m (Cinmemj moved page Draft Samper 178735643 to Cervera 2019a) |
|||
(One intermediate revision by the same user not shown) | |||
Line 1: | Line 1: | ||
+ | ==Abstract== | ||
+ | In classical viscoelasticity, the mechanical behaviour is charac- | ||
+ | terized by the relaxation function or the compliance function and the constitutive relationships | ||
+ | are formulated in the form of Volterra integral equations [Bazant 1988]. This approach is clearly | ||
+ | unsuitable for numerical computations because of its memory and CPU time requirements. | ||
+ | |||
+ | However, it is possible to expand any relaxation function into a Dirichlet series, and retain only | ||
+ | a finite number of terms. This achieves a double goal: first, the constitutive laws for the | ||
+ | viscoelastic material can be written in terms of a finite num- ber of internal variables, and only | ||
+ | these need to be stored from one time step to the next, thus providing huge computational | ||
+ | advantages compared to the hereditary integral equations; and secondly, the resulting rheological | ||
+ | model can be interpreted as a generalized Maxwell chain, where a number of springs and | ||
+ | dashpots are arranged in parallel. Alternatively, the compliance function of concrete can be considered and expanded in a Dirichlet series. This leads to a | ||
+ | generalized Kelvin chain with a series arrangement. Although both approaches are completely | ||
+ | equivalent (if a large enough number of terms is considered in the Dirichlet series), the | ||
+ | first one leads to first order dif- ferential equations to be solved for the evolution of the | ||
+ | inter- nal variables, while the second approach leads to second order differential equations [Carol | ||
+ | and Bazant 1993]. Therefore, the | ||
+ | Maxwell chain model is preferred here. | ||
+ | |||
==Fulltext== | ==Fulltext== | ||
<pdf>Media:Draft_Samper_178735643_6740_M79.pdf</pdf> | <pdf>Media:Draft_Samper_178735643_6740_M79.pdf</pdf> |
In classical viscoelasticity, the mechanical behaviour is charac- terized by the relaxation function or the compliance function and the constitutive relationships are formulated in the form of Volterra integral equations [Bazant 1988]. This approach is clearly unsuitable for numerical computations because of its memory and CPU time requirements.
However, it is possible to expand any relaxation function into a Dirichlet series, and retain only a finite number of terms. This achieves a double goal: first, the constitutive laws for the viscoelastic material can be written in terms of a finite num- ber of internal variables, and only these need to be stored from one time step to the next, thus providing huge computational advantages compared to the hereditary integral equations; and secondly, the resulting rheological model can be interpreted as a generalized Maxwell chain, where a number of springs and dashpots are arranged in parallel. Alternatively, the compliance function of concrete can be considered and expanded in a Dirichlet series. This leads to a generalized Kelvin chain with a series arrangement. Although both approaches are completely equivalent (if a large enough number of terms is considered in the Dirichlet series), the first one leads to first order dif- ferential equations to be solved for the evolution of the inter- nal variables, while the second approach leads to second order differential equations [Carol and Bazant 1993]. Therefore, the Maxwell chain model is preferred here.
Published on 30/01/19
Submitted on 30/01/19
Licence: CC BY-NC-SA license
Are you one of the authors of this document?