Standard Linear Solid model

Standard Linear Solid model

The Standard Linear Solid model (SLS) also know as the Kelvin model [* Fung YC. "Biomechanics", 2nd ed. Springer-Verlag, New York (1993). ISBN 0-387-97947-6 ] is a method of modeling the behavior of a viscoelastic material using a linear combination of springs and dashpots to represent elastic and viscous components, respectively. Often more similar Maxwell model and the Kelvin-Voigt model are used. These models are often proved insufficient, however; the Maxwell model does not describe creep, and the Kelvin-Voigt model does not describe stress relaxation. SLS is the simplest model that predicts both phenomena.

Definition

Materials undergoing strain are often modeled with mechanical components, such as springs (restorative force component) and dashpots (damping component).

Connecting a spring and damper in series yields a model of a Maxwell material while connecting a spring and damper in parallel yields a model of a Kelvin-Voigt material David Roylance, "Engineering Viscoelasticity" (October 24, 2001) http://ocw.mit.edu/NR/rdonlyres/Materials-Science-and-Engineering/3-11Mechanics-of-MaterialsFall1999/038732E6-CF1E-4BD0-A22E-39123ADD3337/0/visco.pdf] . In contrast to the Maxwell and Kelvin-Voigt models, the SLS is slightly more complex, involving elements both in series and in parallel. Springs, which represent the elastic component of a viscoelastic material, obey Hooke's Law::sigma_{s} = E varepsilonwhere σ is the applied stress, E is the Young's Modulus of the material, and ε is the strain. The spring represents the energetic or elastic component of the model's response .

Dashpots represent the viscous component of a viscoelastic material. In these elements, the applied stress varies with the time rate of change of the strain:: sigma_{D}= eta frac {dvarepsilon} {dt} where η is viscosity of the dashpot component.

These elements are connected as shown on the picture:This model consists of two systems in parallel. The first, referred to as the Maxwell arm, contains a spring (E = E_2) and dashpot (viscosity eta) in series. The other system contains only a spring (E = E_1).

olving the Model

In order to model this system, the following physical relations must be realized:

For parallel components: sigma_{tot} = sigma_1 + sigma_2 , and varepsilon_{tot} = varepsilon_1 = varepsilon_2.

For series components: sigma_{tot} = sigma_1 = sigma_2 , and varepsilon_{tot} = varepsilon_1 + varepsilon_2 .

These relationships help relate the various stresses and strains in the overall system and the Maxwell arm:

sigma_{tot} = sigma_{m} + sigma_{s_1}

varepsilon_{tot} = varepsilon_{m} = varepsilon_{s_1}

sigma_{m} = sigma_{D} = sigma_{s_2}

varepsilon_{m} = varepsilon_{D} + varepsilon_{s_2}

where the subscripts M, D, S_1,and S_2 refer to Maxwell, dashpot, spring one, and spring two, respectively.

Using these relationships, their time derivatives, and the above stress-strain relationships for the spring and dashpot elements, the system can be modeled as follows:

: frac {dvarepsilon} {dt} = frac { frac {E_2} {eta} left ( frac {eta} {E_2}frac {dsigma} {dt} + sigma - E_1 varepsilon ight )}{E_1 + E_2} Krystyn J. Van Vliet, MIT course 3.032 Lecture, October 23, 2006 http://stellar.mit.edu/S/course/3/fa06/3.032/index.html]

The relaxation time, au , is different for each material and is equal to: frac {eta} {E_2} = au

Model Characteristics

The Standard Linear Solid model combines aspects of the Maxwell and Kelvin-Voigt models to accurately describe the overall behavior of a system under a given set of loading conditions. The behavior of a material applied to an instantaneous stress is shown as having an instantaneous component of the response. Instantaneous release of a stress also results in a discontinuous decrease in strain, as is expected. The shape of the time-dependent strain curve is true to the type of equation that characterizes the behavior of the model over time, depending upon how the model is loaded.

Although this model can be used to accurately predict the general shape of the strain curve, as well as behavior for long time and instantaneous loads, the model lacks the ability to accurately model material systems numerically.

References

ee also

*Viscoelasticity
*Maxwell material
*Kelvin-Voigt material


Wikimedia Foundation. 2010.

Игры ⚽ Поможем написать курсовую

Look at other dictionaries:

  • Solid modeling — The geometry in solid modeling is fully described in 3‑D space; objects can be viewed from any angle. Modeled and ray traced in Cobalt Solid modeling (or modelling) is a consistent set of principles for mathematical and computer modeling of three …   Wikipedia

  • Standard map — Orbits of the standard map for K = 0.6. Orbits of the standard map for …   Wikipedia

  • Linear Pottery culture — LBK redirects here. For other uses, see LBK (disambiguation). Not to be confused with Linear B. Map of European Neolithic at the apogee of Danubian expansion, c. 4500–4000 BC …   Wikipedia

  • Linear regulator — In electronics, a linear regulator is a voltage regulator based on an active device (such as a bipolar junction transistor, field effect transistor or vacuum tube) operating in its linear region (in contrast, a switching regulator is based on a… …   Wikipedia

  • Nambu–Jona-Lasinio model — In quantum field theory, the Nambu–Jona Lasinio model (or more precisely: the Nambu and Jona Lasinio model) is a theory of nucleons and mesons constructed from interacting Dirac fermions with chiral symmetry which parallels the construction of… …   Wikipedia

  • Viscoelasticity — is the property of materials that exhibit both viscous and elastic characteristics when undergoing deformation. Viscous materials, like honey, resist shear flow and strain linearly with time when a stress is applied. Elastic materials strain… …   Wikipedia

  • RGB color model — RGB redirects here. For other uses, see RGB (disambiguation). A representation of additive color mixing. Projection of primary color lights on a screen shows secondary colors where two overlap; the combination of all three of red, green, and blue …   Wikipedia

  • Stress relaxation — describes how polymers relieve stress under constant strain. Because they are viscoelastic, polymers behave in a nonlinear, non Hookean fashion.Meyers and Chawla. Mechanical Behavior of Materials (1999) ISBN 0 13 262817 1] This nonlinearity is… …   Wikipedia

  • Rasch model — Rasch models are used for analysing data from assessments to measure things such as abilities, attitudes, and personality traits. For example, they may be used to estimate a student s reading ability from answers to questions on a reading… …   Wikipedia

  • Nearly-free electron model — Electronic structure methods Tight binding Nearly free electron model Hartree–Fock method Modern valence bond Generalized valence bond Møller–Plesset perturbat …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”