Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing

Concrete with moderate replacement levels of fly ash (FA) has been used for decades and considered sustainable in harsh environments. If the replacement levels become high (FA/C > 40…50%), the range of properties from fresh to hardened, including performance in frost testing give often unfavorabl...

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Published in:Nordic Concrete Research
Main Author: Shpak, Andrei
Other Authors: Jacobsen, Stephan, Scherer, George W.
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: NTNU 2020
Subjects:
VDP::Technology: 500::Building technology: 530::Construction technology: 533
Arctic
Online Access:https://hdl.handle.net/11250/2686408
id ftntnutrondheimi:oai:ntnuopen.ntnu.no:11250/2686408
record_format openpolar
institution Open Polar
collection NTNU Open Archive (Norwegian University of Science and Technology)
op_collection_id ftntnutrondheimi
language English
topic VDP::Technology: 500::Building technology: 530::Construction technology: 533
spellingShingle VDP::Technology: 500::Building technology: 530::Construction technology: 533
Shpak, Andrei
Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing
topic_facet VDP::Technology: 500::Building technology: 530::Construction technology: 533
description Concrete with moderate replacement levels of fly ash (FA) has been used for decades and considered sustainable in harsh environments. If the replacement levels become high (FA/C > 40…50%), the range of properties from fresh to hardened, including performance in frost testing give often unfavorable results. To reduce the environmental impact of the cement industry, solutions for sustainable frostresistant concrete with high FA replacements should be developed. Designing such concrete is possible if the exposure is properly characterized, requirements to part materials identified, the guideline for work execution understood and test program agreed upon. Apart from that, the reliable production of frostresistant concrete with FA should be established and controlled. Eventually, frost-testing results of the concrete should be satisfactory and reproducible for the clients. All these aspects of a “life cycle” of concrete were studied in the present Ph.D. project. The study was aimed at: (1) reviewing international requirements and recommendations for frost durable concrete from design to execution and testing; (2) developing robust admixture-binder combination for high-volume FA concrete suitable for both onshore and offshore arctic exposure; (3) understand how freeze-thaw performance testing affects high-volume FA concrete. A series of wet freeze-thaw performance tests in presence of freshwater and 3%NaCl were done on high-volume FA concrete. The aim was to investigate the effect of w/b-ratio, air entrainment, extremely low temperature, curing duration, and FA on resistance to the surface and internal damage and understand how surface, internal damage, and liquid transport interrelate for FA-concrete in such tests. Several pilot studies were also carried out to support the main investigations. Requirements and recommendations for frost durable concrete from standards and specifications in Europe, North-America and Asia, various international organizations and construction projects were reviewed, compared and discussed. This was done based on exposure, material, execution, and tests. Also, some practical examples of the specification together with examples of need of stringency and some occurring peculiarities in testing are given. Finally, the large variation in how frost durability is perceived in different parties of the decision, planning, execution, and commissioning process around the world are discussed and illustrated. Development of a robust admixture-binder combination resulted in a study on the effect of a sequence of addition for air-entraining (AEA) and super plasticizing (SP) admixtures on air entrainment in high-volume FA concrete (≈45⁺C)). The addition of SP before AEA was found to be the most favorable admixture combination for air entrainment in FA concrete, unlike that for OPC (where AEA is added first). Also, Foam Index (common method for evaluation AEA-binder systems) measurements on the same binder materials, admixtures, and dosage sequences were found less useful for studying the effect of admixture combinations. Obtaining a certain air content using the experience with the AEA-SPdosage was found to be an untrivial task if there is a lack of parameter control. Using the experience of the admixture combination seven concrete mixes were produced: six mixes with 0.52 FA/C and w/b ratios 0.293, 0.40 and 0.45 with and without entrained air, and one OPC mix w/b 0.45, all with 0.06 SF/C. Two of the most used methods, ASTM C666, procedure A for rapid freezethaw in water and CEN/TS 12390 for surface scaling in presence of 3 % NaCl solution, were used and extended to investigate how cracking, scaling and saturation progress at standard (-20oC) and arctic (-52oC) temperatures in such severe conditions. The results showed that high-volume FA concrete could be produced frost resistant in standardized testing and in arctic exposure when properly air-entrained. Prolonged water curing was found to have a positive effect, except for salt-scaling resistance of air-entrained FA concrete mixes. Long-term water curing allowed FA concrete with 0.293 w/b without air entrainment to survive a rapid freeze-thaw test in freshwater. Liquid uptake during freeze-thaw was found to be a link, connecting internal and surface frost damage. Air entrainment was found to protect against accelerated liquid uptake during wet freeze/thaw. The work conducted in this thesis contributes to the understanding of how to treat high-volume FA concrete in production and what to expect of the performance in various freeze-thaw environments.
author2 Jacobsen, Stephan
Scherer, George W.
format Doctoral or Postdoctoral Thesis
author Shpak, Andrei
author_facet Shpak, Andrei
author_sort Shpak, Andrei
title Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing
title_short Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing
title_full Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing
title_fullStr Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing
title_full_unstemmed Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing
title_sort production and documentation of frost durable high-volume fly ash concrete: air entrainment, cracking and scaling in performance testing
publisher NTNU
publishDate 2020
url https://hdl.handle.net/11250/2686408
geographic Arctic
geographic_facet Arctic
genre Arctic
Arctic
genre_facet Arctic
Arctic
op_relation Doctoral theses at NTNU;2020:366
Report: Requirements and recommendations for frost durable concrete. Test methods. Overview of national and international standards, codes, committees, representative projects Shpak, A., Jacobsen, S. DaCS project reports, report No.06 Trondheim, 2019
Paper 1: Shpak, Andrei; Jacobsen, Stefan. Effect of AEA-SP Dosage Sequence on Air Entrainment in FA Concrete. Nordic Concrete Research 2019 ;Volum 61.(2) s. 1-21 https://doi.org/10.2478/ncr-2019-0013
Manuscript 1: Frost testing of HVFA concrete. Part 1. Surface and internal damage
Manuscript 2: Frost testing of HVFA concrete. Part 2. Strength, hydration and liquid transport
S-1. Shpak, Andrei; Turowski, Marcin; Vimo, Ole Petter; Jacobsen, Stefan. Effect of AEA-SP dosage sequence on air content and air void structure in fresh and hardened fly ash mortar. I: NORDIC CONCRETE RESEARCH. Proceedings of the XXIII Nordic Concrete Research Symposium. Postboks 2312, Solli, Oslo: Norsk Betongforening 2017 ISBN 978-82-8208-056-9. s. 145-148 https://nordicconcrete.net/events/symposium/
S-2. Shpak, Andrei; Fosså, Kjell Tore; Jacobsen, Stefan. Requirements and recommendations to frost durable concrete – an overview. I: Concrete in Arctic Conditions. WORKSHOP PROCEEDINGS NO. 16 FROM A NORDIC WORKSHOP Trondheim, Norway 18–19 June, 2019. Oslo: The Nordic Concrete Federation 2019 ISBN 978-82-8208-067-5. s. 35-39
S-3. Shpak, Andrei; Jacobsen, Stefan. Frost testing of HP/HVFA concrete for severe offshore conditions. I: Concrete in Arctic Conditions. WORKSHOP PROCEEDINGS NO. 16 FROM A NORDIC WORKSHOP Trondheim, Norway 18–19 June, 2019. Oslo: The Nordic Concrete Federation 2019 ISBN 978-82-8208-067-5. s. 63-66
S-4. Shpak, Andrei; Fosså, Kjell Tore; Jacobsen, Stefan. Frost testing of HP/HVFA concrete for severe offshore conditions. I: Durable Concrete for Infrastructure under Severe Conditions Smart Admixtures, Self-responsiveness and Nano-additions Proceedings 10-11 September 2019, Ghent. Belgium: Magnel Laboratory for Concrete Research Technologiepark Zwijnaarde 60 9052 Ghent 2019 ISBN 978-9-463-88638-3. s. 187-190
S-5. Shpak, Andrei; Jacobsen, Stefan. Cracking in High Volume Fly Ash Concrete specimens during the European salt-frost slab test: dilatometry measurements and consequence for surface scaling. I: Workshop Proceedings from a Nordic Workshop. Oslo Norway, October 16th-17th, 2019 Design and construction of sustainable concrete structures: causes, calculation and consequences of cracks. Norsk betongforening 2019 ISBN 978-82-8208-069-9. s. 27-28
S.6. Shpak, Andrei; Brun, Marte Beheim; Fosså, Kjell Tore; Jacobsen, Stefan. Salt frost scaling testing HVFA concrete to -52C: - internal cracking measured with dilatometry. XXIV NORDIC CONCRETE RESEARCH SYMPOSIUM. Artikkelen er godkjent til symposiet som er utsatt til 2021. https://www.tekna.no/en/events/xxiv-nordic-concrete-research-symposium-38680/
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spelling ftntnutrondheimi:oai:ntnuopen.ntnu.no:11250/2686408 2023-05-15T14:28:14+02:00 Production and Documentation of Frost Durable High-Volume Fly Ash Concrete: air entrainment, cracking and scaling in performance testing Shpak, Andrei Jacobsen, Stephan Scherer, George W. 2020 application/pdf https://hdl.handle.net/11250/2686408 eng eng NTNU Doctoral theses at NTNU;2020:366 Report: Requirements and recommendations for frost durable concrete. Test methods. Overview of national and international standards, codes, committees, representative projects Shpak, A., Jacobsen, S. DaCS project reports, report No.06 Trondheim, 2019 Paper 1: Shpak, Andrei; Jacobsen, Stefan. Effect of AEA-SP Dosage Sequence on Air Entrainment in FA Concrete. Nordic Concrete Research 2019 ;Volum 61.(2) s. 1-21 https://doi.org/10.2478/ncr-2019-0013 Manuscript 1: Frost testing of HVFA concrete. Part 1. Surface and internal damage Manuscript 2: Frost testing of HVFA concrete. Part 2. Strength, hydration and liquid transport S-1. Shpak, Andrei; Turowski, Marcin; Vimo, Ole Petter; Jacobsen, Stefan. Effect of AEA-SP dosage sequence on air content and air void structure in fresh and hardened fly ash mortar. I: NORDIC CONCRETE RESEARCH. Proceedings of the XXIII Nordic Concrete Research Symposium. Postboks 2312, Solli, Oslo: Norsk Betongforening 2017 ISBN 978-82-8208-056-9. s. 145-148 https://nordicconcrete.net/events/symposium/ S-2. Shpak, Andrei; Fosså, Kjell Tore; Jacobsen, Stefan. Requirements and recommendations to frost durable concrete – an overview. I: Concrete in Arctic Conditions. WORKSHOP PROCEEDINGS NO. 16 FROM A NORDIC WORKSHOP Trondheim, Norway 18–19 June, 2019. Oslo: The Nordic Concrete Federation 2019 ISBN 978-82-8208-067-5. s. 35-39 S-3. Shpak, Andrei; Jacobsen, Stefan. Frost testing of HP/HVFA concrete for severe offshore conditions. I: Concrete in Arctic Conditions. WORKSHOP PROCEEDINGS NO. 16 FROM A NORDIC WORKSHOP Trondheim, Norway 18–19 June, 2019. Oslo: The Nordic Concrete Federation 2019 ISBN 978-82-8208-067-5. s. 63-66 S-4. Shpak, Andrei; Fosså, Kjell Tore; Jacobsen, Stefan. Frost testing of HP/HVFA concrete for severe offshore conditions. I: Durable Concrete for Infrastructure under Severe Conditions Smart Admixtures, Self-responsiveness and Nano-additions Proceedings 10-11 September 2019, Ghent. Belgium: Magnel Laboratory for Concrete Research Technologiepark Zwijnaarde 60 9052 Ghent 2019 ISBN 978-9-463-88638-3. s. 187-190 S-5. Shpak, Andrei; Jacobsen, Stefan. Cracking in High Volume Fly Ash Concrete specimens during the European salt-frost slab test: dilatometry measurements and consequence for surface scaling. I: Workshop Proceedings from a Nordic Workshop. Oslo Norway, October 16th-17th, 2019 Design and construction of sustainable concrete structures: causes, calculation and consequences of cracks. Norsk betongforening 2019 ISBN 978-82-8208-069-9. s. 27-28 S.6. Shpak, Andrei; Brun, Marte Beheim; Fosså, Kjell Tore; Jacobsen, Stefan. Salt frost scaling testing HVFA concrete to -52C: - internal cracking measured with dilatometry. XXIV NORDIC CONCRETE RESEARCH SYMPOSIUM. Artikkelen er godkjent til symposiet som er utsatt til 2021. https://www.tekna.no/en/events/xxiv-nordic-concrete-research-symposium-38680/ urn:issn:1503-8181 https://hdl.handle.net/11250/2686408 VDP::Technology: 500::Building technology: 530::Construction technology: 533 Doctoral thesis 2020 ftntnutrondheimi https://doi.org/10.2478/ncr-2019-0013 2020-11-11T23:33:59Z Concrete with moderate replacement levels of fly ash (FA) has been used for decades and considered sustainable in harsh environments. If the replacement levels become high (FA/C > 40…50%), the range of properties from fresh to hardened, including performance in frost testing give often unfavorable results. To reduce the environmental impact of the cement industry, solutions for sustainable frostresistant concrete with high FA replacements should be developed. Designing such concrete is possible if the exposure is properly characterized, requirements to part materials identified, the guideline for work execution understood and test program agreed upon. Apart from that, the reliable production of frostresistant concrete with FA should be established and controlled. Eventually, frost-testing results of the concrete should be satisfactory and reproducible for the clients. All these aspects of a “life cycle” of concrete were studied in the present Ph.D. project. The study was aimed at: (1) reviewing international requirements and recommendations for frost durable concrete from design to execution and testing; (2) developing robust admixture-binder combination for high-volume FA concrete suitable for both onshore and offshore arctic exposure; (3) understand how freeze-thaw performance testing affects high-volume FA concrete. A series of wet freeze-thaw performance tests in presence of freshwater and 3%NaCl were done on high-volume FA concrete. The aim was to investigate the effect of w/b-ratio, air entrainment, extremely low temperature, curing duration, and FA on resistance to the surface and internal damage and understand how surface, internal damage, and liquid transport interrelate for FA-concrete in such tests. Several pilot studies were also carried out to support the main investigations. Requirements and recommendations for frost durable concrete from standards and specifications in Europe, North-America and Asia, various international organizations and construction projects were reviewed, compared and discussed. This was done based on exposure, material, execution, and tests. Also, some practical examples of the specification together with examples of need of stringency and some occurring peculiarities in testing are given. Finally, the large variation in how frost durability is perceived in different parties of the decision, planning, execution, and commissioning process around the world are discussed and illustrated. Development of a robust admixture-binder combination resulted in a study on the effect of a sequence of addition for air-entraining (AEA) and super plasticizing (SP) admixtures on air entrainment in high-volume FA concrete (≈45⁺C)). The addition of SP before AEA was found to be the most favorable admixture combination for air entrainment in FA concrete, unlike that for OPC (where AEA is added first). Also, Foam Index (common method for evaluation AEA-binder systems) measurements on the same binder materials, admixtures, and dosage sequences were found less useful for studying the effect of admixture combinations. Obtaining a certain air content using the experience with the AEA-SPdosage was found to be an untrivial task if there is a lack of parameter control. Using the experience of the admixture combination seven concrete mixes were produced: six mixes with 0.52 FA/C and w/b ratios 0.293, 0.40 and 0.45 with and without entrained air, and one OPC mix w/b 0.45, all with 0.06 SF/C. Two of the most used methods, ASTM C666, procedure A for rapid freezethaw in water and CEN/TS 12390 for surface scaling in presence of 3 % NaCl solution, were used and extended to investigate how cracking, scaling and saturation progress at standard (-20oC) and arctic (-52oC) temperatures in such severe conditions. The results showed that high-volume FA concrete could be produced frost resistant in standardized testing and in arctic exposure when properly air-entrained. Prolonged water curing was found to have a positive effect, except for salt-scaling resistance of air-entrained FA concrete mixes. Long-term water curing allowed FA concrete with 0.293 w/b without air entrainment to survive a rapid freeze-thaw test in freshwater. Liquid uptake during freeze-thaw was found to be a link, connecting internal and surface frost damage. Air entrainment was found to protect against accelerated liquid uptake during wet freeze/thaw. The work conducted in this thesis contributes to the understanding of how to treat high-volume FA concrete in production and what to expect of the performance in various freeze-thaw environments. Doctoral or Postdoctoral Thesis Arctic Arctic NTNU Open Archive (Norwegian University of Science and Technology) Arctic Nordic Concrete Research 61 2 1 21

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