Burgers material

A Burgers material is a viscoelastic material having the properties both of elasticity and viscosity. It is named after the Dutch physicist Johannes Martinus Burgers.

Overview[edit]

Maxwell representation[edit]

Given that one Maxwell material has an elasticity $E_{1}$ and viscosity $\eta _{1}$ , and the other Maxwell material has an elasticity $E_{2}$ and viscosity $\eta _{2}$ , the Burgers model has the constitutive equation

\sigma +\left({\frac {\eta _{1}}{E_{1}}}+{\frac {\eta _{2}}{E_{2}}}\right){\dot {\sigma }}+{\frac {\eta _{1}\eta _{2}}{E_{1}E_{2}}}{\ddot {\sigma }}=\left(\eta _{1}+\eta _{2}\right){\dot {\varepsilon }}+{\frac {\eta _{1}\eta _{2}\left(E_{1}+E_{2}\right)}{E_{1}E_{2}}}{\ddot {\varepsilon }}

where $\sigma$ is the stress and $\varepsilon$ is the strain.

Kelvin representation[edit]

Given that the Kelvin material has an elasticity $E_{1}$ and viscosity $\eta _{1}$ , the spring has an elasticity $E_{2}$ and the dashpot has a viscosity $\eta _{2}$ , the Burgers model has the constitutive equation

\sigma +\left({\frac {\eta _{1}}{E_{1}}}+{\frac {\eta _{2}}{E_{1}}}+{\frac {\eta _{2}}{E_{2}}}\right){\dot {\sigma }}+{\frac {\eta _{1}\eta _{2}}{E_{1}E_{2}}}{\ddot {\sigma }}=\eta _{2}{\dot {\varepsilon }}+{\frac {\eta _{1}\eta _{2}}{E_{1}}}{\ddot {\varepsilon }}

where $\sigma$ is the stress and $\varepsilon$ is the strain.^[1]

Model characteristics[edit]

This model incorporates viscous flow into the standard linear solid model, giving a linearly increasing asymptote for strain under fixed loading conditions.

References[edit]

^ Malkin, Alexander Ya.; Isayev, Avraam I. (2006). Rheology: Concepts, Methods, and Applications. ChemTec Publishing. pp. 59–60. ISBN 9781895198331.

External links[edit]

Creep and Stress Relaxation for Four-Element Viscoelastic Solids and Liquids, Wolfram Demonstrations Project

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[1] Malkin, Alexander Ya.; Isayev, Avraam I. (2006). Rheology: Concepts, Methods, and Applications. ChemTec Publishing. pp. 59–60. ISBN 9781895198331.

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