MEDLOC aims at the employment of multi-material 3D printing technologies for the large-scale fabrication of microfluidic MEMS for lab-on-a-chip and sensing applications. The concept is based on the combination of multimaterial direct-ink-writing method and an extrusion-based 3D printing pilot line, in order to fabricate microstructured detection devices with the ability to perform all steps of chemical analysis in an automated fashion. The functionality of these devices will be evaluated based on their ability to streamline all steps needed to obtain mobility and binding-based identity information in one continuous biochemical detection system. Optimum in-line control systems will be incorporated in various stages of the fabrication process, to achieve precise control and repeatability. Microfluidic MEMS are increasingly recognized as a unique technology field for the development of biomedical devices (BioMEMS), due to their functional performance on the microscale, at the dimensions of which most physiological processes are operative. Applications near micro- and nanoscale are promising in the field of intelligent biosensors, where it enables the monolithic integration of sensing devices with intelligent functions like molecular detection, signal analysis, electrical stimulation, data transmission, etc., in a single microchip.

Smartfan aims at the micro and Nano components, which will be used due to their special physico-chemical properties, in order to develop smart (bulk) materials for final application on intelligent structures. CFs for reinforcement and conductivity variance, CNTs and CNFs for sensing, Micro-containers for self-healing, Electro-Magnetic nanoparticles for fields detection and shielding, colouring agents for marking cracks and defects, piezoelectric materials can be the base for manufacturing new smart materials. In order to develop lightweight composite materials and transfer the properties of smart components into bulk materials polymer based matrices, such as Epoxy, PEEK, PVDF etc., will be used because of their compatibility with the above mentioned components, their low cost and their recyclability/reusability. During synthesis of composite bulk materials several processes should take place in order to preserve the special physico-chemical properties of composites and to achieve the best dispersion in the bulk.

FREEWAT aims at promoting water management and planning by simplifying the application of the Water Framework Directive and other EU water related Directives. FREEWAT will be an open source and public domain GIS integrated modelling environment for the simulation of water quantity and quality in surface water and groundwater with an integrated water management and planning module. Specific objectives of the FREEWAT project are: - to coordinate previous EU and national funded research to integrate existing software modules for water management in a single environment into the GIS based FREEWAT; - to support the FREEWAT application in an innovative participatory approach gathering technical staff and relevant stakeholders (in primis policy and decision makers) in designing scenarios for the proper application of water policies. FREEWAT will initiate a process aimed at filling the gap between EU and US on widespread-standardised ICT tools and models for management of water quantity and quality and will set a well recognisable and flagship initiative. The open source characteristics of the platform allow to consider this an initiative "ad includendum" (looking for inclusion of other entities), as further research institutions, private developers etc. may contribute to the platform development. Through creating a common environment among water research/professionals, policy makers and implementers, FREEWAT main impact will be on enhancing science- and participatory approach and evidence-based decision making in water resource management, hence producing relevant and appropriate outcomes for policy implementation. The Consortium is constituted by partners from various water sectors from 11 EU countries, plus Switzerland, Turkey and Ukraine. Synergies with the UNESCO HOPE initiative on free and open source software in water management greatly boost the value of the project. Large stakeholders involvement guarantees results dissemination and exploitation.

The project aims at the development of innovative reclamation and repurposing routes for end-of-life plastic and carbon fibre reinforced polymer (CFRP) components. This will be achieved by employing advanced nanotechnology solutions, Additive Manufacturing (AM) and recycled resources, for the production of high added value 3D printed products with advanced functionalities. In this way, the combination of AM, polymer processing and recycling technologies could constitute a new paradigm of a distributed recycling process, easily implemented at local scale in collaboration with the industrial sector and collection facilities, in order to create competitive, highly customisable products at lower production costs, in a flexible digital environment that fully unravels the potential of eco-design and allows for integration of smart intrinsic self-sensing, self-repairing and recycling options. The project aims to address all aspects and stages of thermoplastic and CF reinforced thermoplastic 3D printing material development from recycled resources, starting with the selection of suitable waste streams, strategies for material repair, compatibilization and upgrade towards AM processing, compatibility between different thermoplastic matrices and the reinforcing fibres and nanoparticles, comparative assessment of various AM thermoplastic processing technologies and closed-loop material optimisation in terms of processability and performance.

In the context of industrialization, informatization and sustainable development of the mining sector, Mine.io solution will build a novel mining digital ecosystem and a systemic structure for the implementation of Industry 4.0 in mining industrial environments. Mine.io solution will embrace the whole mining value chain from resources’ exploration, extraction, and processing to waste management and post mining activity. Our fundamental concept is the provision of a manufacturing system architecture, under cloud environment, to be applied in the digital twin mining “shop floor”. Mine.io envisions an innovative cloud services system and a novel mining ecosystem of sharing, interconnection, and open cooperation. Mine.io will establish a unified data infrastructure and collaborative platform ecosystem to promote the openness and sharing of data and improve the cooperation environment between mining enterprises. Mine.io aims the enhanced systematization of the basic processes of the mining industry, that involve asset and process equipment optimization, through embedded predictive analytics, and optimization procedures based on completely data-driven processes and the integrated cyber-virtual and cyber-physical systems, automation and robotization of mining exploration and production processes, sustainable mining, and post mining management. To meet the increasing social and environmental concerns, Mine.io will enable a resource optimization and digital transformation framework, embedding specific circular economy and “low-impact mining” strategies. Energy innovations, including the transition to autonomous electric vehicles, will lead to socially conscious profit, while creating a safer and cleaner environment for front-line workers, including higher air quality for those working underground. Mine.io ecosystem will be validated in different demonstration sites, involving 4 operational mine facilities and 2 historic mine sites, in 5 EU countries.