To maintain world leadership in complex, value-added and highly specialised vessels European shipbuilders must develop tailor-made innovative concepts that are efficient to design and build. Project NAVAIS proposed solution is a platform-based modular product family approach supported by the 3DEXPERIENCE integrated business platform. By sharing components and production across a platform of vessels, higher efficiency in vessel design and flexibility in production networks is achieved. NAVAIS uses system engineering approaches to develop the principles, procedures and a re-use component library for modular design and production and will apply these to develop two platform-based product families: passenger/road ferries and multi-use workboats. For each product family a demonstrator will be developed to TRL9 “digital twin”-level, validated and assessed on low impact environmental performance e.g. discharges to air and water, underwater radiated noise and cost-benefit aspects. The demonstrators are a 400 passengers/120 cars E-ferry and a multi-use workboat equipped for aquaculture activities. A major aspect of the platform-based modular approach is the change in value chain management. The current class approval procedure of engineered-to-order designs will be replaced by a procedure where pre-engineered product modules are approved by class, stored in a re-use library and applied in new vessel modular designs. This transfer from an engineered-to-order business model to an assemble-to-order business model will allow shorter process lead-times, constant quality, reduced design and production costs and better integration of the SME supply chain. Exploitation of results is expected at the end of the project duration. NAVAIS partnership contains 16 partners from 5 EU and 1 associated countries and includes technology providers, technology integrators and technology users. The project duration is 4 years and the required funding is € 6,6 MIO.

Most maritime products are typically associated with large investments and are seldom built in large series. Where other modes of transport benefit from the economy of series production, this is not the case for maritime products which are typically designed to refined customer requirements increasingly determined by the need for high efficiency, flexibility and low environmental impact at a competitive price. Product design is thus subject to global trade-offs among traditional constraints (customer needs, technical requirements, cost) and new requirements (life-cycle, environmental impact, rules). One of the most important design objectives is to minimise total cost over the economic life cycle of the product, taking into account maintenance, refitting, renewal, manning, recycling, environmental footprint, etc. The trade-off among all these requirements must be assessed and evaluated in the first steps of the design process on the basis of customer / owner specifications. Advanced product design needs to adapt to profound, sometimes contradicting requirements and assure a flexible and optimised performance over the entire life-cycle for varying operational conditions. This calls for greatly improved design tools including multi-objective optimisation and finally virtual testing of the overall design and its components. HOLISHIP (HOLIstic optimisation of SHIP design and operation for life-cycle) addresses these urgent industry needs by the development of innovative design methodologies, integrating design requirements (technical constraints, performance indicators, life-cycle cost, environmental impact) at an early design stage and for the entire life-cycle in an integrated design environment. Design integration will be implemented in practice by the development of integrated design s/w platforms and demonstrated by digital mock-ups and industry led application studies on the design and performance of ships, marine equipment and maritime assets in general.

The RAMSSES project has the strategic objective to obtain recognition and an established role for advanced materials in the European maritime industry. To achieve this the project will demonstrate the benefits of new materials in thirteen industry led and market driven demonstrator cases along the entire maritime process chain from components through equipment and ship integration to repair. Those demonstrators will reach a high Technology Readiness Level between TRL 6 and 8 and will either be installed on shore under close to reality conditions or validated on board. The technical performance as well as life cycle cost efficiency and environmental impact will be assessed and validated by specific expert teams following common procedures and testing standards. The test program will be based on risk assessment and a widest possible use of existing test results and supervised by rule making bodies, such ensuring relevance for a commercial approval beyond the project. Test data as well as best practice procedures on design, qualification and production of new material solutions will be made available in a maritime test database and a central knowledge repository, thus allowing fast qualification and approval of similar maritime applications in future. RAMSSES also aims to improve the innovation capabilities of the European maritime sector by elaborating terms of reference of a future use of the test database and the knowledge repository beyond the project. In cooperation with other initiatives, it will contribute to the formation of a maritime materials innovation Platform including continuous technology transfer from and to other industry sectors.

We are standing at the dawn of a century that will be largely affected by how we as a society are able to manage our oceans and their resources. Marine and Maritime Research has a critical role to play in developing our understanding of the seas and advance technology so that we can develop their economic potential in a sustainable manner. The COLUMBUS project intends to capitalise on the EC’s significant research by ensuring accessibility and uptake of research Knowledge Outputs by end-users (policy, industry, science and wider society). COLUMBUS will ensure measurable value creation from research investments contributing to sustainable Blue Growth within the timeframe of the project. Adopting proven methodologies and building on significant past work, COLUMBUS will first identify end-user needs and priorities. It will then set about identifying and collecting “Knowledge Outputs” from past and current EC projects. Rigorous analysis will take place to identify specific applications and end-users. Transfer will be achieved and measured through tailor-made knowledge transfer. All knowledge collected will be made accessible the pre-existing Marine Knowledge Gate. To achieve the above, COLUMBUS has brought together a multi-disciplinary, multi-stakeholder team representing all aspects of the research value chain from funding agencies to end-users. Key strategic initiatives and networks further strengthen and provide a strong vehicle for project legacy. A network of 9 Competence Nodes, each with a “Knowledge Fellow” and support team across Europe will provide the necessary critical mass (470pm of effort) to ensure full thematic and spatial coverage. COLUMBUS will also carry out strategic actions to enhance the visibility and impact of research to stakeholders and European Citizen’s. Furthermore working with funding agencies and stakeholders, COLUMBUS will examine the feasibility of improved systems and processes to ensure measurable value creation from research.

Ro-ro ships are an important component of the global transportation system, but an increasing trend of ro-ro ship fires in recent years call for improved fire protection. From comprehensive ship operators’ experience and by participation in ongoing work for the European Maritime Safety Agency and the International Maritime Organization (IMO), critical aspects of ro-ro ship fire safety have been identified to form the scope of the project LASH FIRE. It aims to provide a recognized technical basis for the revision of international IMO regulations, which greatly enhances fire prevention and ensures management of fires on ro-ro ships without recourse to external intervention. This is done by developing and demonstrating operational and design solutions which strengthen the fire protection of ro-ro ships in all stages of a fire and which address current and future challenges, including regulatory issues. Twenty specific challenges have been identified, which will be addressed by new solutions developed and demonstrated with regards to performance and ship integration feasibility by system suppliers, researchers, ship owners and shipyards. For the solutions to be considered for regulatory uptake, their impact on risk reduction and cost will be assessed and advisory groups with operators and flag states will be established. Thereby, the project is expected to significantly strengthen the independent fire protection of ro-ro ships and to reduce the frequency of ro-ro ship fires by 35% and the number of fatalities by 45%.