Showing total 37 results

1. Concretes and mortars with waste paper industry: Biomass ash and dregs

Author

Antonio Ramírez-Rodríguez, Pablo Vázquez-Burgo, Marcos Rivas-Fernández, Miriam Velay-Lizancos, Isabel Martínez-Lage, Cristina Vázquez-Herrero, and Miguel Martín-Cano

Subjects

Paper, Environmental Engineering, Materials science, Compressive Strength, 020209 energy, 0211 other engineering and technologies, Biomass, Industrial Waste, 02 engineering and technology, Management, Monitoring, Policy and Law, Industrial waste, Flexural strength, 021105 building & construction, Ultimate tensile strength, 0202 electrical engineering, electronic engineering, information engineering, Green liquor, Waste Management and Disposal, Cement, Waste management, Construction Materials, Water, Book Industry, General Medicine, Pulp and paper industry, Silicon Dioxide, Compressive strength, Mortar

Abstract

This article describes a study on the viability of using waste from the paper industry: biomass boiler ash and green liquor dregs to fabricate mortars and concretes. Both types of ash were characterized by obtaining their chemical and mineralogical composition, their organic matter content, granulometry, adsorption and other common tests for construction materials. Seven different mortars were fabricated, one for reference made up of cement, sand, and water, three in which 10, 20, or 30% of the cement was replaced by biomass ash, and three others in which 10, 20, or 30% of the cement was replaced with dregs. Test specimens were fabricated with these mortars to conduct flexural and compression tests. Flexural strength is reduced for all the mortars studied. Compressive strength increases for the mortars fabricated with biomass ash and decreases for the mortar with dregs. Finally, 5 concretes were made, one of them as a reference (neither biomass ash nor dregs added), two of them with replacements of 10 and 20% of biomass ash instead of cement and another two with replacements of 10 and 20% of dregs instead of cement. The compressive and tensile splitting strength increase when a 10% of ash is replaced and decrease in all the other cases. The modulus of elasticity always decreases.

Published

2016

2. Utilization of drinking water treatment sludge in concrete paving blocks: Microstructural analysis, durability and leaching properties

Author

Phuong Ngoc Pham, Christopher W.K. Chow, Jianyin Huang, Danda Li, Yue Liu, Alexandra Keegan, Yan Zhuge, Rafat Siddique, Liu, Yue, Zhuge, Yan, Chow, Christopher WK, Keegan, Alexandra, Li, Danda, Pham, Phuong Ngoc, Huang, Jianyin, and Siddique, Rafat

Subjects

Ettringite, Environmental Engineering, Absorption of water, Materials science, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Water Purification, chemistry.chemical_compound, paving blocks, Environment effect, Leaching (agriculture), Waste Management and Disposal, 0105 earth and related environmental sciences, Cement, durability properties, Sewage, Construction Materials, leaching ability, Drinking Water, General Medicine, Pulp and paper industry, Durability, 020801 environmental engineering, Waste Disposal Facilities, Compressive strength, chemistry, microstructural analysis, drinking water treatment sludge, concrete, Water treatment

Abstract

The management of abundant drinking water treatment sludge (DWTS) in landfill remains an important issue. The reuse of DWTS as construction material could contribute to the development of greener concrete product and to mitigating the detrimental environment effect from excessive production of DWTS. This paper investigates the potential of using DWTS as sand replacement in Concrete Paving Blocks (CPB). Five CPB mixtures were designed and the replacement ratios of sand by DWTS were 0%, 5%, 10%, 15%, and 20%, by weight. Properties of CPB such as compressive strength, water absorption, abrasion resistance, sulfate attack and metal leachability were determined. The results indicated that above 10% of DWTS, the replacement was detrimental to such properties of the CPB. Microstructure analysis proved the addition of DWTS could result in ettringite formation and the interfacial transition zone (ITZ) between the cement matrix and DWTS was more porous than that of sand. In addition, the metal leachability test of CPB demonstrated that the addition of high-copper DWTS into CPB was safe. Refereed/Peer-reviewed

Published

2020

3. Evaluation of nitric and acetic acid resistance of cement mortars containing high-volume black rice husk ash

Author

Pusit Lertwattanaruk and Burachat Chatveera

Subjects

Cement, Environmental Engineering, Waste management, Construction Materials, Black rice, Chemistry, Fineness, Oryza, General Medicine, Management, Monitoring, Policy and Law, Pulp and paper industry, Nitric Acid, Husk, law.invention, chemistry.chemical_compound, Portland cement, Compressive strength, Nitric acid, law, Materials Testing, Mortar, Waste Management and Disposal, Acetic Acid

Abstract

This paper presents the performance of cement mortar containing black rice husk ash (BRHA) under nitric and acetic acid attacks. The BRHA, collected from an electrical generating power plant that uses rice husk as fuel, was ground using a grinding machine. The compressive strength loss, weight loss, and expansion of mortars under nitric and acetic acid attack were investigated. The test results of BRHA properties in accordance with the ASTM C 618 standard found that the optimal grinding time was 4 h as this achieved a Blaine fineness of 5370 cm 2 /g. For parametric study, BRHA were used as a Portland cement Type 1 replacement at the levels of 0%, 10%, 20%, 30%, 40%, and 50% by weight of binder. The water-to-binder ratios were 0.55, 0.60, and 0.65. From test results, when the percentage replacements of BRHA in cement increased, it was observed that the strength loss and weight loss of mortars containing BRHA under acetic acid attack were higher than those of the mortars against nitric acid attack. It was found that, of the various BHRA mortars, the strength loss and weight loss due to nitric and acetic acid attacks were the lowest in the mortar with 10% BRHA replacement. For 10%, 20% and 30% BRHA replacements, the rate of expansion of the BRHA mortar decreased when compared with the control mortar. For the mortars with other percentage replacements of BRHA, the rate of expansion increased. Furthermore, the effective water-to-binder ratios of control and BRHA mortars were the primary factor for determining the durability of mortar mixed with BRHA.

Published

2014

4. New methodology for assessing the environmental burden of cement mortars with partial replacement of coal bottom ash and fly ash

Author

E. Menéndez, A. M. Alvaro, J. L. Parra, and M.T. Hernández

Subjects

Cement, Environmental Engineering, Materials science, Waste management, Construction Materials, business.industry, General Medicine, Management, Monitoring, Policy and Law, Pulp and paper industry, Coal Ash, law.invention, Portland cement, Compressive strength, law, Bottom ash, Fly ash, Materials Testing, Coal, Leaching (metallurgy), Mortar, business, Waste Management and Disposal

Abstract

This paper assess the mechanical an environmental behaviour of cement mortars manufactured with addition of fly ash (FA) and bottom ash (BA), as partial cement replacement (10%, 25% and 35%). The environmental behaviour was studied by leaching tests, which were performed under several temperature (23 °C and 60 °C) and pH (5 and 10) conditions, and ages (1, 2, 4 and 7 days). Then, the accumulated amount of the different constituents leached was analysed. In order to obtain an environmental burden (EB) value of each cement mixture, a new methodology was developed. The EB value obtained is related to the amount leached and the hazardous level of each constituent. Finally, the integral study of compressive strength and EB values of cement mixtures allowed their classification. The results showed that mortars manufactured with ordinary Portland cement (OPC) and with coal BA had similar or even better environmental and mechanical behaviour than mortars with FA. Therefore, the partial replacement of cement by BA might be as suitable or even better as the replacement by FA.

Published

2014

5. Evaluation of sulfate resistance of cement mortars containing black rice husk ash

Author

Burachat Chatveera and Pusit Lertwattanaruk

Subjects

Environmental Engineering, Materials science, Time Factors, Bioelectric Energy Sources, Incineration, Management, Monitoring, Policy and Law, Husk, law.invention, chemistry.chemical_compound, Magnesium Sulfate, law, Sodium sulfate, Materials Testing, Sulfate, Waste Management and Disposal, Cement, Waste management, Construction Materials, Sulfates, Water, Oryza, General Medicine, Pozzolan, Pulp and paper industry, Portland cement, Compressive strength, chemistry, Microscopy, Electron, Scanning, Mortar

Abstract

In this paper, black rice husk ashes (BRHAs), which are agrowastes from an electricity generating power plant and a rice mill, were ground and used as a partial cement replacement. The durability of mortars under sulfate attack including expansion and compressive strength loss were investigated. For parametric study, BRHA were used as a Portland cement Type 1 replacement at the levels of 0%, 10%, 30%, and 50% by weight of binder. The water-to-binder ratios were 0.55 and 0.65. For the durability of mortar exposed to sulfate attack, 5% sodium sulfate (Na2SO4) and magnesium sulfate (MgSO4) solutions were used. As a result, when increasing the percentage replacement of BRHA, the expansion and compressive strength loss of mortar decreased. At the replacement levels of 30% and 50% of BRHA, the expansion of the mortars was less than those mixed with sulfate-resistant cement. However, the expansion of the mortars exposed to Na2SO4 was more than those exposed to MgSO4. Increasing the replacement level of BRHA tends to reduce the compressive strength loss of mortars exposed to Na2SO4 attack. In contrary, under MgSO4 attack, when increasing the replacement level of BRHA, the compressive strength loss increases from 0% to 50% in comparison to Portland cement mortar. Results show that ground BRHA can be applied as a pozzolanic material to concrete and also improve resistance to sodium sulfate attack, but it can impair resistance to magnesium sulfate attack.

Published

2007

6. Roadmap to a net-zero carbon cement sector: Strategies, innovations and policy imperatives.

Author

Barbhuiya, Salim, Bhusan Das, Bibhuti, and Adak, Dibyendu

Subjects

*CEMENT, *RENEWABLE energy transition (Government policy), *DENTAL cements, *CARBON nanofibers, *CARBON emissions, *CEMENT industries, *GREENHOUSE gas mitigation

Abstract

The cement industry plays a significant role in global carbon emissions, underscoring the urgent need for measures to transition it toward a net-zero carbon footprint. This paper presents a detailed plan to this end, examining the current state of the cement sector, its carbon output, and the imperative for emission reduction. It delves into various low-CO 2 technologies and emerging innovations such as alkali-activated cements, calcium looping, electrification, and bio-inspired materials. Economic and policy factors, including cost assessments and governmental regulations, are considered alongside challenges and potential solutions. Concluding with future prospects, the paper offers recommendations for policymakers, industry players, and researchers, highlighting the roadmap's critical role in achieving a carbon-neutral cement sector. • Cement industry faces urgent need for net-zero transition due to high carbon emissions. • Roadmap spans phases: foundation, acceleration, net-zero, targeting emissions by 2050. • Innovations like alkali-activated cements offer promise for emission reduction. • Collective action and policy crucial for sustainable transformation of cement sector. [ABSTRACT FROM AUTHOR]

Published

2024

7. The mechanisms of heavy metal immobilization by cementitious material treatments and thermal treatments: A review.

Author

Guo, Bin, Liu, Bo, Yang, Jian, and Zhang, Shengen

Subjects

*HEAVY metals, *RADIOACTIVE substances, *ACTINIDE elements, *SOLID waste, *WASTE products

Abstract

Safe disposal of solid wastes containing heavy metals is a significant task for environment protection. Immobilization treatment is an effective technology to achieve this task. Cementitious material treatments and thermal treatments are two types of attractive immobilization treatments due to that the heavy metals could be encapsulated in their dense and durable wasteforms. This paper discusses the heavy metal immobilization mechanisms of these methods in detail. Physical encapsulation and chemical stabilization are two fundamental mechanisms that occur simultaneously during the immobilization processes. After immobilization treatments, the wasteforms build up a low permeable barrier for the contaminations. This reduces the exposed surface of wastes. Chemical stabilization occurs when the heavy metals transform into more stable and less soluble metal bearing phases. The heavy metal bearing phases in the wasteforms are also reviewed in this paper. If the heavy metals are incorporated into more stable and less soluble metal bearing phases, the potential hazards of heavy metals will be lower. Thus, converting heavy metals into more stable phases during immobilization processes should be a common way to enhance the immobilization effect of these immobilization methods. [ABSTRACT FROM AUTHOR]

Published

2017

8. Performance of chemical chelating agent stabilization and cement solidification on heavy metals in MSWI fly ash: A comparative study.

Author

Ma, Wenchao, Chen, Dongmei, Pan, Minhui, Gu, Tianbao, Zhong, Lei, Chen, Guanyi, Yan, Beibei, and Cheng, Zhanjun

Subjects

*FLY ash, *CHELATING agents, *HEAVY metals, *DITHIOCARBAMATES, *INCINERATION, *SOLID waste, *LEACHING

Abstract

Heavy metal stabilization by chemical chelating agent and solidification by cement are technologies currently used to reduce the leaching of heavy metals in municipal solid waste incineration (MSWI) fly ash. This paper studied the physico-chemical properties of the fly ash, heavy metals content in the fly ash, and the leaching concentration of the heavy metals from fly ash. The effect of four chelating agents namely dithiocarbamate (1#), dithiocarbamic acid dipotassium salt (2#), amino dithiocarbamate chelating resin (3#) and thiourea (4#) on the stabilization and leaching of heavy metals were investigated. Different addition ratios (1%, 2% and 3% w/w) of the chelating agents, various curing time (7, 14, 28 days), and different amounts of the cement (10%, 15% and 20% w/w) were used in order to find the agent with the optimum stabilization and leaching of heavy metals as well as find the effect of combining the agent and cement. The results showed that the dithiocarbamate (1#) chelating agent had the best stabilizing performance due to the three-dimensional structure after their reaction. The addition of cement to the fly ash led to the immobilization of heavy metals due to the C-S-H gel formation. The technology of cement solidification and chelating agent stabilization was optimal from the point of economic cost and the complexity aspect. Image 10654 • The stabilization performance of four chemical chelating agents in MSWI fly ash was compared. • Dithiocarbamate presents the best stabilization character among the four agents. • Stabilized agents combined with solidified cements show better performance. • Cd is more difficult to stabilized/solidified than the other heavy metals. [ABSTRACT FROM AUTHOR]

Published

2019

9. Role of policy in managing mined resources for construction in Europe and emerging economies.

Author

Tangtinthai, Napaporn, Heidrich, Oliver, and Manning, David A.C.

Subjects

*MINES & mineral resources policy, *MINERAL aggregates, *CONSTRUCTION & demolition debris, *NATURAL resources management, *ENVIRONMENTAL policy, *CONSTRUCTION industry, *CONCRETE, *CEMENT

Abstract

Abstract Rapid urbanisation, with associated housing and infrastructure demands, leads to increased mining and use of non-renewable mineral raw materials needed for the construction industry including concrete and cement. In an emerging economy, like Thailand, which is part of Association of Southeast Asian Nations (ASEAN), current environmental management policies are insufficient to reduce raw material requirements or waste from demolition by generating inputs to construction through reuse or recycling. As part of the European Union (EU), Great Britain has successfully implemented integrated policies and achieved high rates of recycled aggregates in construction (29%) and a 70% reuse and recycling target for construction and demolition (C&D) waste. In this paper, Material Flow Analysis (MFA) of cement/concrete materials is combined with an interpretation of related policies to provide a deeper understanding how to achieve more sustainable management of natural resources. A comparative MFA for the construction industry in Great Britain and Thailand (representing an ASEAN country) has been developed that quantifies raw material inputs, buildings and infrastructure outputs, so that the practices in the two countries can be contrasted. We report domestic cement production and import/export data, and calculate the raw materials needed for cement and its calcination process for concrete production. Considering the most relevant policies and taxation in Great Britain, we identify possible ways forward for Thailand by introducing new policies and taxation that will have positive effects on raw material extraction, processing, construction and disposal practices and disposal behaviors. Following the MFA and policy analysis, we believe that similar benefits apply to other emerging economies. Graphical abstract Image 1 Highlights • Describes policies to provide a deeper understanding how to achieve more sustainable management of mined resources in the construction sector. • Reports domestic cement production and import/export data, and calculate the raw materials needed for cement and its calcination process for concrete production. • A comparative MFA for the construction industry in EU (Great Britain) and emerging economy (Thailand, representing an ASEAN country), has been developed. • Quantifies raw material inputs, buildings and infrastructure outputs, so that the practices in the two countries can be contrasted. • Identifies policies that can help other countries to reduce the disposal of non-renewable natural and mined resources. • More widely, similar approaches and policies will influence sustainable resource and waste management in other emerging economies. [ABSTRACT FROM AUTHOR]

Published

2019

10. Laboratory stabilizations/solidification of tank sludges: MVST/BVEST

Author

Spence, R.D. and Mattus, A.J.

Subjects

*SEWAGE sludge digestion, *RADIOACTIVE waste disposal, *SOLIDIFICATION/STABILIZATION, *CHROMIUM

Abstract

Oak Ridge tank sludges that have been collected over several decades are being combined for treatment and disposal. Stabilization of the highly radioactive, mixed-waste sludges in the different tank sets has been evaluated prior to the proposed combination and treatment. This paper documents the testing of a Melton Valley Storage Tank (MVST)/Bethel Valley Evaporator Storage Tank set. Subsequent papers will discuss continued work on other tank sets and efforts to maximize the sludge loading. Grout formulations were tested in the laboratory both with a surrogate and with a sample of an actual mixed waste tank sludge from MVST W-25. Wet-sludge loadings of 50–60 wt% resulted in strong wasteforms with no free water and gave a volume increase of about 40–50 vol%. Resource Conservation and Recovery Act (RCRA) metals included in the surrogate testing were cadmium, chromium, lead, selenium, thallium, and mercury. The actual sludge sample was only characteristically hazardous for mercury by the Toxic Characteristic Leaching Procedure but exceeded the Universal Treatment Standard (UTS) limit for chromium. The grout formulations stabilized these two RCRA metals within UTS limits. In addition, a grout leachability index of about 9.0–10.0 was measured for both 85Sr and 137Cs, meeting the recommended requirement of >6.0. [Copyright &y& Elsevier]

Published

2004

11. Laboratory stabilization/solidification of tank sludges: GAAT, OHF, and combined tank sets

Author

Spence, R.D. and Mattus, C.H.

Subjects

*STRONTIUM, *RADIOACTIVE wastes, *SEWAGE sludge digestion, *SOLIDIFICATION/STABILIZATION

Abstract

Highly radioactive, mixed-waste sludges that have been collected at Oak Ridge over several decades are being combined for treatment and disposal. Stabilization of the sludges in the different tank sets was tested prior to the proposed combination and treatment. This paper, which follows a previous article on the Melton Valley Storage Tank/Bethel Valley Evaporator Storage Tank set, documents the testing of the Gunite and Associated Tank and Old Hydrofracture Facility tank sets, as well as the combined sludges of all the Oak Ridge National Laboratory tank sets; the third paper on this subject will discuss efforts to maximize the sludge loading. The grout formulations were tested in the laboratory with surrogates. A wet-sludge loading of 60 wt% resulted in strong wasteforms with no free water and gave a volume increase of about 30–40 vol%. The Resource Conservation and Recovery Act metals included in the surrogate testing were silver, cadmium, chromium, lead, selenium, thallium, zinc, and mercury. The grout formulations stabilized these metals within the Universal Treatment Standards limits. In addition, a grout leachability index of about 10.0–12.0 was measured for both 85Sr and 137Cs, meeting the recommended requirement of >6.0. [Copyright &y& Elsevier]

Published

2004

12. Application of a γRS index-based method and techno-economic analysis for in situ treatment of 137Cs-contaminated soils by cement-barite based stabilisation/solidification.

Author

Falciglia, Pietro P., Romano, Stefano, and Vagliasindi, Federico G.A.

Subjects

*CEMENT, *BARITE, *SOILS, *SOLIDIFICATION, *ECONOMIC research

Abstract

This paper examines the application of cement (C)-barite (Ba) based-Stabilisation/Solidification (S/S) for the remediation of 137 Cs-contaminated soils, investigating the influence of soil: grout and C: Ba ratios on the shielding performance of the S/S mix assessed as gamma radiation shielding ( γRS ) index variation. Results from experiments were used to perform a novel approach and an economic analysis in order to calculate the effective dose reduction achievable by S/S and to assess the optimum quantities and costs of selected mixes, respectively. Gamma ray spectrometer measurements indicate that γRS index increases with increasing barite percentage up to a maximum level of 50%; however a further increase results in a worsening of the shielding performances. A maximum γRS variation of 46.5% was recorded with grout percentage increasing from 16.6 to 50%. At the photon energy of 662 keV ( 137 Cs), the maximum grout amount results in the possibility to shield up to 24.1% of γ-rays emitted. The effective dose reduction achievable by the investigated S/S allows a maximum 137 Cs-soil contamination in the range 2.94–14.55 kBq kg −1 successfully treatable employing a soil: grout ratio of 1: 1 (C: Ba = 1:1). Technical data, jointly with economic analysis findings, make cement-barite based-S/S very competitive in cost-effectiveness and could provide a basis for decision-making of 137 Cs-contaminated site remediation. [ABSTRACT FROM AUTHOR]

Published

2017

13. A critical review of waste glass powder – Multiple roles of utilization in cement-based materials and construction products

Author

Yi Jiang, Caijun Shi, Kim Hung Mo, and Tung-Chai Ling

Subjects

Glass recycling, Engineering, Environmental Engineering, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Recycling, Waste Management and Disposal, 0105 earth and related environmental sciences, Waste Products, Cement, Aggregate (composite), Waste management, Construction Materials, business.industry, Scale (chemistry), Multiple applications, General Medicine, 020801 environmental engineering, Geopolymer, Glass, Cementitious, Powders, business, Waste disposal

Abstract

In light of concerns relating to improper waste disposal and resources preservation, reclamation of the discarded glass in construction materials had been extensively carried out since 1963. In the past decade, although more than 100 papers associated with the use of glass powder (GP) in the micron level scale were published, comprehensive review of all practical applications in cement-based materials and construction products is not available. This paper therefore provides a summary of the body of knowledge on the interaction and effects of using GP in cement-based and extended construction materials. This review concludes that GP is an innovative and promising eco-supplementary cementitious material. Beyond that, use of GP is demonstrated to be potentially beneficial as a precursor in geopolymer and suitable for manufacturing eco-cement, artificial lightweight aggregate and composite phase change material. The multiple applications of GP are seen as an important step towards waste glass recycling as a sustainable construction material and for the overall betterment of the industry.

Published

2019

14. Environmental impact assessment of post-combustion CO2 capture technologies applied to cement production plants.

Author

Galusnyak, Stefan Cristian, Petrescu, Letitia, and Cormos, Calin-Cristian

Subjects

*ENVIRONMENTAL impact analysis, *CARBON sequestration, *CEMENT plants, *MEMBRANE separation, *PRODUCT life cycle assessment, *POWER plants, *CEMENT

Abstract

Decarbonizing the cement manufacturing sector presents an interesting and pressing challenge as it is one of the largest energy consumers in industry (i.e., 7%), emitting considerable amounts of anthropogenic carbon dioxide (i.e., 7%). This paper performs a technical and environmental assessment of decarbonisation of cement production through process modelling and simulation, thermal integration analysis, and Life Cycle Assessment (LCA). Integration of three post-combustion capture methods for a conventional cement plant with an annual productivity of one million tons and a carbon capture rate of 90% is evaluated in comparison to the reference case without carbon capture and storage (CCS). Mass and energy balances derived from simulations are used for the assessment of three innovative capture systems: reactive gas-liquid absorption using Methyl-Di-Ethanol-Amine, reactive gas-solid adsorption using calcium looping (CaL) technology and membrane separation. For the LCA study, a "cradle-to-gate" approach is carried out using GaBi software, according to the ReCiPe impact assessment method. The general conclusion is that integrating the CCS methods into the cement production process leads to a decrease in global warming potential (GWP) in the range of 69.91%–76.74%. Of the CCS technologies analysed, CaL technically outperforms the others as it requires 34% less coal and provides 1.6 times higher gross energy efficiency. From an environmental perspective, CaL integration ranks first, with the lowest scores in six of the nine impact categories and a GWP reduction of 76.74% compared to the baseline scenario without CCS. [Display omitted] • Decarbonisation of the cement industry by post-combustion CO 2 capture technologies. • Thermal integration, technical and environmental evaluation were carried out. • Chemical scrubbing and calcium looping are self-sufficient in terms of heat and power. • Calcium looping exhibits better environmental performances than other two cases. [ABSTRACT FROM AUTHOR]

Published

2022

15. Evaluation of nitric and acetic acid resistance of cement mortars containing high-volume black rice husk ash.

Author

Chatveera, B. and Lertwattanaruk, P.

Subjects

*NITRIC acid, *ACETIC acid, *MORTAR, *RICE hulls, *BINDING agents, *GRINDING machines, *CONTROL groups

Abstract

This paper presents the performance of cement mortar containing black rice husk ash (BRHA) under nitric and acetic acid attacks. The BRHA, collected from an electrical generating power plant that uses rice husk as fuel, was ground using a grinding machine. The compressive strength loss, weight loss, and expansion of mortars under nitric and acetic acid attack were investigated. The test results of BRHA properties in accordance with the ASTM C 618 standard found that the optimal grinding time was 4 h as this achieved a Blaine fineness of 5370 cm2/g. For parametric study, BRHA were used as a Portland cement Type 1 replacement at the levels of 0%, 10%, 20%, 30%, 40%, and 50% by weight of binder. The water-to-binder ratios were 0.55, 0.60, and 0.65. From test results, when the percentage replacements of BRHA in cement increased, it was observed that the strength loss and weight loss of mortars containing BRHA under acetic acid attack were higher than those of the mortars against nitric acid attack. It was found that, of the various BHRA mortars, the strength loss and weight loss due to nitric and acetic acid attacks were the lowest in the mortar with 10% BRHA replacement. For 10%, 20% and 30% BRHA replacements, the rate of expansion of the BRHA mortar decreased when compared with the control mortar. For the mortars with other percentage replacements of BRHA, the rate of expansion increased. Furthermore, the effective water-to-binder ratios of control and BRHA mortars were the primary factor for determining the durability of mortar mixed with BRHA. [Copyright &y& Elsevier]

Published

2014

16. New methodology for assessing the environmental burden of cement mortars with partial replacement of coal bottom ash and fly ash.

Author

Menéndez, E., Álvaro, A.M., Hernández, M.T., and Parra, J.L.

Subjects

*MORTAR, *CEMENT, *FLY ash, *LEACHING, *ENVIRONMENTAL impact analysis, *PORTLAND cement, *HYDROGEN-ion concentration

Abstract

This paper assess the mechanical an environmental behaviour of cement mortars manufactured with addition of fly ash (FA) and bottom ash (BA), as partial cement replacement (10%, 25% and 35%). The environmental behaviour was studied by leaching tests, which were performed under several temperature (23 °C and 60 °C) and pH (5 and 10) conditions, and ages (1, 2, 4 and 7 days). Then, the accumulated amount of the different constituents leached was analysed. In order to obtain an environmental burden (EB) value of each cement mixture, a new methodology was developed. The EB value obtained is related to the amount leached and the hazardous level of each constituent. Finally, the integral study of compressive strength and EB values of cement mixtures allowed their classification. The results showed that mortars manufactured with ordinary Portland cement (OPC) and with coal BA had similar or even better environmental and mechanical behaviour than mortars with FA. Therefore, the partial replacement of cement by BA might be as suitable or even better as the replacement by FA. [Copyright &y& Elsevier]

Published

2014

17. Valorisation of waste ilmenite mud in the manufacture of sulphur polymer cement.

Author

Contreras, Manuel, Gázquez, Manuel Jesús, García-Díaz, Irene, Alguacil, Francisco. J., López, Félix. A., and Bolívar, Juan Pedro

Subjects

*ILMENITE, *MUD, *SULFUR, *CEMENT, *RADIUM isotopes, *LEACHING, *CONCRETE construction, *RAW materials

Abstract

This paper reports the preparation of sulphur polymer cements (SPCs) incorporating waste ilmenite mud for use in concrete construction works. The ilmenite mud raw material and the mud-containing SPCs (IMC-SPCs) were characterised physico-chemically and radiologically. The optimal IMC-SPC mixture had a sulphur/mud ratio (w/w) of 1.05 (mud dose 20 wt%); this cement showed the greatest compressive strength (64 MPa) and the lowest water absorption coefficient (0.4 g cm−2 at 28 days). Since ilmenite mud is enriched in natural radionuclides, such as radium isotopes (2.0·103 Bq kg−1 228Ra and 5.0·102 Bq kg−1 226Ra), the IMC-SPCs were subjected to leaching experiments, which showed their environmental impact to be negligible. The activity concentration indices for the different radionuclides in the IMC-SPCs containing 10% and 20% ilmenite mud met the demands of international standards for materials used in the construction of non-residential buildings. [Copyright &y& Elsevier]

Published

2013

18. Cement replacement by sugar cane bagasse ash: CO2 emissions reduction and potential for carbon credits

Author

Fairbairn, Eduardo M.R., Americano, Branca B., Cordeiro, Guilherme C., Paula, Thiago P., Toledo Filho, Romildo D., and Silvoso, Marcos M.

Subjects

*MATERIALS science, *CEMENT industries & the environment, *EMISSIONS (Air pollution), *CARBON dioxide, *SUGAR by-products, *EMISSION control, *RESEARCH methodology, *SIMULATION methods & models

Abstract

This paper presents a study of cement replacement by sugar cane bagasse ash (SCBA) in industrial scale aiming to reduce the CO2 emissions into the atmosphere. SCBA is a by-product of the sugar/ethanol agro-industry abundantly available in some regions of the world and has cementitious properties indicating that it can be used together with cement. Recent comprehensive research developed at the Federal University of Rio de Janeiro/Brazil has demonstrated that SCBA maintains, or even improves, the mechanical and durability properties of cement-based materials such as mortars and concretes. Brazil is the world’s largest sugar cane producer and being a developing country can claim carbon credits. A simulation was carried out to estimate the potential of CO2 emission reductions and the viability to issue certified emission reduction (CER) credits. The simulation was developed within the framework of the methodology established by the United Nations Framework Convention on Climate Change (UNFCCC) for the Clean Development Mechanism (CDM). The State of São Paulo (Brazil) was chosen for this case study because it concentrates about 60% of the national sugar cane and ash production together with an important concentration of cement factories. Since one of the key variables to estimate the CO2 emissions is the average distance between sugar cane/ethanol factories and the cement plants, a genetic algorithm was developed to solve this optimization problem. The results indicated that SCBA blended cement reduces CO2 emissions, which qualifies this product for CDM projects. [Copyright &y& Elsevier]

Published

2010

19. Evaluation of sulfate resistance of cement mortars containing black rice husk ash

Author

Chatveera, B. and Lertwattanaruk, P.

Subjects

*SULFATES & the environment, *MORTAR, *CEMENT research, *RICE hulls, *ASH (Combustion product), *SODIUM sulfate, *MAGNESIUM sulfate

Abstract

In this paper, black rice husk ashes (BRHAs), which are agrowastes from an electricity generating power plant and a rice mill, were ground and used as a partial cement replacement. The durability of mortars under sulfate attack including expansion and compressive strength loss were investigated. For parametric study, BRHA were used as a Portland cement Type 1 replacement at the levels of 0%, 10%, 30%, and 50% by weight of binder. The water-to-binder ratios were 0.55 and 0.65. For the durability of mortar exposed to sulfate attack, 5% sodium sulfate (Na2SO4) and magnesium sulfate (MgSO4) solutions were used. As a result, when increasing the percentage replacement of BRHA, the expansion and compressive strength loss of mortar decreased. At the replacement levels of 30% and 50% of BRHA, the expansion of the mortars was less than those mixed with sulfate-resistant cement. However, the expansion of the mortars exposed to Na2SO4 was more than those exposed to MgSO4. Increasing the replacement level of BRHA tends to reduce the compressive strength loss of mortars exposed to Na2SO4 attack. In contrary, under MgSO4 attack, when increasing the replacement level of BRHA, the compressive strength loss increases from 0% to 50% in comparison to Portland cement mortar. Results show that ground BRHA can be applied as a pozzolanic material to concrete and also improve resistance to sodium sulfate attack, but it can impair resistance to magnesium sulfate attack. [Copyright &y& Elsevier]

Published

2009

20. Leaching from granular cement-based materials during infiltration/wetting coupled with freezing and thawing

Author

Sanchez, F., Langley White, M.K., and Hoang, A.

Subjects

*LEACHING, *RECYCLED products, *SEEPAGE, *THAWING, *CEMENT, *RUNOFF, *MOISTURE, *WETTING

Abstract

Abstract: Many secondary materials are being considered for use as substitutes for natural aggregates in highway applications due to their suitable engineering and economic properties. During the design life of the application, recycled materials are exposed to freeze/thaw cycles and other aging processes such as carbonation, coupled with intermittent infiltration/wetting by precipitation events. In such scenarios, leaching of material constituents is a primary pathway for environmental impact. This paper presents results of the effect of freezing and thawing on the leaching behavior of major and minor constituents from a laboratory formulated granular cement-based material. Scenarios considered included water percolating through the material (flow-through) and run-off (flow-around), both important leaching pathways in highway environments. The effect of moisture content at the time of freezing, number of freeze/thaw (F/T) cycles, and material size reduction were investigated. F/T exposure and subsequent infiltration/wetting resulted in consolidation and self-cementing of the granular cement-based material. For the flow-around scenario, F/T exposure resulted in a reduction in constituent release with time and increasing F/T cycles. For the flow-through scenario, moisture content at the time of freezing was an important parameter and an increase in the release was initially observed due to preferential flow/cracks and/or constituent redistribution prior to a decrease that resulted from self-cementing during further thawing and percolation. [Copyright &y& Elsevier]

Published

2009

21. Reuse of ultrafine mineral wool production waste in the manufacture of refractory concrete

Author

Valentin Antonovič, Olegas Černašėjus, Jelena Škamat, Kestutis Baltakys, Andrejs Krasnikovs, Rimvydas Stonys, and Denis Kuznetsov

Subjects

Thermal shock, Environmental Engineering, Materials science, Silica fume, Aluminate, Mineral wool, 0211 other engineering and technologies, 02 engineering and technology, Management, Monitoring, Policy and Law, chemistry.chemical_compound, X-Ray Diffraction, 021105 building & construction, Particle Size, Aluminum Compounds, Waste Management and Disposal, Refractory (planetary science), Waste Products, Cement, Construction Materials, Silicates, Metallurgy, Electric Conductivity, Dust, General Medicine, Calcium Compounds, Hydrogen-Ion Concentration, 021001 nanoscience & nanotechnology, Bulk density, Cupola, chemistry, 0210 nano-technology

Abstract

The paper deals with the mineral wool production waste (cupola dust - CD), presents CD characterization and aims to reuse CD in production of refractory concrete with calcium aluminate cement. The study of CD covers its chemical, phase and thermal analyses along with the morphological study and determination of particles size distribution. Zeta-potential, electrical conductivity and pH values of CD suspension are presented in the paper as well. Commercial microsilica additive in refractory concrete has been replaced with cupola dust. Compositions of refractory concrete have been prepared by incorporating 1%, 2% and 3% of CD. The bulk density, ultrasonic wave velocity, cold crushing strength and thermal shock resistance of the created refractory concrete have been determined. Based on experimental results, it has been found that cupola dust may be used for the production of refractory concrete. The environmental impact related to the CD reuse in refractory concrete production has been evaluated as well.

Published

2016

22. Curing temperature dependency of the release of arsenic from cemented paste backfill made with Portland cement.

Author

Bull, Andrew J. and Fall, Mamadou

Subjects

*LEACHING, *SCANNING electron microscopy techniques, *TEMPERATURE control, *PORTLAND cement, *ARSENIC, *X-ray powder diffraction, *PASTE

Abstract

In this research, the effect of curing temperature on the metalloid (As) leachability of cemented paste backfill (CPB; a mix of tailings, cement and water) is studied. ASTM C 1308 leaching protocol is used to determine the leachability of CPB samples subjected to different curing temperatures (2, 20 and 35 °C). In addition, the effect of curing temperature on the microstructure of CPB is assessed to determine if the temperature dependence of the leaching characteristics of CPB is related to variations in the microstructure of the cement matrix. The microstructural techniques used include, powder x-ray diffraction, mercury intrusion porosimetry, and scanning electron microscopy techniques. The results obtained indicate that the curing temperature has a significant effect on the leachability of CPB. It is found that as curing temperature increased from 2 °C to 35 °C the performance of the CPB for arsenic immobilization decreased. The magnitude of this temperature-induced change in As-leachability of CPB depends on the curing temperature range (low (≤20 °C) or elevated (35 °C) temperatures). This curing temperature dependency of the leachability of CPB is attributable to the temperature-induced changes in the pore structure of CPB, formation/development of hydration products and pH in the CPBs during the curing process. The results also indicate that diffusion dominates as the leaching mechanism through the studied temperature range and is independent of curing temperature. However, curing temperature does control the availability for arsenic to leach. The new findings presented in this paper will contribute to design more environmental-friendly cemented paste backfill materials and structures, which is vital for sustainable mining. • Impact of temperature on the As leachability of cemented paste backfill (CPB) is studied. • Curing temperature has a significant effect on the As leachability of CPB. • Diffusion dominates as the leaching mechanism and is independent of curing temperature. • Curing temperature does control the availability for arsenic to leach. [ABSTRACT FROM AUTHOR]

Published

2020

23. The mechanisms of heavy metal immobilization by cementitious material treatments and thermal treatments: A review

Author

Jian Yang, Bin Guo, Bo Liu, and Shengen Zhang

Subjects

Cement, 021110 strategic, defence & security studies, Conservation of Natural Resources, Environmental Engineering, Materials science, Metallurgy, 0211 other engineering and technologies, Sintering, Heavy metals, 02 engineering and technology, General Medicine, 010501 environmental sciences, Management, Monitoring, Policy and Law, Solid Waste, 01 natural sciences, Geopolymer, Metal, visual_art, Metals, Heavy, Thermal, visual_art.visual_art_medium, Vitrification, Cementitious, Waste Management and Disposal, 0105 earth and related environmental sciences

Abstract

Safe disposal of solid wastes containing heavy metals is a significant task for environment protection. Immobilization treatment is an effective technology to achieve this task. Cementitious material treatments and thermal treatments are two types of attractive immobilization treatments due to that the heavy metals could be encapsulated in their dense and durable wasteforms. This paper discusses the heavy metal immobilization mechanisms of these methods in detail. Physical encapsulation and chemical stabilization are two fundamental mechanisms that occur simultaneously during the immobilization processes. After immobilization treatments, the wasteforms build up a low permeable barrier for the contaminations. This reduces the exposed surface of wastes. Chemical stabilization occurs when the heavy metals transform into more stable and less soluble metal bearing phases. The heavy metal bearing phases in the wasteforms are also reviewed in this paper. If the heavy metals are incorporated into more stable and less soluble metal bearing phases, the potential hazards of heavy metals will be lower. Thus, converting heavy metals into more stable phases during immobilization processes should be a common way to enhance the immobilization effect of these immobilization methods.

Published

2016

24. Formulation of criteria for pollution control on cement products produced from solid wastes in China

Author

Huang Zechun, Qifei Huang, Qi Wang, Yufei Yang, and Yu Yang

Subjects

Pollutant, Pollution, Cement, China, Engineering, Environmental Engineering, Municipal solid waste, Waste management, Construction Materials, business.industry, media_common.quotation_subject, Environmental engineering, Water supply, General Medicine, Management, Monitoring, Policy and Law, Risk Assessment, Refuse Disposal, Pipeline transport, Acceptance testing, Metals, Heavy, Leaching (agriculture), Environmental Pollution, business, Waste Management and Disposal, media_common

Abstract

The process of producing cement products from solid waste can increase the level of pollutants in the cement products. Therefore, it is very important to establish a pollution control standard for cement products to protect the environment and human health. This paper presents acceptance limits for the availability of heavy metals in cement products which have been produced from solid wastes and explains how the limits have been calculated. The approach and method used to formulate these criteria were based on EN 12920. The typical exposure scenarios used in this paper involve concrete being used for drinking water supply pipelines and concrete pavements and are based on an analysis of typical applications of cement in China, and the potential for contact with water. The parameters of a tank test which was based on NEN 7375 were set in accordance with the environmental conditions of typical scenarios in China. Mechanisms controlling the release of heavy metals in concrete and a model for that release were obtained using the leaching test. Finally, based on acceptance criteria for drinking water and groundwater quality in China, limit values for the availability of heavy metals in concrete were calculated.

Published

2011

25. Effect of overflow tailings properties on cemented paste backfill

Author

Xin Chen, Qiusong Chen, Jian Zhou, Xiuzhi Shi, Xianyang Qiu, and Du Xianghong

Subjects

Ettringite, Environmental Engineering, Materials science, Compressive Strength, 0208 environmental biotechnology, 02 engineering and technology, Sulfides, 010501 environmental sciences, Management, Monitoring, Policy and Law, Calcium Sulfate, 01 natural sciences, chemistry.chemical_compound, Ultimate tensile strength, Calcium silicate hydrate, Composite material, Porosity, Waste Management and Disposal, 0105 earth and related environmental sciences, Cement, Construction Materials, General Medicine, 020801 environmental engineering, Residual strength, Slump, Compressive strength, chemistry, Microscopy, Electron, Scanning

Abstract

This paper presents the results of an experimental study on the unconfined compressive strength (UCS), indirect tensile strength (ITS), microstructural properties and environmental impacts of overflow tailings (OFT) cemented paste backfill (CPB). The test results show that the poor graded OFT contain 47.15% particles with size below 20 μm, and high content of oxide and sulfide. The slump of fresh CPB mixture ranges from 19.50 cm to 21.60 cm, and its flowability meets the transport requirements. After being cured for 28 days, the UCS and ITS of CPB are less than 2 MPa and 0.5 MPa, respectively. Meanwhile, CPB exhibited low residual strength and high brittleness. The low strength is mainly due to the use of fine OFT. The results show that sulphate also has negative effect on strength and dissolve calcium silicate hydrate (C-S-H) while promoting the formation of secondary products (gypsum and ettringite), leading to generate cracks and decrease UCS at 28 curing time of some CPB mixtures. Increasing the cement content and solid mass concentration is the effective methods to improve the mechanical properties of CPB. The nuclear magnetic resonance (NMR) tests show that fine OFT with low osmotic coefficient (3.10e-06 cm/s) and high sulfur content cause high porosity from 25.0% to 33.1% of CPB, and the increase of the porosity is observed a negative influence on the UCS, but no obvious relationship between ITS and porosity is obtained. Scanning electron microscopy (SEM) and energy dispersive spectrometry (EDS) tests show that OFT particles were covered by C-S-H gel which can enhance the compactness and integrity of CPB. The SEM tests also found secondary products gypsum and ettringite. These finding suggest that OFT can be suitably used as backfill material to fill the underground stopes.

Published

2019

26. A review of additives used in the cemented paste tailings: Environmental aspects and application

Author

Ahmad Khodadadi Darban, Alieh Saedi, and Ahmad Jamshidi-Zanjani

Subjects

Environmental Engineering, 0208 environmental biotechnology, 02 engineering and technology, Acid Rain, 010501 environmental sciences, Management, Monitoring, Policy and Law, Raw material, 01 natural sciences, Mining, law.invention, law, Greenhouse effect, Waste Management and Disposal, Mineral processing, 0105 earth and related environmental sciences, Cement, Minerals, Waste management, Construction Materials, Industrial scale, General Medicine, Tailings, 020801 environmental engineering, Portland cement, Greenhouse gas, Environmental science

Abstract

A large amount of mine wastes is generated every year through mining and mineral processing operation. The management of mine tailings is an attractive topic for researchers from both environmental and economic aspects. Mine tailings have shown a capacity as a raw material for the construction industry or a substitution for previous materials to produce the cement. It is applied in some specific environments such as offshores or massive projects like large bridges and tunnels. However, the cement industry has caused a variety of environmental issues. The production of Portland cement on an industrial scale increases the greenhouse effects and generates acidic rains. It releases greenhouse gases by the generation of carbon dioxide. In recent years, strict environmental regulations led to more efforts from mining industries to manage their tailings. A new approach to decrease the environmental issues, improve cement technology and obtain economic benefits is the use of mine tailings for cement production. Mine tailings in the cement mixtures decrease the initial hydration, retard the setting time, and lower the product mechanical strength. These problems can be fixed by the use of additives. Additives as chemical compounds are added to a cemented paste to change its properties and improve its performance. Therefore, the additives in cemented paste tailings can increase the pump-ability, reduce the water-to-cement ratio, increase density, or even adjust setting time and hydration according to the desired purposes. However, the amount of additives in the cemented paste tailings changes based on the type of additive. It should be optimized to cause a positive effect on the cement properties. Furthermore, the additives and their adaptation to the physical and chemical characteristics in cement and tailings is an important issue that should be investigated. In this paper, the usage of several chemical additives was studied, which can strengthen the properties of cemented paste tailings during backfilling operation. It can cause a better condition to decrease the environmental problems for the cement industry and mine tailings. A review of previous works is presented with an explanation of the gaps in previous studies.

Published

2020

27. Recycling of lithium slag extracted from lithium mica by preparing white Portland cement

Author

Lei Huang, Pinghua Lian, Jinzhen Li, and Shaowen Huang

Subjects

Environmental Engineering, Materials science, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, Raw material, Lithium, 01 natural sciences, Industrial waste, Crystallinity, chemistry.chemical_compound, Spectroscopy, Fourier Transform Infrared, Recycling, Waste Management and Disposal, 0105 earth and related environmental sciences, Cement, Construction Materials, Thermal decomposition, Metallurgy, General Medicine, 020801 environmental engineering, Compressive strength, chemistry, Calcium silicate, Aluminum Silicates, White Portland cement

Abstract

In recent years, lithium slag (LS) has increased sharply with the development of lithium industry, which has caused serious environmental problems. However, the utilization of this industrial waste residue has been a difficult topic in lithium industry. In this paper, the effects of LS on mineral crystal type, ionic solid solution, decomposition temperature of CaCO3 and strength of white Portland cement clinker were studied by XRD, FT-IR, DSC, SEM-EDS and other means. The results show that LS can stabilize the M1 crystal of C3S, improve the crystallinity of C3A, and reduce the content of ACn. The LS content of 5 wt% can reduce the decomposition temperature of CaCO3 about 10 °C, but increase the low eutectic temperature of materials. Na elements tended to be dissolved in the intermediate phase, while Al3+ dissolved in calcium silicate may replace Ca2+ or Si4+. Sintering white Portland cement clinker with appropriate content of LS can effectively reduce the content of f-CaO and greatly improve the early compressive strength of clinker. Therefore, LS within 5 wt% can be used as high quality raw material of white cement, which can recycle LS.

Published

2019

28. Performance of chemical chelating agent stabilization and cement solidification on heavy metals in MSWI fly ash: A comparative study

Author

Dongmei Chen, Zhanjun Cheng, Tianbao Gu, Lei Zhong, Wenchao Ma, Pan Minhui, Beibei Yan, and Guanyi Chen

Subjects

Environmental Engineering, 0208 environmental biotechnology, 02 engineering and technology, Incineration, 010501 environmental sciences, Management, Monitoring, Policy and Law, Solid Waste, 01 natural sciences, Coal Ash, Metal, chemistry.chemical_compound, Metals, Heavy, Chelation, Dithiocarbamate, Waste Management and Disposal, 0105 earth and related environmental sciences, Chelating Agents, Chelating resin, chemistry.chemical_classification, Cement, General Medicine, Carbon, 020801 environmental engineering, Refuse Disposal, Thiourea, chemistry, visual_art, Fly ash, visual_art.visual_art_medium, Particulate Matter, Leaching (metallurgy), Nuclear chemistry

Abstract

Heavy metal stabilization by chemical chelating agent and solidification by cement are technologies currently used to reduce the leaching of heavy metals in municipal solid waste incineration (MSWI) fly ash. This paper studied the physico-chemical properties of the fly ash, heavy metals content in the fly ash, and the leaching concentration of the heavy metals from fly ash. The effect of four chelating agents namely dithiocarbamate (1#), dithiocarbamic acid dipotassium salt (2#), amino dithiocarbamate chelating resin (3#) and thiourea (4#) on the stabilization and leaching of heavy metals were investigated. Different addition ratios (1%, 2% and 3% w/w) of the chelating agents, various curing time (7, 14, 28 days), and different amounts of the cement (10%, 15% and 20% w/w) were used in order to find the agent with the optimum stabilization and leaching of heavy metals as well as find the effect of combining the agent and cement. The results showed that the dithiocarbamate (1#) chelating agent had the best stabilizing performance due to the three-dimensional structure after their reaction. The addition of cement to the fly ash led to the immobilization of heavy metals due to the C-S-H gel formation. The technology of cement solidification and chelating agent stabilization was optimal from the point of economic cost and the complexity aspect.

Published

2019

29. Curing temperature dependency of the release of arsenic from cemented paste backfill made with Portland cement

Author

Mamadou Fall and Andrew J. Bull

Subjects

Environmental Engineering, Materials science, Scanning electron microscope, 0208 environmental biotechnology, chemistry.chemical_element, 02 engineering and technology, Sulfides, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Mining, Arsenic, law.invention, law, Waste Management and Disposal, Curing (chemistry), 0105 earth and related environmental sciences, Cement, Construction Materials, Metallurgy, Temperature, General Medicine, Atmospheric temperature range, Microstructure, 6. Clean water, 020801 environmental engineering, Portland cement, surgical procedures, operative, chemistry, Leaching (metallurgy), circulatory and respiratory physiology

Abstract

In this research, the effect of curing temperature on the metalloid (As) leachability of cemented paste backfill (CPB; a mix of tailings, cement and water) is studied. ASTM C 1308 leaching protocol is used to determine the leachability of CPB samples subjected to different curing temperatures (2, 20 and 35 °C). In addition, the effect of curing temperature on the microstructure of CPB is assessed to determine if the temperature dependence of the leaching characteristics of CPB is related to variations in the microstructure of the cement matrix. The microstructural techniques used include, powder x-ray diffraction, mercury intrusion porosimetry, and scanning electron microscopy techniques. The results obtained indicate that the curing temperature has a significant effect on the leachability of CPB. It is found that as curing temperature increased from 2 °C to 35 °C the performance of the CPB for arsenic immobilization decreased. The magnitude of this temperature-induced change in As-leachability of CPB depends on the curing temperature range (low (≤20 °C) or elevated (35 °C) temperatures). This curing temperature dependency of the leachability of CPB is attributable to the temperature-induced changes in the pore structure of CPB, formation/development of hydration products and pH in the CPBs during the curing process. The results also indicate that diffusion dominates as the leaching mechanism through the studied temperature range and is independent of curing temperature. However, curing temperature does control the availability for arsenic to leach. The new findings presented in this paper will contribute to design more environmental-friendly cemented paste backfill materials and structures, which is vital for sustainable mining.

Published

2020

30. Investigation of high volume of CFBC ash on performance of basic magnesium sulfate cement

Author

Lin Weichao, Hu Zongyue, Zhang Yudong, Xu Xun, Xiao Yulong, and Duan Liling

Subjects

China, Toughness, Environmental Engineering, Materials science, Compressive Strength, 0208 environmental biotechnology, chemistry.chemical_element, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, Coal Ash, 01 natural sciences, Corrosion, Magnesium Sulfate, X-Ray Diffraction, Flexural strength, Fluidized bed combustion, Waste Management and Disposal, 0105 earth and related environmental sciences, Cement, Construction Materials, Magnesium, Metallurgy, technology, industry, and agriculture, General Medicine, Microstructure, 020801 environmental engineering, Compressive strength, chemistry, Microscopy, Electron, Scanning

Abstract

Basic magnesium sulfate cement has the advantages of fast setting, high strength, high toughness, water resistance, corrosion resistance, etc. But the cost has become a reason for limiting its widespread application. With the widespread application of circulating fluidized bed combustion (CFBC) technology in China, the accumulation of CFBC ash is increasing. Reasonable use of CFBC ash can not only reduce cost of basic magnesium sulfate cement but also protect environment. In this paper, the effect of a high volume of CFBC ash on fluidity, flexural strength and compressive strength of basic magnesium sulfate cement is studied. Hydration products and micromorphology analyses are measured by X-ray diffraction (XRD) and scanning electron microscopy (SEM). The results reveal that the strength of basic magnesium sulfate cement with 20% CFBC ash is the highest, and its microstructure is the model that CFBC ash and MgO fill a three-dimensional network structure established by needle-shaped 5·1·7 phase. When the amount of CFBC ash is more than 40%, the formation of 5·1·7 phase is affected severely, which greatly reduces the strength.

Published

2020

31. Combination of ground rice husk and polyvinyl alcohol fiber in cementitious composite

Author

Ali A. A. Jeddi, H. R. Pakravan, and Masoud Jamshidi

Subjects

Dietary Fiber, Environmental Engineering, Absorption of water, Materials science, Compressive Strength, 0211 other engineering and technologies, 02 engineering and technology, Management, Monitoring, Policy and Law, Husk, Polyvinyl alcohol, chemistry.chemical_compound, Flexural strength, 021105 building & construction, Fiber, Composite material, Waste Management and Disposal, Cement, Aggregate (composite), Construction Materials, Oryza, General Medicine, 021001 nanoscience & nanotechnology, Compressive strength, chemistry, Polyvinyl Alcohol, 0210 nano-technology

Abstract

In this study, ground rice husks (GRH) in combination with polyvinyl-alcohol (PVA) fiber were used to produce low-cost and high-quality hybrid cementitious composites. Different amounts of GRH (2.5, 5.0, 7.5 and 12.5% in weight of cement) were added to the concrete. The work presented in this paper provides an insight into the use of an agricultural waste as effective additive in cement based materials. The properties of resultant cementitious composites including density, water absorption, flexural behavior and compressive strength were investigated. The results have shown that incorporation of ground rice husk in combination with PVA fiber can be effective in improvement of the flexural properties of cementitious composite. The study explored the effectiveness of this type of agricultural waste as a beneficial material in fine aggregate concrete materials.

Published

2017

32. Influences of coal fly ash containing ammonium salts on properties of cement paste

Author

Xiaojian Gao, Ling Qin, and Qiyan Li

Subjects

Ammonium sulfate, Environmental Engineering, Materials science, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, Coal Ash, 01 natural sciences, law.invention, chemistry.chemical_compound, Ammonia, law, Ammonium Compounds, Ammonium, Waste Management and Disposal, 0105 earth and related environmental sciences, Cement, Construction Materials, fungi, technology, industry, and agriculture, Superplasticizer, General Medicine, Carbon, 020801 environmental engineering, Portland cement, Coal, Compressive strength, chemistry, Chemical engineering, Fly ash, Salts

Abstract

This paper aims to investigate the influence of coal fly ash containing ammonium salts on properties of cement paste. Fly ash was incorporated at percentage of 20% by weight of the total binder to replace Portland cement. Ammonium hydrogen sulfate (NH3HSO4) or ammonium sulfate ((NH3)2SO4) were introduced at percentages of 3.0%-6.0% or 1.5%-3.0% by fly ash weight. Compressive strength, setting time and hydration heat were evaluated on variable blend mixtures. Adsorption behaviors of polycarboxylate-based superplasticizer and air entraining agent on fly ash particles were also evaluated using total organic carbon (TOC) method. Semi-adiabatic calorimetry, X-ray diffraction, Fourier transform infrared spectroscopy, thermogravimetry-differential thermal analysis, mercury intrusion porosity and scanning electron microscope measurements were carried out on typical samples. Experimental results showed that the chemical admixtures adsorbed by coal fly ash were increased by the introduction of NH3HSO4 or (NH3)2SO4. The addition of 3.0%-6.0% NH3HSO4 and 1.5%-3.0% (NH3)2SO4 decreased the 28d compressive strength of fly ash-cement pastes by 4.3%-10.4% and 6.3%-8.9%, respectively. The initial and final setting times were delayed and the early age hydration of Portland cement was also retarded. Moreover, the pore structure was coarsened and porosity was increased for the hardened cement specimens due to the release of ammonia and lower hydration degree. Therefore, more attention should be paid to the application of denitration fly ash to the cement and concrete industry.

Published

2019

33. Laboratory stabilization/solidification of tank sludges: maximizing sludge loading

Author

A.J Mattus and R.D. Spence

Subjects

Chromium, Environmental Engineering, chemistry.chemical_element, Management, Monitoring, Policy and Law, engineering.material, Waste Disposal, Fluid, Metals, Heavy, Materials Testing, Water Movements, Waste Management and Disposal, Nuclear Physics, Cement, Chromate conversion coating, Waste management, Construction Materials, Grout, technology, industry, and agriculture, Radioactive waste, Hydrogels, General Medicine, Hydrogen-Ion Concentration, Mercury (element), Waste treatment, chemistry, Radioactive Waste, engineering, Environmental science, Laboratories, Sludge

Abstract

Highly radioactive, mixed-waste sludges that have been collected in tanks at Oak Ridge over several decades are being combined for treatment and disposal. Stabilization of the sludges in the different tank sets was tested prior to the proposed combination and treatment. This paper is the third one in a series on the laboratory stabilization/solidification of these tank sludges. It discusses efforts to maximize the sludge loading with no strength criterion for the grout formulation. Grout formulations were tested in the laboratory both with surrogates and with actual samples of tank sludge. Hydrogels eliminated free water generation, even at sludge loadings of >90 wt%, albeit strong monoliths did not form at such high loadings. Correlations established the dependence of the chromium and mercury performance in the Toxicity Characteristic Leach Procedure for the surrogates on the slag content of the grout while the lead performance depended on the extract pH. The surrogate sludge loading was limited by the chromate content to about 90 wt%, meeting Universal Treatment Standard limits. However, tests with actual sludges at such high loadings revealed problems with lead and silver stabilization that were not experienced with the surrogate testing.

Published

2004

34. Effect of desliming of sulphide-rich mill tailings on the long-term strength of cemented paste backfill

Author

Bayram Ercikdi, Hakan Baki, and Muhammet İzki

Subjects

Cement, Environmental Engineering, Gypsum, Materials science, Construction Materials, Metallurgy, Industrial Waste, General Medicine, Management, Monitoring, Policy and Law, engineering.material, Sulfides, Microstructure, Tailings, Mining, Compressive strength, engineering, Microscopy, Electron, Scanning, Geotechnical engineering, Pyrite, Waste Management and Disposal, Curing (chemistry), Waste disposal

Abstract

This paper presents the effect of desliming on the short- and long-term strength, stability and rheological properties of cemented paste backfill (CPB) produced from two different mill tailings. A 28-day unconfined compressive strength (UCS) of ≥1.0 MPa and the maintenance of stability over 224 days of curing were selected as the design criteria for the evaluation of paste backfill performance. Desliming induced some changes in the physical, chemical, mineralogical and rheological properties of the tailings. CPB mixture of the deslimed tailings achieved the required consistency at a lower water to cement ratio. The short-term UCSs of CPB samples of the deslimed tailings were found to be 30–100% higher than those samples of the reference tailings at all the binder dosages and curing times. CPB samples of the deslimed tailings achieved the long-term stability at relatively low binder dosages (e.g. 5 wt% c.f. ≥6.1% for the reference tailings). It was also estimated that desliming could allow a 13.4–23.1% reduction in the binder consumption depending apparently on the inherent characteristics of the tailings. Over the curing period, generation of sulphate and acid by the oxidation of pyrite present in the tailings was also monitored to correlate with the strength losses observed in the long term. Scanning electron microscope (SEM) and Mercury Intrusion Porosimetry (MIP) analyses provided an insight into the microstructure of CPB and the formation of secondary mineral phases (i.e. gypsum) confirming the beneficial effect of desliming. These findings suggest that desliming can be suitably exploited for CPB of sulphide-rich mill tailings to improve the strength and stability particularly in the long term and to reduce binder consumption.

Published

2012

35. Quantification of uncertainty of experimental measurement in leaching test on cement-based materials

Author

Martin Cyr, M. Coutand, and Pierre Clastres

Subjects

Environmental Engineering, Meat, Industrial Waste, Soil science, Management, Monitoring, Policy and Law, Environment, Standard deviation, Hazardous Substances, Recycling, Leachate, Waste Management and Disposal, Pollutant, Cement, Biological Products, Minerals, Construction Materials, Environmental engineering, Uncertainty, Experimental data, General Medicine, Bottom ash, Environmental science, Environmental Pollutants, Leaching (metallurgy), Mortar, Environmental Monitoring

Abstract

When mineral wastes are reused in construction materials, a current practice is to evaluate their environmental impact using standard leaching test. However, due to the uncertainty of the measurement, it is usually quite difficult to estimate the pollutant potential compared to other materials or threshold limits. The aim of this paper is to give a quantitative evaluation of the uncertainty of leachate concentrations of cement-based materials, as a function of the number of test performed. The relative standard deviations and relative confidence intervals are determined using experimental data in order to give a global evaluation of the uncertainty of leachate concentrations (determination of total relative standard deviation). Various combinations were realized in order to point out the origin of large dispersion of the results (determination of relative standard deviation linked to analytical measured and to leaching procedure), generalisation was suggested and the results were compared to literature. An actual example was given about the introduction of residue (meat and bone meal bottom ash – MBM-BA) in mortar, leaching tests were carried out on various samples with and without residue MBM-BA. In conclusion large dispersion were observed and mainly due to heterogeneity of materials. So heightened attention needed to analyse leaching result on cement-based materials and further more other tests (e.g. ecotoxicology) should be performed to evaluate the environmental effect of these materials.

Published

2010

36. Cement replacement by sugar cane bagasse ash: CO2 emissions reduction and potential for carbon credits

Author

Eduardo de Moraes Rego Fairbairn, Marcos Martinez Silvoso, Branca B. Americano, Romildo Dias Toledo Filho, Thiago Pires de Paula, and Guilherme Chagas Cordeiro

Subjects

Engineering, Conservation of Natural Resources, Environmental Engineering, Industrial Waste, Management, Monitoring, Policy and Law, Industrial waste, Clean Development Mechanism, United Nations Framework Convention on Climate Change, Air Pollution, Computer Simulation, Carbon credit, Waste Management and Disposal, Cement, Waste management, business.industry, Construction Materials, Certified Emission Reduction, General Medicine, Carbon Dioxide, Models, Theoretical, Carbon, Saccharum, Greenhouse gas, business, Bagasse, Brazil

Abstract

This paper presents a study of cement replacement by sugar cane bagasse ash (SCBA) in industrial scale aiming to reduce the CO(2) emissions into the atmosphere. SCBA is a by-product of the sugar/ethanol agro-industry abundantly available in some regions of the world and has cementitious properties indicating that it can be used together with cement. Recent comprehensive research developed at the Federal University of Rio de Janeiro/Brazil has demonstrated that SCBA maintains, or even improves, the mechanical and durability properties of cement-based materials such as mortars and concretes. Brazil is the world's largest sugar cane producer and being a developing country can claim carbon credits. A simulation was carried out to estimate the potential of CO(2) emission reductions and the viability to issue certified emission reduction (CER) credits. The simulation was developed within the framework of the methodology established by the United Nations Framework Convention on Climate Change (UNFCCC) for the Clean Development Mechanism (CDM). The State of Sao Paulo (Brazil) was chosen for this case study because it concentrates about 60% of the national sugar cane and ash production together with an important concentration of cement factories. Since one of the key variables to estimate the CO(2) emissions is the average distance between sugar cane/ethanol factories and the cement plants, a genetic algorithm was developed to solve this optimization problem. The results indicated that SCBA blended cement reduces CO(2) emissions, which qualifies this product for CDM projects.

Published

2009

37. Emissions study of co-firing waste carpet in a rotary kiln

Author

Eric Stewart, Matthew J. Realff, James A. Mulholland, and Paul M. Lemieux

Subjects

Cement, Engineering, Air Pollutants, Environmental Engineering, Waste management, Kiln, business.industry, Construction Materials, General Medicine, Free Radical Scavengers, Incineration, Management, Monitoring, Policy and Law, Combustion, Nitric Oxide, law.invention, Refuse Disposal, Volume (thermodynamics), law, Natural gas, Floors and Floorcoverings, Fiber, business, Waste Management and Disposal, Rotary kiln

Abstract

Post-consumer carpet represents a high volume, high energy content waste stream. As a fuel for co-firing in cement kilns, waste carpet, like waste tires, has potential advantages. Technological challenges to be addressed include assessing potential emissions, in particular NO emissions (from nylon fiber carpets), and optimizing the carpet feed system. This paper addresses the former. Results of pilot-scale rotary kiln experiments demonstrate the potential for using post-consumer waste carpet as a fuel in cement kilns. Continuous feeding of shredded carpet fiber and ground carpet backing, at rates of up to 30% of total energy input, resulted in combustion without transient puffs and with almost no increase in CO and other products of incomplete combustion as compared to kiln firing natural gas only. NO emissions increased with carpet waste co-firing due to the nitrogen content of nylon fiber. In these experiments with shredded fiber and finely ground backing, carpet nitrogen conversion to NO ranged from 3 to 8%. Conversion increased with enhanced mixing of the carpet material and air during combustion. Carpet preparation and feeding method are controlling factors in fuel N conversion.

Published

2004