Connect with us

Technology

DNV independent cloud platform Veracity launches new Solution Partner program

Shipowners and managers can now easily connect their verified emissions data from platform with partnering software applications and services, such as EUA settlement and trading solutions.

Admin

Published

on

DNV independent cloud platform Veracity launches new Solution Partner program

DNV’s independent cloud platform Veracity on Thursday (11 April) announced the launch of its new Solution Partner program, where maritime solution providers integrate their applications and services with the platform. 

Shipowners and managers can now easily connect their verified emissions data from the platform with partnering software applications and services, such as EUA settlement and trading solutions.

The Solution Partner program is an expansion of the Veracity Integrated Partner program that already offers connectivity to nearly 50 000 vessels for automated emissions reporting by connecting maritime data providers to the Veracity platform and DNV’s verification services. The first solution partners already connected include ABN Amro, Berenberg, Carlton Carbon, Hecla Emissions Management, INTERTANKO, Vanora, Timing Carbon and zero44.

Mikkel Skou, Executive Director at Veracity by DNV, said: “I am glad to see the ecosystem around Veracity’s maritime emissions cloud grow at an increasing speed.”

“Last year, we partnered with leading maritime data providers, so that our common customers could get real-time verified emissions data through an automated and secure process. Now we expand the program further, enabling customers to easily use verified data in their commercial settlements and with partnering solutions.”

DNV said the need for real-time verified emissions data that can be efficiently used across several solutions and reporting mechanisms in the value chain is fast growing as the industry increases its decarbonization efforts. 

In January 2024, the EU ETS regulations came into effect for several shipping segments and as of 1st of January 2025 more segments will follow as FuelEU Maritime comes into play. 

The increased regulatory requirements come in addition to already established industry initiatives, such as Poseidon Principles; a global framework from the financial sector for integrating climate considerations into maritime lending decisions and Sea Cargo Charter; established to assess and disclose climate alignment of ship chartering activities worldwide.

“The implementation of EU ETS is a game-changer for the industry, setting new requirements on the quality and frequency of emissions data from vessels,” said Skou. 

“As the cost of emissions becomes part of the commercial contract, the data behind the numbers must be accurate and verifiable. To help companies in this transformation, we have built the Emissions Connect service from DNV.”

“It uses the Veracity data platform and our partner network to efficiently connect operational vessel data with DNV’s verification services, and now for further use in partnering software solutions. This way our customers can truly maximize the value of their verified data in an efficient manner.”

Within the scope of the Veracity Solution Partner Program, the Veracity platform serves as a secure digital space where customers can make their own emissions data available from all partners that have signed up to the partner program. This data is not directly submitted to DNV but rather securely stored on the Veracity platform, underlining the autonomy of the customers in managing their data.

Pål Lande, Digital Business Development Director, DNV maritime, said: “DNV’s role is clearly demarcated within this ecosystem. We provide assurance services with the professionalism and independence that stakeholders have come to expect from us, without any undue influence over the data prior to its submission for verification.”

“The model further underscores our commitment to advancing digital transformation and decarbonization efforts in the maritime industry, facilitating a seamless and secure exchange of data that supports our clients’ business needs while adhering to the highest standards of data integrity and impartiality.”

 

Photo credit: DNV
Published: 12 April 2024

Continue Reading

Bunker Fuel Quality

VPS on lifeboat fuel quality: A safety of life at sea critical risk

Neil Chapman and Steve Bee said regular fuel testing, correct fuel selection, and proactive fuel management are essential to ensure lifeboats are ready when they’re needed most.

Admin

Published

on

By

RESIZED VPS logo

Neil Chapman, Managing Director of Americas, and Steve Bee, Group Marketing and Strategic Projects Director of marine fuels testing company VPS, on Monday (13 July) said regular fuel testing, correct fuel selection, and proactive fuel management are essential to ensure lifeboats are ready when they’re needed most: 

Performance when its most critical

In an emergency, a lifeboat engine is not simply a mechanical asset, it is a life-saving system. If the fuel in that system is of poor quality due to degradation, contamination, or simply unsuitable for the operating environment, then the result may be failure to launch, manoeuvre, or sustain operation, when human lives depend on it. Fuel failures in lifeboats onboard Cruise Liners are high-consequence life-safety risk as the engine may be the only power source available during an emergency. It is a key SOLAS (Safety of Life at Sea) requirement that lifeboats should hold sufficient fuel to enable them to run at 6 knots for no less than 25 hours.

The primary consequence of a lifeboat failure is not the commercial  loss, but the potential failure of a safety-critical system during an abandon-ship scenario. Financial, legal and reputational consequences will undoubtedly follow but the immediate risk is to life.

Now with the inclusion of Biofuels and FAME in the marine fuel mix and assuming the same fuel used in the main engines may be used in the emergency systems, how do you verify the operability of the lifeboats in times of crisis?

Fuel grade DMX within the ISO8217 specification is specifically intended for use within emergency equipment. However, since this is not a mandatory requirement, marine gas oil (MGO grade DMA) used for other purposes on board, is often used to fill up lifeboat fuel tanks. This could lead to hazardous outcomes as the DMA grade fuel might not be suitable for its intended use. DMA fuel whilst acceptable for general machinery use, will unlikely provide the same assurance of low-temperature operability, ignition quality, storage reliability, or starting reliability required for emergency craft. The quality of the fuel in the lifeboat tanks may also deteriorate during storage. Hence it is essential to test and ensure that the quality of the fuel being taken into the tanks is ’fit for purpose’ and monitored at regular intervals. DMX fuel should be chosen due to its ability to operate at a lower temperature, superior ignition quality and  improved starting capabilities. However, this fuel only accounts for approximately 1-2% of the global supply, compared to the regular DMA grade.

Failure Modes in Emergency Operations

SOLAS compliance should not be viewed only in terms of carrying the required quality of fuel. The fuel must also remain fit-for-purpose regarding stability, cleanliness and be capable of supporting reliable engine operation throughout the vessel’s operation. Lifeboat failures are rarely a singular dramatic event, rather a chain of events. These are typically caused by degraded fuel, filter blockages or storage issues.  Incorrect handling and storage can result in the ingress of water, which with modern fuels, can promote the growth of filter blocking bacteria rendering the engine inoperable.  So rather than the issue being no fuel, it is more likely to be an issue of fuel that is of poor quality. As lifeboat engines may sit idle for long periods it potentially allows the fuel to degrade, if the correct due care and attention is not paid to this key piece of emergency equipment.

The handling and storage of fuel, coupled with the observance of quality operating procedures can lessen the risk of these failures, but are unlikely to eliminate them completely. However, the failure to follow established procedures can result in issues that are likely to cause catastrophic financial and reputational damage to the cruise line operator.

The most common failure modes in emergency lifeboats can be categorised as follows:

  • Fuel Starvation
  • Contamination
  • Degraded Fuel
  • Blocked Filter/Injectors

Contamination in the engine due to the presence of water, as previously mentioned, can be catastrophic as this can induce corrosion and oxidation, along with promoting microbial growth which results in filter blocking and fuel starvation to the engine.

If an engine fails to start, or runs poorly under load, due to fuel related issues this would likely cause a secondary emergency, compounding the reason the lifeboat was required in the first instance.

The danger with degraded fuel is that the risk is often hidden. A lifeboat may appear available, inspected and compliant, whilst he fuel inside its tank is steadily losing the properties required for reliable emergency operation.

IMO guidelines indicate that inspectors and regulators are increasingly looking at emergency systems for fuel compliance, highlighting its importance in the operation of a vessel.

Seasonal & Regional Fuel Requirements

Often overlooked are the cold flow properties of diesel and biofuels.  While hydrocarbon-based diesel has very good (low temperature) cold flow properties, this is not the case for biofuels, so lifeboats fuelled in the Caribbean for the summer season may be completely inoperable if the vessels are transferred to the Northeast or higher location, for a winter period.

Root Cause Failure Mechanisms

The failure to follow the appropriate standards which result in engine failure can be categorised as follows:

image 45

The Effect of Biofuels on Marine Fuel Quality

In a study recently completed by a major shipping line, blends of biofuels were tested for a wide range of parameters.  The findings were:

Biological growth appeared within the first month, increasing rapidly with exposure to light.

Within 3 months oxidative corrosion started to occur requiring regular monitoring.

46 CFR § 169.837 states:

“(2) The fuel tanks of motor propelled lifeboats have been emptied, and fuel changed once every twelve months.”

Yet the evidence shows fuel stability effectively starts to deteriorate within the first month and can be unusable by month 3.

Prevention Strategy

Fuel testing should be viewed as part of the vessel’s safety assurance programme. It provides evidence that the lifeboat fuel remains fit-for-purpose, not only on the day it was supplied, but throughout storage and across changing operational conditions. A strong housekeeping policy requires a multi-pronged approach to ensure operability in times of crisis; such steps include:

  • Housekeeping – ensuring the fuel system remains closed when not in use to eliminate the ingress of water.
  • Operation – frequently run the engines so that fuel and lubricants are cycled through the units.
  • Testing program – likely to be cheaper and more efficient than changing out the fuel. A well-developed fuel testing program can eliminate the need to change the fuel.
  • Documentation – by recording all the actions taken to protect the emergency systems historic data can be tracked.

Advanced Testing Programs

Due to the importance of these emergency assets several different tests should be considered to ensure the suitability of the fuel.  Testing should include:

  • Cold-Flow properties using Pour Point, Cold Filter plugging Point, Cloud Point
  • Water content for moisture
  • BYF for Microbial testing
  • Acid Number for corrosion tendencies
  • FAME for biofuels content
  • Sulphur for MARPOL Annex VI compliance
  • Visual Appearance
  • Viscosity for flow properties
  • Density
  • Flash Point for SOLAS compliance
  • Cetane Index

Conclusion

It is possible to avoid engine failures, but this can only be achieved with a well-documented and well-followed operating procedure.  Regular fuel sampling and testing along with general good housekeeping techniques will ensure these units are ready go when they are most needed. Once they are seen as an active safety-critical asset rather than a dormant emergency component the value in this process will be realized.

Lifeboat fuel quality is not a housekeeping detail, it is a Safety of Life at Sea issue. Emergency craft must be capable of starting manoeuvring and operating for the required duration whenever called upon. Sub-standard, degraded, contaminated, or unsuitable fuel can compromise that capability and turn an emergency response into a secondary emergency. Regular testing, correct fuel choice, controlled storage and documented fuel management provide the evidence and assurance that lifeboats remain ready when lives depend on them.

 

Photo credit: VPS
Published: 14 July, 2026

Continue Reading

Digital platform

Norwegian Cruise Line to enhance bunker procurement process with ZeroNorth

By leveraging ZeroNorth’s Bunker Procurement Solution, NCLH will create greater efficiencies across the bunker procurement process while enhancing transparency, supplier collaboration, and decision-making.

Admin

Published

on

By

Norwegian Cruise Line to enhance bunker procurement process with ZeroNorth

Maritime technology solutions provider ZeroNorth on Thursday (9 July) said it is partnering with Norwegian Cruise Line Holdings to enhance bunker procurement processes through digital innovation.

“By leveraging ZeroNorth’s Bunker Procurement Solution, NCLH will create greater efficiencies across the bunker procurement process while enhancing transparency, supplier collaboration, and decision-making,” the company said in a social media post. 

ZeroNorth added that fuel procurement is one of the most complex functions in operating a global cruise fleet. 

“Balancing market dynamics, supplier options, operational schedules, and cost considerations require timely insights and the right technology,” it said. 

Lory Urdaneta, Senior Director Energy Strategy at Norwegian Cruise Line Holdings, said: “At Norwegian Cruise Line Holdings, we are committed to embracing innovative technologies that strengthen our operations and deliver long-term value. 

“Our partnership with ZeroNorth is an important step in enhancing our bunker procurement process through greater transparency, data-driven decision-making, and operational efficiencies. We look forward to working together to drive innovation and support the continued evolution of our procurement capabilities.”

 

Photo credit: ZeroNorth
Published: 10 July, 2026

Continue Reading

Engine

VPS on precision testing for reliable engine performance: Importance of coolant analysis

Steve Bee of VPS highlighted that coolant analysis can prevent failures through early chemical detection, protect components, maintain performance, plus reduce costs and downtime.

Admin

Published

on

By

RESIZED VPS logo

Steve Bee, Group Marketing and Strategic Projects Director of marine fuels testing company VPS, on Thursday (9 July) highlighted that coolant analysis can prevent failures through early chemical detection, protect components, maintain performance, plus reduce costs and downtime: 

Engine coolants play a critical role in protecting equipment performance, efficiency, and longevity. As cooling system technologies and coolant formulations continue to evolve, regular laboratory analysis has become an essential part of proactive maintenance.

It is widely known that coolants should be managed with the same discipline as other critical fluids, as chemical changes can develop long before visible failures occur.

However, it must be emphasized that coolant analysis is about reliability, not just fluid condition. Modern engines and cooling systems operate under higher thermal loads and tighter tolerances, so even small changes in coolant chemistry can affect corrosion control, heat transfer, and component life.

An effective coolant analysis service should provide operators with an early warning system, helping to identify contamination, degradation, and inhibitor depletion before they become operational failures. The service can be a practical tool for reducing downtime, preventing avoidable repairs, and extending equipment life.

As stated above, many cooling system issues start at the chemical level, long before anything is visible and without analysis you are effectively blind until a failure starts. Through coolant testing, risks such as corrosion, cavitation and scale formation can be detected long before damage occurs.

image 41

As an example, the above images show the damage that can occur when a coolant does not have sufficient concentration to provide adequate protection. This damage can appear as scale formation, reduced heat-transfer efficiency and lower flow rates, which can ultimately lead to corrosion.

Coolants don’t just control temperature, they also chemically protect engines and coolant systems. They effectively prevent corrosion of metals and components, reduce cavitation damage in liners and pumps and help avoid deposit build-up and blockages in heat exchangers. Its true that cooling system damage, is a major source of engine failure.

Coolants must be chemically stable in order to transfer heat effectively, as poor cooling performance directly impacts engine efficiency, fuel consumption and reliability. As a predictive maintenance tool coolant analysis moves operations from emergency repairs to planned maintenance.

Should coolants exhibit degrees of incompatibility, then further issues can arise. Mixing incompatible coolants can cause sludge formation, which will in turn affect coolant circulation, leading to reduced efficiency. In addition incompatible coolants can form sludge or gels, which negatively impacts circulation and heat transfer creating hotspots. Those hotspots can break down lubrication and cause micro-welding between piston and liner surfaces, leading to piston pick-up.

image 42

Historically, many coolants were relatively simple glycol/water formulations supported by inorganic inhibitors such as silicates, phosphates, or borates. However, modern coolants are more sophisticated, including OAT, HOAT, NOAT, POAT, and other specialized blends designed for longer service life and improved protection. This added sophistication creates a need for verification: when systems are topped up, mixed, contaminated, or serviced.

Organic Acid Technology (OAT) coolants, can be formulated with various organic acids such as Sebacate, which is an ester of sebacic acid. Sebacate exhibits low volatility and excellent flexibility at low temperatures. Also tolytriazole can be a component, which is best known as a thermally stable, metal corrosion inhibitor.

So organic acid technology uses organic acids to provide targeted corrosion protection, especially for aluminum and mixed-metal systems. The advantages are, long service life of up to seven years, reduced abrasive deposits, and protection that is generally gentler on seals and components. However, whilst such coolants offer long service life, OAT coolants are not maintenance-free. Its also possible that coolant protection can be slow to establish and performance can be compromised by incorrect mixing, contamination, or loss of inhibitor balance. This is where routine analysis helps verify that the coolant is still doing its job.

Hybrid Organic Acid Technology (HOAT) coolants are newer generation coolants which combine organic acid technology with selected inorganic additives. They aim to provide both long-life protection and faster initial corrosion control through improved heat transfer and cooling performance. This makes them attractive for demanding engines and systems where heat transfer, compatibility, and corrosion control are all critical. The important point is that HOAT chemistry is more complex than traditional coolant chemistry. That complexity can make correct identification, compatibility, and contamination control more difficult. The downsides to HOAT coolants are they are more expensive than traditional coolants, but more concerning is they can be more susceptible to becoming contaminated, affecting their effectiveness and lifespan. Therefore, routine lab testing helps confirm whether the coolant in service still matches the intended formulation and whether the inhibitor package remains effective.

The shipping fleet has numerous sectors and each have various considerations when it comes to the use of coolants:

image 43However, the underlying need for each shipping sector is similar, in that cooling-system reliability supports uptime, safety, and cost control. Deep-sea shipping, offshore and marine services, harbour and coastal operations, cruise and ferry operators, inland waterway vessels, plus port or terminal operators, all have equipment where coolant condition can affect reliability. The commercial message is that coolant analysis can be positioned alongside existing marine fluid management services, making it a logical extension rather than a separate standalone offering.

A typical coolant analysis test slate includes the following tests highlighting what each test parameter detects, their frequency and benefits:

image 43

To take an analogy from Oil Condition Monitoring, Coolant Analysis is effectively a “blood test” for the cooling system.

So in summary, Coolant Analysis can prevent failures through early chemical detection, protect components, maintain performance, plus reduce costs and downtime.

 

Photo credit: VPS
Published: 10 July, 2026

Continue Reading

Trending