Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement

R. Gettu; R.G. Pillai; M. Santhanam; S. Rathnarajan; A.S. Basavaraj; S. Rengaraju; D. Yuvaraj

Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement

R. Gettu, R.G. Pillai, M. Santhanam, S. Rathnarajan, A.S. Basavaraj, S. Rengaraju, D. Yuvaraj

Civil Engineering and Management

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

Environmental impact due to the emission of carbon dioxide during concrete production can be taken care by reducing the clinker content in the cement. The clinker content can be reduced by replacing it with fly ash and limestone calcined clay. Such systems can have a potential to exhibit enhanced durability/service life when exposed to chloride and carbon dioxide. However, estimating probabilistic service life of concretes with such alternative binder systems is difficult due to the lack of quantitative estimates of the input parameters such as chloride diffusion coefficient (DCl), ageing coefficient (m), carbonation coefficient (KCO₂),and chloride threshold (Clth). This paper presents the experimentally observed estimates of these parameters
for the following systems: (i) 100% OPC, (ii) 70% OPC + 30% fly ash, and (iii) limestone calcined clay cement (LC3) – known as OPC, PFA, and LC3 concretes, respectively, herein. A total of three concrete
mixes were designed. Also, based on these input parameters, the probabilistic service life estimates of a bridge pier and a girder made of these three concretes and exposed to chlorides and carbon dioxide are presented. For chloride ingress study, Fick’s 2^nd Law of diffusion and Cl_th have been used. For carbonation
study, a recently developed model for estimating carbonation depth (using mixture proportion) have been used. Then, the life-cycle assessment (LCA) of these three concrete systems in terms of the CO₂ emissions per unit of concrete per year of estimated service life is presented - for both chloride and carbonation
induced corrosion. In chloride laden environments, the service life of the bridge pier and girder systems could be enhanced by about 10 times by using fly ash or LC3 concretes – for similar strength grade concretes. Also, the average annual CO₂ emissions (during the expected service life) of PFA and LC3 concretes could be about 3 and 7 times, respectively, lower than that of OPC concretes of similar strength grade. In case of carbonation-induced corrosion, the limited experimental data indicate that the PFA and LC3 concretes could exhibit a lower service life and higher average annual CO₂ emissions (during the expected service life) than OPC concretes.

Original language	English
Title of host publication	Durability of Concrete Structures
Subtitle of host publication	Sixth International Conference on - ICDCS 2018
Editors	Muhammed Basheer
Place of Publication	Caithness
Publisher	Whittles Publishing
Pages	27-35
Number of pages	9
ISBN (Electronic)	9781849954099
ISBN (Print)	9781849953948
Publication status	Published - 18 Oct 2018
Event	Sixth International Conference on Durability of Concrete Structures - University of Leeds, Leeds, United Kingdom Duration: 18 Jul 2018 → 20 Jul 2018

Conference

Conference	Sixth International Conference on Durability of Concrete Structures
Country/Territory	United Kingdom
City	Leeds
Period	18/07/18 → 20/07/18

Keywords

concrete
chloride
carbonation
corrosion
durability
service life
life-cycle assessment

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

https://docs.lib.purdue.edu/cgi/viewcontent.cgi?article=1347&context=icdcs

Cite this

Gettu, R., Pillai, R. G., Santhanam, M., Rathnarajan, S., Basavaraj, A. S., Rengaraju, S., & Yuvaraj, D. (2018). Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement. In M. Basheer (Ed.), Durability of Concrete Structures: Sixth International Conference on - ICDCS 2018 (pp. 27-35). Article KN01 Whittles Publishing. https://docs.lib.purdue.edu/cgi/viewcontent.cgi?article=1347&context=icdcs

@inproceedings{a7dcec2aaee44705b66a337389837602,

title = "Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement",

abstract = "Environmental impact due to the emission of carbon dioxide during concrete production can be taken care by reducing the clinker content in the cement. The clinker content can be reduced by replacing it with fly ash and limestone calcined clay. Such systems can have a potential to exhibit enhanced durability/service life when exposed to chloride and carbon dioxide. However, estimating probabilistic service life of concretes with such alternative binder systems is difficult due to the lack of quantitative estimates of the input parameters such as chloride diffusion coefficient (DCl), ageing coefficient (m), carbonation coefficient (KCO2),and chloride threshold (Clth). This paper presents the experimentally observed estimates of these parametersfor the following systems: (i) 100% OPC, (ii) 70% OPC + 30% fly ash, and (iii) limestone calcined clay cement (LC3) – known as OPC, PFA, and LC3 concretes, respectively, herein. A total of three concretemixes were designed. Also, based on these input parameters, the probabilistic service life estimates of a bridge pier and a girder made of these three concretes and exposed to chlorides and carbon dioxide are presented. For chloride ingress study, Fick{\textquoteright}s 2nd Law of diffusion and Clth have been used. For carbonationstudy, a recently developed model for estimating carbonation depth (using mixture proportion) have been used. Then, the life-cycle assessment (LCA) of these three concrete systems in terms of the CO2 emissions per unit of concrete per year of estimated service life is presented - for both chloride and carbonationinduced corrosion. In chloride laden environments, the service life of the bridge pier and girder systems could be enhanced by about 10 times by using fly ash or LC3 concretes – for similar strength grade concretes. Also, the average annual CO2 emissions (during the expected service life) of PFA and LC3 concretes could be about 3 and 7 times, respectively, lower than that of OPC concretes of similar strength grade. In case of carbonation-induced corrosion, the limited experimental data indicate that the PFA and LC3 concretes could exhibit a lower service life and higher average annual CO2 emissions (during the expected service life) than OPC concretes.",

keywords = "concrete, chloride, carbonation, corrosion, durability, service life, life-cycle assessment",

author = "R. Gettu and R.G. Pillai and M. Santhanam and S. Rathnarajan and A.S. Basavaraj and S. Rengaraju and D. Yuvaraj",

year = "2018",

month = oct,

day = "18",

language = "English",

isbn = "9781849953948",

pages = "27--35",

editor = "Muhammed Basheer",

booktitle = "Durability of Concrete Structures",

publisher = "Whittles Publishing",

address = "United Kingdom",

note = "Sixth International Conference on Durability of Concrete Structures ; Conference date: 18-07-2018 Through 20-07-2018",

}

Gettu, R, Pillai, RG, Santhanam, M, Rathnarajan, S, Basavaraj, AS, Rengaraju, S & Yuvaraj, D 2018, Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement. in M Basheer (ed.), Durability of Concrete Structures: Sixth International Conference on - ICDCS 2018., KN01, Whittles Publishing, Caithness, pp. 27-35, Sixth International Conference on Durability of Concrete Structures, Leeds, United Kingdom, 18/07/18. <https://docs.lib.purdue.edu/cgi/viewcontent.cgi?article=1347&context=icdcs>

Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement. / Gettu, R.; Pillai, R.G.; Santhanam, M. et al.
Durability of Concrete Structures: Sixth International Conference on - ICDCS 2018. ed. / Muhammed Basheer. Caithness: Whittles Publishing, 2018. p. 27-35 KN01.

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement

AU - Gettu, R.

AU - Pillai, R.G.

AU - Santhanam, M.

AU - Rathnarajan, S.

AU - Basavaraj, A.S.

AU - Rengaraju, S.

AU - Yuvaraj, D.

PY - 2018/10/18

Y1 - 2018/10/18

N2 - Environmental impact due to the emission of carbon dioxide during concrete production can be taken care by reducing the clinker content in the cement. The clinker content can be reduced by replacing it with fly ash and limestone calcined clay. Such systems can have a potential to exhibit enhanced durability/service life when exposed to chloride and carbon dioxide. However, estimating probabilistic service life of concretes with such alternative binder systems is difficult due to the lack of quantitative estimates of the input parameters such as chloride diffusion coefficient (DCl), ageing coefficient (m), carbonation coefficient (KCO2),and chloride threshold (Clth). This paper presents the experimentally observed estimates of these parametersfor the following systems: (i) 100% OPC, (ii) 70% OPC + 30% fly ash, and (iii) limestone calcined clay cement (LC3) – known as OPC, PFA, and LC3 concretes, respectively, herein. A total of three concretemixes were designed. Also, based on these input parameters, the probabilistic service life estimates of a bridge pier and a girder made of these three concretes and exposed to chlorides and carbon dioxide are presented. For chloride ingress study, Fick’s 2nd Law of diffusion and Clth have been used. For carbonationstudy, a recently developed model for estimating carbonation depth (using mixture proportion) have been used. Then, the life-cycle assessment (LCA) of these three concrete systems in terms of the CO2 emissions per unit of concrete per year of estimated service life is presented - for both chloride and carbonationinduced corrosion. In chloride laden environments, the service life of the bridge pier and girder systems could be enhanced by about 10 times by using fly ash or LC3 concretes – for similar strength grade concretes. Also, the average annual CO2 emissions (during the expected service life) of PFA and LC3 concretes could be about 3 and 7 times, respectively, lower than that of OPC concretes of similar strength grade. In case of carbonation-induced corrosion, the limited experimental data indicate that the PFA and LC3 concretes could exhibit a lower service life and higher average annual CO2 emissions (during the expected service life) than OPC concretes.

AB - Environmental impact due to the emission of carbon dioxide during concrete production can be taken care by reducing the clinker content in the cement. The clinker content can be reduced by replacing it with fly ash and limestone calcined clay. Such systems can have a potential to exhibit enhanced durability/service life when exposed to chloride and carbon dioxide. However, estimating probabilistic service life of concretes with such alternative binder systems is difficult due to the lack of quantitative estimates of the input parameters such as chloride diffusion coefficient (DCl), ageing coefficient (m), carbonation coefficient (KCO2),and chloride threshold (Clth). This paper presents the experimentally observed estimates of these parametersfor the following systems: (i) 100% OPC, (ii) 70% OPC + 30% fly ash, and (iii) limestone calcined clay cement (LC3) – known as OPC, PFA, and LC3 concretes, respectively, herein. A total of three concretemixes were designed. Also, based on these input parameters, the probabilistic service life estimates of a bridge pier and a girder made of these three concretes and exposed to chlorides and carbon dioxide are presented. For chloride ingress study, Fick’s 2nd Law of diffusion and Clth have been used. For carbonationstudy, a recently developed model for estimating carbonation depth (using mixture proportion) have been used. Then, the life-cycle assessment (LCA) of these three concrete systems in terms of the CO2 emissions per unit of concrete per year of estimated service life is presented - for both chloride and carbonationinduced corrosion. In chloride laden environments, the service life of the bridge pier and girder systems could be enhanced by about 10 times by using fly ash or LC3 concretes – for similar strength grade concretes. Also, the average annual CO2 emissions (during the expected service life) of PFA and LC3 concretes could be about 3 and 7 times, respectively, lower than that of OPC concretes of similar strength grade. In case of carbonation-induced corrosion, the limited experimental data indicate that the PFA and LC3 concretes could exhibit a lower service life and higher average annual CO2 emissions (during the expected service life) than OPC concretes.

KW - concrete

KW - chloride

KW - carbonation

KW - corrosion

KW - durability

KW - service life

KW - life-cycle assessment

UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85065063877&partnerID=40&md5=177046a1d91baee0c18bed543fb5dd82

M3 - Conference contribution

SN - 9781849953948

SP - 27

EP - 35

BT - Durability of Concrete Structures

A2 - Basheer, Muhammed

PB - Whittles Publishing

CY - Caithness

T2 - Sixth International Conference on Durability of Concrete Structures

Y2 - 18 July 2018 through 20 July 2018

ER -

Service life and life-cycle assessment of reinforced concrete with fly ash and limestone calcined clay cement

Abstract

Conference

Keywords

UN SDGs

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