully electric vessels, or the vessels that can benefit most from energy storage technology, coastal vessels are the obvious place to start. The nature of energy storage systems (ESS) makes them the ideal candidate for small-scale, short journey vessels: they are neat, compact, and efficient in their design. And under IMO regulation, ports and coastal areas are seen to benefit most from these kinds of emissions reduction changes in the short-term. 

    Coastal areas and inland waterways are heavily reliant upon these types of commuter vessels, running ferries as often as city buses through and around built-up areas. Air pollution is a serious issue in many of these cities, and the toxic SOx and NOx emissions from traditional waterborne transportation has a tangible health impact on residents. At the same time, these are the areas in which vessel owners are coming under the most pressure to reduce greenhouse emissions.  

    Now, fully-electric as well as hybrid vessels are a viable option as proven by the likes of Damen, with their recent work in Copenhagen on the Movia zero-emission ferries, and our own ventures with the Cape Islander tour boat partnership with Glad Ocean Electric, but energy storage systems are equipped to aid in reducing emissions in a number of ways – not just a full replacement for traditional fossil fuel engines.

    Electric ferry crossing to Sweden

    Whether as a hybrid or fully electric solution, energy storage can be catered to any size of vessel, with the installation of anything from a single unit, to an entire battery room. Fully electric vessels produce virtually no greenhouse emissions or air pollution, and represent significant cost savings. For ferries or river cruise vessels, the operational benefits significantly improve passenger experience with less vibrations and less noise.  

    But it further raises the question: why has this perfect fit for passenger transport not been implemented on a widespread scale already? There is huge opportunity to implement environmentally positive solution that works at scale and build the infrastructure required for a zero-emission future – including overnight yards and charging stations. 

    Decarbonisation regulations are often focussed on land-based transportation at a national level, and IMO targets largely focus on deep-sea shipping operations. This means that the pressure for greener near shore vessels is felt strongest in market forces – in the cost savings delivered by energy storage, and the public and customer pressure for less polluting solutions. 

    With the correct teams, electric commuter ferries can be easily implemented in a matter of years, fitting a tailored solution within their cityscape whether a retrofit to a pre-existing transport system, or setting up an entirely new infrastructure with newbuild vessels and charging stations that are compatible.  

  • SPBES and Glas Ocean Electric Announce first Electric Cape Islander Tour Boat

    SPBES and Glas Ocean Electric Announce first Electric Cape Islander Tour Boat

    [vc_row][vc_column][vc_column_text]History was made this week as marine energy storage experts Sterling PBES and naval engineering firm Glas Ocean Electric launched a first of kind electric Cape Islander vessel. The vessel, formerly named Peggy’s Cove Express, served many seasons as a trawler on the East Coast and is a familiar design that has been in use for decades. The completely refit and renamed Alutasi will continue service with Ambasatours in Halifax and is the first lithium-ion powered vessel Transport Canada approved for more than 12 passengers. In a partnership with Mi’kmaw artist Alan Syliboy, the boat is covered in colourful designs of ocean animals.

    This project will show the reduction in air emissions, water pollution and underwater radiated noise by ‘going electric’. It has already been shown that the reduction in vibrations an electric system provides reduces fatigue in crew and passengers. The reduction in ambient noise and air pollution is expected to reduce hearing loss and health effects in operators over time. Reduced fuel and maintenance costs will also be assessed.

    A Sterling PBES liquid cooled battery provides ample power for day to day operations while in tour mode. The lithium-ion battery system has been engineered to the highest standards of performance and safety and is designed to seamlessly integrate with virtually any electrical infrastructure.

    The battery system that was retrofit to Alutasi may be installed in a variety of vessels of this size. The fishermen of the East Coast who use the Cape Islander style vessels will see significant reductions in operating costs by using batteries in their workboats and by doing so will help transition their industry to a sustainable future.

    “Alutasi is a great example of a cost-effective system for smaller vessels,” said Brent Perry, CEO of Sterling PBES. “Our goal as a team was to create a total solution that delivers turnkey performance with realistic financial payback to all vessels of this size, while meeting all of the safety and reliability needs that are involved with transporting passengers and goods.”

    About Glas Ocean Electric
    Glas Ocean Electric is helping to decarbonize the marine industry through hybrid and electric operation. In addition to providing engineering and equipment, Glas Ocean Electric also helps owners and operators find funding to convert vessels to zero or low emission.  www.glasoceanelectric.com[/vc_column_text][/vc_column][/vc_row]

  • The Alutasi is first lithium-ion-powered boat approved in Canada

    The Alutasi is first lithium-ion-powered boat approved in Canada

    Hybrid electric boat launches on Halifax’s Northwest Arm
    Shaina Luck · CBC News · Link to original CBC story here.

    A unique new boat was launched Wednesday morning on Halifax’s Northwest Arm, carrying with it a smudge blessing from a Mi’kmaw elder and the hope that it can help reduce the carbon footprint of the marine industry.

    The Alutasi is the first lithium-ion-powered boat approved in Canada to carry more than 12 people.

    The boat is owned by Halifax’s Ambassatours and was converted from diesel to hybrid electric by Glas Ocean Electric.

    “What’s significant about this boat is this carries over 12 passengers, and that’s a rating with Transport Canada that requires significantly more safety to be involved,” said Sue Molloy, CEO of Glas Ocean.

    Smaller recreational electric boats do exist in Canada, but Molloy is excited about the potential for this boat. It will be used for deep-sea fishing tours offered out of Halifax harbour.

    Molloy’s company chose to make the boat a hybrid with a backup diesel engine in order to balance the size and weight of the batteries with the need for space for passengers. She said the boat could be converted fully to electric if needed.

    “The marine industry is risk-averse, which is understandable when you think about people going out in the ocean, and if something goes wrong,” Molloy said.

    “We decided to focus on day-trippers because day-trippers tend not to go in really extreme weather. And they’re always planning to come home. So, by focusing on the day-trippers, I think it’s given us a way into the industry, to show people what the options are.”

    In a partnership with Mi’kmaw artist Alan Syliboy, the boat is covered in colourful designs of ocean animals.

    Alutasi, which signifies “fishing guide boat” in Mi’kmaq, received a smudge blessing from elder Dorene Bernard.

    Artist Alan Syliboy and elder Dorene Bernard pose with the Alustasi at its launch on Wednesday. (Robert Short/CBC)

    “Finally, we have something clean and quiet that’s going into the water. It’s almost like the canoes that have a very small footprint,” Syliboy said.

    The federal and provincial governments contributed a total of slightly under $500,000 to the project, with some of that money supporting a partnership between Glas Ocean, the NSCC and the Offshore Energy Research Association.

    The Alutasi has a hybrid diesel-electric engine. (Robert Short/CBC)
  • Energy Storage Solutions are the future, but suppliers must do more

    Energy Storage Solutions are the future, but suppliers must do more

    While electrification is increasingly recognised as a core part of the maritime industry’s future, it’s fair to say that the age of electrification has already begun.
    Published in Seatrade Maritime News, Article by Grant Brown, Published July 25, 2020 https://www.seatrade-maritime.com/technology/energy-storage-solutions-are-future-suppliers-must-do-more

    DNV-GL recently found that more fully-electric or hybrid-electric vessels were under in operation or under construction than there are LNG vessels, while projects like the installation of a 600kWh battery on the Maersk Cape Town and the construction of the zero emission hybrid container ship the Yara Birkeland provide proof that energy storage is viable on larger vessels.

    One of the main misconceptions around electrified shipping is the understanding of the roles that Energy Storage Systems (ESS) can play on board a vessel. Using an ESS means different things in different vessels today.

    Short range or smaller vessels are able to take advantage of huge fuel cost savings from fully-electric propulsion, while passenger vessels are also able to take full advantage of the operational benefits of the systems – with fewer vibrations, less noise and no emissions on deck improving passenger experiences. Hybrid propulsion is proving its value for more versatile or mid-range vessels, while battery solutions are gaining traction in the containership and tanker markets for auxiliary power supplies.

    This is set to become an even more important factor for shipowners over the coming years.

    Regulators are setting their sights on decarbonisation, both internationally and regionally, and new several new ‘zero-carbon’ fuels are in the latter stages of development. All of these fuels can benefit from energy storage for efficiency and viability; we believe that in the near future, all commercial ships will have a battery room to supplement other energy solutions.

    Expansion of energy storage supply is therefore expected to accelerate in the next few years. As this happens, the industry must be cautious to ensure that safety is not side-lined in a rush to provide systems quickly – or that look to be cheaper on paper. To facilitate this, suppliers must take an honest and safety-focussed approach.

    Modern ESS utilise lithium-ion cells as the energy source inside the battery. The most prominent risk with these cells is thermal runaway.

    Thermal runaway starts when a single lithium-ion cell is damaged. This damaged cell then heats up, releasing toxic, flammable gasses. Unmitigated, the heat from one failed cell will damage surrounding cells. To deliver a valuable amount of energy, a maritime battery requires many banks of cells – meaning that a damaged cell can quickly turn into a potentially catastrophic chain reaction.

    Excess loads placed on the battery such as those from over or under charging, as well as physical damage and general wear and tear, increase the risk of cell failure. However, even when a battery operates at optimum levels non-stop throughout its lifecycle, there is always a small risk that a cell is delivered with an undetectable fault.

    Many manufacturers have not yet been clear about the significance of these risks, or how they can by managed. Holistic ESS design, starting with the cooling system and the space around the battery, can bring these risks to near zero, while delivering a less expensive system.

    Ensuring safe systems

    The space surrounding a marine battery must form part of the system’s design to ensure safety and efficiency. Safety systems must be integrated from the start of this design process to make sure that they work as efficiently as possible and ensure that these systems work together in harmony. They are not optional add-ons, but vital parts of any system that should not be sold separately.

    The first stage of this design must look at cell cooling. Cell cooling can cut the risk of thermal runaway, or slow or stop a chain reaction when a damaged cell starts to heat. Integrated liquid cooling can stop thermal runaway – and deliver better battery performance.

    A truly effective cooling system must cool the whole of the cells uniformly. When designed as part of the system from inception, water cooling can deliver uniform temperature control and remove “hot spots” on the cells. These hot spots will degrade the cells, and over time will cause premature failure.

    Liquid cooling systems designed in this way are also able to stop thermal runaway before it starts. By ensuring that a cell is operating in optimal conditions at all times, it also improves performance and lifespan, but even in the case of a damaged cell failing, the cooling system will be able to remove more energy than is produced, keeping adjacent cells cool. The battery avoids the chain reaction of thermal runaway and stays within operational parameters.

    Some systems today are designed as add-ons that only cool the exterior of the cell or use air cooling technology – which requires 3,500 times more air flow volume to achieve the same heat removal, and require expensive add-on HVAC systems.

    Despite the confidence that manufacturers can provide with holistically designed cooling systems, the risk of thermal runaway from incidents of catastrophic failure will always persist to some degree. Shipowners must also be confident that such a failure would not put their crew or vessel in danger.

    This type of catastrophic failure is extremely rare in a liquid cooled system, but a last layer of safety can be delivered through direct venting mechanisms which, despite the clear need for this to work seamlessly with other safety mechanisms, are not often integrated with the ESS design. Such venting mechanisms remove flammable and toxic gasses from the battery, never allowing them to even enter the machinery room. Not only does a directly vented battery reduce explosion risk, it also allows emergency and service personnel to renter and secure the area far sooner than an unvented system. This venting system must be explosion-proof, and it must be entirely fool-proof – it must be designed to work regardless of how other parameters have been set by crew. This means it must be provided alongside specialised control units, and architecturally it must vent the gas to an appropriately safe environment.

    Safer systems can cut costs

    Safe design, as well as proper maintenance, means better performance – and a longer service life before replacement.

    Using a fully optimised cooling system can aid efficiency to such a degree that an ESS can operate at an average continuous rate of 300%. This means that a 1MWh system can be met with a 333kWh battery; meaning a smaller, lighter, lower cost and easier to install system. It also means that systems degrade slower, and less redundancy must be built in.

    Lower discharge rates mean a much bigger battery must be created to do the same duty, increasing costs and adding to the space and weight used.

    Reducing the need for full system replacements is also important as many companies adopt rigorous sustainability standards.

    One of the most important innovations in this space comes in the form of Sterling PBES’s CellSwap technology. As part of the battery architecture, CellSwap allows for individual battery cells to be easily removed and replaced without the replacement of an entire battery system. This simple maintenance can be performed at sea, reducing downtime. Because only the cells are replaced, the vessel owner only pays for the cells and the service to install them.

    CellSwap also allows shipowners to benefit from consistent advances in battery cell technologies over time, as battery science constantly finds new ways of storing more power in smaller cells and improving cell safety and lifespan.

    Demand for marine energy storage is already soaring. Countless vessels are already proving the cost benefits of electric of hybrid electric solutions, while future technologies and regulation – coupled with improvements in system technology – are expected to make it an even more attractive prospect for shipowners.

    At this crucial time for the industry, suppliers must ensure that they build trust with shipowners and integrators by designing the safest, and most efficient, complete systems. In this way, the shipping industry will realise the full potential of energy storage and maximise their return on investment.

  • A Future-Proof Fleet: Modular and Adaptable Design

    A Future-Proof Fleet: Modular and Adaptable Design

    Owners may have a dilemma when picking an energy technology capable of lasting a vessel’s 20 or 30-year lifetime, writes Stevie Knight

    Published In The MotorShip Magazine on June 12, 2020 by Stevie Knight. Link to the article can be found here.

    Eco-legislation ensures shipping has to move on, but “being locked to a single option could make it tough to adapt” says Kjetil Martinsen of DNV GL: he points out that the fuels of today may not be those of tomorrow and choosing a low-emission alternative that turns out to be extortionately priced or unavailable “could result in stranded assets”.

    But there is already a dizzying array of potential solutions “and everybody is considering everything… so all the cards are in play” he adds. Therefore, some believe the answer may lie in judicious spread betting.

    MODULAR DESIGN

    Modular design may provide an answer: it certainly stands to relieve owners of a lot of drudge work as maintenance could be performed by the OEMs themselves, the result assured by the class societies. But it also holds the potential for shaking the industry to its foundations.

    As Martinsen’s colleague, Knut Erik Knutsen of DNV GL remarks, “there’s been a gradual move by the big manufacturers toward ‘power-by-the-hour’… a service agreement rather simply selling an engine”.

    Modularity could be seen as a logical extension of this approach, especially as it paves the way for greater standardization. That in turn broadens the appeal of remote, condition-based monitoring, “something that’s been held back by the number of unique, custom-built ships” he adds.

    The potential is already being explored. The MIDAS project, that experiments with modules installed on Subsea7’s PSV Seaway Moxie and the Norwegian Coastal Administration ship OV Ryvingen, have navigation, communication and propulsion modules operating onboard to yield “continuous monitoring and specific health indicators”, says Knutsen.

    But what’s so different about it, really? “At the moment the mechanical drives, the electrical lines and the control systems are not just in different packages but also different disciplines,” he remarks. “Instead, we suggest tying it all together into one module with one, single concern, how to maintain the function.”

    This approach has a number of advantages. Firstly, “embedding a propulsion system inside a standardised unit gives you a much better idea of its performance and reliability”, he explains. “If something goes wrong, it’s far easier find out who’s responsible for putting it right.”

    Follow the implications through and logically, this puts as much emphasis on defining the boundaries as system integration, inherently tightening up the scope for each OEM. In itself that will yield efficiency benefits for manufacturers.

    But further, standardised interfaces “allow freedom to design alternatives” to meet the specified demand, says Martinsen.

    This, in turn, ushers in a still more radical concept – what about swapping out the onboard kit if another solution appears more appropriate? After all, a defined output within a particular footprint appears supremely well-matched to a ‘plug-and-play’ approach.

    DNV GL’s laboratory ship concept does just that. Envisioned as a vessel to test, qualify and benchmark new maritime technologies,  Experior is designed to be flexible in terms of interchanging onboard components and systems. Therefore, it holds the potential for interrogating a vast array of alternatives, from superstructure and cabins to power and manoeuvring kit, to comms and control, mostly by sitting them in dedicated containers with monitored interfaces.

    Although not a commercial vessel, the ideas behind Experior may hold a clue to the future: its set up allows clients to calibrate and optimise their own innovations against the lab ship’s digital twin before installation.

    ANALYSIS

    In fact, according to Knutsen, a digital twin may be part of a modular delivery, allowing systems to be pretested in the factory.

    There’s a further advantage. “So far full vessel reliability modelling has been challenging,” he says. However, since each module will have a health check element, it’s possible to network these together, creating a “system of systems”. It would, he remarks, gradually build up over time, being far less costly and troublesome to implement than dropping an entirely new, ship-wide layer into place.

    It may also help resolve another niggling issue: cybersecurity. There’s often persistent doubt that the vessel’s onboard systems are as watertight as the hull, so modularity should provide more reassurance – firstly, it could potentially reduce shared weak points, secondly it “ensures that software systems are always up to date and robust in the face of challenges”, says Sverre Torben of Kongsberg Maritime Digital.

    COMPLEXITY

    However, the MIDAS project has shown there are a few knotty issues to overcome – not all purely technical in nature.

    Knutsen explains: “You can create a health indicator for a bearing with no problem, but doing the same for the power management involves thousands of signals. If the manufacturers are tasked with keeping their modules running, they will need to be able to pull the data out in the same way from any ship.” And, he adds, without it being “the labour-intensive process” it is at present.

    It’s not just the OEMs: the information will have to be shared with owner, systems integrators and last but not least, the classification societies. As Knutsen underlines, “there are more than 10,000 ships on DNV GL’s books so we’ll need a good, sanitized way of sorting it all out”.

    Although there is “some movement” toward developing an industry-wide ISO standard, he admits rather than trying to make existing arrangements line up, it’s far easier to accomplish coherency on a newbuild where a useable format can be implemented from the very start.

    SAFETY

    Any module worth its salt would need to cover all the bases: “Besides the monitoring, maintenance plans, approvals and so on, it would need to include designed-in safety systems,” points out Knutsen. The latter presents its own challenges as its characteristics change with the fuel. Take LPG, he says: “It’s heavier than air, so standard gas detection equipment in the ceiling won’t work.”

    Further, while modularity relies on a set of discrete systems, safety kit appears to pull in the other direction. Ammonia, for example is toxic and corrosive, so if there’s a failure in any part of the fuel supply, the entire ship could be endangered. Therefore, these safety systems have to extend throughout the whole vessel.

    “There is no perfect fuel, no perfect way forward”, underlines Niclas Dahl of Alfa Laval. “They all have pros and cons: some may simply be limited in supply. Some, like ammonia, require more in handling the risks.” But he stresses, this should not stop development.

    FUELS AND ENGINES

    Wärtsilä has been playing with modularity for a while: Nico Höglund explains that development really picked up with the release of the Wärtsilä 31 medium-speed four-stroke: “Before that, if you wanted to change from diesel to dual fuel, you’d have to re-machine the engine block…. but the 31 makes it all much more straightforward, you basically only need to add the gas components.”

    It sets the scene for what lies ahead. Höglund adds: “Both methanol and ammonia are currently being evaluated as potential next-generation fuels, partly because they have the potential of being created in a completely green supply chain.” Interestingly, both can also be kept in liquid form with a modest amount of pressure and cooling.

    Therefore, Wärtsilä’s modular approach should enable easier conversions: “If you have a dual-fuel engine running on LNG, the installation already contains the majority of what’s required, such as the fuel storage tank,” says Höglund, although both methanol and ammonia will need modified fuel injection along with process equipment and corresponding safety systems.

    MANAGEMENT

    Despite sounding deceptively simple, these fuel changes “require very good engine management”, adds Höglund: ammonia ignites and burns differently compared to other methane fuels and likewise, methanol has a lower calorific value requiring a change to the automation software.

    This is central, he says: “Outside its operational parameters, the engine can start to knock or miss-ignite. The engine’s automation system has to take action to ensure proper combustion in order to avoid a potential escalation of the situation, which could lead to shutdown. So it’s not just about optimising performance, it’s also about safety.”

    Moreover Alex Grasman of MARIN points out: “One important factor is that burning alternative fuels in a combustion engine makes for a narrow ‘operational envelope’ compared to diesel.” Further, heavy seas compound the issue by adding dynamic loads to the system.

    In short, new fuels require “tests on timing and management, and a lot of time spent searching for the sweet spot”, says Höglund.

    TWO STROKES

    While it might be expected that four-stroke, diesel-electric vessels like Moxie are the first candidates for a modular approach, Knutsen points out the big container vessels also tend toward fairly typical drive lines “with one or two two-stroke engines, propeller shafts and so on… so you could create a complete propulsion package delivered in a range of vessel sizes”.

    Martinsen adds that when it comes to cargo ship engines “we are not suggesting swapping big lumps of metal, instead we’re talking about transitional technologies that can adapt to new requirements”.

    In fact, large, robust two-strokes don’t need so much in the way of modification. For example high-pressure engines like those from MAN ES currently allow for mixing different energy sources such as methanol and ammonia with more standard LNG: “This strategy allows you to step down in stages over time, all the way to zero emission fuels.”

    FUEL PATHWAYS

    Ammonia and methanol aren’t the only candidates: there are potential crossovers from a number of directions. Wärtsilä has already equipped ethane carriers with 50DF engines, and within the company’s landside power generation arm are plants running on LPG.

    But there are varying levels of challenge inherent in repurposing the different engine systems and so fuel ‘pathways’ will likely open up.

    For example, Höglund points out that as liquid petroleum gas, LPG, consists largely of propane and butane, “it needs rather different treatment to LNG – which is mostly methane”.

    However, when it comes to big two-strokes, Dahl adds: “While ammonia is still in the development phase, LPG is a good first step.” The two have enough characteristics in common that MAN’s ME-LGIP engine can burn ammonia, using the same cylinder cover, injection valve and gas block – albeit with the addition of larger tanks.

    FUTURE KIT

    It’s worth mentioning alternative power technologies: “If you’re considering modularity, there’s a lot to be said for batteries,” says Höglund. And since the cells are now half the size and double the capacity of a decade ago, producers such as Stirling PBES are recoring their systems, retaining the cooling and control architecture but swapping the old cells for more efficient versions.

    There are certain limitations: “If the amount of power taken out in one go stays at a similar level, your electrical equipment can remain roughly the same,” explains Höglund. However, increasing peak power output may impact other components, such as converters, transformers and switchboards – so those too could require future-proof capacity.

    Likewise, ABB is now collaborating with Hydrogène de France on megawatt-scale fuel cell systems able to power ocean-going vessels. Further, since they’re going to be based on proton exchange membrane (PEM) solutions developed by Ballard, they only need pure hydrogen and oxygen feeds, allowing flexible positioning around the ship. In fact, PEM cell stacks are almost ideally suited to modular, distributed energy configurations.

    RELIABILITY

    For owners, yards and equipment manufacturers, modularisation promises greater reliability, lower lead and build times and generally far less fuss. Moreover, for class societies like DNV GL it could mean “a move toward system-level analysis, the focus shifting from individual ships to repeatable modules” says Knutsen.

    What it doesn’t promise is lower CAPEX. In fact, some research suggests that it will initially be more expensive – how much isn’t currently known – though as Martinsen has already pointed out, placing the wrong bet on the future will likely cost more in the long run.

  • Full Disclosure

    Full Disclosure

    All-electric and hybrid vessels offer demonstrable cost savings as well as environmental and operational benefits. However, Grant Brown of Sterling PBES is calling for a more holistic and transparent approach to battery system evaluation, which includes a firm focus on safety factors as well as life-cycle and ‘add-on’ costs

    Published in Bunkerspot by Grant Brown. https://www.bunkerspot.com/images/mags/flipbook/bs_v17n2_AprilMay20/mobile/index.html#p=67

    The age of hybrid and electric hybrid vessels is upon us. Research from DNV GL points to 356 all-electric or hybrid-electric vessels in operation or under construction in 2019, already surpassing the number of LNG vessels in the global fleet. Ferries, tugboats, and other near-shore vessels have been the trailblazers for electrification up to this point, yet ground-breaking projects like the installation of a 600 kWh battery on the Maersk Cape Town as well as the construction of the zero emission hybrid container ship Yara Birkeland show that electrification is gaining traction through-out the maritime sector.

    The benefits of electrification are clear to see. Many large shipowners today are compelled by regulatory or shareholder pres-sure to set targets and provide accountability on sustainability initiatives; with a traditional vessel environmental gains are hard won. Electric or electric hybrid solutions minimise noise and vibrations while cutting or eliminating toxic air pollution. They are used to optimise on-board generators and can provide black start capability, which represents a particular benefit to passenger ships. Yet the most important benefit to shipowners today is the substantial cut in operational costs that marine batteries represent. Indeed, data from the early adopters of fully-electric ferries in Norway have shown that the operator achieved an 80% cut in operational expenditure alongside a 95% cut in emissions. These are the cost savings that many in the industry are now understandably seeking to emulate. Electrification is an obvious win for the shipping industry but it is a relatively new concept. Like any new technology there are hidden risks and costs that shipowners must understand in order to make an educated decision on when and how to deploy a battery system.

    HIDDEN INCREMENTAL COSTS ADD UP

    Good battery design does not end with the cells. It extends to the space that a battery operates within and the equip-ment that houses it. This space greatly dictates the cost, efficiency, durability and the safety of the system as a whole. There is a clear need for holistic bat-tery design; fully integrating safety and effi-ciency measures throughout the battery system and its surroundings. When this need is coupled with a manufacturer who is up front about what is included, marine bat-teries are much safer and more efficient, as well as free of any hidden incremental costs.

    With many battery manufacturers on the market, factors like fire safety, fire detection, gas detection, gas extraction, battery cooling, and emergency ventilation are left to other contractors and not included in the price of the battery system. These so-called ‘add-on systems’ are critical to functionality and safety, yet in most cases battery suppliers will pass on the significant cost of installing these systems to the ship’s builders. Over time it has become clear that designers and manufacturers must take an integrated approach. Systems today must be smarter and more connected than they have ever been, features are continually being developed to ensure efficiency and safety. In the marine battery of today, integrated cool-ing systems must be designed and implemented throughout the core of a module down to the individual cells. Gas venting systems must be designed to be fail-safe, electronic control and monitoring systems must always monitor key parameters and must always be connected to safety monitoring systems. Offering these systems together as a single package ensures that all of the critical parts of the battery are fully compatible, and as efficient and safe as possible. It has the added bonus of making actual installed system costs clearer and in many cases, less expensive overall.

    YSTEM LIFESPAN

    Modern marine battery systems generally have an operational lifecycle of five to ten years, which represents an incredible rate of technological progress. With vessels last-ing 30 years or more this means that most shipowners will have to deal with natural degradation and ultimately battery system rebuilds. Similar to a conventional ship’s engine hardware requiring a re-build sev-eral times in its lifespan, battery replacement represents an additional challenge. One of the most important innovations in this space comes in the form of SPBES’ CellSwap technology, which allows for individual battery cells to be easily removed and replaced without the replacement of an entire battery system. This significantly reduces replacement costs. Due to lower operational hours and reduced low load run time, CellSwap aligns more closely with the normal maintenance intervals of a traditional vessel’s propulsion gear. With regular CellSwap replacement intervals, shipowners can benefit from newer battery cell technology such as improved energy density, improved discharge rates and improved lifespan. This means that more usable power can be stored in the same sized batteries. The usefulness of this additional power depends on the amount of energy that is available on a continuous basis. As in any electrical component, heat is the enemy and efficient cooling increases both the system’s continuous rating and its lifespan. Robust cooling aids efficiency to such a degree that a system with fully integrated liquid cooling can operate at an average continuous rate of 300%. This means that a system requiring 1 MW at peak could easily be met with a 350 kWh battery; a much smaller, much lighter, and far less costly system to install and maintain. Many cooling systems on the market today do not evenly regulate the temperature of the core of the battery cells, which cuts lifespan and continuous rating. For a cooling system to be truly effective, it must cool the entire battery unit evenly. Most ‘add on’ systems, as well as air cooled systems, are not able to cool the entire battery completely. However, a fully integrated liquid cooling system can pro-vide the required thermal exchange by circulating chilled water through the very core of a battery, in effect similar to the cooling system on a traditional internal combustion engine. Fully integrated liquid cooling has the added benefit of being far more efficient than the air cooled counterpart and requires 3,500 times less water flow volume compared to air to achieve the same heat removal, removing the need for expensive add-on HVAC systems.

    SAFETY AS PRIORITY

    While the industry sits up and takes notice of the cost savings and operational advantages that electrification offers, there is still consider-able and justifiable concern about safety. The most prominent safety issue associated with lithium ion marine batteries is thermal runaway. Thermal runaway occurs when a dam-aged or faulty cell overheats, damaging the cells that surround it and emitting highly flammable and toxic gasses that may ignite. The adjacent cells damaged by the initial faulty cell also overheat, thus creating a thermal chain reaction that will continue until all the energy in the battery is depleted. As we gain more practical experience, these risks must be dealt with honestly and mitigated. A holistic battery design is key, with all parts of the system designed to work together with safety at its core.

    This starts with the cooling system. An effective liquid cooling system integrated into the core of the cells is the first line of defence against thermal runaway. Effective liquid cooling can cool a battery faster than it can heat up in a thermal runaway incident. This stops the chain reaction before it starts. Yet the risk of thermal runaway cannot be removed entirely, so failsafe mechanisms beyond cooling further reduce the risk to the crew and vessel. Venting mechanisms can remove flammable gasses from an unstable battery, reducing the risk of explosion as well as the risk posed by toxic fumes. Thermal barriers between cells can also help to reduce the risk of a damaged cell from starting a thermal chain reaction. These are exciting times for marine battery systems. Demand and viability are growing at an amazing pace, as is supporting infrastructure. As manufacturers, we must ensure that we bring the best possible batteries to market. We must do this as cost efficiently as possible, with safety always being the number one priority. To do anything else makes marine batteries needlessly expensive to install or creates needless risks to shipowners. This holistic, safety first approach will require that battery manufacturers develop and offer fully formed systems that provide the highest in safety, value, and ultimately, return on investment.

  • Want Electric Ships? Build a Better Battery

    Want Electric Ships? Build a Better Battery

    Large container ships are a major contributor to greenhouse gas emissions, but electrifying the world’s fleet faces steep technological hurdles.

    Published in WIRED Magazine, By Daniel Oberhaus, March 19, 2020 https://www.wired.com/story/want-electric-ships-build-a-better-battery/

    LATER THIS YEAR, the world’s largest all-electric container ship is expected to take its maiden voyage, setting sail from a port in Norway and traveling down the Scandanavian coast. Known as the Yara Birkeland, the ship was commissioned by Yara, a Norwegian fertilizer company, to move its product around the country. The company expects the ship to reduce carbon emissions by eliminating about 40,000 trips each year that would otherwise be made by diesel-powered trucks.

    There are about 50,000 cargo ships operating around the world, and each year their engines spew about 900 million metric tons of CO2 and other pollutants into the atmosphere. Indeed, the 15 largest container ships alone emit more nitrogen oxide and sulphur oxide pollutants than all the world’s cars combined. Electrifying cars and other modes of transport promises to significantly reduce greenhouse gas emissions, and the same is true of the shipping sector.

    Yara Birkeland illustration showing it being docked
    An illustration of the Yara Birkeland, which will transport cargo in Norway using battery power.

    COURTESY OF YARA INTERNATIONAL ASA

    But conventional lithium-ion batteries can only pack enough power to move small ships like the Yara Birkeland over short distances. If we want to electrify the world’s largest cargo ships, we’re going to need some better batteries.

    Building battery-powered ships comes with two big problems. The first is that conventional lithium-ion batteries pose safety risks, because they use liquid electrolytes to carry lithium ions between the electrodes. If the components in a battery degrade, this can cause the cell to rapidly heat up and fail, a process known as thermal runaway. The battery’s heat can lead to a cascade of failures in nearby batteries. If these batteries release their chemicals as they fail, all it takes is one battery to catch on fire and cause a large explosion. That would be bad anywhere, but it’s particularly bad at sea where there are millions of dollars of cargo on the line and limited escape routes for crew.

    Last year, a small fire in the battery room of a hybrid-electric ferry in Norway resulted in an explosion. The ferry operator was able to evacuate passengers and crew to land before the explosion, but a similar event on a cargo ship in the middle of the ocean could be catastrophic.

    SPBES, a Canadian energy-technology company, is working to reduce the risk of electric vessels by designing marine energy systems that are resistant to thermal runaway. The company’s energy system, which is currently installed on roughly 20 ferries and tugboats around the world, uses lithium nickel manganese cobalt, or NMC, batteries. This is the same conventional lithium-ion chemistry you’ll find in most consumer electronics or electric vehicles, which have had their fair share of thermal runaway problems.

    a man in a control room
    COURTESY OF FORSEA

    To lower the risk of explosions on boats, SPBES built a battery container with a liquid cooling system that wicks away thermal energy faster than a battery in meltdown can produce it. While this won’t prevent a battery from failing, it does prevent the kinds of cascading failures that lead to explosions, says Grant Brown, cofounder and vice president of marketing at SPBES. “Our technology is basically bomb-proof,” says Brown. “It’s really tough stuff.”

    SPBES also designed its energy system to make it easy to swap out individual cells if they fail or reach the end of their lifetime. This helps address what may become a bane of the electric shipping industry: handling battery waste. Cargo ships will require hundreds of thousands of batteries, so the ability to selectively remove individual cells rather than scrapping the entire energy system will be critical to reducing waste. “Why throw away so much perfectly good material when you can simply reuse most of it?” asks Brown. “In terms of environmental impact, this is the future.”

    A second major challenge facing electric ships is that conventional lithium-ion battery chemistries simply don’t pack enough power to move cargo around the world. Today, batteries based on NMC chemistries can only be used to electrify ferries and small container ships like the Yara Birkeland. Yara’s ship is powered by enough batteries to provide up to 9 megawatt-hours of energy. It’s the equivalent of 90 Tesla Model S battery packs, and enough for short trips of up to 30 nautical miles while carrying 3,200 tons of cargo.

    But to meet the energy demands of massive international cargo ships, which carry tens of thousands of tons of cargo and use dozens of gigawatt-hours of energy, we’re going to need more advanced batteries. “Cargo ship engines can be as tall as a four-story house and as wide as three buses,” says Natasha Brown, a spokesperson for the UN International Maritime Organization. “At present, the size of the battery needed would likely limit the amount of cargo that could be carried, making it commercially nonviable.”

    To meet the energy needs of the next generation of electrified boats, Washington-based energy-technology company Lavle is developing an advanced energy-storage system based on solid electrolyte batteries. Lavle’s cells are made by 3DOM, a Japanese battery manufacturer that created a new type of separator made from a porous resin that is stacked between the layers of solid electrolyte material that carry ions between the battery’s electrodes. Swapping out liquid electrolytes for solid electrolytes reduces the risk of thermal runaway. Adding in the new separator increases the battery’s performance by efficiently transporting lithium ions.

    battery render showing patented CellCool system.
    COURTESY OF SPBES

    “From an energy density standpoint, we’re approaching three times what standard lithium-ion batteries on the market can do,” says Lavle CEO Jason Nye. But Nye sees Lavle’s solid electrolyte batteries as just a step on the road to an even better type of power pouch known as a lithium metal battery, which uses an anode made from solid lithium metal rather than a more typical carbon anode. Nye says its lithium metal anode can push the cell’s energy density even higher and would be easier to mass produce than a solid electrolyte battery.

    Ben Gully, Lavle’s chief technical officer, describes this kind of cell as a “holy grail” in energy storage development. Lithium metal batteries can boost a cell’s energy density and charging rates because the lithium metal anode easily gives up its ions. But the lithium anode swells a lot while a battery is charging, which can cause it to decouple from the electrolyte. Furthermore, lithium metal is highly reactive with most available electrolytes, and this causes them to degrade.

    Gully says Lavle and 3DOM were able to overcome these issues by using its new separator technology and making other tweaks to the lithium metal battery chemistry. Gully wouldn’t go into the details of the company’s “secret sauce” for making lithium metal batteries, but he says the company’s experimental lithium metal cells have already demonstrated a threefold improvement in energy density compared with conventional lithium-ion batteries.

    a boat
    COURTESY OF FORSEA

    Considering that the efficiency of rechargeable lithium-ion cells has only tripled since they were commercialized 30 years ago, Lavle’s batteries are showing the sort of large performance increase that is needed to electrify the world’s shipping fleet. For now, these batteries remain experimental, and the company still needs to demonstrate that they can be used in a commercial vessel. Lavle expects to begin deploying prototypes of its advanced energy systems in smaller vessels like ferries by the middle of next year, but Nye says that in the future their system could scale to meet the needs of large cargo ships.

    Even with these new advancements in marine energy-storage systems, cargo ships may never be able to rely on battery systems alone. Agis Koumentakos, a Greek energy trader and coauthor of a recent paper on electric ships, cites several environmental and geopolitical challenges that come with the electrification of the maritime sector.

    On the environmental side, each cargo ship will require dozens of tons of batteries that have limited shelf lives. The recycling industry isn’t ready to handle the surge in depleted lithium-ion cells, which come with several storage and handling challenges. Electrifying cargo ships could significantly accelerate the problem. On the geopolitical side, batteries require a lot of mined material, some of which is sourced from mines that employ child labor. Even if these materials can be sourced ethically, China controls a lot of the supply chain for lithium-ion batteries, and Koumentakos says policymakers may be wary of becoming totally dependent on China for maritime cargo transport.

    But using batteries for cargo ships isn’t an all-or-nothing proposition. Instead, they may be combined with other clean forms of energy generation, such as hydrogen fuel cells, solar, or even wind. “Batteries probably won’t be a monopoly in ship propulsion,” says Koumentakos. “It’s going to be a mixture of technologies.”

    Solar energy has been used on cargo ships for years to partially meet their electricity needs, but photovoltaic tech will never be energy-dense enough to power a ship on its own, Koumentakos says. Another option is to return to the original source of ship propulsion—the wind—using technologies like large metal sails or rotor sails to propel large cargo ships and reduce energy costs. And if the fabled hydrogen economy emerges in the coming decades, ships could implement hydrogen fuel cells as a primary source of propulsion and use batteries as backups.

    The development of high-performance energy-storage systems for ships may also see wide application beyond the maritime sector. Nye says Lavle’s technology could also be a good fit for electric aircraft like the vertical-takeoff-and-landing vehicles currently under development as air taxis, and Brown says SPBES is exploring large-scale applications for its energy system on land.

    The maiden voyage of the Yara Birkeland later this year will be a small but important milestone toward electrifying the world’s ships. As one of the only fully electric cargo ships in the world, it will show what’s possible with today’s technology and serve as a blueprint for the electrified ships of the future.