par Göbel, Luise;Konigsberger, Markus 
;Osburg, Andrea;Pichler, Bernhard
Référence Applied Sciences (Switzerland), 8, 4, 487
Publication Publié, 2018-01-01
;Osburg, Andrea;Pichler, BernhardRéférence Applied Sciences (Switzerland), 8, 4, 487
Publication Publié, 2018-01-01
Article révisé par les pairs
| Résumé : | Adding polymers to cementitious materials improves their workability and impermeability, but also increases their creep activity. In the present paper, the creep behavior of polymer-modified cement pastes is analyzed based on macroscopic creep tests and a multiscale model. The continuum micromechanics model allows for "downscaling" the results of macroscopic hourly-repeated ultra-short creep experiments to the viscoelastic behavior of micron-sized hydration products and polymer particles. This way, the increased creep activity of polymer-modified cement pastes is traced back to an isochoric power-law-type creep behavior of the polymers. The shear creep modulus of the polymers is found (i) to be two orders of magnitude smaller than that of the hydrates and (ii) to increase considerably with increasing material age. The latter result suggests that the creep activity of the polymers decreases with the self-desiccation-related decrease of the relative humidity inside the air-filled pores of cement paste. Furthermore, its decrease is most likely related to the penetration of cementitious hydrates into compliant polymer agglomerates. |
