Difference between revisions of "Trilinear Traction Law"

From OSUPDOCS
Jump to navigation Jump to search
 
(12 intermediate revisions by the same user not shown)
Line 11: Line 11:
<math>J_c = {1\over2}\bigl(\sigma_1\delta_2 + \sigma_2(\delta_c-\delta_1)\bigr)</math>
<math>J_c = {1\over2}\bigl(\sigma_1\delta_2 + \sigma_2(\delta_c-\delta_1)\bigr)</math>


The traction law for each mode depends up seven properties - (&delta;<sub>1</sub>,&sigma;<sub>1</sub>) and (&delta;<sub>2</sub>,&sigma;<sub>2</sub>) breakpoints, critical COD (&delta;<sub>c</sub>), total area or toughness (J<sub>c</sub>), and the initial elastic slope (k). You must enter exactly 5 of these seven properties for each mode. Furthermore, if one of the 5 is the initial slope, then either &sigma;<sub>1</sub> or &delta;<sub>1</sub> for that mode (but not both) must be one of the five specified properties. The two remaining unspecified parameters will be calculated from the five provided parameters. The final law must satisfy &delta;<sub>1</sub> &le; &delta;<sub>2</sub> &le; &delta;<sub>c</sub>, &delta;<sub>c</sub> &gt; 0, &sigma;<sub>1</sub> &ge; 0, &sigma;<sub>2</sub> &ge; 0, and &sigma;<sub>1</sub>+&sigma;<sub>2</sub> &gt; 0.
The traction law for each mode depends up seven properties - (&delta;<sub>1</sub>,&sigma;<sub>1</sub>) and (&delta;<sub>2</sub>,&sigma;<sub>2</sub>) breakpoints, critical COD (&delta;<sub>c</sub>), total area or toughness (J<sub>c</sub>), and the initial elastic slope (k). You must enter exactly 5 of these seven properties for each mode. Furthermore, if one of the 5 is the initial slope, then &delta;<sub>c</sub> along with either &sigma;<sub>1</sub> or &delta;<sub>1</sub> for that mode (but not both) must be among the specified properties. The two remaining unspecified parameters will be calculated from the five provided parameters. The final law must satisfy 0 &lt; &delta;<sub>1</sub> &le; &delta;<sub>2</sub> &le; &delta;<sub>c</sub>, &delta;<sub>c</sub> &gt; 0, &sigma;<sub>1</sub> &ge; 0, &sigma;<sub>2</sub> &ge; 0, and &sigma;<sub>1</sub>+&sigma;<sub>2</sub> &gt; 0. Note that these restriction prohibit infinite initial stiffness (''i.e.'', &delta;=0) but allow zero initial stiffness (''i.e.'', &sigma;<sub>1</sub>=0). It is not clear if zero initial stiffness has any realistic applications.


One useful interpretation of a trilinear law is that it is modeling two physically mechanisms. The total toughness is the total area under the curve and is given above. The first failure mechanism can be identified with the area under the first peak and bounded by the dotted red line in the above figure. This partial area is the toughness for the first mechanism and is equal to
One useful interpretation of a trilinear law is that it is modeling two physically mechanisms. The total toughness is the total area under the curve and is given above. The first failure mechanism can be identified with the area under the first peak and bounded by the dotted red line in the above figure. This partial area is the toughness for the first mechanism and is equal to
Line 23: Line 23:
<math>J_2 = {1\over2}\sigma_2\delta_c</math>
<math>J_2 = {1\over2}\sigma_2\delta_c</math>


For example, the first peak might be associated with crack tip fracture toughness while the tail models a process zone such as fiber bridging. In fact, in the limit as &sigma;<sub>1</sub> &rarr; &infin; and &delta;<sub>2</sub> &rarr; 0, a simulation with a pre-existing cohesive zone should approach a simulation propagating a crack tip using fracture mechanics along with a linear softening traction law having &sigma;<sub>2</sub> as the cohesive stress. [[NairnMPM]] can do both these simulations and the results will be similar. The pure cohesive zone simulation is done by using a trilinear traction law on an existing crack. The combined fracture mechanics/cohesive zone simulation starts with a crack that propagates when energy release rate at the crack tip is equal to J<sub>1</sub>. Furthermore, the [[Crack Propagation Commands|crack propagation commands]] are set to leave a cohesive zone in the wake of the crack. This cohesive zone can be a [[Triangular Traction Law||triangular traction law]] with its toughness equal to J<sub>2</sub> and stress equal to &sigma;<sub>2</sub>. Both these types of simulations are described in Nairn (2009).<ref name="czm">J. A. Nairn, "Analytical and Numerical Modeling of R Curves for Cracks with Bridging Zones" <i>Int. J. Fracture</i>, <b>155</b>, 167-181 (2009). ([http://www.cof.orst.edu/cof/wse/faculty/Nairn/papers/JBridging.pdf See PDF])</ref>
For example, the first peak might be associated with crack tip fracture toughness while the tail models a process zone such as fiber bridging. In fact, in the limit as &sigma;<sub>1</sub> &rarr; &infin; and &delta;<sub>2</sub> &rarr; 0, a simulation with a pre-existing cohesive zone should approach a simulation propagating a crack tip using fracture mechanics along with a linear softening traction law having &sigma;<sub>2</sub> as the cohesive stress. [[NairnMPM]] can do both these simulations and the results will be similar. The pure cohesive zone simulation is done by using a trilinear traction law on an existing crack. The combined fracture mechanics/cohesive zone simulation starts with a crack that propagates when energy release rate at the crack tip is equal to J<sub>1</sub>. Furthermore, the [[Crack Propagation Commands|crack propagation commands]] are set to leave a cohesive zone in the wake of the crack. This cohesive zone can be a [[Triangular Traction Law|triangular traction law]] with its toughness equal to J<sub>2</sub> and stress equal to &sigma;<sub>2</sub>. Both these types of simulations are described in Nairn (2009).<ref name="czm"/>


== Failure ==
== Failure ==


The failure criterion under pure more or possible mixed-mode conditions is identical to the one used in the [[Triangular Traction Law#Failure|triangular traction law]].
This laws uses uncoupled mode I and mode II cohesive laws. The failure is handled by the same methods used for the [[Triangular Traction Law]]. This trilinear cohesive law can also be used for mode I or mode II laws in coupled mixed-mode modeling<ref name="mmzone"/> by using the [[Mixed Mode Traction Law]].


== Traction Law Properties ==
== Traction Law Properties ==
Line 39: Line 39:
| sigmaI2 || The stress at the second break point (&sigma;<sub>2</sub>) in mode I or opening mode || [[ConsistentUnits Command#Legacy and Consistent Units|pressure units]] || none
| sigmaI2 || The stress at the second break point (&sigma;<sub>2</sub>) in mode I or opening mode || [[ConsistentUnits Command#Legacy and Consistent Units|pressure units]] || none
|-
|-
| sigmaII2 || The stress at the second break point in mode I| or sliding mode || [[ConsistentUnits Command#Legacy and Consistent Units|pressure units]] || none
| sigmaII2 || The stress at the second break point in mode II or sliding mode || [[ConsistentUnits Command#Legacy and Consistent Units|pressure units]] || none
|-
|-
| delpkI2 || The relative COD at the second break point in mode I or opening mode; it is equal to &delta;<sub>2</sub>/&delta;<sub>c</sub>  || dimensionless || none
| delpkI2 || The relative COD at the second break point in mode I or opening mode; it is equal to &delta;<sub>2</sub>/&delta;<sub>c</sub>  || dimensionless || none
|-
|-
| delpkII2 || The relative COD at the second break point in mode |I or sliding mode; it is equal to &delta;<sub>2</sub>/&delta;<sub>c</sub>  || dimensionless || none
| delpkII2 || The relative COD at the second break point in mode II or sliding mode; it is equal to &delta;<sub>2</sub>/&delta;<sub>c</sub>  || dimensionless || none
|-
|-
| ([[Triangular Traction Law#Traction Law Properties|first point]]) || Use the [[Triangular Traction Law|triangular traction law]] properties to enter the first break point COD and initial slope for each mode || varies || varies
| ([[Triangular Traction Law#Traction Law Properties|first point]]) || Use the [[Triangular Traction Law|triangular traction law]] properties to enter the first break point COD and initial slope for each mode || varies || varies
Line 49: Line 49:
| ([[Common Traction Law Properties|other]]) || Properties common to all traction laws, where sigmaI and sigmaII apply to the first break point stress || varies || varies
| ([[Common Traction Law Properties|other]]) || Properties common to all traction laws, where sigmaI and sigmaII apply to the first break point stress || varies || varies
|}
|}
== Traction History Variables ==
This material tracks two history variables:
# Maximum normal opening displacement (or equal to normal &delta;<sub>e</sub> prior to initiation).
# Maximum shear opening displacement magnitude (or equal to tangential &delta;<sub>e</sub> prior to initiation).
These history variables can be [[MPM Archiving Options#ToArchive Command|archived]] for later plotting. The [[MPM Archiving Options#ToArchive Command|cmdisp archiving option]] can archive total mode I and mode II cumulative dissipated energies.


== References ==
== References ==


<references/>
<references>
<ref name="czm">J. A. Nairn, "Analytical and Numerical Modeling of R Curves for Cracks with Bridging Zones" <i>Int. J. Fracture</i>, <b>155</b>, 167-181 (2009). ([http://www.cof.orst.edu/cof/wse/faculty/Nairn/papers/JBridging.pdf See PDF])</ref><ref name="mmzone">J. A. Nairn and Y. E. Aimene "A re-evaluation of mixed-mode cohesive zone modeling based on strength concepts instead of traction laws" <i>in preparation</i> (2020).</ref>
</references>

Latest revision as of 21:16, 2 January 2021

The Traction Law

Trilintraction.jpg

This traction law assumes a piece-wise linear relation with two arbitrarily-specifiable break points (i.e., three linear pieces). There are separate traction laws for opening displacement (mode I) and sliding displacement (mode II).

The toughness is

      [math]\displaystyle{ J_c = {1\over2}\bigl(\sigma_1\delta_2 + \sigma_2(\delta_c-\delta_1)\bigr) }[/math]

The traction law for each mode depends up seven properties - (δ11) and (δ22) breakpoints, critical COD (δc), total area or toughness (Jc), and the initial elastic slope (k). You must enter exactly 5 of these seven properties for each mode. Furthermore, if one of the 5 is the initial slope, then δc along with either σ1 or δ1 for that mode (but not both) must be among the specified properties. The two remaining unspecified parameters will be calculated from the five provided parameters. The final law must satisfy 0 < δ1 ≤ δ2 ≤ δc, δc > 0, σ1 ≥ 0, σ2 ≥ 0, and σ12 > 0. Note that these restriction prohibit infinite initial stiffness (i.e., δ=0) but allow zero initial stiffness (i.e., σ1=0). It is not clear if zero initial stiffness has any realistic applications.

One useful interpretation of a trilinear law is that it is modeling two physically mechanisms. The total toughness is the total area under the curve and is given above. The first failure mechanism can be identified with the area under the first peak and bounded by the dotted red line in the above figure. This partial area is the toughness for the first mechanism and is equal to

      [math]\displaystyle{ J_1 = {1\over2}(\sigma_1\delta_2 - \sigma_2\delta_1) }[/math]

The remaining area is associated with the second mechanism. Its toughness is equal to

      [math]\displaystyle{ J_2 = {1\over2}\sigma_2\delta_c }[/math]

For example, the first peak might be associated with crack tip fracture toughness while the tail models a process zone such as fiber bridging. In fact, in the limit as σ1 → ∞ and δ2 → 0, a simulation with a pre-existing cohesive zone should approach a simulation propagating a crack tip using fracture mechanics along with a linear softening traction law having σ2 as the cohesive stress. NairnMPM can do both these simulations and the results will be similar. The pure cohesive zone simulation is done by using a trilinear traction law on an existing crack. The combined fracture mechanics/cohesive zone simulation starts with a crack that propagates when energy release rate at the crack tip is equal to J1. Furthermore, the crack propagation commands are set to leave a cohesive zone in the wake of the crack. This cohesive zone can be a triangular traction law with its toughness equal to J2 and stress equal to σ2. Both these types of simulations are described in Nairn (2009).[1]

Failure

This laws uses uncoupled mode I and mode II cohesive laws. The failure is handled by the same methods used for the Triangular Traction Law. This trilinear cohesive law can also be used for mode I or mode II laws in coupled mixed-mode modeling[2] by using the Mixed Mode Traction Law.

Traction Law Properties

The following properties are used to create a trilinear traction law:

Property Description Units Default
sigmaI2 The stress at the second break point (σ2) in mode I or opening mode pressure units none
sigmaII2 The stress at the second break point in mode II or sliding mode pressure units none
delpkI2 The relative COD at the second break point in mode I or opening mode; it is equal to δ2c dimensionless none
delpkII2 The relative COD at the second break point in mode II or sliding mode; it is equal to δ2c dimensionless none
(first point) Use the triangular traction law properties to enter the first break point COD and initial slope for each mode varies varies
(other) Properties common to all traction laws, where sigmaI and sigmaII apply to the first break point stress varies varies

Traction History Variables

This material tracks two history variables:

  1. Maximum normal opening displacement (or equal to normal δe prior to initiation).
  2. Maximum shear opening displacement magnitude (or equal to tangential δe prior to initiation).

These history variables can be archived for later plotting. The cmdisp archiving option can archive total mode I and mode II cumulative dissipated energies.

References

  1. J. A. Nairn, "Analytical and Numerical Modeling of R Curves for Cracks with Bridging Zones" Int. J. Fracture, 155, 167-181 (2009). (See PDF)
  2. J. A. Nairn and Y. E. Aimene "A re-evaluation of mixed-mode cohesive zone modeling based on strength concepts instead of traction laws" in preparation (2020).