Summary
Buildings wield substantial influence on the environment, accounting for a hefty 30% of global energy usage and a consequential 19% of greenhouse gas emissions. To combat this looming crisis, the Net-Zero Energy Building (NZEB) concept emerges as a transformative paradigm shift in the world of construction.
In the midst of this environmental renaissance, a digital revolution sweeps across manufacturing, presenting a tantalizing prospect of reducing embodied CO2 and enhancing thermal control. Yet, a considerable chasm separates these cutting-edge digital technologies from structures crafted from sustainable materials. The intricacies of computational and algorithmic design struggle to encapsulate the rich tapestry of Nature multi-scale marvels, the very essence of this green metamorphosis. Bridging this gap could boost digital fabrication to a mass production system, but issues include the complexity of multi-scale modeling, reliability uncertainties, technical limitations in 3D printing, and poor solution versatility.
PANTAREI project addresses all these challenges by implementing a revolutionary adaptive intelligent computational irreversible thermodynamics paradigm to design and assess novel bio-waste-derived meta-structures for the reduction of embodied CO2 in buildings. PANTAREI over-arching aim is to extend the capabilities of current computational tools for material design, by developing adaptive solutions based on the intertwining of virtual physics of failure and non-equilibrium thermodynamics principles for the bio-waste multi-scale meta-structure design and tailored realization through the entire structure life-cycle with a human-centered perspective.
This could be materialised only with the aid of a multi-disciplinary stakeholder coalition, which involves renowned universities and companies, leaders in computational/digital design of multi-scale meta-structures and sustainable manufacturing.
In the midst of this environmental renaissance, a digital revolution sweeps across manufacturing, presenting a tantalizing prospect of reducing embodied CO2 and enhancing thermal control. Yet, a considerable chasm separates these cutting-edge digital technologies from structures crafted from sustainable materials. The intricacies of computational and algorithmic design struggle to encapsulate the rich tapestry of Nature multi-scale marvels, the very essence of this green metamorphosis. Bridging this gap could boost digital fabrication to a mass production system, but issues include the complexity of multi-scale modeling, reliability uncertainties, technical limitations in 3D printing, and poor solution versatility.
PANTAREI project addresses all these challenges by implementing a revolutionary adaptive intelligent computational irreversible thermodynamics paradigm to design and assess novel bio-waste-derived meta-structures for the reduction of embodied CO2 in buildings. PANTAREI over-arching aim is to extend the capabilities of current computational tools for material design, by developing adaptive solutions based on the intertwining of virtual physics of failure and non-equilibrium thermodynamics principles for the bio-waste multi-scale meta-structure design and tailored realization through the entire structure life-cycle with a human-centered perspective.
This could be materialised only with the aid of a multi-disciplinary stakeholder coalition, which involves renowned universities and companies, leaders in computational/digital design of multi-scale meta-structures and sustainable manufacturing.
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More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/101161602 |
Start date: | 01-10-2024 |
End date: | 30-09-2028 |
Total budget - Public funding: | 3 085 000,00 Euro - 3 085 000,00 Euro |
Cordis data
Original description
Buildings wield substantial influence on the environment, accounting for a hefty 30% of global energy usage and a consequential 19% of greenhouse gas emissions. To combat this looming crisis, the Net-Zero Energy Building (NZEB) concept emerges as a transformative paradigm shift in the world of construction.In the midst of this environmental renaissance, a digital revolution sweeps across manufacturing, presenting a tantalizing prospect of reducing embodied CO2 and enhancing thermal control. Yet, a considerable chasm separates these cutting-edge digital technologies from structures crafted from sustainable materials. The intricacies of computational and algorithmic design struggle to encapsulate the rich tapestry of Nature multi-scale marvels, the very essence of this green metamorphosis. Bridging this gap could boost digital fabrication to a mass production system, but issues include the complexity of multi-scale modeling, reliability uncertainties, technical limitations in 3D printing, and poor solution versatility.
PANTAREI project addresses all these challenges by implementing a revolutionary adaptive intelligent computational irreversible thermodynamics paradigm to design and assess novel bio-waste-derived meta-structures for the reduction of embodied CO2 in buildings. PANTAREI over-arching aim is to extend the capabilities of current computational tools for material design, by developing adaptive solutions based on the intertwining of virtual physics of failure and non-equilibrium thermodynamics principles for the bio-waste multi-scale meta-structure design and tailored realization through the entire structure life-cycle with a human-centered perspective.
This could be materialised only with the aid of a multi-disciplinary stakeholder coalition, which involves renowned universities and companies, leaders in computational/digital design of multi-scale meta-structures and sustainable manufacturing.
Status
SIGNEDCall topic
HORIZON-EIC-2023-PATHFINDERCHALLENGES-01-02Update Date
19-09-2024
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