Using ready-mixed mortars in concrete block structural masonry

Matos, Paulo Ricardo de; Schankoski, Rudiele Aparecida; Pilar, Ronaldo; Prudêncio Junior, Luiz Roberto

doi:10.1590/s1678-86212020000300438

Abstract

Ready-mixed mortars have been increasingly used due to their potential for waste reductions and productivity increases. However, research regarding their use in structural masonry applications are practically non-existent. Thus, this work investigated the technical feasibility of using ready-mixed mortars with nominal compressive strengths of 6, 9 and 14 MPa and storage times of 0 and 36 hours in concrete block structural masonry. The fresh state properties of the mortars were evaluated at 0 and 36 hours through the slump test, consistency and plasticity by the Gtec test, and entrained air content. The compressive and flexural strengths of the mortars were determined at 28 days. In addition, three-row prisms were tested for compressive strength and modulus of elasticity, and four-row prisms for flexural strength in the bending test, all at 28 days. The results showed that the 6 and 9 MPa ready-mixed mortars showed satisfactory maintenance of the fresh properties from 0 to 36 hours and adequate hardened properties for both casting ages, in contrast to the 14 MPa mortar. Regarding the prism tests, the increase in storage time did not significantly affect the properties evaluated for a reliability of 95%.

Keywords:
Ready-mixed mortar; Structural masonry; Concrete blocks

Resumo

O uso de argamassas estabilizadas vem ganhando espaço devido ao seu potencial de reduções no desperdício e aumento na produtividade. Entretanto, estudos referentes ao emprego deste material em alvenaria estrutural são praticamente inexistentes. Assim, este trabalho investigou a viabilidade técnica do emprego de argamassas estabilizadas com resistências nominais à compressão de 6, 9 e 14 MPa e tempos de armazenamento de 0 e 36 horas, em alvenaria estrutural de blocos de concreto. As propriedades das argamassas foram avaliadas no estado fresco após 0 e 36 horas, através do abatimento do tronco de cone, consistência e plasticidade pelo Gtec teste, e teor de ar incorporado. As resistências à compressão e à flexão das argamassas foram determinadas aos 28 dias. Adicionalmente, foram ensaiados prismas de três fiadas para a determinação da resistência à compressão e módulo de elasticidade, e quatro fiadas para a determinação da resistência à flexão, aos 28 dias. As argamassas de 6 e 9 MPa apresentaram manutenção satisfatório nas propriedades do estado fresco de 0 para 36 horas, e no estado endurecido para ambas as idades de moldagem, opostamente a de 14 MPa. Em relação aos prismas, o aumento do tempo de armazenamento não alterou significativamente as propriedades investigadas, para uma confiabilidade de 95%.

Palavras-chave:
Argamassa estabilizada; Alvenaria estrutural; Blocos de concreto

Introduction

Structural masonry is one of the oldest known building systems but has been changing over the years according to scientific and industrial evolution (MOHAMAD, 1998MOHAMAD, G. Comportamento mecânico na ruptura de prismas de alvenaria de blocos de concreto. Florianópolis, 1998. Dissertação (Mestrado em Engenharia Civil) - Universidade Federal de Santa Catarina, Florianópolis, 1998.). In this type of structure, the walls are loadbearing elements comprising masonry units (bricks or blocks) joined by mortar joints and are capable of resisting loads beyond their own weight (PRUDÊNCIO JUNIOR; OLIVEIRA; BEDIN, 2002PRUDÊNCIO JUNIOR, L. R.; OLIVEIRA, A. L.; BEDIN, C. A. Alvenaria estrutural de blocos de concreto, Florianópolis: Gráfica Palloti, 2002.). This building system presents a few technical and economic aspects that makes it advantageous over traditional methods, such as the combination of reinforced concrete structures and brick masonry walls. The main advantage lies in the great potential of rationalisation of all construction stages, through the optimisation of temporal, material and human resources (HENDRY, 2001HENDRY, E. A. W. Masonry walls: materials and construction. Construction and Building Materials, v. 15, p. 323-330, 2001.).

In order to rationalise the construction process, industrialised mortars were developed in the 1950s, which are previously dry-mixed mortars that require only the addition of water at the construction site. Later, the ready-mixed mortars appeared in the 1970s, which are ready-to-use mortars that can be used for up to three days, while maintaining their characteristics (PANARESE; KOSMATKA; RANDALL, 1991PANARESE, W. C.; KOSMATKA, S. H.; RANDALL, F. A. Concrete mansory handbook for architects, engineers, builders. 5. ed. New York: Portland Cement Association, 1991.). This is feasible due to hydration controller admixtures. These can work in two ways: by reducing the solubility of Portland cement compounds (such as gypsum, which reduces the dissolution of aluminate phases), or by forming precipitates on the cement particles, thereby forming a low permeability layer over the grains and slowing their hydration. The first mechanism is associated with the commonly called "retarder" admixtures and have a faster effect, while the second mechanism is associated with "hydration inhibitors" admixtures, which have a longer effect (HEWLEET; JUSTNES; EDMEADES, 2019HEWLEET, P. C.; JUSTNES, H.; EDMEADES, R. N. Cement and concrete admixtures. In: LEA'S Chemistry of Cement and Concrete. 5th. ed. New York: Elsevier, 2019.), and are conventionally used in ready- mixed mortars.

Some scientific papers investigated the properties of ready-mixed rendering mortars. Calçada et al. (2013)CALÇADA, L. M. L. et al. Influência das características do molde e da superfície de contato nas propriedades da argamassa estabilizada. In: SIMPÓSIO BRASILEIRO DE TECNOLOGIA DE ARGAMASSA, 10., Fortaleza, 2013. Anais [...] Fortaleza, 2013. evaluated the compressive strength of ready-mixed mortars cast in metallic moulds and on absorbent surfaces (i.e. ceramic and concrete blocks), with storage times of 0 and 48 hours. The authors found higher strengths for the specimens cast on absorbent surfaces. In addition, they reported a trend of increasing the compressive strength and reducing the workability with the increase in the storage time, justified by the general reduction in the entrained air content over time.

Casali et al. (2011)CASALI, J. M. et al. Avaliação das propriedades do estado fresco e endurecido da argamassa estabilizada para revestimento. In: SIMPÓSIO BRASILEIRO DE TECNOLOGIA DAS ARGAMASSAS, 9., Belo Horizonte, 2011. Anais [...] Belo Horizonte, 2011. and Macioski et al. (2013)MACIOSKI, G. et al. Avaliação de propriedades no estado fresco e endurecido de argamassas estabilizadas. In: SIMPÓSIO BRASILEIRO DE TECNOLOGIA DAS ARGAMASSAS, 10., Fortaleza, 2013. Proceedings [...] Fortaleza, 2013. evaluated the fresh and hardened properties of ready-mixed rendering mortars with up to 72 hours of storage times. In general, the increase in storage time reduced the mechanical strength of the mortars (in contrast to Calçada et al. (2013)CALÇADA, L. M. L. et al. Influência das características do molde e da superfície de contato nas propriedades da argamassa estabilizada. In: SIMPÓSIO BRASILEIRO DE TECNOLOGIA DE ARGAMASSA, 10., Fortaleza, 2013. Anais [...] Fortaleza, 2013.), in addition to reducing the consistency index of the mixtures. Furthermore, Casali et al. (2011)CASALI, J. M. et al. Avaliação das propriedades do estado fresco e endurecido da argamassa estabilizada para revestimento. In: SIMPÓSIO BRASILEIRO DE TECNOLOGIA DAS ARGAMASSAS, 9., Belo Horizonte, 2011. Anais [...] Belo Horizonte, 2011. found that the application of a water film over the mortar after its use resulted in lower workability losses from the previous day to the next one.

Bauer et al. (2015)BAUER, E. et al. Requisitos das argamassas estabilizadas para revestimento. In: SIMPÓSIO BRASILEIRO DE TECNOLOGIA DAS ARGAMASSAS, 11., Porto Alegre, 2015. Anais [...] Porto Alegre, 2015. evaluated 17 batches of ready-mixed rendering mortars produced in plants from Brasília - DF, proposing performance requirements for these materials. The authors evaluated the mixtures through cone penetration test, flow table test, water retention, air content, fresh and hardened densities, compressive, tensile and flexural strength, dimensional variation and capillary absorption. Finally, the authors proposed a standard performance profile for this type of mortar.

Oliveira et al. (2017)OLIVEIRA, V. et al. Estudo comportamental das argamassas estabilizadas de revestimentos quanto a suscetibilidade a fissuração. In: CONGRESSO INTERNACIONAL SOBRE PATOLOGIA E REABILITAÇÃO DE ESTRUTURAS, 13., Creto, 2017. Anais […], Creto, 2017. investigated the effect of the admixture type and content on the susceptibility to cracking of ready-mixed rendering mortars. The authors evaluated the flexural strength, modulus of elasticity and volumetric variation by drying shrinkage of the mortars. In general, they found that the contents of both air-entraining and hydration stabiliser admixtures affected the mortars susceptibility to cracking.

Finally, Casali et al. (2018)CASALI, J. M. et al. Influence of cement type and water content on the fresh state properties of ready mix mortar. Ambiente Construído, Porto Alegre, v. 18, n. 2, p. 33-52, abr./jun. 2018. studied the influence of the type of cement and water content on the fresh state properties of ready-mixed rendering mortars with storage times of 0, 24 and 48 hours. The consistency index, fresh density, air content, and rheological behaviour through the squeeze-flow test were evaluated at different storage times. The authors found that the type of cement and storage time significantly affected the rheological properties of the mortars. However, the authors found that both the consistency index and entrained air content tests were not sensitive to evaluate the changes in the fresh state properties, even though these are the tests conventionally employed in production control.

In addition, some academic studies evaluated the properties of ready-mixed mortars, such as Mann Neto, Andrade and Soto (2010)MANN NETO, A.; ANDRADE, D. C.; SOTO, N. T. A. Avaliação das propriedades do estado fresco e endurecido da argamassa estabilizada para revestimento. Trabalho de Conclusão de Curso (Engenharia de Produção Civil) - Universidade Tecnológica Federal do Paraná, Curitiba, 2010., Pereira (2012)PEREIRA, L. Estudo das propriedades da argamassa estabilizada para revestimento: influência das características do molde, do tempo e das condições de armazenamento. Florianópolis, 2012. Trabalho de Conclusão de Curso (Curso Superior de Tecnologia em Construção de Edifícios) - Instituto Federal de Tecnologia, Ciência e Educação de Santa Catarina, Florianópolis, 2012., Fernandes (2011)FERNANDES, A. Avaliação da variabilidade das propriedades da argamassa estabilizada fornecida para a grande Florianópolis. Florianópolis, 2011. Trabalho de Conclusão de Curso (Curso Superior de Tecnologia em Construção de Edifícios) - Instituto Federal de Tecnologia, Ciência e Educação de Santa Catarina, Florianópolis, 2011. and Campos (2012)CAMPOS, G. M. Estudo do Tempo de Início de Pega de Argamassas Com Aditivo Estabilizador de Hidratação. Curitiba, 2012. Monografia (Especialização em Patologia das Construções) - Universidade Tecnológica Federal do Paraná, Curitiba, 2012.. In general, these studies evaluated the properties of the mortars themselves or for the purpose of wall coatings.

Despite the list of works mentioned above addressing the use of ready-mixed mortars in rendering or bricklaying applications, this material is still rarely used in structural applications, such as in structural masonry. In fact, to the best of the author’s knowledge, there are no scientific reports on the use of ready-mixed mortars for structural masonry production. Therefore, this work investigated the technical feasibility of using three ready-mixed mortars with two storage times in concrete block structural masonry.

Materials and methods

Materials

A Portland cement type CP IV-32 RS (ABNT, 2018ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 16697: cimento Portland: requisitos. Rio de Janeiro, 2018.) was used to prepare the mortars. Table 1 and Table 2, respectively, present the chemical and physical characteristics of the Portland cement used, provided by the manufacturer.

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Table 1
Chemical composition of the Portland cement

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Table 2
Physical properties of the Portland cement

The aggregate fraction of the mortars consisted of a combination of a natural quartz sand, with a fineness modulus of 1.34 and a specific gravity of 2.65 g/cm³, and a granitic manufactured sand with fineness modulus of 2.60 and a specific gravity of 2.86 g/cm³. The sands were used in mass proportions of 70% natural sand and 30% manufactured sand. The composition of sands had a fineness modulus of 1.73 and specific gravity of 2.71g/cm³. Figure 1 shows the particle size distribution of the sands.

Figure 1
Particle size distribution of the sands

When preparing the mortars, an air-entraining admixture (Rheomix 701, BASF) and a hydration stabiliser admixture (Rheomix 702, BASF) were used. The characteristics of the admixtures provided by the manufacturer are shown in Table 3.

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Table 3
Properties of the chemical admixtures

Finally, concrete blocks of three nominal compressive strengths (6, 9 and 14 MPa) were used in the prism production. All blocks had nominal dimensions of 140 x 190 x 390 mm (width x height x length), and a wall thickness of 25 ± 3 mm.

Mortar mix composition

Three ready-mixed mortars, provided by a plant from Florianópolis - SC, were investigated in this work. They were respectively designed for 28-day compressive strengths of 6, 9 and 14 MPa, and for a maximum storage time of 48 hours. The mass unitary compositions of the mortars were provided by the plant and are shown in Table 4.

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Table 4
Mass unitary composition of the mortars investigated

Experimental procedures

Concrete blocks

For each block strength class, eighty units were collected. It is known that the weight of the block affects its mechanical strength. Since the blocks had the same volume, heavier blocks have greater compactness, thus resulting in greater strengths (PRUDÊNCIO JUNIOR; OLIVEIRA; BEDIN, 2002PRUDÊNCIO JUNIOR, L. R.; OLIVEIRA, A. L.; BEDIN, C. A. Alvenaria estrutural de blocos de concreto, Florianópolis: Gráfica Palloti, 2002.). Therefore, in order to reduce the variability of the results, the blocks of each strength class were weighed and classified according to their weight. Thirty-three blocks with "intermediate" weight were selected, six of which were used for the blocks´ compressive strength test, eight for the central rows of the compression prisms, sixteen for the central rows of the bending prisms, and three for the water absorption test. The blocks classified as "light" and "heavy" were respectively used in the lower and upper rows of the compression and bending prisms. This procedure is further explained in item “Prisms”.

The compressive strength of the blocks was determined according to NBR 12118 (ABNT, 2013ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 12118: blocos vazados de concreto simples para alvenaria: métodos de ensaio. Rio de Janeiro, 2013.). For each strength class, six units were tested, and the characteristic strength (f_bk) was calculated through Equation 1 prescribed by NBR 6136 (ABNT, 2016aASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 6136: blocos vazados de concreto simples para alvenaria: requisitos. Rio de Janeiro, 2016a.), where fb₍₁₎, fb₍₂₎, ..., fb_(i) are the individual compressive strength values in increasing order; n is the number of blocks tested; and i = n/2 if n is even, or n/2 - 1 if n is odd. Moreover, this standard prescribes that, for n = 6 (adopted in this work), the f_bk value should not be lower than 0.89 × f_b1. For this test, the upper and lower faces of the blocks were previously capped with cement paste for surface regularisation.

Eq. 1

f_{bk} = 2 [\frac{f_{b (1)} + f_{b (2)} + ... + f_{(i - 1)}}{i - 1}] - f_{b (i)}

Finally, the water absorption (a) was determined following the NBR 12118 (ABNT, 2013ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 12118: blocos vazados de concreto simples para alvenaria: métodos de ensaio. Rio de Janeiro, 2013.) and calculated by Equation 2. The procedure consists of drying the block in an oven at 110 ºC for 24 hours and then determining its weight (m₁). After cooling it, the block is immersed in water at 23 ºC for 24 h. Finally, the block is weighed in a saturated surface dry condition (m₂). For each strength class, three units were tested, and the mean values were adopted.

Eq. 2

a = \frac{m 2 - m 1}{m 1} \times 100

Mortars

The mortars were delivered by the plant in a plastic container of 1/3 of a cubic meter (333 liters), similar to a water tank. The container was kept inside the laboratory throughout the study, protected from the sun and wind. After performing the tests on the first day (referred to as "0 hours"), the mortars were covered with a waterproof plastic sheeting in addition to a water film over it, similarly to that suggested by Casali et al. (2011)CASALI, J. M. et al. Avaliação das propriedades do estado fresco e endurecido da argamassa estabilizada para revestimento. In: SIMPÓSIO BRASILEIRO DE TECNOLOGIA DAS ARGAMASSAS, 9., Belo Horizonte, 2011. Anais [...] Belo Horizonte, 2011.. This procedure avoided changing the water content of the mixtures, either by evaporation or incorporating additional water by applying the water film directly onto the mortar. After 36 hours, both the sheeting and water film were removed, and the mortars were manually homogenised according to the procedure conventionally adopted on site, which consists of mixing the mortar with a paddle until obtaining a homogeneous material. Finally, the "36-hour" tests were performed. The tests performed in the fresh and hardened mortars are described below.

Fresh state

The mortar consistency is commonly evaluated using the flow table test (ABNT, 2016bASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 13276: argamassa para assentamento e revestimento de paredes e tetos: determinação do índice de consistência. Rio de Janeiro, 2016b). However, in this study we chose to use the slump test (ABNT, 1998ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR NM 67: concreto: determinação da consistência pelo abatimento do tronco de cone. Rio de Janeiro, 1998.) to evaluate this property as it is the test conventionally used by the plants, and it is adopted as acceptance criterion on the construction site.

The entrained air content was determined by the pycnometer method, developed by Schankoski et al. (2012)SCHANKOSKI, R. A. et al. Entre diferentes métodos de determinação do teor de ar incorporado em argamassas. In: CONGRESSO BRASILEIRO DE CONCRETO, 54., Maceió, 2012. Anais [...] Maceió, 2012.. In this method, the air content is determined by the volume variation of a mortar sample added to a pycnometer, which contains a solution of 50% ethyl alcohol + 50% distilled water, before and after the removal of the air by shaking the sample with a glass rod.

Additionally, the consistency and plasticity of the mortars were evaluated through the Gtec test, developed by Casali and Prudêncio Junior (2008)CASALI, L.; PRUDÊNCIO JUNIOR, L.R. New test method for the evaluation of the workability of con-crete block masonry bedding mortars. In: INTERNATIONAL BRICK AND BLOCK MASONRY CON-FERENCE, 14., Sidney, 2008. Proceedings […] Sidney, 2008., which is also presented by Carasek (2017)CARASEK, H. Argamassas. In: ISAIA, G. C. (ed.) Materiais de Construção Civil e Princípios de Ciências e Engenharia de Materiais. São Paulo: Ipsis Gráfica e Editora, 2017.. The apparatus is illustrated in Figure 2. The test simulates the application of a real block over a mortar fillet, and consists of the following steps:

Figure 2
Gtec test apparatus

a mortar fillet of 20 mm is cast in the F mold and positioned over the E base. Then, the mortar fillet + E base set is positioned over the A base;
the GH probe is placed in its initial position at 20 mm height of the E base, resting over the mortar fillet;
the GH probe is released, and the deformation suffered by the mortar sample is measured; and
the K sliding mass is dropped from a standard height (from the L ring) until the mortar fillet reaches a thickness of 10 mm.

The consistency of the mortar is taken as the deformation of the mortar fillet after releasing the probe, and the plasticity as the number of drops required for the mortar fillet to reach the thickness of 10 mm. According to Casali and Prudêncio Junior (2008)CASALI, L.; PRUDÊNCIO JUNIOR, L.R. New test method for the evaluation of the workability of con-crete block masonry bedding mortars. In: INTERNATIONAL BRICK AND BLOCK MASONRY CON-FERENCE, 14., Sidney, 2008. Proceedings […] Sidney, 2008., a mortar suitable for concrete block structural masonry applications should have a consistency between 15.0 and 18.0 mm, and a plasticity between 7 and 15 drops. These values were used as acceptance criterion for mortar workability, for both storage times.

Hardened state

For each mortar and storage time, three cylindrical specimens of 50 x 100 mm were cast for the compressive strength test, following the NBR 7215 (ABNT, 2019ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 7215: cimento Portland: determinação da resistência à compressão de corpos de prova cilíndricos. Rio de Janeiro, 2019.). In addition, three prismatic specimens of 40 x 40 x 160 mm were cast for the bending test, according to NBR 13279 (ABNT, 2005ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 13279: argamassa para assentamento e revestimento de paredes e tetos: determinação da resistência à tração na flexão e à compressão. Rio de Janeiro, 2005.). After the bending test, the specimen halves were submitted to the compression test following the NBR 15961 (ABNT, 2011ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 15961: alvenaria estrutural: blocos de concreto: partes 1 e 2. Rio de Janeiro, 2011.), which prescribes the compressive strength determination in cubic specimens of 40 x 40 x 40 mm.

Prisms

For each mortar and storage time, four prisms of three rows were produced for the compressive strength and modulus of elasticity tests, according to Prudêncio Junior, Oliveira and Bedin (2002), and four prisms of four rows were produced for the bending tests. The mortars were applied with wooden trowels over the whole web of the blocks. Some care was taken at this step, following the recommendations of Prudêncio Junior, Oliveira e Bedin (2002):

the blocks were previously air dried and kept in the laboratory before the tests;
before producing the compression prisms, the blocks for the top and bottom rows had one face capped with cement paste for surface regularisation;
the mortar joints had a final thickness of 10 ± 3 mm; and
the blocks classified as "heavy" were applied in the upper rows and the "light" blocks in the lower rows.

This procedure aimed to compensate for the absence of subsequent rows, present on a real wall. The weight of the wall applies pressure on the mortar that assists its penetration into the pores of the substrate. This provides a mechanical bonding between the mortar and the block and is essential to achieve a proper adhesion between them (CARASEK, 2017CARASEK, H. Argamassas. In: ISAIA, G. C. (ed.) Materiais de Construção Civil e Princípios de Ciências e Engenharia de Materiais. São Paulo: Ipsis Gráfica e Editora, 2017.). For the same purpose, an additional block was positioned at the top of each prism (without mortar application), which was maintained until the test age.

The compressive strength and modulus of elasticity tests were performed simultaneously in each prism according to NBR 15961 (ABNT, 2011ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 15961: alvenaria estrutural: blocos de concreto: partes 1 e 2. Rio de Janeiro, 2011.), 28 days after their production. The prisms were submitted to axial compression, and the strain was measured by digital extensometers (ID-C112B, Mitutoyo) with instant readings every 20 kN until the mortar yielded. After this, the strain measurement apparatus was removed, and the prisms were tested until the breaking load.

The flexural strength of the prisms was evaluated at 28 days through the four-point bending test in four-row prisms, following the NBR 8798 (ABNT, 1985ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 8798: execução e controle de obras em alvenaria estrutural de blocos vazados concreto: procedimento. Rio de Janeiro, 1985.). This test differs from the NBR 15961 (ABNT, 2011ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 15961: alvenaria estrutural: blocos de concreto: partes 1 e 2. Rio de Janeiro, 2011.) standard, currently in effect, which prescribes the test in five-row prisms. This choice is justified below. Figure 3 shows the loads, shear force diagrams and bending moment diagrams in prisms during the bending test, for four- and five-row prisms. In the four-row prism (Figure 3a), the central section consists of a mortar joint which is subjected to pure bending, i.e., it does not undergo shear stress. In contrast, in the five-row prism (Figure 3b), both mortar joints of the central block are subjected to shear stress, and are not subject to the maximum bending moment (which occurs in the middle of the central block, and is used to calculate the flexural strength). Therefore, the four-row prisms were chosen for the bending tests.

Figure 3
Loads, shear force diagram (S.F.D.) and bending moment diagram (B.M.D.) in the prism bending test

In order to handle the prisms preventing the blocks from detaching and applying loads before the tests, they were placed on confining supports developed by Schankoski et al. (2012)SCHANKOSKI, R. A. Influência do tipo de argamassa nas propriedades mecânicas de alvenarias estruturais de blocos de concreto de alta resistência. Florianópolis, 2012. Dissertação (Mestrado em Engenharia Civil) - Escola de Engenharia, Universidade Federal de Santa Catarina, Florianópolis, 2012., illustrated in Figure 4a. The bending test is conventionally performed by placing concrete blocks over the load distribution apparatus, as prescribed by NBR 15961 (ABNT, 2011ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 15961: alvenaria estrutural: blocos de concreto: partes 1 e 2. Rio de Janeiro, 2011.). However, for a greater accuracy of the results, the loading was applied through a hydraulic press (UH-A, Shimadzu), as shown in Figure 4b.

Figure 4
Prism flexural test

Statistical analysis of the results

Based on the experimental results obtained in the laboratory, the statistical analysis of the data was performed through comparison of means. To do this, a chi-squared test was used for a significance of 5% (i.e. reliability of 95%). This test evaluates the mean, standard deviations and number of data from two groups, accepting the hypothesis of difference between the means if the dispersions are small enough for the given reliability.

Results and discussion

Concrete blocks

Table 5 shows the compressive strength and water absorption of the blocks. The average compressive strengths exceeded the characteristic strength values (f_bk) by 61%, 93% and 66%, respectively for the 6, 9 and 14 MPa blocks, well above the expected. Regarding the absorption test, the average results were below the maximum limit of 9% prescribed by NBR (ABNT, 2016aASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 6136: blocos vazados de concreto simples para alvenaria: requisitos. Rio de Janeiro, 2016a.) for blocks with strength between 4 and 8 MPa, and 8% for blocks with strength greater than 8 MPa. According to Parsekian et al. (2019)PARSEKIAN, G. et al. Concrete block. In: LONG-TERM performance and durability of masonry structures. Cambridge: Woodhead Publishing, 2019., high absorption values can lead to high moist absorption over time, facilitating the incidence of mould, fungi, lichens, and vegetation in the masonry. There was a progressive reduction in water absorption as the block strength increased. These reductions were of 5.0% and 7.0% respectively for the 9 and 14 MPa blocks compared to the 6 MPa blocks. This confirms that increasing the block strength increases its compactness, consequently reducing the water absorption, as reported in the literature (PARSEKIAN et al., 2019PARSEKIAN, G. et al. Concrete block. In: LONG-TERM performance and durability of masonry structures. Cambridge: Woodhead Publishing, 2019.). This behaviour was also reported by other authors for compressive strengths different from those found in the current work (MARTINS et al., 2018MARTINS, R.O.G. et al. Influence of blocks and grout on compressive strength and stiffness of concrete masonry prisms. Construction and Building Materials, v. 182, p. 233-241, 2018.; FONSECA et al., 2019FONSECA, F. S. et al. Compressive strength of high-strength concrete masonry grouted prisms. Construction and Building Materials, v. 202, n. 30, p. 861-876, 2019.). Since the adhesion between the mortar and the block can be largely affected by the mechanical bonding provided by the mortar penetration into the block pores, this trend may lead to progressive reductions in adhesion as the block strength increases, as discussed later.

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Table 5
Compressive strength and water absorption of the concrete blocks

Fresh state

The results of the mortar fresh state tests are shown in Figure 5 and Table 6. The 14 MPa mixture was not workable at 36 hours. Thus, water was gradually added to this mixture until it reached the Gtec test target range values for consistency and plasticity. This procedure increased the water/cement ratio of the mixture, tending to reduce its mechanical strength. However, this procedure is conventionally adopted on the construction site for the workability adjustment of the ready-mixed mortars.

Figure 5
Correlation between the compressive strength of the mortars in cubic and cylindrical specimens

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Table 6
Summary of the fresh state tests results

Ready-mixed mortar

In general, the mortars showed consistency and plasticity within the limits proposed by Casali and Prudêncio Junior (2008)CASALI, L.; PRUDÊNCIO JUNIOR, L.R. New test method for the evaluation of the workability of con-crete block masonry bedding mortars. In: INTERNATIONAL BRICK AND BLOCK MASONRY CON-FERENCE, 14., Sidney, 2008. Proceedings […] Sidney, 2008. for the Gtec test (consistency between 15.5 and 18.0 mm and plasticity between 7 and 15 drops). According to this test, the 9 MPa mortar had a slight variation in the fresh state properties from 0 to 36 hours, maintaining the plasticity and varying the consistency by 3%. The 6 MPa mortar had greater variations on those properties in the same period but remained within the proposed limits after 36 hours. The workability loss (i.e. increases in the consistency and plasticity values) over time observed for the 6 MPa mortar is in line with the results reported by Casali et al. (2018)CASALI, J. M. et al. Influence of cement type and water content on the fresh state properties of ready mix mortar. Ambiente Construído, Porto Alegre, v. 18, n. 2, p. 33-52, abr./jun. 2018., who found reductions in the flow table test values over time for ready-mixed mortars produced with different types of Portland cement. The authors justified this behaviour by a possible start in the cement hydration reactions. Finally, the 14 MPa mortar showed very high plasticity on the first day, which was compensated by the water incorporation on the second day. It worth noting that the limit values proposed by Casali and Prudêncio Junior (2008)CASALI, L.; PRUDÊNCIO JUNIOR, L.R. New test method for the evaluation of the workability of con-crete block masonry bedding mortars. In: INTERNATIONAL BRICK AND BLOCK MASONRY CON-FERENCE, 14., Sidney, 2008. Proceedings […] Sidney, 2008. refer to concrete blocks, and those values may vary depending on the material and geometry of the blocks. Dafico (2007)DAFICO, D. A. Método para obtenção de independência entre resistência e elasticidade em estudos de dosagem de argamassas mistas. Ambiente Construído, Porto Alegre, v. 7, n. 4, p. 35-42, out./dez. 2007., for example, proposed consistency values between 3 and 13 mm for the Gtec test, for clay blocks of 90 x 190 x 190 mm (width x height x length).

Regarding the air content of the mortars, the 6 and 9 MPa mixtures showed values between 5.9% and 7.2% at both storage times. According to Prudêncio Junior, Oliveira and Bedin (2002)PRUDÊNCIO JUNIOR, L. R.; OLIVEIRA, A. L.; BEDIN, C. A. Alvenaria estrutural de blocos de concreto, Florianópolis: Gráfica Palloti, 2002., an air content lower than 10% usually does not cause significant losses in compressive strength and in the adhesion between the mortar joint and the block. In contrast, the 14 MPa mortar had air contents of 9.0% at 0 hours and 10.7% at 36 hours. These values are respectively 43% and 70% higher than the average of the other mortars and may lead to reductions in mechanical strength and adhesion. This was confirmed by Santamaría-Vicario et al. (2015)SANTAMARÍA-VICARIO, I. et al. Design of masonry mortars fabricated concurrently with different steel slag aggregates. Construction and Building Materials, v. 95, n. 1, p. 197-206, 2015., which reported that increasing the mortar air content from 8% to 22% reduced its adhesive strength by 61% in ceramic-based masonry. Furthermore, it can be noted that both the 6 MPa and 14 MPa mortars had increases in the air content from 0 to 36 hours. This probably occurred due to the homogenisation process performed after 36 hours, which may have incorporated air into the mixture. Thus, it can be stated that the 6 and 9 MPa ready-mixed mortars had satisfactory maintenance of both consistency and plasticity from 0 to 36 hours. One can expect a greater air content for this type of mortar, which usually ranges from 10 to 20%. However, the values found in the current work (7.5% on average) are in line with those reported by Lozovey (2018)LOZOVEY, A. C. R. Método de dosagem de argamassa estabilizada para assentamento de alvenaria estrutural de blocos de concreto. Florianópolis, 2018. Dissertação (Mestrado em Engenharia Civil) - Escola de Engenharia, Universidade Federal de Santa Catarina, Florianópolis, 2018. (down to 8.0%) for this material.

The slump results did not show good correlations with the consistency and plasticity values of the Gtec test (R² < 0.38). For example, the 14 MPa - 36h mixture showed the same consistency value as the 14 MPa - 0h, but slump was 4 times higher. Moreover, the 9 MPa - 36h and 14 MPa - 0h mixtures had similar slump, but very different plasticity. This probably resulted from the sum of two factors. Firstly, the Gtec test evaluates the mortar fresh behaviour through a combination of static and dynamic loads, respectively related to the plasticity and consistency of the mortar. In turn, the slump test evaluates the fresh behaviour only through a static loading condition (i.e. the sample own weight). In addition, the compaction process performed during the slump test may remove part of the entrained air of the mixtures, while the Gtec test is performed in a mortar sample that is practically undisturbed, which is closer to a real condition. Casali et al. (2018)CASALI, J. M. et al. Influence of cement type and water content on the fresh state properties of ready mix mortar. Ambiente Construído, Porto Alegre, v. 18, n. 2, p. 33-52, abr./jun. 2018. also reported the limitation of some empirical tests on the evaluation of fresh state properties of mortars. The authors evaluated the influence of the cement type and storage time on the fresh properties of ready-mixed mortars. They observed significant differences in the rheological behaviour of the mixtures through the squeeze-flow test, while the consistency index (measured by the flow table test) was not sensitive enough to evaluate such differences.

Hardened state

Figure 6 shows the compressive and flexural strength of the mortar at 28 days. Error bars correspond to ± 1 standard deviation. Except for the 6 MPa - 36h and 14 MPa - 36h mixtures, the compressive strength values of the cylindrical specimens were 2% higher on average compared to those of the cubic specimens. This behaviour was not expected as cubic specimens generally provide values from 5 to 10% higher than the cylindrical ones (GREYBEAL; DAVIS, 2008GREYBEAL, B. A.; DAVIS, M. Cylinder or Cube: strength testing of 80 to 200 MPa (11.6 to 29 ksi) ultra-high-performance fiber-reinforced concrete. ACI Materials Journal, v. 105, p. 603-606, 2008.; KUSUMAWARDANINGSIH; FEHLING; ISMAILB, 2015KUSUMAWARDANINGSIH, Y.; FEHLING, E.; ISMAILB, M. UHPC compressive strength test specimens: cylinder or cube? Procedia Engineering, v. 125, p. 1076-1080, 2015.; ALSELMAN; DANG; HALE, 2017ALSELMAN, A.; DANG, C. N.; HALE, W. M. Development of ultra-high performance concrete with locally available. Construction and Building Materials, v. 133, p. 135-145, 2017.). In the current study, the bending test previously performed on the cubic specimens may have caused internal cracking, thus resulting in mechanical strength reductions. Nonetheless, a good linear correlation was found between the strengths of the cylindrical and cubic specimens (shown in Figure 7), with R² = 0.88.

Figure 6
Correlation between the flexural and compressive strength (in cubic specimens) of the mortars

Figure 7
Prism compressive strength at 28 days

The compressive strengths of the 6 and 9 MPa mortars were respectively 80% and 62% higher than their nominal values on average, for cubic specimens. In contrast, the 14 MPa mortar did not reach the nominal strength, regardless of the storage times. This can be explained mainly because the 14 MPa mortar had an air content greater than the 6 and 9 MPa mortars and required the addition of extra water at 36 hours, both leading to strength reductions. In addition, the 14 MPa mortar mixture had a high consistency in 0 hours (18 drops in Gtec test and 10 mm in slump), which may have resulted in casting failures.

Regarding the compressive strength variation from 0 to 36 hours, the 6 and 14 MPa mortars showed strength reduction trends, while the 9 MPa mortar showed a slight increase trend over time (Figure 6). These trends can be explained by the air content of the mortars (Table 6). Both 6 and 14 MPa mortars showed increases in their air content over time, in addition to the extra water incorporation in the latter at 36 hours. This would result in mechanical strength losses due to increases in the porosity of the mortar. In contrast, the 9 MPa mortar had a slight decrease in its air content over time, resulting in the opposite behaviour to other mortars, i.e., mechanical strength gains. Nonetheless, the comparison of means showed that the storage time did not significantly change the compressive strength of the 6 and 9 MPa mortars for a reliability of 95%, as can be seen in Table 7. In contrast, the comparison of means confirmed that the increase in the storage time significantly reduced the 14 MPa mortar strength, which can be related to the fact that this was the only mixture that required extra water addition at 36 hours.

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Table 7
Comparison of means between the compressive strength of mortars with different storage times (in cubic specimens)

Regarding the flexural strength obtained by the bending test, the mortars showed strengths from 2.7 to 4.6 MPa, which corresponds to 30% on average of its respective compressive strengths. This value is similar to the average of 32% reported by Schankoski, Prudêncio Junior and Pilar (2015)SCHANKOSKI, R. A.; PRUDÊNCIO JUNIOR, L. R.; PILAR, R. Influência do tipo de argamassa e suas propriedades do estado fresco nas propriedades mecânicas de alvenarias estruturais de blocos de concreto para edifícios altos. Revista Matéria, v. 20, n. 4, p. 1008-1023, 2015. for industrialised and mixed mortars of 6 to 16 MPa and is well above the 10% average generally reported for conventional mortars and concretes (MEHTA; MONTEIRO, 2015MEHTA, P. K.; MONTEIRO, P. J. M. Concrete: microstructure, properties and materials. 3rd. ed. São Paulo: Ibracon, 2015.). Figure 8 shows that a satisfactory linear correlation was found between the flexural and compressive strength values in the cubic specimens, with R² = 0.79. As in the compressive strength, the 14 MPa mortar showed lower flexural strength than expected for both storage times, justified by the same reasons previously presented.

Figure 8
Breaking mechanism of the prisms: (a) 6 MPa - 0h; (b) 6 MPa - 36h; (c) 9 MPa - 0h; (d) 9 MPa - 36h

Comparing the flexural strength of each mortar with different storage times, all the mortars had reductions in their average strength from 0 to 36 hours. However, for a reliability of 95%, the storage time did not significantly change the flexural strength of the 9 MPa mortar, while it changed the strengths of the 6 and 14 MPa mortars (Table 8). Despite these reductions, the flexural strengths of these mortars were 29% of their compressive strength values.

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Table 8
Comparison of means between the flexural strength of mortars with different storage times

Prisms

Figure 9 shows the compressive strength of the prisms at 28 days. Error bars correspond to ± 1 standard deviation. A substantial variability in the results can be observed with a coefficient of variation of 20% on average. This variability is inherent to the prism tests and is compatible with the average coefficient of variation of 17% reported by Schankoski, Pridêncio Junior Pilar (2015)SCHANKOSKI, R. A.; PRUDÊNCIO JUNIOR, L. R.; PILAR, R. Influência do tipo de argamassa e suas propriedades do estado fresco nas propriedades mecânicas de alvenarias estruturais de blocos de concreto para edifícios altos. Revista Matéria, v. 20, n. 4, p. 1008-1023, 2015. for concrete block prisms of 6 to 16 MPa. The 6 MPa prisms showed strengths similar to the nominal value, while the 9 and 14 MPa prisms had strengths, respectively, higher and lower than their nominal values, as observed in mortars.

Figure 9
Correlation between the compressive strength of the prisms and the respective mortars in cylindrical specimens (in black), and in cubic specimens (in red)

Regarding the effect of storage time on the compressive strength of the prisms, an overall trend of strength reduction over time is observed (Figure 9). However, for a reliability of 95%, no significant differences were found in the compressive strength of the prisms with the same nominal strength as the storage time increased, as can be seen in Table 9.

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Table 9
Comparison of means between the compressive strength of prisms with different storage times

Figure 10 shows the breaking mechanism of some of the prisms tested. In general, the failure occurred by crushing the mortar joint. This probably occurred because the actual strengths of the blocks were much higher than the nominal values, especially for the 9 and 14 MPa blocks. In fact, the average strengths of these blocks were respectively 31% and 55% higher than the strengths of their respective mortars. Once the prisms breaking occurred due to the collapse of the mortar joints, the strength of this element commanded the strength of the masonry. Thus, a correlation between the compressive strength of the prisms and their respective mortars was proposed, as shown in Figure 11. The R² coefficients obtained were 0.85 and 0.89, respectively, for the compressive strength in cylindrical and cubic specimens. These values are in line with the R² of 0.84 reported by Schankoski, Prudêncio Junior and Pilar (2015)SCHANKOSKI, R. A.; PRUDÊNCIO JUNIOR, L. R.; PILAR, R. Influência do tipo de argamassa e suas propriedades do estado fresco nas propriedades mecânicas de alvenarias estruturais de blocos de concreto para edifícios altos. Revista Matéria, v. 20, n. 4, p. 1008-1023, 2015. for the same correlation. It can also be noted that the correlation between the strengths of the prisms and mortars in cubic specimens had the highest R² coefficient. This indicates a better prediction of the strength of prisms by this specimen geometry and corroborates with the NBR 15961 (ABNT, 2011ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 15961: alvenaria estrutural: blocos de concreto: partes 1 e 2. Rio de Janeiro, 2011.), which prescribes the test in cubic specimens.

Figure 10
Prism mean flexural strength (in grey) and characteristic flexural strength – ftk (in red)

Figure 11
Modulus of elasticity of the prisms at 28 days

Figure 12 shows the prisms flexural strength obtained by the bending test. Error bars correspond to ± 1 standard deviation. Although the NBR 15961 (ABNT, 2011ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 15961: alvenaria estrutural: blocos de concreto: partes 1 e 2. Rio de Janeiro, 2011.) does not prescribe minimum values for this property, it provides characteristic strength values (ftk) in the case of not having tests to determine it. Those values are 0.20 MPa for mortars with compressive strength from 3.5 to 7.0 MPa, and 0.25 for mortars with compressive strength above 7.0 MPa. In the case of bending tests, the ftk calculation is prescribed by this standard as follows:

Figure 12
Prism mean flexural strength (in grey) and characteristic flexural strength – ftk (in red)

the test is performed following the Annex C - Part II of the standard;
the values lower than 30% of the average of the 50% highest values are excluded; and
for 4 specimens (which is the number of samples tested in this work), the ftk value is given by 0.84 × ft₁, where ft₁ is the lowest valid values obtained.

Since the referred standard does not prescribe limit values for this property, the results experimentally obtained were compared with those provided by the standard in the absence of the bending tests. Figure 12 also shows the ftk values of the prisms in red. None of the prisms reached the values proposed by the NBR 15961 (ABNT, 2011ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 15961: alvenaria estrutural: blocos de concreto: partes 1 e 2. Rio de Janeiro, 2011.), even at 0 hours of storage time. This is similar to that reported by Schankoski, Prudêncio Junior and Pilar (2015)SCHANKOSKI, R. A.; PRUDÊNCIO JUNIOR, L. R.; PILAR, R. Influência do tipo de argamassa e suas propriedades do estado fresco nas propriedades mecânicas de alvenarias estruturais de blocos de concreto para edifícios altos. Revista Matéria, v. 20, n. 4, p. 1008-1023, 2015., who found flexural strengths of about 0.05 MPa for industrialised and mixed mortars in prisms with compressive strengths of 6 to 16 MPa (close to those investigated in the current work). This indicates the difficulty of meeting such standard values, especially for high strength masonries (i.e. above 9 MPa). It may occur because of the high compactness of these units, which may lead to a reduction in the adhesion strengths between the mortar joint and the block. Such compactness hinders the percolating of water from the mortar to the block, which carries cementitious materials to the pores of the substrate and promotes the mechanical bonding between the parts.

Regarding the effect of the storage time on the prism flexural strength, the comparison of means indicated that the storage time did not significantly influence the flexural strength of the prisms for a reliability of 95%.

Figure 13 shows the modulus of elasticity of the prisms. Error bars correspond to ± 1 standard deviation. Table 11 presents the statistical comparison of means of the modulus of elasticity of the prisms. Trends of increasing the modulus of elasticity over time can be noted for the 9 and 14 MPa mortar, while the opposite is observed for the 6 MPa mortar. However, the comparison of means indicated that the increase in storage time did not lead to significant differences in this property for a reliability of 95%.

Figure 13
Modulus of elasticity of the prisms at 28 days

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Table 10
Comparison of means between the flexural strength of prisms with different storage times

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Table 11
Comparison of the means between the modulus of elasticity of prisms with different storage times

Finally, it is worth noting that both mortars and prisms of 6 and 14 MPa had compatible strengths (difference of 20% on average), while the modulus of elasticity of the 14 MPa prisms were up to 150% higher than those of 6 MPa prisms. This occurred because the blocks used in the 14 MPa prisms had an average strength of 25.8 MPa, compared to 10.5 MPa of the 6 MPa blocks (Table 5). Since the rigidity of the masonry is directly related to the rigidity of its composing elements, the use of blocks with higher compactness (i.e. with higher mechanical strength and lower water absorption) led to higher modulus of elasticity values in the 14 MPa prisms.

Conclusions

This paper evaluated the technical feasibility of using three ready-mixed mortars in concrete block structural masonry. The mortars had nominal strengths of 6, 9 and 14 MPa, and were used at storage times of 0 and 36 hours. Based on the results presented in this paper, the following conclusions were established.

The 6 and 9 MPa mortars presented satisfactory workability maintenance from 0 to 36 hours. In contrast, the 14 MPa mortar was not workable after 36 hours, thus requiring the addition of water. The slump test, which is conventionally used both by the plants for the consistency control and as an acceptance criterion on site, was not adequate to evaluate the mortars´ fresh state properties.

The storage time did not significantly change the compressive strength of the 6 and 9 MPa mortars for a reliability of 95%. In contrast, both the water incorporation and the increase in the entrained air content reduced the compressive strength of the 14 MPa mortar as the storage time increased. Regarding the mortars´ flexural strength, only the 9 MPa mortar did not show a significant reduction in this property as the storage time increased for a reliability of 95%. Nevertheless, the 6 and 14 MPa mortars showed flexural strengths of about 29% of those compressive strengths, even after 36 hours. Thus, increasing the storage time did not result in great losses in this property.

Regarding the prisms, neither the compressive strength, the flexural strength in the bending test, nor the modulus of elasticity were significantly influenced by the storage time with a reliability of 95%. For the set of mortars and blocks used, none of the prisms reached the standard flexural strengths even at 0 hours of storage time, similarly to that reported by the authors in previously published research.

Taken as a whole, the 6 and 9 MPa ready-mixed mortars investigated in this work did not present significant impairments in fresh and hardened properties after 36 hours, thus enabling its use in concrete block structural masonry.

Acknowledgements

The authors gratefully acknowledge the Brazilian governmental research agencies: the National Council for Scientific and Technological Development (CNPq) and Coordination for the Improvement of Higher Education Personnel (CAPES) for providing the financial support for this research. Thanks also Foundation for Supporting Research and Innovation in Espírito Santo (FAPES). We would also like to acknowledge the Max Mohr/Mormix Group for providing the mix proportions and mortars, and Vale do Selke for providing the concrete blocks used in this research.

References

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Publication Dates

Publication in this collection
03 July 2020
Date of issue
Jul-Sep 2020

History

Received
01 May 2019
Accepted
28 Oct 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ALSELMAN, A.; DANG, C. N.; HALE, W. M. Development of ultra-high performance concrete with locally available. Construction and Building Materials, v. 133, p. 135-145, 2017.

[2] ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. NBR 12118: blocos vazados de concreto simples para alvenaria: métodos de ensaio. Rio de Janeiro, 2013.

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Composition (%)								Property (%)
SiO₂	Al₂O₃	Fe₂O₃	CaO	K₂O	Na₂O	MgO	SO₃	LOI	IR	Free CaO
28.99	9.79	4.07	45.45	^* * Na2O equivalent = Na2O + 0.64 K2O; LOI = loss on ignition; and IR = insoluble residue. 1.18		4.97	2.34	3.17	28.67	0.67

Property		Value
Density (g/cm³)		2.82
Blaine fineness (cm²/g)		4583
Fineness (% retained)	# 200	0.56
Fineness (% retained)	# 325	1.91
Setting time (min)	Start	255
Setting time (min)	End	328
Compressive strength (MPa)	1 day	14.71
	3 days	24.55
	7 days	29.65
	28 days	42.03

Property	Admixture
Property	Air-entraining	Hydration stabiliser
Chemical Base	Synthetic resins	Polysaccharides
Colour	Reddish brown liquid	Yellow liquid
pH (at 23ºC)	10 - 12	8 - 11
Density at 23ºC (g/cm³)	1.000 - 1.040	1.160 - 1.200
Solid content (% by mass)	4.0 - 6.0	38.0 - 42.0

Constituent	Unitary composition
Constituent	6 MPa	9 MPa	14 MPa
Portland cement	1.00	1.00	1.00
Natural sand	6.43	5.41	4.54
Manufactured sand	2.79	2.35	1.97
Water	1.50	1.21	1.07
Air-entraining admixture (%)	0.23	0.20	0.18
Hydration stabiliser admixture (%)	0.70	0.70	0.70
Water/dry material ratio (% by mass)	14.7	13.8	14.2

Nominal strength (MPa)	Block						Average (MPa)	SD (MPa)	CV (%)	F_bk (MPa)	Absorption (%)
Nominal strength (MPa)	1	2	3	4	5	6	Average (MPa)	SD (MPa)	CV (%)	F_bk (MPa)	Absorption (%)
6 MPa	9.78	9.93	10.08	10.30	11.18	11.64	10.49	0.75	7.16	9.63	6.97
9 MPa	18.06	19.44	20.16	21.77	23.71	24.07	21.20	2.40	11.34	17.34	6.62
14MPa	23.48	23.64	23.95	26.68	27.75	29.31	25.80	2.47	9.56	23.17	6.48

Brasil

Brasil

Using ready-mixed mortars in concrete block structural masonry

Uso de argamassas estabilizadas em alvenaria estrutural de blocos de concreto

Abstract

Resumo

Introduction

Materials and methods

Materials

Mortar mix composition

Experimental procedures

Concrete blocks

Mortars

Fresh state

Hardened state

Prisms

Statistical analysis of the results

Results and discussion

Concrete blocks

Fresh state

Ready-mixed mortar

Hardened state

Prisms

Conclusions

Acknowledgements

References

Publication Dates

History

Mortar		Slump (mm)	Gtec test		Air content (%)
Mortar		Slump (mm)	Consistency (mm)	Plasticity (drops)	Air content (%)
6 MPa	0 h	75	16.5	4	5.94
6 MPa	36 h	70	17.5	8	7.18
9 MPa	0 h	40	15.5	7	6.22
9 MPa	36 h	10	15.0	7	5.89
14 MPa	0 h	10	18.0	18	9.00
14 MPa	36 h^* * additional water incorporation.	40	18.0	8	10.72

Combination	Sp²	t(Sp)	t α/2 (Nx+Ny - 2)	Result
6 MPa - 0h vs. 6 MPa - 36h	0.0885	0.7686	-2.7764	Equal
9 MPa - 0h vs. 9 MPa - 36h	0.0920	2.6779	-2.7764	Equal
14 MPa - 0h vs. 14 MPa - 36h	0.0819	9.9333	-2.7764	Different

Combination	Sp²	t(Sp)	t α/2 (Nx+Ny - 2)	Result
6 MPa - 0h vs. 6 MPa - 36h	0.0260	7.2257	-2.7764	Different
9 MPa - 0h vs. 9 MPa - 36h	0.1032	0.7880	-2.7764	Equal
14 MPa - 0h vs. 14 MPa - 36h	0.0681	2.9413	-2.7764	Different

Combination	Sp²	t(Sp)	t α/2 (Nx+Ny - 2)	Result
6 MPa - 0h vs. 6 MPa - 36h	1.2527	0.8111	-2.7764	Equal
9 MPa - 0h vs. 9 MPa - 36h	2.8467	0.1112	-2.7764	Equal
14 MPa - 0h vs. 14 MPa - 36h	4.1131	0.3362	-2.7764	Equal

Combination	Sp²	t(Sp)	t α/2 (Nx+Ny - 2)	Result
6 MPa - 0h vs. 6 MPa - 36h	0.0021	2.1246	-2.7764	Equal
9 MPa - 0h vs. 9 MPa - 36h	0.0070	1.6161	-2.7764	Equal
14 MPa - 0h vs. 14 MPa - 36h	0.0007	1.5515	-2.7764	Equal

Combination	Sp²	t(Sp)	t α/2 (Nx+Ny - 2)	Result
6 MPa - 0h vs. 6 MPa - 36h	0.6044	1.5662	-2.7764	Equal
9 MPa - 0h vs. 9 MPa - 36h	8.5610	0.2944	-2.7764	Equal
14 MPa - 0h vs. 14 MPa - 36h	2.3032	1.7378	-2.7764	Equal