The main goal of the ENSEMBLE project is to pave the way for the adoption of multi-brand truck platooning in Europe to improve fuel economy, traffic safety and throughput. This will be demonstrated by driving six differently branded trucks in one (or more) platoon(s) under real world traffic conditions across national borders. Following objectives are defined: -Achieve safe platooning for trucks of different brands. Relevant authorities will be approached to jointly define road approval requirements including V2I communication. -Work towards the standardization of different aspects of platooning: manoeuvres for forming and dissolving of platoons, operational conditions, communication protocols, message sets, and safety mechanisms. Platooning Levels will be defined to guide the design of different platooning functionalities and strategies, reflecting the full diversity of trucks with platooning functionality. Stakeholder groups will be set up to ensure that the pre-standards are taken up by the respective organisations and working groups to form the actual standards. If necessary a multi-brand platooning working group will be initiated. -Real-life platooning: The intended practical tests on test tracks and in real life serve a three-fold purpose: 1) “learning by doing” testing across a C-ITS corridor in Europe, 2) assess the impact on traffic, infrastructure and logistics, while gathering relevant data of critical scenarios and 3) promote multi-brand platooning through a final event. ENSEMBLE brings the key actors for deployment together: six major truck OEMs will form the core of the project consortium, supported by CLEPA that will act as an umbrella organisation to involve all relevant suppliers. In addition, a limited number of expert organizations will be involved to cover specific topics such as safety assessment, traffic impact, and platoon control system design.

The project brings together ten participants from industrial and academic backgrounds to provide innovative and mass-production optimised components enabling the efficient integration of powertrain and chassis systems, which will increase EV range and user acceptance. Given the recent progress related to in-wheel motors technology, and the benefits of in-wheel architectures in terms of active safety, packaging and drivability, EVC1000 will focus on in-wheel drivetrain layouts, as well as a wheel-centric integrated propulsion system and EV manager. More specifically, the consortium will develop: - New components for in-wheel powertrains: i) Efficient, scalable, reliable, low-cost and production-ready in-wheel motors, suitable for a wide range of torque and power specifications; and ii) Dual inverters for in-wheel motor axles based on Silicon Carbide technology. The designs will include detailed consideration and measurement of the electro-magnetic compatibility aspects, as well as the implementation of model-predictive health monitoring techniques of the electronic components. - New components for electrified chassis control with in-wheel motors: i) Brake-by-wire system for seamless brake blending, high regeneration capability and enhanced anti-lock braking system control performance; and ii) Electro-magnetic active suspension actuators, targeting increased comfort and electric vehicle efficiency. - Controllers for the novel EVC1000 components, exploiting the benefits of functional integration, vehicle connectivity and driving automation for advanced energy management The new EVC1000 components will be showcased in two production-ready electric vehicle demonstrators of different market segments. EVC1000 will assess the increased energy efficiency and will include demonstration of long distance daily trips. The vehicle demonstration phase will consider objective and subjective performance indicators for human factor analysis, to deliver enhanced customer experience.

Current technological demands are increasingly stretching the properties of advanced materials to expand their applications to more severe or extreme conditions, whilst simultaneously seeking cost-effective production processes and final products. The aim of this project is to demonstrate the influence of different surface enhancing and modification techniques on CF-based materials for high value and high performance applications. These materials are a route to further exploiting advanced materials, using enabling technologies for additional functionalities, without compromising structural integrity. Carbon fibre (CF) based materials have particular advantages due to their lightweight, good mechanical, electrical and thermal properties. Current generation CFs have extensively been used in a multitude of applications, taking advantage of their valuable properties to provide solutions in complex problems of materials science and technology, however the limits of the current capability has now being reached. MODCOMP aims to develop novel fibre-based materials for technical, high value, high performance products for non-clothing applications at realistic cost, with improved safety and functionality. Demonstrators will be designed to fulfil scalability towards industrial needs . End users from a wide range of industrial sectors (transport, construction, leisure and electronics) will adapt the knowledge gained from the project and test the innovative high added value demonstrators. An in-depth and broad analysis of material development, coupled with related modelling studies, recycling and safety will be conducted in parallel for two types of materials (concepts): • CF-based structures with increased functionality (enhanced mechanical, electrical, thermal properties). • CNF-based structures for flexible electronics applications. Dedicated multiscale modelling, standardisation and production of reference materials are also considered

The Systems ITD will develop and build highly integrated, high TRL demonstrators in major areas such as power management, cockpit, wing, landing gear, to address the needs of future generation aircraft in terms of maturation, demonstration and Innovation.

Air pollution in European cities is still threatening human health, even though EU emission directives have been sharpened over the last 25 years. Adverse health effects of airborne particles are strongly linked to their size. A major fraction of outdoor ultrafine particles is traffic generated from road, rail, air, and sea transportation. The story that nPETS aims to communicate is the life of the sub 100 nm emissions from its creation to its potential path to human beings and animals. The nPETS consortium aims to improve the knowledge of transport generated exhaust and non-exhaust nanoparticle emissions and their impacts on health and new public policies. It aims to monitor and sample with state-of-the-art particle instruments the sub 100 nm transport generated emissions from shipping, road, rail, and aviation both in field and controlled laboratory environments. Both aged and fresh aerosols will be considered, including primary and secondary volatile and non-volatile particles. Characterising the emissions will be done from shipping, road, rail, and aviation by linking their sizes, chemical compositions, and morphologies to its specific emission sources such as engines, brakes, clutches, and tyres to increase the understanding of the mechanisms behind adverse risks posed by different types and sources of the identified sub 100 nm particles. The effects of nanoparticles from various transport modes and fuels, as well as specific emission sources, will be compared with a focus on markers of relevance for carcinogenesis and inflammation. Living cells will be exposed to collected and real-world primary and aged aerosols as well as primary and aged aerosols generated in the laboratory. Furthermore, it also aims to evaluate the possible future impact of new policies in this area on public health and linking the impacts with specific emission sources. This should lead to an understanding and quantification of the risks posed by different types and sources.