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Handbook of Sustainable Concrete and Industrial Waste Management: Recycled and Artificial Aggregate, Innovative Eco-friendly Binders, and Life Cycle Assessment [Mīkstie vāki]

Edited by (Full Professor, MASERG Materials Science and Engineering Research Group, Department of Engineering, Parthenope University of Naples, Naples, Italy), Edited by , Edited by (Professor of Materials Science and Technology and Materials Engineering, Department )
  • Formāts: Paperback / softback, 728 pages, height x width: 229x152 mm, weight: 1000 g, 180 illustrations (30 in full color); Illustrations
  • Sērija : Woodhead Publishing Series in Civil and Structural Engineering
  • Izdošanas datums: 06-Dec-2021
  • Izdevniecība: Woodhead Publishing
  • ISBN-10: 0128217308
  • ISBN-13: 9780128217306
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Handbook of Sustainable Concrete and Industrial Waste Management: Recycled and Artificial Aggregate, Innovative Eco-friendly Binders, and Life Cycle AssessmentPalielināt
  • Formāts: Paperback / softback, 728 pages, height x width: 229x152 mm, weight: 1000 g, 180 illustrations (30 in full color); Illustrations
  • Sērija : Woodhead Publishing Series in Civil and Structural Engineering
  • Izdošanas datums: 06-Dec-2021
  • Izdevniecība: Woodhead Publishing
  • ISBN-10: 0128217308
  • ISBN-13: 9780128217306
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9780128217306.html
Keywords:

The Handbook of Sustainable Concrete and Industrial Waste Management summarizes key research trends in recycling and reusing concrete and demolition waste to reduce their environmental impact. This volume also includes important contributions carried out by colleagues at the CRI-TEST Innovation Lab, Acerra (Naples).

Part one discusses eco-friendly innovative cement and concrete and reviews key substitute materials. Part two analyzes the use of industrial waste as aggregates and the mechanical properties of concrete containing waste materials. Part three discusses differences between innovative binders, focusing on alkali-activated and geopolymer concrete. Part four provides a thorough overview of the life cycle assessment (LCA) of concrete containing industrial wastes and the impacts related to the logistics of wastes, the production of the concrete, and the management of industrial wastes.

By providing research examples, case studies, and practical strategies, this book is a state-of-the-art reference for researchers working in construction materials, civil or structural engineering, and engineers working in the industry.

  • Offers a systematic and comprehensive source of information on the latest developments in sustainable concrete;
  • Analyzes different types of sustainable concrete and innovative binders from chemical, physical, and mechanical points of view;
  • Includes real case studies showing application of the LCA methodology.
List of contributors
xv
About the editors xxiii
Foreword xxv
Part One Eco-friendly innovative cement and concrete
1(146)
1 Foamed concrete containing industrial wastes
3(20)
Natt Makul
1.1 Introduction
3(2)
1.2 Constituent materials
5(1)
1.3 Proportioning of foam concretes
6(1)
1.4 Form concrete properties
7(5)
1.5 Functional characteristics
12(2)
1.6 Fresh and hardened features
14(4)
1.7 Summary
18(5)
References
18(5)
2 Valorization of industrial byproducts and wastes as sustainable construction materials
23(22)
U. Johnson Alengaram
2.1 Overview of industrial byproducts and wastes as sustainable cement replacement materials
23(1)
2.2 Ground granulated blast furnace slag
24(2)
2.3 Fly ash
26(1)
2.4 Metakaolin
27(1)
2.5 Rice husk ash
27(1)
2.6 Palm oil fuel ash
28(1)
2.7 Palm oil clinker ash
29(1)
2.8 Coal bottom ash
30(1)
2.9 Effect of sustainable cement replacement materials
30(1)
2.10 Significance of achieving sustainability through replacement of conventional fine and coarse aggregates
31(1)
2.11 Manufactured sand
32(2)
2.12 Palm oil clinker sand
34(2)
2.13 Coal bottom ash
36(1)
2.14 Oil palm shell as coarse aggregate
36(2)
2.15 Palm oil clinker as coarse aggregates
38(1)
2.16 Properties of lightweight aggregates
39(6)
References
41(4)
3 Enunciation of lightweight and self-compacting concretes using non-conventional materials
45(18)
U. Johnson Alengaram
3.1 Properties of lightweight concrete
45(18)
References
60(3)
4 The use of construction and demolition waste as a recycled aggregate in sustainable concrete production: workability, strength and durability properties
63(22)
Ayobami Busari
4.1 Introduction
63(1)
4.2 Review of literature
64(7)
4.3 Conclusion
71(14)
References
73(8)
Further Reading
81(4)
5 Natural fibers
85(24)
J.M. Khatib
M.M. Machaka
A.M. Elkordi
5.1 Introduction
85(1)
5.2 Types of natural fibers in construction
86(2)
5.3 Manufacturing and production of natural fibers
88(2)
5.4 Treatment of natural fibers
90(1)
5.5 Using fibers in construction
91(2)
5.6 Using fibers in concrete
93(2)
5.7 Fresh properties of concrete containing natural fibers
95(1)
5.8 Compressive strength
96(1)
5.9 Flexural strength
97(1)
5.10 Shrinkage and expansion
98(1)
5.11 Ductility and impact resistance
98(1)
5.12 Durability
99(1)
5.13 Economic, environmental and societal factors
100(1)
5.14 Concluding remarks
101(8)
References
102(7)
6 Eco-friendly fiber-reinforced concretes
109(38)
R. Prakash
Sudharshan N. Raman
C. Subramanian
N. Divyah
6.1 Introduction
109(1)
6.2 Aggregates: environmental impact
110(2)
6.3 Sustainability of coconut shell aggregate
112(5)
6.4 Cement production: carbon emission
117(1)
6.5 Fibers in concrete
118(1)
6.6 Steel fiber-reinforced CS concrete
119(6)
6.7 Sisal fiber-reinforced CS concrete
125(7)
6.8 Roselle fiber-reinforced CS concrete
132(7)
6.9 Ecofriendliness and sustainability of fiber-reinforced concrete
139(1)
6.10 Future trends
139(1)
6.11 Conclusions
140(7)
References
141(6)
Part Two Use of industrial waste as aggregates: Properties of concrete
147(272)
7 Energy-saving materials
149(18)
Lateef N. Assi
Ali Alsalman
Kealy Carter
Paul Ziehl
7.1 Introduction
149(1)
7.2 Mixture selection
150(1)
7.3 Energy produced
151(5)
7.4 CO2 emissions
156(1)
7.5 Results and discussion
157(4)
7.6 Concluding remarks
161(6)
List of acronyms and notations
162(5)
References
163(2)
Further Reading
165(2)
8 Fresh and mechanical properties of concrete made with recycled plastic aggregates
167(20)
Rabar H. Faraj
Hemn Unis Ahmed
Hunar F. Hama Ali
Aryan Far H. Sherwani
8.1 Introduction
167(1)
8.2 Types and preparation of plastic waste used in the concrete production
168(1)
8.3 Properties of concrete containing recycled plastic aggregates
169(12)
8.4 Empirical relationships among different properties of RPAC
181(1)
8.5 Summary
181(6)
References
183(4)
9 Recycled glass as a concrete component: possibilities and challenges
187(24)
Aziz Hasan Mahmood
Alireza Kashani
9.1 Introduction
187(1)
9.2 Production and recycling of glass as aggregate
187(2)
9.3 Properties of glass aggregate
189(1)
9.4 Concrete incorporating glass aggregate
190(3)
9.5 Alkali-silica reaction of glass aggregate
193(6)
9.6 Ground glass as a pozzolan
199(1)
9.7 Glass aggregate in alkali-activated binders and foam concrete
200(2)
9.8 Conclusions
202(9)
References
203(8)
10 Recycled aggregate concrete: mechanical and durability performance
211(18)
Syed Minhaj Saleem Kazmi
Muhammad Junaid Munir
Yu-Fei Wu
10.1 Introduction
211(1)
10.2 Recycled coarse aggregates
212(1)
10.3 Recycled aggregate concrete
213(8)
10.4 Future trends
221(8)
References
221(8)
11 Microstructure and properties of concrete with ceramic wastes
229(26)
Qiang Zeng
Le Li
Jiahan Liu
Tingfeng Lu
Jinyi Xu
Ahmed Al-Mansour
Jiyang Wang
Jin Xia
11.1 Introduction
229(1)
11.2 General characteristics of ceramic wastes
230(3)
11.3 Properties of concrete with ceramic wastes
233(8)
11.4 Microstructure of concrete with ceramic wastes
241(7)
11.5 Conclusion and outlooks
248(7)
References
248(7)
12 Agricultural plastic waste
255(14)
E. Schettini
G. Scarascia-Mugnozza
I. Blanco
F. Convertino
G. Vox
12.1 Plastics in agriculture
255(3)
12.2 Agricultural plastic waste management
258(2)
12.3 Geographical information systems for agricultural plastic waste mapping
260(2)
12.4 Agricultural plastic waste mapping using satellite images
262(2)
12.5 Conclusions
264(5)
Acknowledgments
265(1)
References
265(4)
13 Recycling and applications of steel slag aggregates
269(20)
Qiao Dong
Xueqin Chen
13.1 Introduction
269(1)
13.2 Steel slag aggregate (SSA)
270(10)
13.3 Performance of SSA concrete
280(6)
13.4 Conclusions
286(3)
References
286(3)
14 Use of quarry waste in concrete and cementitious mortars
289(16)
Thomaida Polydorou
Nicholas Kyriakides
Kyriacos Neocleous
Diofantos Hadjimitsis
14.1 Introduction
289(1)
14.2 Use of quarry waste in concrete and cementitious mortars
290(1)
14.3 Effects of quarry waste on fresh concrete and cementitious mortar properties
290(4)
14.4 Effects of quarry waste on hardened concrete and cementitious mortar properties
294(8)
14.5 Conclusion
302(3)
References
303(2)
15 Implementation of agricultural crop wastes toward green construction materials
305(28)
Sara Boudali
Bahira Abdulsalam
Ahmed Soliman
Sebastien Poncet
Stephan Godbout
Johann Palacios
Adel ElSafty
15.1 Introduction
305(28)
References
329(4)
16 Balancing sustainability, workability, and hardened behavior in the mix design of self-compacting concrete
333(26)
Victor Revilla-Cuesta
Flora Faleschini
Marta Skaf
Vanesa Ortega-Lopez
Juan M. Manso
16.1 Introduction
333(1)
16.2 Properties of recycled concrete aggregate
334(2)
16.3 Particularities and mix design of self-compacting concrete
336(1)
16.4 Fresh behavior: effect of RCA addition
336(9)
16.5 Hardened behavior: Strength and stiffness of SCC containing RCA
345(6)
16.6 Conclusions
351(8)
References
352(7)
17 Design guidelines for structural and non-structural applications
359(28)
Flora Faleschini
Mariano Angelo Zanini
Cristoforo Demartino
17.1 Introduction
359(1)
17.2 Environmental and economic aspects: benefits and constraints
360(2)
17.3 Recycled aggregates and other industrial aggregates in concrete mix designs
362(7)
17.4 Design of reinforced concrete structures with EAF concrete
369(11)
17.5 Conclusions
380(7)
References
381(6)
18 Strength and microstructure properties of self-compacting concrete using mineral admixtures. Case study I
387(20)
S.S. Vivek
G. Dhinakaran
18.1 Introduction
387(1)
18.2 Self-compacting concrete (SCC)
388(1)
18.3 Mineral admixtures from industrial waste for SCC preparation
389(6)
18.4 Strength of binary and ternary blend SCC with mineral admixtures
395(7)
18.5 Cost analysis
402(1)
18.6 Conclusions
402(5)
References
404(3)
19 Durability properties of self-compacting concrete using mineral admixtures. Case study II
407(12)
S.S. Vivek
G. Dhinakaran
19.1 Introduction
407(2)
19.2 Comparison between CVC and SCC
409(1)
19.3 Classification of SCC
409(1)
19.4 Binary and ternary SCC mixes
410(1)
19.5 Durability studies on binary and ternary blend SCC
410(4)
19.6 SCC applications
414(2)
19.7 Conclusions
416(3)
References
416(3)
Part Three Innovative binders: alkali-activated and geopolymer concrete
419(132)
20 Difference between geopolymers and alkali-activated materials
421(16)
Parham Shoaei
Farshad Ameri
Misagh Karimzadeh
Erfan Atabakhsh
Seyed Alireza Zareei
Babak Behforouz
20.1 Introduction
421(1)
20.2 Zero-cement versus cementitious binders
422(1)
20.3 History and development of AAMs and GPs
422(1)
20.4 AAMs versus GPs
423(6)
20.5 Challenges and opportunities
429(8)
References
430(7)
21 Geopolymer binders containing construction and demolition waste
437(38)
Sina Dadsetan
Hocine Siad
Mohamed Lachemi
Obaid Mahmoodi
Mustafa Sahmaran
21.1 Introduction
437(1)
21.2 Geopolymer terminology: effective chemical and physical factors
438(2)
21.3 Characterization of construction and demolition wastes (CDW) as aluminosilicate resources
440(5)
21.4 An overview of CDW-based geopolymer binders
445(1)
21.5 Properties of CDW-based geopolymers
445(19)
21.6 Future development and challenges of CDW-based geopolymer
464(1)
21.7 Concluding remarks
465(10)
Acknowledgments
466(1)
References
466(9)
22 On the properties of sustainable concrete containing mineral admixtures
475(14)
Francesco Colangelo
Ilenia Farina
Ivan Moccia
Marco Ruggiero
Raffaele Ciojfi
22.1 Introduction
475(2)
22.2 Materials and methods
477(2)
22.3 Experimental results
479(4)
22.4 Results and discussion
483(2)
22.5 Conclusions
485(4)
References
486(3)
23 Sustainable alkali-activated materials
489(20)
Mohammad Jamalimoghadam
Rassoul Ajalloeian
Amirhomayoun Saffarzadeh
23.1 Introduction
489(2)
23.2 Management of industrial waste in the preparation of alkali-activated cement materials
491(6)
23.3 Radioactive waste and toxic contaminants stabilization
497(1)
23.4 High-performance alkali-activated cement
498(1)
23.5 Water and wastewater treatment
499(2)
23.6 Soil stabilization
501(1)
23.7 Future trends
501(8)
References
502(6)
Further Reading
508(1)
24 Design guidelines for structural and non-structural applications
509(20)
Kwok Wei Shah
Ghasan Fahim Huseien
24.1 Introduction
509(2)
24.2 Effect of binding materials
511(1)
24.3 Effect of aggregates type
512(3)
24.4 Effect of alkaline solution
515(3)
24.5 Effect of binder to aggregates
518(1)
24.6 Alkali-activated as high performance repair materials
519(2)
24.7 Beam flexural behavior
521(1)
24.8 Conclusions
522(7)
References
523(6)
25 Future trends: nanomaterials in alkali-activated composites
529(22)
Shaswat Kumar Das
R.S. Krishna
Subhabrata Mishra
Syed Mohammed Mustakim
Malaya Kumar Jena
Ankit Kumar Tripathy
Trilochan Sahu
25.1 Introduction
529(1)
25.2 Nanomaterials in AAC
530(16)
25.3 Challenges and recommendations for use of nanomaterials in AAC
546(5)
References
546(5)
Part Four Life cycle assessment of concrete
551(136)
26 Calculation of the environmental impact of the integration of industrial waste in concrete using LCA
553(26)
Jorge de Brito
Hisham Hafez
Rawaz Kurda
Jose Silvestre
26.1 Introduction
553(3)
26.2 LCA methodology for the use of industrial waste in concrete
556(23)
References
571(5)
Further Reading
576(3)
27 Role of transport distance on the environmental impact of the construction and demolition waste (CDW) recycling process
579(16)
Lais Peixoto Rosado
Beatriz Leao Evangelista de Lara
Carmenlucia Santos Giordano Penteado
27.1 Introduction
579(1)
27.2 Premises for considering the transport distances of C&DW and recycled aggregates
580(5)
27.3 Methodological aspects related to transport in LCA studies
585(5)
27.4 Influence of transport distance on LCA results
590(1)
27.5 Conclusions
591(4)
Acknowledgments
591(1)
References
591(4)
28 Management of industrial waste and cost analysis
595(20)
Runxiao Zhang
Tanvir S. Qureshi
Daman K. Panesar
28.1 Introduction
595(1)
28.2 Coal-burning ash
596(4)
28.3 Iron and steel slags
600(5)
28.4 Silica fume
605(5)
28.5 Conclusion
610(5)
References
610(5)
29 Use of industrial waste in construction and a cost analysis
615(22)
Runxiao Zhang
Tanvir S. Qureshi
Daman K. Panesar
29.1 Introduction
615(1)
29.2 Utilization in construction
615(9)
29.3 Cost analysis
624(5)
29.4 Future perspectives
629(3)
29.5 Conclusion
632(5)
References
632(5)
30 Life cycle assessment (LCA) of concrete containing waste materials: comparative studies
637(24)
Mohammad Saberian
Jingxuan Zhang
Akvan Gajanayake
Jie Li
Guomin Zhang
Mahdi Boroujeni
30.1 Introduction
637(2)
30.2 Methodological framework
639(1)
30.3 Conceptual basis of life cycle assessment (LCA)
639(2)
30.4 Comparative LCA studies of waste materials as substitute components in concrete
641(7)
30.5 Discussions
648(4)
30.6 Conclusions and further research
652(9)
References
653(8)
31 Opportunities and future challenges of geopolymer mortars for sustainable development
661(26)
Antonella Petrillo
Ilenia Farina
Marta Travaglioni
Cinzia Salzano
Salvatore Puca
Antonio Ramondo
Renato Olivares
Luigi Cossentino
Raffaele Cioffi
31.1 Introduction
661(2)
31.2 Portland cement versus geopolymer concrete
663(6)
31.3 Environmental and sustainable perspective of geopolymer
669(3)
31.4 Brief analysis of LCA on geopolymer mortars
672(6)
31.5 Conclusions
678(9)
Nomenclature
679(1)
Acknowledgments
679(1)
References
679(6)
Further Reading
685(2)
Index 687
Francesco Colangelo is a Full Professor of Innovative Materials for Civil Engineering and the director of the masters course in Safety Engineering in the Department of Engineering at Parthenope University of Naples, Italy. His main research areas include recycling of waste materials in concrete and geo-environmental and civil applications, treatment of MSWI fly ash, application of lifecycle assessment methodology to various processes for preparing innovative building materials, evaluation of the durability of mortars and concrete, stabilization and solidification of hazardous wastes, and synthesis of geopolymeric eco-sustainable materials based on industrial waste. He has extensive consultancy experience in the treatment and recycling of solid waste, remediation of old landfills, and resource recovery plants. He has served as the principal investigator for numerous research projects in collaboration with public and private companies. Since 2012, he has been a senior member of RILEM.

Raffaele Cioffihas a degree in Chemical Engineering from the University of Naples Federico II. He is Professor of Materials Science and Technology and Materials Engineering at the University of Naples Parthenope”, Naples, Italy. He has been the Head of the Department of Technology and thedirector of the Research Quality Centre of the University of Naples "Parthenope". He has been the director of the Sustainable Development Engineering Laboratory of the Department of Technology, the president of the Teaching Board fortheIndustrial Engineering Course, and he is the coordinator of the Technical and Scientific Committee for the Master Course in Safety Engineering of the University of Naples " Parthenope". He is the vice-president of the Italian Association on Materials Engineering (AIMAT). Ilenia Farina is an Assistant Professor in Materials Science and Engineering in the Department of Engineering at Parthenope University of Naples, Italy. She received a DPhil in Energy Science and Engineering from the same university. Her main research activities focus on the stabilization and solidification of hazardous industrial solid wastes, soils, and sediments; the development of energy-saving blended cements, concrete, and geopolymer materials made with coal fly ash, blast furnace slag, MSWI ashes, and other industrial by-products; the inertization of industrial and asbestos-containing wastes and sediments through mechanochemical treatments, with subsequent reuse of the resulting products as building materials; and life cycle assessment (LCA) of production processes for eco-compatible construction materials. She is responsible for several research projects in collaboration with public and private companies.