Energy-saving potential of 3D printed concrete building with integrated living wall

Abstract Large-scale concrete 3D printing and digital construction has brought enormous potential to expand the design space of building components (e.g., building envelope) for the integration of multiple architectural functionalities including energy saving. In this research, a modular 3D printed vertical concrete green wall system – namely the 3D-VtGW, was developed. The 3D-VtGW envelope was assembled with prefabricated (3D printed) multifunctional wall modular elements, which serves as the enclosure of the building as well as the backbone for a green wall system to improve building’s energy efficiency. Using this design concept and large-scale concrete 3D printing, a prototype commercial building was built in Nanjing, China. To quantify the energy-saving potential of the 3D-VtGW system, a thermal network model was developed to simulate the thermal behavior of buildings with 3D-VtGW system and for thermal comfort analysis. Whole-building energy simulation was carried out using Chinese Standard Weather Data (CSWD) of Nanjing, China. The simulation results indicate that the building with 3D-VtGW exhibited prominent potential for energy saving and improved thermal comfort. The integrated greenery system in 3D-VtGW largely reduces wall exterior surface temperature and through-wall heat flux via the combined effects of plant shading, evapotranspiration, and heat storage from soil. This study presents the immense opportunities brought by digital fabrication and construction to extend the design space and function integration in buildings.

[1]  Clément Gosselin,et al.  Large-scale 3D printing of ultra-high performance concrete – a new processing route for architects and builders , 2016 .

[2]  Martin Skitmore,et al.  Three-dimensional printing in the construction industry: A review , 2015 .

[3]  P. Jones,et al.  Temperature decreases in an urban canyon due to green walls and green roofs in diverse climates , 2008 .

[4]  P. C. Tabares-Velasco,et al.  A heat transfer model for assessment of plant based roofing systems in summer conditions , 2012 .

[5]  A. Kashani,et al.  Additive manufacturing (3D printing): A review of materials, methods, applications and challenges , 2018, Composites Part B: Engineering.

[6]  Kasun Hewage,et al.  Lifecycle assessment of living walls: air purification and energy performance , 2014 .

[7]  Freek Bos,et al.  Early age mechanical behaviour of 3D printed concrete: Numerical modelling and experimental testing , 2018 .

[8]  Lonnie J. Love,et al.  Additive Manufacturing Integrated Energy—Enabling Innovative Solutions for Buildings of the Future , 2017 .

[9]  Kah Fai Leong,et al.  3D printing trends in building and construction industry: a review , 2017 .

[10]  Eric Courteille,et al.  Underwater 3D printing of cement-based mortar , 2019, Construction and Building Materials.

[11]  Virginia Stovin,et al.  Green roofs; building energy savings and the potential for retrofit , 2010 .

[12]  S. Wilkinson,et al.  Attenuating heat stress through green roof and green wall retrofit , 2018, Building and Environment.

[13]  J. Deardorff Efficient prediction of ground surface temperature and moisture, with inclusion of a layer of vegetation , 1978 .

[14]  Ali Nazari,et al.  Mechanical properties of layered geopolymer structures applicable in concrete 3D-printing , 2018, Construction and Building Materials.

[15]  Clément Gosselin,et al.  Large-scale 3D printing with a cable-suspended robot , 2015 .

[16]  João Castro-Gomes,et al.  Green wall systems: A review of their characteristics , 2015, Renewable and Sustainable Energy Reviews.

[17]  Kuppusamy Vijayaraghavan,et al.  Green roofs: A critical review on the role of components, benefits, limitations and trends , 2016 .

[18]  A.H.C. van Paassen,et al.  Modelling the double skin façade with plants , 2005 .

[19]  Nannan Dong,et al.  An investigation on the thermal and energy performance of living wall system in Shanghai area , 2017 .

[20]  L. Cabeza,et al.  Green vertical systems for buildings as passive systems for energy savings , 2011 .

[21]  Guowei Ma,et al.  A critical review of preparation design and workability measurement of concrete material for largescale 3D printing , 2018 .

[22]  Freek Bos,et al.  Additive manufacturing of concrete in construction: potentials and challenges of 3D concrete printing , 2016, International Journal of Civil Engineering and Construction.

[23]  Fabio Favoino,et al.  Design and control optimisation of adaptive insulation systems for office buildings. Part 2: A parametric study for a temperate climate , 2017 .

[24]  Cheuk Lun Chow,et al.  Studying the potential of energy saving through vertical greenery systems: Using EnergyPlus simulation program , 2017 .

[25]  Mostafa Refat Ismail,et al.  Quiet environment: Acoustics of vertical green wall systems of the Islamic urban form , 2013 .

[26]  Marjorie Musy,et al.  A hydrothermal model to assess the impact of green walls on urban microclimate and building energy consumption , 2014 .

[27]  Celina Filippín,et al.  Modeling double skin green façades with traditional thermal simulation software , 2015 .

[28]  Fabio Peron,et al.  Modeling the energy performance of living walls: Validation against field measurements in temperate climate , 2014 .

[29]  Michael Maks Davis,et al.  The potential for vertical gardens as evaporative coolers: An adaptation of the ‘Penman Monteith Equation’ , 2015 .

[30]  Hongyu Zhou,et al.  3-D printing of concrete: Beyond horizons , 2020 .

[31]  Neil Leach,et al.  3D Printing in Space , 2014 .

[32]  Ji Hun Park,et al.  Novel proposal to overcome insulation limitations due to nonlinear structures using 3D printing: Hybrid heat-storage system , 2019, Energy and Buildings.

[33]  Muhammad Shafique,et al.  Green roof benefits, opportunities and challenges – A review , 2018, Renewable and Sustainable Energy Reviews.

[34]  Freek Bos,et al.  Rethinking reinforcement for digital fabrication with concrete , 2018, Cement and Concrete Research.

[35]  Moncef Krarti,et al.  Control strategies for dynamic insulation materials applied to commercial buildings , 2017 .

[36]  Geert De Schutter,et al.  Vision of 3D printing with concrete — Technical, economic and environmental potentials , 2018, Cement and Concrete Research.

[37]  James E. Braun,et al.  A general approach for generating reduced-order models for large multi-zone buildings , 2015 .

[38]  Q. Meng,et al.  Thermal behavior of a vertical green facade and its impact on the indoor and outdoor thermal environment , 2019 .

[39]  Chi Yung Jim,et al.  Greenwall classification and critical design-management assessments , 2015 .

[40]  Abdul Hakim Mohammed,et al.  Green retrofitting – A review of current status, implementations and challenges , 2017 .

[41]  David J. Sailor,et al.  A green roof model for building energy simulation programs , 2008 .

[42]  Cheuk Lun Chow,et al.  Comparing reduction of building cooling load through green roofs and green walls by EnergyPlus simulations , 2018 .

[43]  Lex Reiter,et al.  The role of early age structural build-up in digital fabrication with concrete , 2018, Cement and Concrete Research.

[44]  Olivier Baverel,et al.  Classification of building systems for concrete 3D printing , 2017 .

[45]  Yiwei Weng,et al.  Mixture Design Approach to optimize the rheological properties of the material used in 3D cementitious material printing , 2019, Construction and Building Materials.

[46]  Tobias Armborst,et al.  Architecture Takes Time , 2016 .

[47]  R. Belarbi,et al.  Characterization of green roof components: Measurements of thermal and hydrological properties , 2012 .

[48]  T. T. Le,et al.  Mix design and fresh properties for high-performance printing concrete , 2012 .