Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2011 |
| Tipo de documento: | Dissertação |
| Idioma: | por |
| Título da fonte: | Manancial - Repositório Digital da UFSM |
| Texto Completo: | http://repositorio.ufsm.br/handle/1/7764 |
Resumo: | Natural rice husk ash (RHA) used in concrete contributes to civil construction sustainability. In fact, RHA is considered a residual pollutant and then it is necessary to destine this material correctly. However, it is necessary to investigate the consequences of replacing part of cement by natural RHA to produce concrete for structural purposes. In this context, the aim of this study was to evaluate the concrete durability produced with 15 % of blinder partial replacement by natural RHA in the expansion due to alkali-silica reaction (ASR) and penetration of chloride ion, as well as to suggest preventive measures with the use of mineral additions. In the present study, natural RHA was used as partially replacement of Portland cement. This natural RHA has been obtained without temperature control burning and placed directly into the mixer to suffer self-grinding with aggregates. We investigated the RAS neutralization of natural RHA by the use of cement with mineral additions (CPIIZ, CPIII e CPIV), as well as, we performed additional replacements of part from CPIIZ cement by fly ash (10, 15, 20, 30 and 40 %). We employed accelerated expansion method at 80°C in mortar bars followed by scanning electron microscopy (SEM) and X-ray diffraction (XRD), and long term at 38 °C and accelerated at 60 °C methods in concrete prisms. To investigate concrete resistance in the chloride ion penetration, we used chloride ions penetration method by immersion in saline solution (CPT) of concrete produced with natural RHA and CPIIZ cement added of fly ash (0, 12.75 or 17 %) and water-binder ratios of 0.45, 0.55 and 0.65 were adopted. Analyses of results were based in slope (K ) obtained from the average depths of penetration. In this study, we verified that in mortar bars assay the natural RHA generated expansion above of results allowed by norm in mixtures with standard cement, while CPIIZ cement with addition from 20 % of fly ash showed to mitigate the ASR. These results demonstrated that effect of mitigation of RAS proportionally increased with fly ash addition. Moreover, CPIV cement demonstrated excellence in mitigate the expansive reaction. The SEM analysis identified the characteristic products of ASR in the samples containing natural RHA. XRD analysis showed that the samples of mixtures with higher content of mineral addition showed peaks of calcium hydroxide (CH) with less intensity and mixtures with natural RHA presented greater calcium carbonate content. In relation to concrete prisms molded at 60°C, results showed an increase in expansion for mixture of CPIIZ with natural RHA, but these results remained below of maximum expansion predicted by test. Mixtures of CPII-Z with natural RHA added of 10 and 15% fly ash demonstrated better efficiency in expansion mitigation. In relation to concrete prisms molded at 38°C, the results are not conclusive to 12 months, but mixtures that presented a great expansion were of CPII-Z with natural RHA and 15% fly ash, the CPII-Z with RHA natural and CPII-Z with natural RHA and 10% fly ash, respectively. However, all mixtures had expansion below the maximum limit suggested by the Brazilian standard at 24 months. Through of results CPT, we can conclude that mineral additions provided improvements to the concrete with higher ages due to pozzolanic effect. Moreover, the best results obtained were in trace with lowest water-binder ratios, probably due to increased consumption of cement, which increases the CH amount to interact with the RHA and the fly ash. Therefore, mixtures of Portland cement with fly ash and natural RHA meet the durability of concrete, and also the use of natural RHA would be an important contribution to sustainability and preservation of environment by civil construction. |
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2011-11-192011-11-192011-05-06TRINDADE, Guilherme Höehr. DURABILITY OF CONCRETE WITH NATURAL RICE HUSK ASH WITHOUT GRINDING: MITIGATION OF ALKALI-SILICA REACTION AND CHLORIDE PENETRATION. 2011. 200 f. Dissertação (Mestrado em Engenharia Civil) - Universidade Federal de Santa Maria, Santa Maria, 2011.http://repositorio.ufsm.br/handle/1/7764Natural rice husk ash (RHA) used in concrete contributes to civil construction sustainability. In fact, RHA is considered a residual pollutant and then it is necessary to destine this material correctly. However, it is necessary to investigate the consequences of replacing part of cement by natural RHA to produce concrete for structural purposes. In this context, the aim of this study was to evaluate the concrete durability produced with 15 % of blinder partial replacement by natural RHA in the expansion due to alkali-silica reaction (ASR) and penetration of chloride ion, as well as to suggest preventive measures with the use of mineral additions. In the present study, natural RHA was used as partially replacement of Portland cement. This natural RHA has been obtained without temperature control burning and placed directly into the mixer to suffer self-grinding with aggregates. We investigated the RAS neutralization of natural RHA by the use of cement with mineral additions (CPIIZ, CPIII e CPIV), as well as, we performed additional replacements of part from CPIIZ cement by fly ash (10, 15, 20, 30 and 40 %). We employed accelerated expansion method at 80°C in mortar bars followed by scanning electron microscopy (SEM) and X-ray diffraction (XRD), and long term at 38 °C and accelerated at 60 °C methods in concrete prisms. To investigate concrete resistance in the chloride ion penetration, we used chloride ions penetration method by immersion in saline solution (CPT) of concrete produced with natural RHA and CPIIZ cement added of fly ash (0, 12.75 or 17 %) and water-binder ratios of 0.45, 0.55 and 0.65 were adopted. Analyses of results were based in slope (K ) obtained from the average depths of penetration. In this study, we verified that in mortar bars assay the natural RHA generated expansion above of results allowed by norm in mixtures with standard cement, while CPIIZ cement with addition from 20 % of fly ash showed to mitigate the ASR. These results demonstrated that effect of mitigation of RAS proportionally increased with fly ash addition. Moreover, CPIV cement demonstrated excellence in mitigate the expansive reaction. The SEM analysis identified the characteristic products of ASR in the samples containing natural RHA. XRD analysis showed that the samples of mixtures with higher content of mineral addition showed peaks of calcium hydroxide (CH) with less intensity and mixtures with natural RHA presented greater calcium carbonate content. In relation to concrete prisms molded at 60°C, results showed an increase in expansion for mixture of CPIIZ with natural RHA, but these results remained below of maximum expansion predicted by test. Mixtures of CPII-Z with natural RHA added of 10 and 15% fly ash demonstrated better efficiency in expansion mitigation. In relation to concrete prisms molded at 38°C, the results are not conclusive to 12 months, but mixtures that presented a great expansion were of CPII-Z with natural RHA and 15% fly ash, the CPII-Z with RHA natural and CPII-Z with natural RHA and 10% fly ash, respectively. However, all mixtures had expansion below the maximum limit suggested by the Brazilian standard at 24 months. Through of results CPT, we can conclude that mineral additions provided improvements to the concrete with higher ages due to pozzolanic effect. Moreover, the best results obtained were in trace with lowest water-binder ratios, probably due to increased consumption of cement, which increases the CH amount to interact with the RHA and the fly ash. Therefore, mixtures of Portland cement with fly ash and natural RHA meet the durability of concrete, and also the use of natural RHA would be an important contribution to sustainability and preservation of environment by civil construction.O emprego de cinza de casca de arroz (CCA) natural no concreto visa contribuir para a sustentabilidade da construção civil, destinando de maneira adequada, esse material que antes seria considerado um resíduo poluente. Porém, é necessária a investigação das consequências em substituir parte do cimento por CCA natural para produzir concreto com finalidade estrutural. Neste sentido, o objetivo deste trabalho foi avaliar a durabilidade de concretos produzidos com teor de 15 % de substituição parcial do aglomerante por CCA natural, frente à expansão devido à reação álcali-sílica (RAS) e à penetração de íons cloretos, assim como, sugerir medidas preventivas através do uso de adições minerais. No presente estudo, a CCA natural foi utilizada em substituição parcial ao cimento Portland no estado em que se encontra ao sair dos fornos de queima (sem controle de temperatura), diretamente na betoneira para sofrer auto-moagem com os agregados. Foi investigada a neutralização das RAS da CCA natural pelo emprego de cimentos com adições minerais (CPIIZ, CPIII e CPIV), assim como foram realizadas as substituições adicionais de parte do cimento CPIIZ por cinza volante (10, 15, 20, 30 e 40 %). Na investigação da RAS foram empregados os métodos de expansão acelerado a 80 °C em barras de argamassa acompanhado pela microscopia eletrônica de varredura (MEV) e difração de raios-X (DRX), e os métodos de longa duração a 38 °C e acelerado a 60 °C em prismas de concreto. Na investigação da resistência a penetração de íons cloretos foi empregado o método de penetração de íons cloretos por imersão em solução salina (EPCI) dos concretos produzidos com CCA natural e cimento CPIIZ adicionados de cinza volante (0; 12,75 ou 17 %) e nas relações água/aglomerante(a/ag) de 0,45; 0,55 e 0,65. A análise dos resultados do EPCI foi realizada com base no coeficiente angular da equação da reta (K ) obtido a partir das profundidades médias de penetração dos períodos investigados. Neste trabalho verificou-se que, no ensaio em barras de argamassa a CCA natural gerou expansão acima do permitido por norma nas misturas com cimento padrão, enquanto o cimento CPIIZ com adição a partir de 20 % de cinza volante se mostrou mitigador da RAS. Através desses resultados pode-se verificar que o efeito mitigador da RAS aumentou proporcionalmente com a adição de cinza volante. Além disso, o cimento CPIV mostrou excelência em mitigar a reação expansiva. A análise de MEV identificou os produtos característicos da RAS nas amostras contendo CCA natural e a DRX verificou que as amostras retiradas das misturas com maior teor de adição mineral apresentaram picos de hidróxido de cálcio (CH) com menor intensidade e ainda, que as misturas com CCA natural apresentaram maior quantidade de carbonato de cálcio. Em relação aos prismas de concreto moldados a 60 °C, os resultados mostraram maior expansão na mistura de CPIIZ com CCA natural, mas ela se manteve abaixo do limite máximo de expansão preconizado pelo ensaio. As misturas de CPII-Z com CCA natural adicionadas de 10 e 15 % de cinza volante mostraram melhor eficiência em mitigar a expansão. Em relação aos prismas de concreto moldados a 38 °C os resultados ainda não são conclusivos aos 12 meses, porém as misturas que apresentaram maior expansão em 12 meses foram as de CPII-Z com CCA natural e 15 % de cinza volante, de CPII-Z com CCA natural e CPII-Z com CCA natural e 10 % de cinza volante, respectivamente, entretanto, todas abaixo do limite máximo de expansão aos 24 meses, preconizado pela norma brasileira. Através das análises dos resultados do EPCI concluiu-se que as adições minerais proporcionaram melhorias ao concreto com maiores idades devido ao efeito pozolânico. Além disso, os melhores resultados obtidos foram nos traços com menor relação a/ag, provavelmente devido ao maior consumo de cimento que aumenta a quantidade de CH para interagir com a CCA e a cinza volante. Portanto, as misturas de cimento Portland com CCA natural e cinza volante atendem aos parâmetros de durabilidade do concreto, e com isso o uso da CCA natural seria um importante contribuinte na sustentabilidade e preservação do meio ambiente pela construção civil.Coordenação de Aperfeiçoamento de Pessoal de Nível Superiorapplication/pdfporUniversidade Federal de Santa MariaPrograma de Pós-Graduação em Engenharia CivilUFSMBREngenharia CivilCinza de casca de arroz naturalReação álcali-sílicaArgamassaConcretoEnsaio aceleradoDifusão de cloretosNatural rice husk ashAlkali-silica reactionMortar barsConcreteAcelerated testChloride diffusionCNPQ::ENGENHARIAS::ENGENHARIA CIVILDurabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretosDurability of concrete with natural rice husk ash without grinding: mitigation of alkali-silica reaction and chloride penetrationinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisIsaia, Geraldo Cechellahttp://buscatextual.cnpq.br/buscatextual/visualizacv.do?id=K4787985U6http://buscatextual.cnpq.br/buscatextual/visualizacv.do?id=K4464742D4Trindade, Guilherme Höehr3001000000034003003005d5ff349-6e1b-45f0-a3fc-dfb31b446dec2abcca07-89ec-4df9-9245-d10f37adea0einfo:eu-repo/semantics/openAccessreponame:Manancial - Repositório Digital da UFSMinstname:Universidade Federal de Santa Maria (UFSM)instacron:UFSMORIGINALTRINDADE, GUILHERME HOEHR.pdfapplication/pdf6205729http://repositorio.ufsm.br/bitstream/1/7764/1/TRINDADE%2c%20GUILHERME%20HOEHR.pdfd3ad81c9fe0dcbd16efc6eb392b4735aMD51TEXTTRINDADE, GUILHERME HOEHR.pdf.txtTRINDADE, GUILHERME HOEHR.pdf.txtExtracted texttext/plain326772http://repositorio.ufsm.br/bitstream/1/7764/2/TRINDADE%2c%20GUILHERME%20HOEHR.pdf.txt02573e103a1f0da04fc8eb7179f52637MD52THUMBNAILTRINDADE, GUILHERME HOEHR.pdf.jpgTRINDADE, GUILHERME HOEHR.pdf.jpgIM Thumbnailimage/jpeg5291http://repositorio.ufsm.br/bitstream/1/7764/3/TRINDADE%2c%20GUILHERME%20HOEHR.pdf.jpg365d8673ff266370457e5e115251d1f8MD531/77642022-03-04 15:08:25.757oai:repositorio.ufsm.br:1/7764Repositório Institucionalhttp://repositorio.ufsm.br/PUBhttp://repositorio.ufsm.br/oai/requestopendoar:39132022-03-04T18:08:25Manancial - Repositório Digital da UFSM - Universidade Federal de Santa Maria (UFSM)false |
| dc.title.por.fl_str_mv |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos |
| dc.title.alternative.eng.fl_str_mv |
Durability of concrete with natural rice husk ash without grinding: mitigation of alkali-silica reaction and chloride penetration |
| title |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos |
| spellingShingle |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos Trindade, Guilherme Höehr Cinza de casca de arroz natural Reação álcali-sílica Argamassa Concreto Ensaio acelerado Difusão de cloretos Natural rice husk ash Alkali-silica reaction Mortar bars Concrete Acelerated test Chloride diffusion CNPQ::ENGENHARIAS::ENGENHARIA CIVIL |
| title_short |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos |
| title_full |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos |
| title_fullStr |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos |
| title_full_unstemmed |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos |
| title_sort |
Durabilidade do concreto com cinza de casca de arroz natural sem moagem: mitigação da reação álcali-sílica e penetração de cloretos |
| author |
Trindade, Guilherme Höehr |
| author_facet |
Trindade, Guilherme Höehr |
| author_role |
author |
| dc.contributor.advisor1.fl_str_mv |
Isaia, Geraldo Cechella |
| dc.contributor.advisor1Lattes.fl_str_mv |
http://buscatextual.cnpq.br/buscatextual/visualizacv.do?id=K4787985U6 |
| dc.contributor.authorLattes.fl_str_mv |
http://buscatextual.cnpq.br/buscatextual/visualizacv.do?id=K4464742D4 |
| dc.contributor.author.fl_str_mv |
Trindade, Guilherme Höehr |
| contributor_str_mv |
Isaia, Geraldo Cechella |
| dc.subject.por.fl_str_mv |
Cinza de casca de arroz natural Reação álcali-sílica Argamassa Concreto Ensaio acelerado Difusão de cloretos |
| topic |
Cinza de casca de arroz natural Reação álcali-sílica Argamassa Concreto Ensaio acelerado Difusão de cloretos Natural rice husk ash Alkali-silica reaction Mortar bars Concrete Acelerated test Chloride diffusion CNPQ::ENGENHARIAS::ENGENHARIA CIVIL |
| dc.subject.eng.fl_str_mv |
Natural rice husk ash Alkali-silica reaction Mortar bars Concrete Acelerated test Chloride diffusion |
| dc.subject.cnpq.fl_str_mv |
CNPQ::ENGENHARIAS::ENGENHARIA CIVIL |
| description |
Natural rice husk ash (RHA) used in concrete contributes to civil construction sustainability. In fact, RHA is considered a residual pollutant and then it is necessary to destine this material correctly. However, it is necessary to investigate the consequences of replacing part of cement by natural RHA to produce concrete for structural purposes. In this context, the aim of this study was to evaluate the concrete durability produced with 15 % of blinder partial replacement by natural RHA in the expansion due to alkali-silica reaction (ASR) and penetration of chloride ion, as well as to suggest preventive measures with the use of mineral additions. In the present study, natural RHA was used as partially replacement of Portland cement. This natural RHA has been obtained without temperature control burning and placed directly into the mixer to suffer self-grinding with aggregates. We investigated the RAS neutralization of natural RHA by the use of cement with mineral additions (CPIIZ, CPIII e CPIV), as well as, we performed additional replacements of part from CPIIZ cement by fly ash (10, 15, 20, 30 and 40 %). We employed accelerated expansion method at 80°C in mortar bars followed by scanning electron microscopy (SEM) and X-ray diffraction (XRD), and long term at 38 °C and accelerated at 60 °C methods in concrete prisms. To investigate concrete resistance in the chloride ion penetration, we used chloride ions penetration method by immersion in saline solution (CPT) of concrete produced with natural RHA and CPIIZ cement added of fly ash (0, 12.75 or 17 %) and water-binder ratios of 0.45, 0.55 and 0.65 were adopted. Analyses of results were based in slope (K ) obtained from the average depths of penetration. In this study, we verified that in mortar bars assay the natural RHA generated expansion above of results allowed by norm in mixtures with standard cement, while CPIIZ cement with addition from 20 % of fly ash showed to mitigate the ASR. These results demonstrated that effect of mitigation of RAS proportionally increased with fly ash addition. Moreover, CPIV cement demonstrated excellence in mitigate the expansive reaction. The SEM analysis identified the characteristic products of ASR in the samples containing natural RHA. XRD analysis showed that the samples of mixtures with higher content of mineral addition showed peaks of calcium hydroxide (CH) with less intensity and mixtures with natural RHA presented greater calcium carbonate content. In relation to concrete prisms molded at 60°C, results showed an increase in expansion for mixture of CPIIZ with natural RHA, but these results remained below of maximum expansion predicted by test. Mixtures of CPII-Z with natural RHA added of 10 and 15% fly ash demonstrated better efficiency in expansion mitigation. In relation to concrete prisms molded at 38°C, the results are not conclusive to 12 months, but mixtures that presented a great expansion were of CPII-Z with natural RHA and 15% fly ash, the CPII-Z with RHA natural and CPII-Z with natural RHA and 10% fly ash, respectively. However, all mixtures had expansion below the maximum limit suggested by the Brazilian standard at 24 months. Through of results CPT, we can conclude that mineral additions provided improvements to the concrete with higher ages due to pozzolanic effect. Moreover, the best results obtained were in trace with lowest water-binder ratios, probably due to increased consumption of cement, which increases the CH amount to interact with the RHA and the fly ash. Therefore, mixtures of Portland cement with fly ash and natural RHA meet the durability of concrete, and also the use of natural RHA would be an important contribution to sustainability and preservation of environment by civil construction. |
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TRINDADE, Guilherme Höehr. DURABILITY OF CONCRETE WITH NATURAL RICE HUSK ASH WITHOUT GRINDING: MITIGATION OF ALKALI-SILICA REACTION AND CHLORIDE PENETRATION. 2011. 200 f. Dissertação (Mestrado em Engenharia Civil) - Universidade Federal de Santa Maria, Santa Maria, 2011. |
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TRINDADE, Guilherme Höehr. DURABILITY OF CONCRETE WITH NATURAL RICE HUSK ASH WITHOUT GRINDING: MITIGATION OF ALKALI-SILICA REACTION AND CHLORIDE PENETRATION. 2011. 200 f. Dissertação (Mestrado em Engenharia Civil) - Universidade Federal de Santa Maria, Santa Maria, 2011. |
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