Analysis of deformability modulus by linear and nonlinear elastic methods in ceramic structural masonry and mortars

Cerqueira, N. A.; Marvila, M. T.; Azevedo, A. R. G. de; Alexandre, J.; Xavier, G. C.; Souza, V. B. de

doi:10.1590/0366-69132020663792845

Acessibilidade / Reportar erro

Brasil

Español English

sumário « anterior atual seguinte »

Sumário

Articles • Cerâmica 66 (379) • Jul-Sep 2020 • https://doi.org/10.1590/0366-69132020663792845 copy

Analysis of deformability modulus by linear and nonlinear elastic methods in ceramic structural masonry and mortars

Análise do módulo de deformabilidade por métodos elásticos lineares e não lineares em alvenaria estrutural cerâmica e argamassas

Authorship SCIMAGO INSTITUTIONS RANKINGS

Abstract

There are studies analyzing the parameters of structural masonry strength, however few are performed evaluating the interference of the mortar in the deformability parameters. The objective of this study was to verify the theories of elasticity (Hooke’s linear model and nonlinear models by Ghosh, Duffing, and Martin, Roth, and Stiehler) applied to structural masonry. Ceramic blocks were pressed and fired at 890 ºC and mortars prepared with the proportion 1:1:5:0.5:2 of cement: hydrated lime: sand: PVA binder: water. The materials were tested in compression individually and in prisms with and without the use of mortars. The results obtained with the linear elastic analysis were incoherent since the deformability modulus obtained for the mortar prisms was higher than those without mortar. Performing the analysis by nonlinear theories, it was found that the results obtained were more coherent, mainly by Duffing’s theory that uses one parameter for stiffness and another for damping of the material.

Keywords:
structural blocks; compressive strength; deformability; nonlinear elastic relationship

Table I Representation of the studied models.

Geometry	Mortar	Representation
Blocks	Without
Prisms with whole blocks	Without
Prisms with whole blocks	With

Table II Deformability parameters obtained.

Model studied		Prism without mortar	Prism with mortar
Hooke’s law	E (GPa)	1.42±0.10	1.69±0.11
Hooke’s law	R²	0.693-0.712	0.705-0.723
Ghosh equation (p=2)	K (GPa)	1.27±0.14	1.22±0.11
Ghosh equation (p=2)	R²	0.891-0.923	0.912-0.945
Ghosh equation (p=3)	K (GPa)	1.24±0.09	1.12±0.06
Ghosh equation (p=3)	R²	0.967-0.986	0.973-0.992
Duffing equation	β (GPa)	1.67±0.14	1.38±0.11
	α (GPa)	(1.30 ± 0.07)x10⁶	(1.16 ± 0.17)x10⁶
	R²	0.751-0.876	0.812-0.898
Martin, Roth, and Stiehler equation (A=0.38)	M	3.14±0.17	2.78±0.21
Martin, Roth, and Stiehler equation (A=0.38)	R²	0.570-0.662	0.592-0.703

Associação Brasileira de Cerâmica Av. Prof. Almeida Prado, 532 - IPT - Prédio 36 - 2º Andar - Sala 03 , Cidade Universitária - 05508-901 - São Paulo/SP -Brazil, Tel./Fax: +55 (11) 3768-7101 / +55 (11) 3768-4284 - São Paulo - SP - Brazil
E-mail: ceram.abc@gmail.com

Acompanhe os números deste periódico no seu leitor de RSS

[1] * markssuel@hotmail.com