Under the scientific direction of Graz University of Technology, an Austrian consortium is working on new investigation methods for rapid and precise assessments of concrete structures.
Whether crumbling tunnel walls, cracks in concrete facades or porous bridge piers, according to statistics from the National Association of Corrosion Engineers (NACE), damage to concrete structures caused by various environmental influences accounts for several billion euros worldwide every year.
In close cooperation with the Austrian Society for Construction Technology (ÖBV) researchers at TU Graz want to contribute to the solution of this global and problem.
In the LumAConM (high-resolution luminescent analyses of construction materials) project, the consortium is working on a new, simple and cost-effective method that enables a detailed assessment of the condition of concrete structures on site as well as laboratory measurements with unprecedented precision for the first time.
This enables the service life, as well as any problem areas, to be assessed much more quickly and precisely than is possible with currently available methods of analysis. The researchers also hope that the new method will provide them with a better understanding of the course of essential corrosion processes.
"This knowledge enables targeted and cost-effective refurbishment and is essential for the development of new, sustainable and durable materials," explains Florian Mittermayr, researcher at the Institute of Technology and Testing of Construction Materials at TU Graz.
Innovative sensor material as basis
Optical-chemical sensor technology forms the basis for the new process. This highly advanced, optical measurement analysis has so far been used primarily in biotechnology and medical technology.
"We now want to use the tool to assess the condition of concrete infrastructure and thus develop a completely new generation of sensors for the construction industry," says Bernhard Müller, chemist at the Institute of Analytical Chemistry and Food Chemistry.
An example of this is an imaging measurement system implemented at TU Graz for the quantitative determination of the pH value in cement-based materials – a parameter that usually correlates directly with corrosion damage. The measuring system consists of a plastic film with a swellable (i.e. water-absorbent) polymer layer containing an indicator dye and a reference dye.
The size of the sensor foil can be adapted to the size of the sample to be examined. The wet film is applied to the sample and the pH distribution images are then generated with the aid of a special camera.
This technique has already been able to detect changes in the pH value in various building materials very accurately and to characterise corrosion damage in great detail. In the LumAConM project, the measurement system is now to be further developed by the end of 2022 and will result in a versatile measurement technology.
Extensive application possibilities
On the one hand, the researchers want to expand the measuring system to include other parameters, such as chloride. This would enable for the first time the combined determination of chloride concentration and pH directly on site at concrete structures. Chloride attacks, caused for example by road salt in winter, pose a considerable risk of corrosion for concrete structures (especially for bridges) and are one of the most frequent causes of corrosion worldwide.
On the other hand, the sensor material developed for the films is also to be transferred to other sensor formats. For uneven concrete surfaces, for which the films are not suitable, the team would like to use sprayable sensor particles and thus make the imaging technology available for the common practice of exposing underlying structures on site.
At present, the condition is assessed by means of core sampling and complex chloride determination by chloride titration. The researchers also plan to make miniaturized probes based on optical fibers.
This would not only enable measurements to be taken on the concrete surface, but would also allow depth profiles to be easily created using drill holes.
Cyrill Grengg from the Institute of Applied Geosciences at TU Graz confirms the enormous potential of the measurement technology: "I think that in the medium to long term, the procedure can replace other, more expensive and more complex investigation methods to a large extent and make quality management in concrete construction much easier."
The engineering sector project LumAConM submitted by the Austrian Society for Construction Technology (ÖBV) is funded in the framework of the Collective Research programme supported by the Austrian Research Promotion Agency (FFG).
The project results are available to the entire Austrian construction and concrete industry in line with the funding scheme. LumAConM is anchored in the Fields of Expertise "Advanced Materials Science" (https://www.tugraz.at/en/research/fields-of-expertise/advanced-materials-science...) and "Sustainable Systems" (https://www.tugraz.at/en/research/fields-of-expertise/sustainable-systems/overvi...), two of the five strategic research core areas of TU Graz.
TU Graz: Institute of Analytical Chemistry and Food Chemistry (ACFC); Institute of Applied Geosciences (IAG); Institute of Technology and Testing of Construction Materials (IMBT)
Austrian Society for Construction Technology (ÖBV)
ÖBB Infrastruktur AG
ASFiNAG Bau Management GmbH
Linz Service GmbH
Wiener Linien GmbH
Holding Graz AG
Energie Steiermark AG
Verband Österreichischer Beton und Fertigteilwerke (VÖB)
PyroScience AT GmbH
Materialprüfanstalt Hartl GmbH
Nievelt Labor GmbH
Bautechnische Versuchsanstalt HTL Rankweil
Palfinger Structural Inspection GmbH
Vermessung ADP Rinner
Dr.rer.nat. BSc MSc
TU Graz | Institute of Applied Geosciences
Phone +43 316 873 6366 | e-mail email@example.com
TU Graz | Institute of Technology and Testing of Construction Materials
Tel.: +43 316 873 7159 | E-Mail: firstname.lastname@example.org
Dr.techn. BSc MSc
TU Graz | Institute of Analytical Chemistry and Food Chemistry
Tel.: +43 316 873 32518 | E-Mail: email@example.com
https://www.tugraz.at/institute/imbt-tvfa/home/ (TU Graz | Institute of Technology and Testing of Construction Materials)
https://www.tugraz.at/institute/acfc/home/ (TU Graz | Institute of Analytical Chemistry and Food Chemistry)
https://www.tugraz.at/institutes/iag/home/ (TU Graz | Institute of Applied Geosciences)
https://www.ffg.at/en/node/96200 (Collective Research Programme FFG)
https://www.bautechnik.pro/EN/News (Austrian Society for Construction Technology)
Mag. Christoph Pelzl, MSc | Technische Universität Graz
The digital construction site: A smarter way of building with mobile robots
02.06.2020 | Fraunhofer Italia
Double helix of masonry -- Researchers discover the secret of Italian renaissance domes
18.05.2020 | Princeton University, Engineering School
Kiel physics team observed extremely fast electronic changes in real time in a special material class
In physics, they are currently the subject of intensive research; in electronics, they could enable completely new functions. So-called topological materials...
Solar cells based on perovskite compounds could soon make electricity generation from sunlight even more efficient and cheaper. The laboratory efficiency of these perovskite solar cells already exceeds that of the well-known silicon solar cells. An international team led by Stefan Weber from the Max Planck Institute for Polymer Research (MPI-P) in Mainz has found microscopic structures in perovskite crystals that can guide the charge transport in the solar cell. Clever alignment of these "electron highways" could make perovskite solar cells even more powerful.
Solar cells convert sunlight into electricity. During this process, the electrons of the material inside the cell absorb the energy of the light....
Empa researchers have succeeded in applying aerogels to microelectronics: Aerogels based on cellulose nanofibers can effectively shield electromagnetic radiation over a wide frequency range – and they are unrivalled in terms of weight.
Electric motors and electronic devices generate electromagnetic fields that sometimes have to be shielded in order not to affect neighboring electronic...
A promising operating mode for the plasma of a future power plant has been developed at the ASDEX Upgrade fusion device at Max Planck Institute for Plasma...
Live event – July 1, 2020 - 11:00 to 11:45 (CET)
"Automation in Aerospace Industry @ Fraunhofer IFAM"
The Fraunhofer Institute for Manufacturing Technology and Advanced Materials IFAM l Stade is presenting its forward-looking R&D portfolio for the first time at...
07.07.2020 | Event News
02.07.2020 | Event News
19.05.2020 | Event News
07.07.2020 | Life Sciences
07.07.2020 | Life Sciences
07.07.2020 | Life Sciences