contents | technologies | |||||||||
| RCC2 research project The Austrian research study RCC2 (reduced carbon concrete) investigated the potential of innovative concrete mix designs to decarbonise concrete. The broad-based consortium tested ways of establishing CO2-reduced and even climate-neutral concrete as the new state of the art. In the RCC2 research project, a unique consortium consisting of STRABAG Real Estate, Doka, Romm ZT, Mischek ZT, bauXund, CarStorCon Technologies, MPA Hartl and the concrete manufacturers Asamer, Holcim and Wopfinger worked closely together. Their common goal is to overcome the technical, legal and economic hurdles of establishing CO2-reduced concrete as the new state of the art and to open the way for this climate-friendly building material on Austria's construction sites. In the previous RCC (reduced carbon concrete) project back in 2021, the consortium investigated the practical use of clinker-reduced concrete mixes on construction sites. Compared to standard concrete, these RCC concretes have a significantly smaller carbon footprint, but still have one disadvantage: they take longer to harden, especially at low outside temperatures. In practice, this leads to longer construction times and higher costs, as striking the formwork, for example, may be delayed and the formwork material is therefore in use on the construction site for longer. Focus on life cycle assessment The current study therefore focuses on building a functional prototype of an intelligently heated formwork developed by Doka. This should compensate for the delayed strength development of RCC concretes at low ambient temperatures. Electric heating of the formwork also consumes energy, the production of which in turn emits CO2 – something the project participants are aware of. This apparent conflict can be neutralised through the use of electricity from renewable energy and the smart use of heating for the component. Assessing the life cycle of heatable moulds for clinker-reduced concrete is therefore an important key in evaluating the sustainability and sensible use of innovative RCC formulations. In this cooperation project, research was also conducted into how these innovative concrete formulations can be developed to be even more climate-friendly by adding technical carbon based on biochar. Extensive series of tests The project team carried out extensive test series that simulated both summer and winter conditions. Each test series comprised floor and wall elements with 3 different mix designs: a standard concrete (as a reference), a CO2-reduced concrete mix design (RCC2) and a CO2-reduced concrete mix design with technical carbon (RCC2+). All components were monitored in the laboratory in accordance with the relevant standards, and their temperature development was documented using Doka's Concremote concrete monitoring system. This enabled the project partners to draw conclusions about the strength development of the individual mixtures at any time. Important contribution to the establishment of CO2-reduced concrete The starting point for the winter tests the consortium carried out are the reference values from the summer series: Here, all the concrete mix designs tested achieved the required strength for stripping the formwork after 24 hours. Due to the delayed strength development of RCC concretes, one component per mix design with – and one component without – heated formwork was constructed in the winter test. The tests clearly show that in the winter tests with low ambient temperatures, heated formwork proved to be crucial in order to support the strength development of the RCC mixes and also to avoid the damage to the concrete components that would have occurred due to the temperature conditions below zero degree Celsius. Furthermore, now it is evident that clinker-reduced concrete, especially when technical carbon is added, has the potential to significantly improve the carbon footprint of concrete. For example, with the RCC2+ concrete mix (with technical carbon), the CO2 savings potential compared to the reference concrete is around 80% for ceilings (without heating). At winter temperatures with the support of a heated formwork, the potential CO2 reduction of RCC2+ is still 67%. The tests with the functional prototype of an intelligently heated formwork from Doka create an important perspective for an industry-wide use of CO2-reduced and climate-neutral concrete regardless of temperature, construction site conditions and, depending on construction progress, also while maintaining the usual demoulding times. SOLEY - Pilot project with RCC concrete in residential construction STRABAG Real Estate is building a pioneering energy and climate showcase with the SOLEY residential project in Vienna's Brigittenau district. CO2-reduced performance concrete is being used for the first time in this new residential building in Leystrasse. In addition, the building is supplied with electricity via a photovoltaic system including battery storage and – thanks to a groundwater heat pump is independent of fossil fuels for heating. Cooperation within the industry Due to its unique structural and physical properties, there will be no way around concrete as a building material in the future. It is equally undisputed that radically reducing the CO2 footprint of concrete is one of the most urgent environmental priorities in the construction sector. Researchers, politicians, and the industry are therefore working on various solutions, such as the reduction of clinker, CO2 cycle processes and carbon capture programmes. The RCC2 research project emphasises the vital importance of collaboration in the construction industry. The results prove that bringing together different experts creates opportunities for innovation in decarbonising this most important building material without compromising on performance. write your comments about the article :: © 2023 Construction News :: home page |