DigitalTwin Technology.

We specialize in providing top-notch services for Finite Element Analysis (FEA). With our expertise in this field, we offer comprehensive solutions to analyze and optimize the structural integrity, performance, and reliability of your designs. Our skilled engineers employ advanced FEA software to simulate complex physical behaviors, stress distributions, and deformations in your components or systems. By leveraging the power of FEA, we can assist you in making informed design decisions, identifying potential weaknesses, and optimizing your product's performance while minimizing risks. With our accurate and reliable FEA services, you can enhance the efficiency, durability, and safety of your designs, ensuring superior quality and customer satisfaction.

We have expertise in providing comprehensive services for physics-based digital twins. Using our deep expertise in physics modeling, simulation, and data integration, we create highly accurate virtual replicas of physical systems. Our physics-based digital twins enable real-time monitoring, predictive analysis, and optimization for various industries, including manufacturing, energy, and transportation. By leveraging advanced computational physics techniques, we empower organizations to gain valuable insights, optimize performance, and minimize risks. Our tailored solutions help improve operational efficiency, asset reliability, and decision-making processes. With us you can harness the power of physics-based digital twins to unlock new levels of productivity, innovation, and competitiveness.

We specialize in offering comprehensive services for factory digital twins. With our expertise in industrial automation, data integration, and advanced analytics, we create virtual replicas of manufacturing facilities that enable real-time monitoring and optimization. Our factory digital twins provide invaluable insights into production processes, equipment performance, and resource utilization. By leveraging this technology, businesses can identify bottlenecks, optimize workflows, and enhance overall efficiency. Our tailored solutions cater to specific industry needs, allowing organizations to simulate scenarios, test new strategies, and make data-driven decisions. With [Company Name], you can unlock the potential of your factory and pave the way for enhanced productivity, cost savings, and competitive advantage.

We offer comprehensive services for construction digital twins, revolutionizing the way projects are planned, executed, and managed. Leveraging advanced technologies like Building Information Modeling (BIM) and 3D visualization, we create accurate virtual replicas of construction projects. Our construction digital twins provide real-time monitoring, predictive analytics, and clash detection, enabling stakeholders to optimize workflows, mitigate risks, and streamline collaboration. From design validation to construction simulation, our tailored solutions empower project teams to visualize and analyze every aspect of the project, enhancing efficiency, reducing costs, and ensuring successful project outcomes.

We specialize in providing exceptional services for the creation of Building Information Modeling (BIM) for buildings, tunnels, and bridges. With our expertise in architecture, engineering, and construction, we offer comprehensive solutions for developing accurate and detailed BIM models. Our skilled team utilizes advanced software and techniques to capture every aspect of the project, including structural elements, architectural features, systems, and infrastructure. By creating intelligent BIM models, we enable seamless collaboration, clash detection, and enhanced visualization for effective design coordination and construction planning. Our tailored BIM services empower clients to optimize project efficiency, mitigate risks, and achieve superior outcomes for buildings, tunnels, and bridges projects.

We specialize in providing exceptional services for setting up construction IoT platforms. Leveraging the power of Internet of Things (IoT) technologies, we enable seamless connectivity and real-time data exchange across construction projects. Our experienced team assists in designing and implementing robust IoT infrastructure, integrating sensors, devices, and networks to capture valuable data from construction sites. By setting up an IoT platform, we empower clients to monitor equipment performance, track resource utilization, enhance safety measures, and optimize workflows. Our tailored solutions enable data-driven decision-making, predictive analytics, and remote monitoring, enhancing project efficiency, productivity, and overall project success. With us, unlock the potential of construction IoT for improved project outcomes.

ASHVIN aims at enabling the European construction industry to significantly improve its productivity, while reducing cost and ensuring absolutely safe work conditions, by providing a proposal for a European wide digital twin standard, an open source digital twin platform integrating IoT and image technologies, and a set of tools and demonstrated procedures to apply the platform and the standard proven to guarantee specified productivity, cost, and safety improvements.

IMOCO4.E targets to provide vertically distributed edge-to-cloud intelligence for machines, robots and other human in-the-loop cyber-physical systems having actively controlled moving elements. They face ever-growing requirements on long-term energy efficiency, size, motion speed, precision, adaptability, self-diagnostic, secure connectivity or new human-cognitive features.

DIDYMOS-XR will research and develop robust and scalable methods for 3D scene reconstruction from heterogeneous cameras and sensor data (e.g., lidar), integrating data captured at different times and under different environmental conditions and creating accurate maps of the scene.

MASTERMINE aspires to become the go-to ecosystem for mines that envision digitalisation, environmental sustainability, productivity monitoring and public acceptance within their strategic goals. The focus will be on an Industrial Metaverse (IM) approach to build a digitalized copy of a real-world mine.

CIRCUIT aims at fostering circular, smart, resilient, and sustainable transport infrastructures and facilitating wider deployment of GPP and IP in the EU. Holistic approach to foster CIRCUlar and resilient transport InfrasTructures and support the deployment of Green and Innovation Public Procurement and innovative engineering practices.

The RoBétArmé project aims toward a step-change in the Construction 4.0 by automating particularly laborious construction tasks in all phases of shotcrete application. RoBétArmé is a Research and Innovation Action (RIA) project, funded by the European Commission under the Horizon program and will have a duration of 42 months.

SCENE project will combine cutting-edge technology with a commitment to social responsibility and sustainability. From AI-based audience scouting, distribution mechanisms, and blockchain for IPR protection to 3D representations of monuments, the project is revolutionizing the industry while respecting the values of the European Bauhaus.

The ENERGENIUS project provides an innovative pathway dedicated to cultivating an inclusive, community-driven energy transition, underpinned by the ethos of 'Leave No One Behind.' At its heart is the ENERGENIUS Suite, a comprehensive, one-stop-shop digital platform providing a wide range of interlinked services, including digital twin models, serious games, cross-sectoral dashboards, marketplace and AI-driven recommendations. This robust ecosystem amalgamates data across various sectors—from energy, healthcare, and finance to traffic, social media, real estate, and tourism—delivering customized, AI-powered solutions for energy efficiency. By harnessing the collective intelligence of its community, ENERGENIUS not only offers personalized energy-saving advice but also reciprocally enriches multiple sectors. Upholding the highest standards in interoperability and privacy-by-design, ENERGENIUS is establishing new milestones for secure, seamless cross-sectoral data exchange.

DISCOVER aims to develop an autonomous, synchronous, continuous and intelligent identification and data analysis system for materials and products in existing end-of-life built works. The proposed approach will provide key stakeholders, including academia research performers, along with construction industry representatives, with data-driven insights to make deconstruction more efficient, optimise the use of resources, improve the environmental footprints and enhance the circularity of construction and demolition, unlocking the potential of end-of-life built works, which will become material banks. The expected outcomes include an autonomous robotic platform coupled with continuous identification tools to scan built works and provide synchronous quantitative and qualitative data from different materials, including complex and concealed elements. Artificial intelligence algorithms will allow a rapid analysis of the properties and characteristics of components, and feed the automated scan-to-BIM model creation.

Europe’s mining industry is struggling to recover critical raw materials (CRMs) from increasingly complex and lower quality ores. These materials are essential for many technologies, but the extraction process is becoming increasingly inefficient and unsustainable. There is a growing need for better solutions to make mining more environmentally friendly and cost-effective. Without improvement, Europe risks shortages of key materials. In this context, the EU-funded OPTIMINER project steps in as a game-changer. By integrating advanced technologies, digital tools and sustainability strategies, it aims to help the mining industry recover CRMs more efficiently. With pilot projects across Europe and Chile, OPTIMINER aims to transform the industry and also promote international collaboration.

In the face of a rapidly advancing digital healthcare terrain, the DTRIP4H project emerges as a momentous effort to revolutionize predictive, preventive, personalized, and participatory health paradigms within the EU. Amid significant incidence of chronic conditions and cancer, there is a pressing need for a proactive shift in health strategies. Yet, the full potential of European research infrastructures (RIs) is curtailed by investment deficits, fragmentation, and the intricacies of data management. Digital Twin (DT) technology introduces a new age of precision by enabling sophisticated simulations and analyses of intricate biological processes. In DTRIP4H, we start a new initiative in Europe “decentralized health digital twin ecosystem consisting of RIs”. Using DTs, we aim to resolve critical challenges around data harmonization, equitable access, and stringent privacy safeguards. Incorporating technologies such as federated learning, Generative AI, and Virtual Reality (VR), the project aspires to create a decentralized digital twin environment (DDTE). This will empower both internal and external RI users, such as researchers, innovators, and SMEs, to craft DT applications that address specific scientific challenges, utilizing a blend of real-world and synthetic data in compliance with regulatory frameworks, i.e. GDPR. We will develop 7 innovative proof of concept thematic health-related Use cases fulfilling the needs of scientists, SMEs, and industrial end users, particularly in health topics related to cancer treatment, drug development, human environmental exposome, precision treatment for schizophrenia and personalized medicine through Artificial Intelligence (AI), AR/VR empowered DTs utilizing DDTE, while adhering to FAIR data principles. DTRIP4H adopts a human-centric methodology to elevate research efficacy, narrow the skills gap, and align with the objectives of the European Research Area (ERA) and the Sustainable Development Goals (SDGs) by 2030.

Additive Manufacturing (AM) is replacing current production methods as it allows complex geometry parts manufacture for different industries, offering potential benefits in terms of weight, functionality, lead time and manufacturability. The obtained components need however to go through a number of postprocessing steps to guarantee final requirements fulfilment, for example in terms of corrosion protection. This postprocessing, which is often not considered when designing the AM process, has a significant impact on the final cost, thus preventing a higher market penetration of AM.
The BOOST3DMETAL project aims to boost metal AM and specifically Powder-Bed-Fusion (PBF) technology through the development and validation of:

• Design, manufacturing, and post-processing guides and assessment tools to allow producing optimised 3D geometry components made with innovative light alloys, which meet the Transport sector requirements; and
• customised surface treatments able to treat non-homogeneous and complex AM surfaces in a synchronous way.

The project and consortium cover the entire AM manufacturing process chain and the contribution of each partner is described below:

• Fraunhofer IAPT enables sustainable innovations in Additive Manufacturing. It adopts a holistic view, considering all aspects of the AM process chain from end to end. The institute will develop guidelines and a tool for the design and fabrication of AM parts, integrating post-processing considerations from the start.
• OPTIMUS 3D will contribute to the project with its capacities and knowledge in AM parts design and manufacturing. Additionally, OPTIMUS3D will provide the perspective and the industrial focus of a company fully focused on AM parts design and manufacturing and will validate the guidelines developed by Fraunhofer IAPT.
• DigitalTwin Technology GmbH will develop an advanced image software based on finite element analysis for surface quality assessment.
• Kripton will develop special chemical products adapted for the surface treatments of AM parts.
• ELHCO is the Project Coordinator and will be in charge of validating customised surface treatments for AM-made light alloys parts.
• CIDETEC Surface Engineering will support the three Spanish partners on the development of the surface treatments and will actively participate in the surface characterization tasks throughout the project using its advanced characterization equipment.