Your search keyword '"Cementitious"' showing total 11,298 results

1. تطبيق علم السمنتيكيه والابستمولوجية على حديث هشام بن الحكم.

Author

حميد رضا شريعتمد and حميد علي منصور ا&#1604

Abstract

Copyright of Journal of Babylon Center for Humanities Studies is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

2. Continuous Monitoring of the Early-Age Strength Development of Cement Paste Using Embeddable Piezoelectric-Based Ultrasonic Transducers

Author

Narayanan, Arun, Duddi, Murali, Kocherla, Amarteja, Subramaniam, K. V. L., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Abdullah, Waleed, editor, Chaudhary, Muhammad Tariq, editor, Kamal, Hasan, editor, Parol, Jafarali, editor, and Almutairi, Abdullah, editor

Published

2024

3. 基于矿冶废渣制备充填专用胶凝材料.

Author

董 峰, 李 明, 郭利杰, and 杨 超

Abstract

The basic chemical properties of mining and metallurgical waste slag and raw materials are measured, and compound strong alkaline activator is developed according to the test results, which can be used to activate the activity of mining and metallurgical waste slag, so as to prepare special backfill cementitious material. The hydration reaction products in the backfill were tested by XRD. The results showed that the main hydration products supporting the strength of backfill were ettringite (AFt), calcium hydroxide (CH), aluminum glue(AH8_10), calcium silicate hydrate(C S H), hydrated calcium aluminosilicate(C A S H), et al. The formation of one ettringite(AFt) molecule will bind and adsorb 32 H2 0 molecules, indicating that the special backfill cementitious material is more suitable for backfill slurry with larger water content. At the same time, SEM was used to analyze the internal structure of the backfill at different ages, revealing the strength growth law of the backfill, and analyzing the strength mechanism of the backfill at each stage. The strength of backfill of two kinds of cementitious materials was tested by strength test under different conditions. The results showed that the strength of backfill prepared by special cementitious materials(KS) was higher than that prepared by cement (SN), there was a one fold difference in the strength value. [ABSTRACT FROM AUTHOR]

Published

2024

4. A Review of Waterborne Polymer–Cementitious Composite Repair Materials for Application in Saline Soil Environments: Properties and Progress.

Author

Yang, Yan'e, Pang, Bo, Zhang, Yunsheng, Wang, Minghui, Miao, Gaixia, and Zhou, Aoxiang

Subjects

SOIL salinity, COMPOSITE materials, ENVIRONMENTAL soil science, CEMENT composites, POLYMER-impregnated concrete

Abstract

The properties of a large number of concrete infrastructures in China are deteriorating year by year, raising the need for repairing and strengthening these infrastructures. By introducing waterborne polymers into a cement concrete system, brittle cracks and easy bonding performance defects of concrete can be compensated for to form a long-life, semi rigid, waterborne polymer-modified cementitious repair material with a promising development prospect. This paper investigates the modification effect of polymer emulsions on ordinary cement mortar. Our research mainly focused on the physical and mechanical properties, durability, microstructure and application status of waterborne polymer-modified cementitious composites. Literature studies show that with the increase in waterborne polymer content (0 wt%~20 wt%), the performance of cement mortar significantly improves, which in turn expands its application range. Compared with ordinary cement mortar, the introduction of waterborne polymers blocks some of the pores in the cement to a certain extent, thus improving its permeability, freeze–thaw resistance and durability. Finally, this paper describes the application of waterborne polymer–cementitious composites in western saline soil environments, as well as discusses the prospects of their development. [ABSTRACT FROM AUTHOR]

Published

2024

5. An Investigation on Mechanical Characteristics of Carbon Nanomaterials Used in Cementitious Composites

Author

Bhatrola, Kanchna, Maurya, Sameer Kumar, Budhalakoti, Bharti, Kothiyal, N. C., Shanker, Uma, editor, Hussain, Chaudhery Mustansar, editor, and Rani, Manviri, editor

Published

2023

6. Long-Term Natural Carbonation in Concretes with Fly Ash and Limestone Calcined Clay Systems

Author

Rathnarajan, Sundar, Hule, Umesh, Pillai, Radhakrishna G., Gettu, Ravindra, Jędrzejewska, Agnieszka, editor, Kanavaris, Fragkoulis, editor, Azenha, Miguel, editor, Benboudjema, Farid, editor, and Schlicke, Dirk, editor

Published

2023

7. Effect of steam curing system on compressive strength of solid waste based low-carbon cementitious materials.

Author

ZHOU Yi, BIAN Huaying, WANG Zhi, and LI Jing

Subjects

SOLID waste, COMPRESSIVE strength

Abstract

By designing different steam curing systems and comparing the changes law of compressive strength of low-carbon cementitious materials, optimum suitable steam curing system for low-carbon cementitious materials can be obtained. The results indicate that for solid waste based low-carbon cementitious materials, the early strength can be improved by using a waiting time the same as the induction period during steam curing. For steam curing temperature and steam curing time, 65 °C and 12 hours is sufficient to achieve ideal early strength, the compressive strength can not be improved significantly by longer steam curing time and higher steam curing temperature. [ABSTRACT FROM AUTHOR]

Published

2023

8. The impact of natural and synthetic zeolite when used in cementitious based systems

Author

Hodgkiss, Conner and Williams, Craig

Subjects

zeolite, mortar, ordinary portland cement, cementitious, compressive strength, ultra-sonic pulse velocity, density, pozzolan

Abstract

The production of Portland cement, the most commonly used binding material in the construction and maintenance industry, is one of the principle carbon dioxide emission contributors. Indeed, up to 85% of the cement quantity produced is discharged into the atmosphere. As a result, efforts are being made to introduce new and advanced alternative construction materials to combat this adversity. Despite the recent introduction of new advanced materials such as polymer rubbers and alternative mineral sands, the overall percentage emission of carbon dioxide has not decreased. Improvement of cement mortar characteristics and the reduction of carbon emissions is of keen interest to researchers and industry experts in the field of construction materials engineering. Interestingly in the literature, zeolite minerals have the ability to absorb carbon dioxide and thus aid in reducing the concentration levels present in the atmosphere. Zeolites are very stable solids that are resistant to environmental conditions that challenge many other materials. They possess high melting points and can exhibit resistance to temperatures exceeding 1000°C. They can also resist high pressure, do not dissolve in water or inorganic solvents and their unreactive nature means that they exhibit no harmful environmental impacts. I believe that this makes them an ideal investigative compound to consider in terms of being adopted as a cement replacement in construction material. Zeolites have been used as a supplementary cementitious material in the construction industry and both natural and synthetic zeolites have shown interesting properties as mineral additions, notably increased compressive strength, resistance to sulphate attack and favourable leaching properties. However, there has been minimal research carried out on synthetic zeolites in this area in contrast to the abundance of natural zeolite study and notably research considering using zeolites as replacements for rather than in addition to cement. In this research programme, synthetic and natural zeolites were used to partially replace cement in mortar samples. Synthetic zeolites 3A, 4A and 13X were used to replace 5, 10 and 15% of the total cement mass in the mortar specimens with chabazite, mordenite, natrolite and philipsite chosen as a selection of natural zeolites. Ordinary Portland cement was used with a water-cement ratio of 0.40 and a sand-cement ratio of 1:3. All specimens were water-cured at 20°C before a suite of laboratory tests were performed, comprising of; specific gravity, ultrasonic pulse velocity, compressive strength testing, scanning electron microscopy, x-ray diffraction and Fourier transform infrared spectroscopy. All test results were determined at ages of two, seven, twenty-eight and seventy curing days. The research study demonstrated that mortar samples produced with zeolite incorporation as a replacement of cement demonstrated comparatively good engineering and chemical compositional properties when compared to control mixes. Encouraging data was recorded namely for the utilisation of mordenite and philipsite zeolite types, in that the zeolites demonstrated increased compressive strength in comparison to the control mortar as well as having decreased density and increased compactness. Notably, mordenite and philipsite can be utilised as a way of decreasing the cement content needed in a given mortar mix, indeed replacement of cement at 10 and 15% both produced increased compressive strength recordings when compared to both the control and synthetic zeolite incorporated samples.

Published

2021

9. Effect of Mix design parameters on the properties of cementitious composites incorporating volcanic ash and dune sand

Author

Jad Bawab, Hilal El-Hassan, Amr El-Dieb, and Jamal Khatib

Subjects

Volcanic ash, Dune sand, Cementitious, Sustainability, Environment, Superplasticizer, Engineering (General). Civil engineering (General), TA1-2040, Building construction, TH1-9745

Abstract

This study examines the properties of cementitious composites incorporating volcanic ash (VA) and dune sand. The effect of five mix design parameters was studied using the Taguchi method. The fresh, mechanical, and durability properties of sixteen mixes were evaluated. To convert the evaluation from single criterion to multi-criteria, a hybrid Taguchi-TOPSIS was employed. Results showed that the optimum composite mix was made with a binder content of 500 kg/m3, a water-to-binder ratio of 0.5, VA replacement of 20%, dune sand replacement of 20%, and SP content of 0.75%. The optimum mix had a flow, final setting time, 28-day compressive strength, volume of permeable voids, and calcium leaching strength retention of 175 mm, 440 min, 50.5 MPa, 11.3%, and 78.8%, respectively. Portlandite, tobermorite, and gismondine were characterized as hydration products, while calcite and dolomite were also detected. This work provides an advanced understanding of the impact of mix design parameters on various properties while optimizing their levels for superior performance.

Published

2023

10. Self-Flowable Rich Cementitious Matrices for Ferrocement Jacketed Beam-Column Joint

Author

Revathy, J., Gajalakshmi, P., Vijayan, D. S., Rajalakshmi, M., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Kolathayar, Sreevalsa, editor, Ghosh, Chandan, editor, Adhikari, Basanta Raj, editor, Pal, Indrajit, editor, and Mondal, Arpita, editor

Published

2022

11. A Review of Waterborne Polymer–Cementitious Composite Repair Materials for Application in Saline Soil Environments: Properties and Progress

Author

Yan’e Yang, Bo Pang, Yunsheng Zhang, Minghui Wang, Gaixia Miao, and Aoxiang Zhou

Subjects

waterborne polymers, cementitious, repair materials, bonding, durability, Building construction, TH1-9745

Abstract

The properties of a large number of concrete infrastructures in China are deteriorating year by year, raising the need for repairing and strengthening these infrastructures. By introducing waterborne polymers into a cement concrete system, brittle cracks and easy bonding performance defects of concrete can be compensated for to form a long-life, semi rigid, waterborne polymer-modified cementitious repair material with a promising development prospect. This paper investigates the modification effect of polymer emulsions on ordinary cement mortar. Our research mainly focused on the physical and mechanical properties, durability, microstructure and application status of waterborne polymer-modified cementitious composites. Literature studies show that with the increase in waterborne polymer content (0 wt%~20 wt%), the performance of cement mortar significantly improves, which in turn expands its application range. Compared with ordinary cement mortar, the introduction of waterborne polymers blocks some of the pores in the cement to a certain extent, thus improving its permeability, freeze–thaw resistance and durability. Finally, this paper describes the application of waterborne polymer–cementitious composites in western saline soil environments, as well as discusses the prospects of their development.

Published

2024

12. Effect of Nano Materials on the Cement and Concrete Properties.

Author

Goyal, R., Verma, V. K., and Singh, N. B.

Abstract

The importance of nanomaterials has been known for many years, but their usage in cement and concrete production is not accelerated and emphasized extensively. Cement and concrete are the base input material for the construction industry, and the industry is facing tremendous pressure to reduce its greenhouse gas emission (GHG); in 2021, the cement industry emitted about 7% GHG, equal to 2.5 Giga Ton gases of global GHG emission. It is estimated that by enhancing various supplementary cementitious materials (SCM), approximately 9% of the GHG emission of the cement industry can be reduced globally. It is also known that the cement hydration process is very sensitive and altered by many factors such as temperatures, amount of water, surface area, chemical properties, mineral phases, and type of SCM used. The alteration of hydration has adverse influences on cement and concrete performance. Nanomaterials can play an essential role by offsetting the adverse effects of high usage of SCMs in the cement, helping in increasing sustainability by reducing the intensity of CO2, and offering value-added features like self-sensing self-cleaning, antibacterial, anti-fungal, anti-algae, and antistain in the cement other than cement strength, which may promote the use of blended cement and replace ordinary Portland cement in the construction industry. This comparative review aims to understand nanomaterials' advantages and challenges and compare their role and their influence on the cement hydration process based on the types of nanomaterials and their nature as Pozzolanic Nanomaterial (nano SiO2, nano MgO, Nano CaCO3, Nano Metakaolin), Metal oxide Nanomaterial (nano TiO2, nano CuO, nano ZnO, nano Al2O3, nano Fe2O3) and Carbon Based Nanomaterial (Carbon Nanotubes CNTs, Carbon Nano Fibers CNFs, Graphene Oxides). [ABSTRACT FROM AUTHOR]

Published

2023

13. Additive construction in practice – Realities of acceptance criteria.

Author

Kreiger, Megan, Kreiger, Eric, Mansour, Stephan, Monkman, Sean, Delavar, Mohammad Aghajani, Sideris, Petros, Roberts, Casey, Friedell, Matthew, Platt, Shawn, and Jones, Scott

Subjects

*CONCRETE construction, *BETROTHAL, *THREE-dimensional printing, *ACADEMIA, *ADDITIVES

Abstract

Additive Construction has increased dramatically within the United States in the last few years. Efforts to develop acceptance criteria have increased since 2020 and are being developed through integration of research efforts and early engagement with partners across academia, industry, and government. This review paper builds on the work by Bos et al. (2022) through addressing gaps identified and outlines developments within the United States through engagements with the international community to align experts within the field towards common goals, acceptance criteria, and the early integration of acceptance criteria with lessons learned for Additive Construction in practice. [ABSTRACT FROM AUTHOR]

Published

2024

14. Development of Vegetable Fibre-Mortar Composites of Improved Durability

Author

Akinyemi, Banjo A., Oguntayo, Daniel O., Khan, Anish, Jawaid, Mohammad, Series Editor, and Khan, Anish, editor

Published

2021

15. Top-Down Production of Nano-Seeds from Activated Fly Ash Tuned for Enhancing the Early Strength in Blended Cements.

Author

Sobolev, Konstantin, Pradoto, Rani, Flores-Vivian, Ismael, Kozhukhova, Marina, and Zhernovskaya, Irina

Subjects

*FLY ash, *MORTAR, *PORTLAND cement, *HEAT of hydration, *CEMENT, *HEAT flux

Abstract

To achieve the new level of blended cement performance, the slurries of Class C and F fly ash were mechano-chemically activated in a vibro-mill with superplasticizer and nanosilica. The resulting activated products were tested in mortars replacing up to 30% portland cement. The activation process resulted in the formation of nano-seed clusters and micronized ash particles that both significantly improve the early strength of mortars as well as allow for the replacement of portland cement with industrial by-products. A small amount, 0.1% (of a binder weight), of nanosilica was used in selected compositions to improve the process of activation and facilitate the formation of nano-seeds. Due to an intensive activation of fly ash in the vibro-mill and the formation of nano-seed hydration products, the increase in the heat of the hydration flux and improvement of the mechanical properties such as compressive strength, especially in the early stages of hardening, were achieved. It is envisioned that fly ash activation and the use of supplementary cementitious materials as a precursor can induce a denser structure of cementitious matrix due to better particle packing realized with the application of the nano-seed product, nanosilica, ultra-fine particles of fly ash, and the formation of a refined C-S-H structure realized with the incorporation of the nano-seed particles. [ABSTRACT FROM AUTHOR]

Published

2022

16. A Study on the Healing Performance of Solid Capsules for Crack Self-Healing of Cementitious Composites.

Author

Kim, Yong Jic, Choi, Yun Wang, and Oh, Sung-Rok

Subjects

CEMENT composites, SELF-healing materials, SOLIDS, COMPRESSIVE strength, TENSILE strength, PERFORMANCE theory

Abstract

The purpose of this study is to investigate the healing performance of solid capsules made of cement as a basis for manufacturing self-healing capsules that can heal cracks in cementitious composites. The solid capsules were mixed with 5%, 10%, and 15% concentrations on the cement. The self-healing performance of cementitious composites with solid capsules was investigated through three evaluations. First, the mechanical strength-healing performance was evaluated through a re-loading test. Second, the durability-healing performance was evaluated through a permeability test. Finally, the crack-healing performance was examined by observing the crack widths. Through evaluation of the healing performance of the solid capsules, the healing performance of the compressive strength was found to be high when the capsule proportion was 10% and its size was within the range of 300 μm to 850 μm. Furthermore, the splitting tensile strength showed a high healing performance when the capsule proportion mixed was 15% and its size was 850 μm. In the case of the permeability test, a capsule size of 850 μm showed a healing effect greater than 95%. Cracks with a width of up to 200 μm tended to heal using capsules with a size of 600 μm to 850 μm. [ABSTRACT FROM AUTHOR]

Published

2022

17. Editorial: Advanced cementitious materials and structures under extreme conditions

Author

Xiaoshan Lin, Jiafei Jiang, and Paolo Del Linz

Subjects

cementitious, concrete structure, extreme condition, seismic, composite, temperature, Technology

Published

2022

18. Geopolymer- and Cement-Based Fabric-Reinforced Matrix Composites for Shear Strengthening of Concrete Deep Beams: Laboratory Testing and Numerical Modeling.

Author

Khir Allah, Nour, El-Maaddawy, Tamer, and El-Hassan, Hilal

Subjects

CONCRETE beams, SHEAR strength, TESTING laboratories, COMPOSITE numbers, REINFORCED concrete, COMPOSITE construction

Abstract

This paper examines the effectiveness of using carbon fabric-reinforced matrix (C-FRM) composites to improve the shear response of reinforced concrete (RC) deep beams. Ten RC deep beams were tested. Test variables included the presence of internal steel stirrups, number of C-FRM layers, angle of inclination of the second layer of C-FRM, and type of matrix. In the absence of minimum steel stirrups, the use of one layer of C-FRM with cementitious and geopolymeric matrices resulted in 95% and 77% shear strength gains, respectively. Increasing the number of C-FRM composites to two layers insignificantly increased the shear strength gain. Positioning the second layer of C-FRM in the vertical direction tended to be more effective than placing it in the horizontal direction. The gain in the shear capacity was less pronounced in the presence of steel stirrups, where a maximum shear strength gain of 18% was recorded. Numerical models were developed to predict the shear response of the tested beams. Outcomes of the numerical modeling were in good agreement with those obtained from the tests. The inclusion of a bond–slip law at the fabric–matrix interface insignificantly reduced the predicted shear strength. The ratios of the predicted-to-measured shear capacity of the models with and without the bond–slip law were, on average, 0.90 and 0.95, with corresponding standard deviations of 0.09 and 0.11, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

19. Humic acid assisted stabilization of dispersed single-walled carbon nanotubes in cementitious composites

Author

Hu Tao, Jing Hongwen, Li Luan, Yin Qian, Shi Xinshuai, and Zhao Zhenlong

Subjects

single-walled carbon nanotubes, humic acid, dispersed stabilization, cementitious, Technology, Chemical technology, TP1-1185, Physical and theoretical chemistry, QD450-801

Abstract

Significant research has been done in recent decades in the field of the dispersion of carbon nanotubes in aqueous solutions and the reinforcement of ordinary Portland cement (OPC). However, the cementitious mixture, as an alkaline environment, easily leads to the re-agglomeration of dispersed single-walled carbon nanotubes (SWCNTs) and influences their enhancing effects. Humic acid (HA) is a type of natural organic matter which can assist the stabilization of dispersed single-walled carbon nanotubes in cementitious composites. The present study characterizes the influence of HA in stabilizing the dispersion of SWCNTs by means of ultraviolet spectrophotometer tests. The fluidity of fresh cement slurry and mechanical performance of hardened OPC pastes were measured to better illustrate the dispersion of SWCNTs in real cement composites. The results not only reveal that the addition of an alkaline environment to the SWCNT suspensions results in a rapid decrease of the dispersion, but also suggest that the appropriate content of HA (0.12 wt.%) can play a significant role in stabilizing the dispersion of SWCNTs. When the mixed hybrid of SWCNTs and HA with a concentration of HA/c equal to 0.05 wt.% is used, the fluidity of the fresh cement slurry experiences a maximum decline and this mixture content of materials will dramatically increase the compressive and flexural strength by about 31% and 48%, which indicates that more SWCNTs are in a dispersed state under this concentration. SEM images further prove that a suitable HA/c can inhibit the expansion of cracks in the cementitious composites.

Published

2019

20. Physio-chemical and microstructural characteristics of selected pozzolanic materials for possible utilization in the cement and concrete production

Author

D. O. Oyejobi, S. A. Raji, S. T. Aina, A. Siva

Subjects

aquatic, agricultural, cementitious, sem, xrf, xrd, Technology, Geophysics. Cosmic physics, QC801-809

Abstract

Abundant aquatic animal by-products are available in Nigeria which include clam, oyster, rock Snail and periwinkle shells. These are usually dumped on open lands without any economic value after fleshy parts of these animals had been consumed by humans, hence, result into environmental problems. In the agricultural sector, Rice husk and Palm oil fuel ashes are by-products from rice and palm oil industries after the husks have been used as source of fuel. Disposal of these wastes are always a major issue as they constitute nuisance to the environment. This research has collected and characterized these wastes in the laboratory to ascertain their suitability as supplementary cementitious materials. With this study, physical properties such as particle size, specific gravity, specific surface area and morphology are conducted by Scanning Electron Morphology, SEM; chemical analysis are carried out with the aid of X-ray Fluorescence (XRF), for microstructure examination, X-ray Diffraction (XRD) machine is used for detecting minerals in the materials while Field Emission Scanning Electron Microscopy and Energy-Dispersive X-ray analysis (FESEM-EDX) are used for image and element detection. The results of these analyses will help in the future work of pozzolanic and geopolymer construction in Nigeria. The results are further compared with previous literature to see their compatibility and discrepancy.

Published

2019

21. AIR POLLUTANTS MITIGATION BY USING VARIOUS FORMS OF PHOTOCATALYTIC CEMENTITIOUS COATINGS MATERIALS

Author

Ayat Hussein, Riyad H. Al Anbari, and Maan S. Hassan

Subjects

Cementitious, Coatings, mixtures, photocatalytic, air pollutants, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Nitric oxide generated from various sources like car combustion is one of the most surrounding pollutants, which can be transferred from one form to another in the presence of sunlight. Titanium dioxide considered one of the most environmentally friendly active photocatalytics that can be used with building materials safely and effectively to react with nitric oxides. To study the possibility for the reduction of air pollutants like nitric oxides, two types of substrates coatings were prepared. First, mixing nano particles of TiO2 with cement paste in two percents 3% and 6%. Second, mortar substrates coated with nano TiO2 aqueous solution. Two coating methods have been used dip and spray. A laboratory test procedure was adopted to assess the performance of the prepared photoactive specimens. The specimens were subjected to NO gas and there efficiency in gas removal was monitored with time. Results showed the effectivity of coating building materials with titanium dioxide, the removal of gaseous pollutants like nitric oxide reached to 98.85% when spray and dip methods are used. Mixing nano titanium with a percent of 3% was also efficient in the removal of nitric oxides, the removal reached to 97%. It was concluded that spray method was more practical to be used.

Published

2019

22. A Study on the Healing Performance of Solid Capsules for Crack Self-Healing of Cementitious Composites

Author

Yong Jic Kim, Yun Wang Choi, and Sung-Rok Oh

Subjects

cementitious, composites, crack, self-healing, solid capsules, Crystallography, QD901-999

Abstract

The purpose of this study is to investigate the healing performance of solid capsules made of cement as a basis for manufacturing self-healing capsules that can heal cracks in cementitious composites. The solid capsules were mixed with 5%, 10%, and 15% concentrations on the cement. The self-healing performance of cementitious composites with solid capsules was investigated through three evaluations. First, the mechanical strength-healing performance was evaluated through a re-loading test. Second, the durability-healing performance was evaluated through a permeability test. Finally, the crack-healing performance was examined by observing the crack widths. Through evaluation of the healing performance of the solid capsules, the healing performance of the compressive strength was found to be high when the capsule proportion was 10% and its size was within the range of 300 μm to 850 μm. Furthermore, the splitting tensile strength showed a high healing performance when the capsule proportion mixed was 15% and its size was 850 μm. In the case of the permeability test, a capsule size of 850 μm showed a healing effect greater than 95%. Cracks with a width of up to 200 μm tended to heal using capsules with a size of 600 μm to 850 μm.

Published

2022

23. Tensile stress strain model of polyvinyl chloride/calcium carbonate (PVC/CaCO3) nanocomposite plank

Author

Sary A. Malak

Subjects

Ductility, Porosity, Tensile strength, Toughness, Rupture strains, Cementitious, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

This paper presents the tensile stress strain model of a recyclable polyvinyl chloride/calcium carbonate (PVC/CaCO3) thermo-formable, fire/water proof resistant, and durable composite mineral plank. The paper presents experimentally obtained material stress-strain properties in direct tension as a function of its parameters including thickness, surface texture and grain alignment. With an increase in thickness from 1 mm (0.039 in.) to 12 mm (0.47 in.) for rough surface texture and parallel grain alignment, tensile and rupture strengths decreased from 27.4 MPa (4.11 ksi) to 14 MPa (2.1 ksi) and from 14 MPa (2.1 ksi) to 6 MPa (0.9 ksi) respectively. Strains at rupture increased from 0.01 to 0.02 while the modulus of elasticity decreased from 23078 MPa (3462 ksi) to 2139 MPa (320.85 ksi). Smoothness of surface texture increased the ultimate and rupture stresses by 16% while rupture strains increased by 45% leading to a more ductile material. Grain orientation perpendicular to the load direction resulted in an 18% reduction in ultimate strength. The paper proposes models for predicting the stress strain relationship including modulus of elasticity, toughness, stress and strain in the proportional, ultimate and rupture states in terms of the material parameters. The developed models are essential for establishing code requirements and design criteria for structural members retrofitted with this type of composite.

Published

2021

24. Surface Treatment of Cementitious Composites by Ultrasound and Its Effect on Durability Performance.

Author

Shi, Yong and Shi, Z. M.

Subjects

*SURFACE preparation, *CEMENT composites, *CONCRETE testing, *LASER microscopy, *ACCELERATED life testing

Abstract

In this study, the method of changing the surface layer microstructure of cementitious composites by ultrasonic surface treatment at the early stage of hydration is introduced, and the formation mechanism of the gel phase powder layer (GPPL) formed by ultrasound is analyzed. The microstructure of GPPL is observed and analyzed by laser confocal microscopy scanning (LCMS), scanning electron microscopy (SEM) and backscattered electron (BSE) imaging. The phase component is measured by X-ray diffraction (XRD) and thermogravimetry (TG). Four ultrasonic frequencies (28, 40, 80, and 120 kHz) were used in the experiment. Apparent density and water vapor permeability of the cement paste specimens with GPPL structure were tested. The accelerated carbonation test of concrete and mortar specimens with GPPL structure were carried out. It is proved that GPPL structure can significantly improve the carbonation resistance performance of cementitious composites. Finally, the prospects for engineering applications of this method are presented. [ABSTRACT FROM AUTHOR]

Published

2021

25. Improving the durability of organic matter in cement-treated sludge using metakaolin and lime.

Author

Tan, Yun-zhi, Ke, Rui, and Ming, Hua-jun

Subjects

*ORGANIC compounds, *KAOLIN, *CALCIUM ions, *DURABILITY, *COMPRESSIVE strength, *HUMIC acid, *ION traps, *CEMENT

Abstract

Solidified sludge, a potentially useful engineering material, contains organic matter that decomposes, releasing humic acid. The resultant corrosion reduces the compressive strength of the solidified sludge. This can be ameliorated by adding small quantities of lime and cement, which creates a strongly alkaline environment; unfortunately, the improvement is not long-lasting. We attempted to counteract this by adding metakaolin, which can capture calcium ions and form a stable binder in the solidified soil. The resulting material proved strongly resistant to the erosive effect of humic acid, improving and maintaining the durability throughout the curing period (180 days). [ABSTRACT FROM AUTHOR]

Published

2021

26. An Overview of Pumice Stone as a Cementitious Material – the Best Manual for Civil Engineer.

Author

Rashad, Alaa M.

Abstract

Pumice stone is a natural sponge-like lightweight aggregate formed during the rapid cooling and solidification of molten lava. After suitable preparation, it can be used as an aggregate to produce lightweight concrete or as a cementitious material to produce blended cement or geopolymer. This article focused on the influence of pumice powder (PP) on fresh properties and hardened properties of conventional cementitious materials and geopolymers. Additionally, different modification methods carried out to modify some properties of conventional cementitious materials containing PP have been included. This review showed that the incorporation of PP in the traditional cement matrix has some benefits such as increasing thermal and acoustic insulation, increasing fire resistance, increasing abrasion resistance, decreasing unit weight, decreasing hydration heat, decreasing drying shrinkage, decreasing autoclave expansion, increasing sulfate resistance, increasing seawater resistance, increasing acid resistance, increasing electrical resistivity, decreasing alkali silica reaction (ASR) expansion, decreasing porosity, water absorption and permeability. On the other hand, it has a negative effect on workability, mechanical strength and increasing carbonation rate. This review also confirmed that PP has a promising future in the field of alkali-activated and geopolymer materials. [ABSTRACT FROM AUTHOR]

Published

2021

27. Empirical models for permanent deformation of cement-grouted bituminous mixes

Author

Daka Sita Rami Reddy and Kusam Sudhakar Reddy

Subjects

Cement, Materials science, Mechanics of Materials, Asphalt, Empirical modelling, General Materials Science, Cementitious, Deformation (meteorology), Mortar, Composite material, Porosity, Material technology, Civil and Structural Engineering

Abstract

Cement-grouted bituminous (CGB) mix is a semi-flexible type of pavement comprising an open-graded (porous) bituminous mix grouted with a cementitious mortar. CGB mixes have the advantages of both flexible and rigid pavements. This hybrid material of bituminous mix and cement grout offers better rut resistance and is more resistant to fuel and oil spillage compared to conventional bituminous mixes. This paper presents the details of different investigations carried out for the evaluation of the permanent deformation characteristics of different CGB mixes. A conventional bituminous concrete mix was also tested for comparison. The permanent deformation susceptibility of different CGB mixes was evaluated in a wheel tracking test facility. The rut depth developed after 20 000 load applications in the specimens conditioned at 60°C was correlated to different porous bituminous mix and CGB mix parameters. The empirical models presented in this paper will be useful for estimating the relative rutting performance of different CGB mixes in terms of their design parameters such as aggregate gradation, binder content and air voids in the mix.

Published

2023

28. Evaluation survey of concrete composite using nano and micro silica materials for better properties

Author

Mohit Verma

Subjects

Cement, Aggregate (composite), Materials science, Flexural strength, Silica fume, Fly ash, Nano, Ultimate tensile strength, General Medicine, Cementitious, Composite material

Abstract

Concrete will be the very flexible material. Because of continuous and persistent demands made on concrete to assemble the several problematic necessities, extensive examination work is being carried out in region of concrete method. The engineers have frequently pushing restrictions to expand its presentation with support of supplementary cementitious materials and innovative chemical admixtures such as steel slag, fly ash, and silica fume and so on. Nanomaterial concrete is advanced one the composition of nanomaterial concrete it has following water, coarse aggregate, cement nano silica grain of the size of 10 nm-140 nm and fine aggregate. The nano materials like nano alumina, nano titanium oxide, nano silica, and carbon nano tubes, so on, which are currently utilized in concrete to change its strength assets. The “nano materials” have functions or properties diverse from same materials of bigger size. The “nano materials” have a bigger value of ratio among volume and surface region than other same particles in larger size, creating the “nano-materials” much reactive. The “nano silica” will react with C3S and C2S in cement &generate CSH-2 that will create a solid &strong connection of gel. In current survey, properties of strength like split tensile, compressive, and flexural strength of M50 and M40 grades of concrete with utilization of nano silica (1%, 1.5%, 2%, 2.5%) and micro silica (5%, 7.5%, 10%, 15%) as incomplete replacement of cement were deliberated. It was establish from evaluation survey that concrete composites with better properties could be generated utilizing nano silica, micro silica, and mixture of nanosilica and micro silica.

Published

2023

29. Dataset of wind blow sand erosion test on ultrasonic surface treated cementitious composites

Author

Y Shi and ZM Shi

Subjects

Ultrasonic, Surface treatment, Wind blown sand, Erosion, Cementitious, Computer applications to medicine. Medical informatics, R858-859.7, Science (General), Q1-390

Abstract

In this paper, we take cement mortar and paste as specimens, a novelty method named ultrasonic surface treatment(UST) was employed to form a hardening surface layer on cementitious specimens to improve its wind-blown sand erosion resistance, surface hardness and apparent density. The specimens with curing ages of 1-day, 3-days, 7-days, and 28-days were adopted. The wind blown sand erosion test was carried out in a wind-blown sand erosion test system, which simulated a wind blown sand environment of a wind speed of 30 m/s and a sand feed rate of 30 g/min. The erosion angle of 30°, 60°, 90° were adopted. The mass loss in erosion process was measured, then the erosion resistance was calculated. The surface hardness was tested with a Vickers micro hardness tester. The apparent density of cement paste was measured with mass volume method. The data provided reveal the improvement on wind blown sand erosion resistance, surface hardnenss and apparent density of cementitious materials with ultrasonic surface treatment. That may be used in the investigation on improving the erosion resistance and to evaluate the effectiveness of the UST method on cementitious materials.

Published

2020

30. The physico-mechanical influence of dehydroxylized activated local kaolin: A supplementary cementitious material for construction applications

Author

Kwame K. Marfo, David Dodoo-Arhin, Benjamin Agyei-Tuffou, Emmanuel Nyankson, David O. Obada, Lucas N.W. Damoah, Ebenezer Annan, Abu Yaya, B. Onwona-Agyeman, and Mark Bediako

Subjects

Cementitious, Dehydroxylation, Kaolinite, Construction, Mortars, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

This work presents the effect of partially replacing metakaolin with Portland limestone cement to produce mortars for construction. Teleku Bokazo kaolin was explored as a SCM in the production of mortars. The hydration product between Portland limestone and metakaolin was studied. The kaolin was heat treated to form metakaolin and partially used to replace Portland limestone cement (PLC) in mortars to explore the optimum replacement and its mechanical and durability effect. The samples were characterized using X-ray diffraction (XRD) for phases and crystallinity of the kaolin. Fourier transform infrared spectroscopy (FTIR) and Scanning electron microscopy (SEM) gave information on the functional groups formed during the hydration and structure and surface morphology respectively. The pastes and mortars produced were subjected to setting time, water absorption, flexure and compression strength test. The mechanical properties were observed to increase with increasing metakaolin replacements. Therefore, from the results obtained, it is suggested that ∼20 % replacement of Portland limestone cement with Teleku Bokazzo metakaolin can be very suitable for construction applications.

Published

2020

31. The Use of Photocatalytic Cementitious Coatings to Reduce Nitric Oxide from Ambient Air

Author

ayat Hussian, Riyad Al Anbari, and Maan Hassan

Subjects

air pollution, cementitious, coatings, no, photocatalysis, titanium dioxide, Science, Technology

Abstract

Titanuim dioxide represents a novel photocatalyst material that can be used in different ways for air pollutants remediation. Air pollutants that are spreaded in the surrounding air could be transferred to more complex materials, especially in the presence of sunlight. To study the possibility for the reduction of these pollutants a laboratory tests have been conducted on the coated specimen substrate by using nitric oxide as pollutant gas, and there efficiency in gas removal was monitored with time. Two different particle sizes of TiO2 have been used; micro with particle size range between 150-200 nm and nano PC105 with particle size 20+ 5 nm, both are 100% anatse. Two coatings methods were applied on cementitious substrate material dip and spray to study the photochemical reaction with TiO2, aqueous solution prepared by dispersing 3g/L of TiO2 with deionized water and ethanol. Results show that using nano and micro size TiO2 aqueous solutions were effective in the removal of nitric oxidewith variations in the time consumed for the removal. Using nano aqueous solution in both dip and spray methods gives the same removal efficiency reached to 98.85% ,while using micro aqueous solution the removal reached to 98.08% when dip method was used and 87.69% when spray method was used.

Published

2018

32. Numerical Analysis of Shrinkage Process Based on Experimental Data.

Author

Kucharczyková, Barbara, Šimonová, Hana, Frantík, Petr, and Kocáb, Dalibor

Subjects

NUMERICAL analysis, EXPANSION & contraction of concrete, DATABASES, FORECASTING, PREDICTION models, RESEARCH teams

Abstract

This paper focuses on the comparison of experimentally obtained data with the shrinkage model B4 designed by a research group led by Professor Z. P. Bažant. Two cementitious materials, one having a high water-cement ratio (w/c) and one having a low w/c, were prepared for the experiment. Intentionally, the test specimens were not protected from drying during the entire period of measurement. Test results confirmed that the actual shrinkage process as measured does not correspond with the prediction model, especially during its early age. Shrinkage during the plastic and semi-plastic stages of the solidification process is not reflected in the predicted shrinkage curve. However, if the start time of the evaluation of the experimental data corresponds to the time of maximum derivatives of the temperature, length changes, and ultrasonic pulse velocity curves, better correspondence between the experiment and prediction model is observed for material with a low w/c. However, this approach does not improve the correspondence between the experiment and numerical prediction in the case of material with a high w/c. [ABSTRACT FROM AUTHOR]

Published

2020

33. Effects of Wet Separated and High Speed Milling Fly Ash Added in High Volume to Cementitious Materials.

Author

Haider, Usman, Ali, Asif, Bittnar, Zdeněk, Humayon, Muhammad, and Valentin, Jan

Subjects

*FLY ash, *FLEXURAL strength testing, *LIGNITE, *MILLING (Metalwork), *EXPANSION & contraction of concrete, *COMPRESSIVE strength

Abstract

In this research high speed milling was carried out on particles of brown coal raw fly ash, on second layer, and on third layer particles obtained from wet separation of brown coal raw fly ash. Due to milling process, median particle size d50 of raw fly ash, second layer, and third layer reduced by 46%, 23%, and 77%, densities reduced by 11%, 17%, and 8% respectively. Due to milling process, formation of agglomerations was observed, the standard deviation of the chemical composition of each element from the mean value reduced. After milling, high volume cementitious paste mixes were prepared with 60% cement replacement. Due to the milling process the increase in compressive strength at 28 and 90 days was observed for raw fly ash is 59% and 16%, for second layer is 12% and 15%, for third layer and milled third layer is 78% and 75%. Flexural strength testing showed that due to the milling process the deflections at maximum loads have reduced considerably leading to brittle behavior of milled cementitious specimens. The testing for Mercury Intrusion Porosimetry showed that the cementitious specimens of third layer have maximum concentration of large capillary pores between 0.05 and 10 µm, whereas, all others have maximum concentration of medium capillary pores between 0.01 and 0.05 µm. Autogenous shrinkage of cementitious specimens was measured for first sixteen hours after mixing which showed that the second layer particles have the least shrinkage as compared to all other specimens. [ABSTRACT FROM AUTHOR]

Published

2020

34. Solidification of Dredged Sludge by Hydraulic Ash-Slag Cementitious Materials

Author

Zhu, Shu-Jing, Qin, Ying, Hwang, Jiann-Yang, Ikhmayies, Shadia Jamil, editor, Li, Bowen, editor, Carpenter, John S., editor, Hwang, Jiann-Yang, editor, Monteiro, Sergio Neves, editor, Li, Jian, editor, Firrao, Donato, editor, Zhang, Mingming, editor, Peng, Zhiwei, editor, Escobedo-Diaz, Juan P., editor, and Bai, Chenguang, editor

Published

2016

35. Failure mechanism of bonding between natural fiber and cement matrix at high temperature.

Author

Fu, Zishuo, Yao, Yao, Duan, Yugang, Ben Wang, and Li, Xiaohan

Subjects

*NATURAL fibers, *FIBER cement, *CHEMICAL processes, *HIGH temperatures, *CEMENT composites, *FIBER-matrix interfaces

Abstract

The debonding behavior of natural fibers with cement matrix at elevated temperatures has been investigated by introducing a new test method for measuring the interfacial shear strength between the fibers and the cement matrix in the field of cementitious composites research. In addition, the effects of shrinkage, surface roughness, and tensile strength changes of natural fibers on the interface at high temperatures were analyzed by characterizing the failure process of chemical bonding with the matrix due to changes in the surface functional groups of natural fibers. The results show that the bonding properties between natural fibers and the cement matrix gradually decrease with increasing temperature, which is due to the contraction of the natural fibers in the radial direction at high temperatures leading to debonding with the cement matrix on the one hand, and the degradation of chemical bonding enhancement due to the reduction of polar groups on the surface of the fibers on the other hand, which contributes to the reduction of the interfacial strength between the fibers and the matrix. In the post-high-temperature phase, the temperature dependence of the inherent material properties of the natural fibers leads to a decrease in the mechanical properties as an additional factor affecting the interfacial behavior. This work evaluates the durability of natural fibers in cement matrices under high temperature conditions from the viewpoint of their inherent physical properties and surface chemical properties, providing unique research ideas and insights for related studies. Meanwhile, a new experimental method is introduced in the field of fiber-reinforced cementitious composites interface research, which can be widely attempted to be used in the study of selective combinations of different fiber-matrix interfaces, fiber size selection, and fiber modification to optimize the overall performance of the composites, which is of great significance to the research in this field. • The bonding properties between FCNTs repair mortar and fire exposed old mortar substrate has been investigated. • The bonding strength and microscopic test were performed to determine the mechanism of FCNTs in the ITZ. • An effective prediction model is proposed to quantify the effects of porosity and different FCNTs. [ABSTRACT FROM AUTHOR]

Published

2024

36. Concrete compressive strength variation due to cement source change

Author

Isaac L. Howard, Jared L. Brown, and Robert Varner

Subjects

Cement, Materials science, Variation (linguistics), Compressive strength, Mechanics of Materials, General Materials Science, Cementitious, Composite material, Civil and Structural Engineering

Abstract

Cementitious materials obtained from different sources, although evaluated and classified by the same methods and criteria, inevitably produce concrete with compressive strength variance despite other inputs and constituents remaining constant. This paper investigates the effect of cement by type and source on strength as a function of supplementary cementitious material (SCM) replacement and aggregate type. This was accomplished by compiling and analysing compressive strength data from previous research initiatives; it was concluded that a cement source change can produce coefficients of variation, range and range divided by average compressive strength values up to 18%, 2700 psi (18·6 MPa) and 0·40, respectively, at 14 to 56 d time frames. Concrete comprising SCMs displayed a statistically significant increase in compressive strength variation and a general decrease in compressive strength predictability against mixtures without SCMs when a cement source was changed, and specific aggregate/cementitious material combinations influenced compressive strength variability due to a change in the cement source.

Published

2022

37. Molecular Simulation of Cement-Based Materials and Their Properties

Author

Mohammed Maslehuddin, Tawfik A. Saleh, Mohammed A. Al-Osta, Ime B. Obot, Omar S. Baghabra Al-Amoudi, Ashraf A. Bahraq, and Habib-ur-Rehman Ahmed

Subjects

Cement, Environmental Engineering, General Computer Science, Materials Science (miscellaneous), General Chemical Engineering, Scale (chemistry), Composite number, General Engineering, Energy Engineering and Power Technology, Durability, law.invention, chemistry.chemical_compound, Portland cement, chemistry, law, Phase (matter), Cementitious, Calcium silicate hydrate, Composite material

Abstract

Hydrated cement is one of the complex composite systems due to the presence of multi-scale phases with varying morphologies. Calcium silicate hydrate (C–S–H), which is the principal binder phase in the hydrated cement, is responsible for the stiffness, strength, and durability of Portland cement concrete. To understand the mechanical and durability behavior of concrete, it is important to investigate the interactions of hydrated cement phases with other materials at the nanoscale. In this regard, the molecular simulation of cement-based materials is an effective approach to study the properties and interactions of the cement system at the fundamental scale. Recently, many studies have been published regarding atomistic simulations to investigate the cement phases to define/explain the microscopic physical and chemical properties, thereby improving the macroscopic performance of hardened binders. The research in molecular simulation of cementitious systems involves researchers with multidisciplinary backgrounds, mainly in two areas: (1) cement chemistry, where the hydration reactions govern most of the chemical and physical properties at the atomic scale; and (2) computational materials science and engineering, where the bottom-up approach is required. The latter approach is still in its infancy, and as such, a study of the prevailing knowledge is useful, namely through an exhaustive literature review. This state-of-the-art report provides a comprehensive survey on studies that were conducted in this area and cites the important findings.

Published

2022

38. Bond Behavior of Carbon Fabric-Reinforced Matrix Composites: Geopolymeric Matrix versus Cementitious Mortar

Author

Feras Abu Obaida, Tamer El-Maaddawy, and Hilal El-Hassan

Subjects

carbon fabric, matrix, bond, slip, geopolymer, cementitious, Building construction, TH1-9745

Abstract

This study aims to examine the potential use of a geopolymeric matrix as a sustainable alternative to commercial mortars in carbon fabric-reinforced matrix composites. Single-lap shear tests were conducted to examine the bond behavior at the fabric-matrix interface. Test parameters included the type of matrix (geopolymeric and cementitious matrices) and the bonded length (50 to 300 mm). The geopolymeric matrix was a blend of fly ash/ground granulated blast furnace slag activated by an alkaline solution of sodium silicate and sodium hydroxide. The bond behavior of the geopolymeric-matrix specimens was characterized and compared to that of similar specimens with a cementitious matrix. The specimens failed due to fabric slippage/debonding at the fabric-matrix interface or fabric rupture. The effective bond lengths of the geopolymeric- and cementitious-matrix specimens were 150 and 170 mm, respectively. The geopolymeric-matrix specimens exhibited higher fabric strains, higher ultimate loads, and a steeper strain profile along the bonded length than those of their cementitious-matrix counterparts. New bond-slip models that characterize the bond behavior at the fabric-matrix interface for geopolymeric- and cementitious-matrix specimens were developed. Both models exhibited equal maximum shear stress of 1.2 MPa. The geopolymeric-matrix model had, however, higher fracture energy and higher slip at maximum shear stress than those of the cementitious matrix model.

Published

2021

39. Self-degradable Cementitious Sealing Materials

Published

2010

40. The addition of microsilicas to the ordinary Portland cement (OPC) system

Author

Vazifdar, Rukshana

Subjects

691, Pozzolana, Cementitious, Trimethylsilylation

Published

1996

41. Dynamic increased reinforcing effect of graphene oxide on cementitious nanocomposite.

Author

Li, Chen Yang, Chen, Shu Jian, Li, Wen Gui, Li, Xiang Yu, Ruan, Dong, and Duan, Wen Hui

Subjects

*GRAPHENE oxide, *MICROFIBERS, *CEMENT composites, *STRAIN rate, *BLAST effect, *DEAD loads (Mechanics)

Abstract

Highlights • Increase in reinforcing effect of graphene oxide at strain rate up to 1700 s−1. • Graphene oxide increases DIF when the strain rate reaches different thresholds. • Correlation is found between the increase in DIF and the speed of crack development. Abstract The reinforcing effect of graphene oxide on cementitious materials under high strain rate remains largely unknown. Existing studies on microfiber reinforced cementitious composites showed that the dynamic increase factor (DIF) decreases due to these fibres. This study reports that the reinforcing effect of graphene oxide nanosheets can, in contrast, increase with strain rate. Tensile splitting and compression tests were conducted under both static and dynamic loadings. High strain rate, up to 1700 s−1, is achieved using a split Hopkinson pressure bar apparatus. It is found that the DIF of graphene oxide nanocomposite only increase when the DIF is higher than a threshold which is about 780 and 30 s−1 for compression and tensile test respectively. The increased of DIF was correlated with the speed of crack development and pull-out of the graphene oxide nanosheets. Also, the pull-out or fracture of graphene oxide on fragmented sand was also found a possible contributing factor to the increased DIF. The findings of this study indicate the future potential of atomic-thin nanosheets for materials under extreme impact and blast loading. [ABSTRACT FROM AUTHOR]

Published

2019

42. OPTIMIZED PREPARATION OF RICE HUSK ASH (RHA) AS A SUPPLEMENTARY CEMENTITIOUS MATERIAL.

Author

Isberto, Carmela Denise, Labra, Krystoffer Lloyd, Landicho, Jan Marielle B., and De Jesus, Richard

Subjects

RICE hulls, SILICA fume, EFFECT of temperature on concrete, PRESCRIBED burning, PORTLAND cement, SILICA, MATERIALS

Abstract

For years, supplementary cementitious materials (SCM) has been extensively used as an integral component in the production of concrete. This has been motivated by sustainability efforts and reduced environmental impact. Correspondingly, this study intended to develop an appropriate method for the use of rice husk ash (RHA), a by-product of rice husk (RH) which exists abundantly in the Philippines, as a partial replacement to ordinary Portland cement (OPC). Different studies have suggested optimal percentage replacement values of RHA, from 10% to 20%, which demonstrated vast improvement in strength of the resulting blended concrete. These optimal values, however, immensely depends on the burning preparation of RHA which adversely affects the amorphous silica components, and therefore the pozzolanic activities of RHA in concrete. In this research, a potential approach to convert RH into optimized and highly reactive RHA by controlled burning and grinding is provided. The effect of RHA in the strength of cement mortar was investigated through the various proportions of 5, 10, 15, and 20% RHA by weight replacement of cement. Some of the findings are: (i) controlled combustion of RH with temperature ranging from 400 to 600 °C and a slow method of cooling for 6 to 8 hours were some of the critical factors needed to produce high silica content, (ii) concrete containing up to 10% RHA replacement is optimal in maximizing the strength of cement mortar, and (iii) the incorporation of RHA in concrete by 15% and 20% replacement by weight indicated a lower workability. [ABSTRACT FROM AUTHOR]

Published

2019

43. EXPERIMENTAL INVESTIGATION ON DURABILITY PROPERTIES OF CONCRETE ADDED WITH NANO SILICA.

Author

Prashanth, R., Senthil Selvan, S., and Balasubramanian, M.

Subjects

*SILICA fume, *CONCRETE durability, *PORE size distribution, *CONCRETE mixing, *PERMEABILITY of concrete, *HYDROTHERAPY

Abstract

The study examined the durability properties of concrete added with Nano-silica. Lifeline buildings and other infrastructures have highlighted concrete durability issues. The use of nanoparticles in materials based on cement has been recently attractive because of the unique properties at Nano-level that they are able to achieve. This can be prominently utilized in enhancing the ductility of cement-based composites which are generally brittle, also cracks at the nanoscale could be arrested by incorporating carbon nanotube or carbon nanofiber. Nano-silica has a unique advantage in the potential pozzolanic-reaction with cement hydration products over other nanoparticles. Addition of Nano-silica is known to redefine pore size and distribution which would alter the durability of the concrete. Durability properties were tested by checking how concrete of grade M30, with 2% by weight of its cementitious materials replaced with Nano-silica, withstands in alkali environment, acidic environment, sulphate environment, and in a water curing in comparison to conventional concrete of M30 grade in respective environments. The Nanofiller effect and the pozzolanic-reaction increased the homogeneity of the microstructure and the porosity, particularly at the Interfacial Transition Zone, which decreased the permeability of deteriorating gases. Durability tests validated the positive effects of Nano-silica added to concrete. The distribution of pore size also showed that Nano-silica refined the large capillary pores, subsequently decreasing the permeability nature of concrete, enhancing its durability. Also, Nano-silica added concrete mix shows increased compression strength, tensile strength, and flexural strength compared to the conventional concrete mix. [ABSTRACT FROM AUTHOR]

Published

2019

44. AIR POLLUTANTS MITIGATION BY USING VARIOUS FORMS OF PHOTOCATALYTIC CEMENTITIOUS COATINGS MATERIALS.

Author

Hussein, Ayat, Al Anbari, Riyad H., and Hassan, Maan S.

Subjects

AIR pollutants, CEMENT composites, PHOTOCATALYTIC oxidation, TITANIUM dioxide, NITRIC oxide

Abstract

Nitric oxide generated from various sources like car combustion is one of the most surrounding pollutants, which can be transferred from one form to another in the presence of sunlight. Titanium dioxide considered one of the most environmentally friendly active photocatalytics that can be used with building materials safely and effectively to react with nitric oxides. To study the possibility for the reduction of air pollutants like nitric oxides, two types of substrates coatings were prepared. First, mixing nano particles of TiO2 with cement paste in two percents 3% and 6%. Second, mortar substrates coated with nano TiO2 aqueous solution. Two coating methods have been used dip and spray. A laboratory test procedure was adopted to assess the performance of the prepared photoactive specimens. The specimens were subjected to NO gas and there efficiency in gas removal was monitored with time. Results showed the effectivity of coating building materials with titanium dioxide, the removal of gaseous pollutants like nitric oxide reached to 98.85% when spary and dip methods are used. Mixing nano titanium with a percent of 3% was also efficient in the removal of nitric oxides, the removal reached to 97%. It was concluded that spray method was more practical to be used. [ABSTRACT FROM AUTHOR]

Published

2019

45. Use of recycled gypsum in the cement-based stabilization of very soft clays and its micro-mechanism

Author

Guoping Zhang, Annan Zhou, Jun Wu, Li Liu, Henglin Xiao, and Yongfeng Deng

Subjects

Cement, Ettringite, Materials science, Gypsum, engineering.material, Geotechnical Engineering and Engineering Geology, Microstructure, Clinker (cement), chemistry.chemical_compound, Compressive strength, chemistry, engineering, Cementitious, Composite material, Metakaolin

Abstract

This paper presents an experimental study and micro-mechanism discussion on gypsum role in the mechanical improvements of cement-based stabilized clay (CBSC). A soft marine clay at two initial water contents (i.e. 50% and 70%) was treated by reconstituted cementitious binders with varying gypsum to clinker (G/C) ratios and added metakaolin to facilitate the formation of ettringite, followed by the measurements of final water contents, dry densities and strengths in accordance with ASTM standards as well as microstructure by mercury intrusion porosimetry (MIP) and scanning electron microscopy (SEM). Results reveal that the gypsum fraction has a significant influence on the index and mechanical properties of the CBSC, and there exists a threshold of the G/C ratio, which is 10% and 15% for clays with 50% and 70% initial water contents, respectively. Beyond which adding excessive gypsum cannot improve the strength further, eliminating the beneficial role. At these thresholds of the G/C ratio, the unconfined compressive strength (UCS) values for clays with 50% and 70% initial water contents are 1.74 MPa and 1.53 MPa at 60 d of curing, respectively. Microstructure characterization shows that, besides the common cementation-induced strengthening, newly formed ettringite also acts as significant pore infills, and the associated remarkable volumetric expansion is responsible, and may be the primary factor, for the beneficial strength gain due to the added gypsum. Moreover, pore-filling ettringite also leads to the conversion of relatively large inter-aggregate to smaller intra-aggregate pores, thereby causing a more homogeneous matrix or solid skeleton with higher strength. Overall, added gypsum plays a vital beneficial role in the strength development of the CBSC, especially for very soft clays.

Published

2022

46. Eco-efficient cementitious composites with large amounts of waste glass and plastic

Author

Henriette Szilagyi, Dan Bompa, and Ofelia Corbu

Subjects

Materials science, Cementitious, Cementitious composite, Composite material, Civil and Structural Engineering

Abstract

This paper presents an experimental study, which has been lacking to date, into the properties and applications of waste glass–plastic cementitious (WGPC) composites incorporating recycled aggregates as a full replacement of natural aggregates, with direct application in highly eco-efficient construction components. Detailed experimental assessments of the fresh properties, strength and durability characteristics of such composites are undertaken. Particular focus is given to the mix rationale and optimisation process as well as possible routes of exploitation of such materials in construction elements. The experimental assessments showed that such composite materials meet the strength and durability criteria for direct application in practice. The best balance in terms of strength and workability was achieved for a waste glass-to-plastic aggregate ratio of 92/8. The presence of relatively large amounts of recycled waste glass particles with small sizes acted as secondary hydration products and contributed to achieving an adequate strength of the material. Besides a lower unit weight and superior thermal properties compared with those of conventional concrete, WGPC components have shown a reliable behaviour under vehicle impact loading and potential wider application in sustainable non-structural construction applications.

Published

2022

47. Utilisation of supplementary cementitious materials from agricultural wastes: a review

Author

Oluwadamilola Fadele and Mike Otieno

Subjects

Crop residue, Waste management, Mechanics of Materials, Agriculture, business.industry, Sustainability, Environmental science, General Materials Science, Cementitious, business, Material technology, Civil and Structural Engineering

Abstract

This paper presents a critical literature review on the use of supplementary cementitious materials (SCMs) from agricultural wastes (mainly from crop residues) in cementitious systems. The current utilisation of these materials as partial replacement of Portland cement is reviewed with respect to the influence of the materials' characteristics on the performance and the limit of replacement in cementitious systems. In spite of the benefits of SCMs from agricultural wastes (such as rice husk ash, palm oil fuel ash and sugarcane bagasse ash), their unavailability in the required form, heterogeneous nature and insufficient data make it difficult to generalise their performance. Therefore, a review of the existing information available will help to unravel areas of further research, any relationship between the influence of the processing method and materials characteristics on the limit of replacement and performance in cementitious systems and assist in their standardisation and sustainable utilisation. This, coupled with the reproducibility of results, will assist the processing and adoption of other agricultural wastes in cementitious systems.

Published

2022

48. Carbonation curing of alkaline industrial waste for binders: comparison of different wastes

Author

Yuzhuo Zhang, Miao Zhang, Mingyu Zhao, Yanfeng Fang, and Qinghe Wang

Subjects

Materials science, Carbonation, Metallurgy, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, Building and Construction, Industrial waste, 0201 civil engineering, chemistry.chemical_compound, Compressive strength, chemistry, 021105 building & construction, Carbon dioxide, General Materials Science, Cementitious, Curing (chemistry), Civil and Structural Engineering

Abstract

The potential of utilising alkaline industrial waste with weak or no cementitious properties for carbon dioxide (CO2) capture and for new binders by accelerated carbonation was studied; steel slag (SS), calcium carbide residue (CCR) and waste hydrated cement (WHC) were compared. The carbon dioxide uptake and strength development of SS, CCR and WHC were studied and the relationship of strength development with carbon dioxide uptake and characteristics of carbonation products was analysed. The results indicate that carbon dioxide uptake of SS, CCR and WHC strongly depends on the mineral composition: calcium hydroxide (Ca(OH)2) and calcium silicate hydrate (C–S–H) show relatively higher carbonation activity; dicalcium silicate (Ca2SiO4) absorbs less carbon dioxide than calcium hydroxide and C–S–H. The carbon dioxide uptake of SS, CCR and WHC are 6.1, 23.2 and 17.9%, respectively, after 2 h carbonation curing. Compacted SS, CCR and WHC specimens displayed a compressive strength of 74.9, 20.5 and 28.6 MPa after carbonation for 2 h. Compressive strength development depends on carbon dioxide uptake and mechanical properties of raw materials and carbonation products. Calcium carbonate (CaCO3) and amorphous products fill the pore structure, making the matrix denser; improvement of pore structure relates positively to carbon dioxide uptake. The highest compressive strength of compacted SS is mainly caused by the high elastic modulus of SS and formation of C–S–H gel in the carbonation process.

Published

2022

49. Review on mechanical and microstructural properties of cementitious composites with graphene oxide

Author

S. Balaji and A. Swathika

Subjects

Materials science, Scanning electron microscope, Graphene, Oxide, Nanomaterials, law.invention, chemistry.chemical_compound, Properties of concrete, chemistry, law, Ultimate tensile strength, Cementitious, Fourier transform infrared spectroscopy, Composite material

Abstract

Now-a-days nanomaterials are gaining popularity in all fields. In the same way construction industry also joined the line by using nanomaterials as a perfect additive to attain improved properties. In this paper detailed usage of Graphene oxide (GO) with the cementitious material in various ratios is discussed. Different methods to synthesize GO from graphene adapted by different researchers are reviewed. Further, this paper reviews the mechanical properties such as compressive, tensile and flexure strength for GO mixed cement composites at different ratios. In addition to this, microstructural studies such as Scanning Electron Microscopy (SEM), X-ray diffraction (XRD), Mercury Intrusion Porosimetry (MIP), Fourier-Transform Infrared Spectroscopy (FTIR), Energy Dispersive X-Ray Analysis (EDX) or (EDAX) are also reviewed. From this discussion, it is clear that the usage of GO as an additive in concrete provides promising improvement in the properties of concrete.

Published

2022

50. The effect of carbon nanotubes on mechanical properties of structural lightweight concrete using LECA aggregates

Author

Reza Abaeian, Hamid Pesaran Behbahani, Shahram Jalali Mosallam, and Mehran Shahpari

Subjects

Cement, Materials science, Absorption of water, Building and Construction, Carbon nanotube, law.invention, Compressive strength, Properties of concrete, Flexural strength, law, Architecture, Ultimate tensile strength, Cementitious, Composite material, Safety, Risk, Reliability and Quality, Civil and Structural Engineering

Abstract

According to the latest studies, nanoparticles are the best additive materials to improve concrete's mechanical properties. Among these nanoparticles, Carbon Nanotubes (CNTs) are famous for their extreme tensile strength and flexibility. These particles can be used as a reinforcement to increase the mechanical properties of concrete. In the present study, the effects of using CNTs with different dosages were investigated on structural lightweight concrete’s mechanical properties. Structural Lightweight Expanded Clay Aggregates (LECA) were used in the mixture of Structural Lightweight Concrete (LWC) as a substitute for coarse aggregates. Along with LECA, CNTs as a partial replacement for cement with varied weight ratios were added to the lightweight concrete (0.02, 0.1, and 0.3 percent of cement weight). The effects of carbon nanotubes on fresh concrete performance, water absorption, compressive strength, tensile strength, and flexural strength of 7- and 28-day lightweight concrete were carried out. The results indicate that the presence of 0.02% of cement weight of CNTs increased compressive strength, tensile strength, and flexural strength of the 28-day-old lightweight concrete up to 29%, 44%, and 26%, respectively. Moreover, it reduced the water absorption of lightweight concrete by 28.3%. Utilizing more content of CNTs resulted in less mechanical properties. Having done experimental tests, nanoparticles and cementitious materials bonding have been visualized by Scanning Electron Microscopy (SEM) device.

Published

2022