viscoelastic damping: zener model
DESCRIPTION
Zener model of Viscoelastic Materials Can you add complexity? #WikiCourses http://wikicourses.wikispaces.com/Topic01+Viscoelastic+MaterialsTRANSCRIPT
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Viscoelastic DampingMohammad Tawfik
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Viscoelastic Damping
Zener Model
![Page 2: Viscoelastic Damping: Zener model](https://reader035.vdocuments.pub/reader035/viewer/2022080210/554c6af6b4c90575798b4b04/html5/thumbnails/2.jpg)
Viscoelastic DampingMohammad Tawfik
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Zener Model
• The Zener model describes the material as a viscous damper in parallel with an elastic stiffness and both are in series with another stiffness.
• The strain may be written as: ε=ε s+ε1
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Viscoelastic DampingMohammad Tawfik
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Stress-Strain Relation
• The stress is is given by the relation:
• From which we may write:
• Or:
σ=E s ε s=E p ε1+Cd ε̇1
ε s=σEs, ε1=
σE p+sCd
ε=σE s
+σE p+sCd
¿σ(E p+sC d+E sE s (E p+sCd ) )
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Viscoelastic DampingMohammad Tawfik
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Stress-Strain Relation
• Giving:
• Back to time domain:
E s(E p+sC d ) ε=(E p+sC d+E s )σ
E sE pε+EsC d ε̇=(E p+E s) σ+Cd σ̇
Eε+Eβ ε̇=σ+α σ̇
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Viscoelastic DampingMohammad Tawfik
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Zener Model Characteristics
• Creep:– For constant stress, we get:
– Giving:
Eε+Eβ ε̇=σ0
ε=σ0E
−e−t / β
E s
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Viscoelastic DampingMohammad Tawfik
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Zener Model Characteristics
• Relaxation:– For constant strain, we get:
– Which gives:
σ=σ 0+Eε0 (1−e−t /α )
Eε=σ+α σ̇
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Viscoelastic DampingMohammad Tawfik
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Zener Model Characteristics
• Storage and Loss Factors:– For harmonic stress:– Which drives the strain
harmonically:– Giving:Eεo+ jωE βεo=σo+ j ωασo
σ=σ 0ejωt
ε=ε 0ejωt
σ o=E1+ j ωβ1+ j ωα
ε o=E1+ω2αβ+ jω ( β−α)
1+ω2α 2εo
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Viscoelastic DampingMohammad Tawfik
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Zener Model Characteristics
σ o=E' (1+ jη ) εo
σ o=E(1+ω2αβ
1+ω2α2+jω ( β−α)1+ω2 α2 )εo
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Viscoelastic DampingMohammad Tawfik
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Frequency Dependent Behavior
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
2
0 1 2 3 4
Frequency
Modulus
E
u
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Viscoelastic DampingMohammad Tawfik
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Other Models
• Some, more accurate, models were developed to represent the behavior of viscoelastic material
• The greatest concern was paid for the modeling in the time domain.
• The most famous models are:– Golla-Hughes-McTavish – Augmented Temperature Field– Fractional Derivative