/MAT/LAW58 (FABR_A)
Block Format Keyword This law describes a hyperelastic anisotropic fabric material. It uses an anisotropic coordinate system with anisotropy angle, following element deformation.
The material formulation provides coupling between warp and weft directions in order to reproduce physical interaction between fibers. The shear degree of freedom is fully decoupled from the translational degrees of freedom. Optionally, nonlinear stressstrain curves for loading and unloading can be specified for warp, weft directions and in shear.
Format
(1)  (2)  (3)  (4)  (5)  (6)  (7)  (8)  (9)  (10) 

/MAT/LAW58/mat_ID/unit_ID or /MAT/FABR_A/mat_ID/unit_ID  
mat_title  
${\rho}_{i}$  
E_{1}  B_{1}  E_{2}  B_{2}  Flex  
G_{0}  G_{T}  ${\alpha}_{T}$  G_{sh}  sens_ID  
D_{f}  D_{s}  G_{frot}  ZeroStress  
N_{1}  N_{2}  S_{1}  S_{2}  Flex_{1}  Flex_{2} 
(1)  (2)  (3)  (4)  (5)  (6)  (7)  (8)  (9)  (10) 

fct_ID_{1}  Fscale_{1}  
fct_ID_{2}  Fscale_{2}  
fct_ID_{3}  Fscale_{3}  
fct_ID_{4}  fct_ID_{5}  Fscale_{4}  Fscale_{5}  fct_ID_{6}  Fscale_{6} 
Definitions
Field  Contents  SI Unit Example 

mat_ID  Material
identifier (Integer, maximum 10 digits) 

unit_ID  Unit Identifier (Integer, maximum 10 digits) 

mat_title  Material
title (Character, maximum 100 characters) 

${\rho}_{i}$  Initial
density (Real) 
$\left[\frac{\text{kg}}{{\text{m}}^{\text{3}}}\right]$ 
E_{1}  Young's modulus in
the warp direction. (Real) 
$\left[\text{Pa}\right]$ 
B_{1}  Softening
coefficient in the warp direction. Default = 0.00 (Real) 
$\left[\text{Pa}\right]$ 
E_{2}  Young's modulus in
the weft direction. (Real) 
$\left[\text{Pa}\right]$ 
B_{2}  Softening
coefficient in the weft direction. Default = 0.00 (Real) 
$\left[\text{Pa}\right]$ 
Flex  Fiber bending
modulus reduction factor. Default = 0.01 (Real) 

G_{0}  Initial shear
modulus. Default = G, where $G=\frac{{G}_{T}}{1+{\mathrm{tan}}^{2}({\alpha}_{T})}$ (Real) 
$\left[\text{Pa}\right]$ 
G_{T}  Tangent shear
modulus at
$\alpha \text{=}{\alpha}_{T}$
. (Real) 
$\left[\text{Pa}\right]$ 
${\alpha}_{T}$  Shear locking
angle. (Real) 
$\left[\mathrm{deg}\right]$ 
G_{sh}  Traverse shear
modulus (only used with multilayer property). Default ${G}_{sh}={G}_{0}$ (Real) If G_{0} = 0, then ${G}_{sh}=\frac{{G}_{T}}{1+{\mathrm{tan}}^{2}({\alpha}_{T})}$ 
$\left[\text{Pa}\right]$ 
sens_ID  Sensor identifier
to activate reference geometry. 8 (Integer, maximum 10 digits) 

D_{f}  Damping coefficient
in the warp and weft directions (0.0 <
D_{f}
< 1.0). 2 Default = 0.00 (Real) 

D_{s}  Friction
coefficient between fibers in shear (0.0 <
D_{s}
< 1.0). 6 Default = 0.00 (Real) 

G_{frot}  Shear friction
modulus. 6 Default ${G}_{\mathit{frot}}={G}_{0}$ (Real) If G_{0} = 0, then ${G}_{\mathit{frot}}=\frac{{G}_{T}}{1+{\mathrm{tan}}^{2}({\alpha}_{T})}$ 

ZeroStress  Zero stress flag
for initial stresses in tension and compression by using
reference state geometry. 7
(Real) 

N_{1}  Fiber density
(number of fiber per length unit) in warp direction. 1 Default = 1 (Integer) 

N_{2}  Fiber density
(number of fiber per length unit) in weft direction. 1 Default = 1 (Integer) 

S_{1}  Straightening
strain in the warp direction. 5 Default = 0.10 (Real) 

S_{2}  Straightening
strain in the weft direction. 5 Default = 0.10 (Real) 

Flex_{1}  Fiber bending
modulus reduction factor in warp direction. 5 Default = Flex (Real) 

Flex_{2}  Fiber bending
modulus reduction factor in weft direction. 5 Default = Flex (Real) 

fct_ID_{1}  Loading function identifier for
true stress versus true strain in warp direction. 3 Default = 0 (Integer) 

Fscale_{1}  Scale factor for ordinate of
function 1. Default = 1.0 (Real) 
$\left[\text{Pa}\right]$ 
fct_ID_{2}  Loading function identifier for
true stress versus true strain in weft direction. 3 Default = 0 (Integer) 

Fscale_{2}  Scale factor for ordinate of
function 2. Default = 1.0 (Real) 
$\left[\text{Pa}\right]$ 
fct_ID_{3}  Loading function identifier for
true shear stress versus the anisotropy complementary angle
(in degrees) between fiber directions (axes of anisotropy).
6 Default = 0 (Integer) 

Fscale_{3}  Scale factor for ordinate of
function 3. Default = 1.0 (Real) 
$\left[\text{Pa}\right]$ 
fct_ID_{4}  Loading function identifier for
unloading for true stress versus true strain in warp
direction. 3 Default = 0 (Integer) 

Fscale_{4}  Scale factor for ordinate of
function 4. Default = 1.0 (Real) 
$\left[\text{Pa}\right]$ 
fct_ID_{5}_{5}  Unloading function identifier
for unloading for true stress versus true strain in weft
direction. 3 Default = 0 (Integer) 

Fscale_{5}  Scale factor for ordinate of
function 5. Default = 1.0 (Real) 
$\left[\text{Pa}\right]$ 
fct_ID_{6}  Unloading function identifier
for true shear stress versus the anisotropy complementary
angle (in degrees) between fiber directions (axes of
anisotropy). 6 Default = 0 (Integer) 

Fscale_{6}  Scale factor for ordinate of
function 6. Default = 1.0 (Real) 
$\left[\text{Pa}\right]$ 
Example (Fabric with parameter input)
#RADIOSS STARTER
#12345678910
/UNIT/1
unit for mat
kg m s
#12345678910
# 2. MATERIALS:
#12345678910
/MAT/LAW58/1/1
FABRIC
# RHO_I
722.5
# E1 B1 E2 B2 FLEX
450000000 0 450000000 0 0.01
# G0 GT AlphaT Gsh sensor_ID
0 10000000 60 0 0
# Df Ds GFROT ZERO_STRESS
.05 .05 0 0
# N1 N2 S1 S2 FLEX1 FLEX2
1 1 .05 .05 0 0
#12345678910
#ENDDATA
/END
#12345678910
Example (Fabric with function input)
#RADIOSS STARTER
#12345678910
/UNIT/1
unit for mat
kg mm ms
#12345678910
# 2. MATERIALS:
#12345678910
/MAT/LAW58/1/1
Altair test fabric LAW58
# RHO_I
8e07
# E1 B1 E2 B2 FLEX
0.38 0 0.38 0 1
# G0 GT AlphaT Gsh sensor_ID
0.0035 0.0055 7.175 0 1
# Df Ds GFROT ZERO_STRESS
0.00 0.00 0 1
# N1 N2 S1 S2 FLEX1 FLEX2
1 1 0 0 0 0
# fct_ID1 Fscale1
500 1
# fct_ID2 Fscale2
501 1.07
# fct_ID3 Fscale3
502 1
#12345678910
/FUNCT/500
stressstrain curve dir 1
# true strain true stress
0.0000000000e+000 0
9.9503308532e003 2.9636979188e003
1.9802627296e002 5.3682944250e003
2.9558802242e002 7.1312474875e003
3.9220713153e002 8.7543744167e003
4.8790164169e002 1.0626227281e002
5.8268908124e002 1.2828957400e002
6.7658648474e002 1.5214981140e002
7.6961041136e002 1.7923677525e002
8.6177696241e002 2.0931047458e002
9.5310179804e002 2.4244941875e002
1.0436001532e001 2.8050134750e002
1.1332868531e001 3.2157106333e002
1.2221763272e001 3.6791281562e002
1.3102826241e001 4.1811352500e002
1.3976194238e001 4.7185817708e002
1.4842000512e001 5.3009665500e002
/FUNCT/501
stressstrain curve dir 2
# true strain true stress
0.0000000000e+000 0
9.9503308532e003 3.7850414917e003
1.9802627296e002 6.6041801875e003
2.9558802242e002 8.9026150938e003
3.9220713153e002 1.1200598067e002
4.8790164169e002 1.3569178437e002
5.8268908124e002 1.6244941225e002
6.7658648474e002 1.9356706823e002
7.6961041136e002 2.2930409250e002
8.6177696241e002 2.7109342313e002
9.5310179804e002 3.1773431250e002
1.0436001532e001 3.6903321313e002
1.1332868531e001 4.2590270333e002
1.2221763272e001 4.8734555250e002
1.3102826241e001 5.5311888000e002
1.3976194238e001 6.2350489167e002
1.4842000512e001 6.9690045000e002
#12345678910
/FUNCT/502
stressstrain curve dir 12
# angle true stress
16.170000000e000 1.5741500000e003
7.1750000000e000 4.3750000000e004
0.0000000000e+000 0.0000000000e+000
7.1750000000e000 4.3750000000e004
16.170000000e000 1.5741500000e003
#ENDDATA
/END
#12345678910
Comments
 This law is used with the properties, /PROP/TYPE16 (SH_FABR), /PROP/TYPE19 (PLY), /PROP/TYPE51, /PLY and /PROP/PCOMPP.
 Fiber
characterization:
 N_{1} and N_{2} are the number of fibers per length unit, which are used to calculate stress in both fiber directions.
 The fiber directions (warp and weft) define local axes of anisotropy. Material data is specified independently for each direction and in shear.
 Fiber damping is used to suppress instabilities as a result of elastic material behavior. The recommended value for the damping coefficient in the fiber direction D_{f} is 0.05.
 Rules concerning input
functions for the optional loading and unloading stressstrain curves.
 All tabulated input curves must be monotonically increasing. Radioss Starter will output write an error message when the input is not monotonically increasingin case of wrong input.
 Case without unloading (fct_ID_{4}=fct_ID_{5}=fct_ID_{6}=0):
All loading functions are optional. The user may use an analytical formula or define a loading function in any direction. Tabulated and analytical behavior may be mixed in any direction.
 Case of loading / unloading with hysteresis with at least one
unloading function is defined.
 Loading functions tabulated input in are loading is mandatory in all directions. Functions fct_ID_{1}, fct_ID_{2}, and fct_ID_{3} must all be defined. It is not possible to mix analytical formulae in loading with unloading functions.
 Not all unloading curves need to be defined. If an unloading curve is missing in any direction, the loading and unloading will take the same path with no hysteresis.
 If loading and unloading functions are defined, they must have strictlyonly one intersection point to define the hysteresis loop. An error message is written in case on incorrect input. The exception is the shear functions are curves in shear which must have two intersection points for negative and positive values.
 An error message is written when input is incorrect.
 Stressstrain
relation in tension and compression in direction of fibres.
 When nonlinear functions are used.fct_ID_{1}, fct_ID_{2} define loading and fct_ID_{4}, fct_ID_{5} unloading behavior
 When parameters are used, the analytical relationships between
stress and strain are defined as:
 For Loading
$\frac{d\sigma}{d\epsilon}>0$
(1) $${\sigma}_{ii}={E}_{i}{\epsilon}_{ii}\frac{({B}_{i}{\epsilon}_{ii}{}^{2})}{2}\text{(}i=1,2)\text{}$$  For Unloading
$\text{}\frac{d\sigma}{d\epsilon}\le 0$
(2) $${\sigma}_{ii}={\mathrm{max}}_{{\epsilon}_{ii}}\left({E}_{i}{\epsilon}_{ii}\frac{({B}_{i}{\epsilon}_{ii}{}^{2})}{2}\right)\text{(}i=1,2)\text{}$$
The analytical parameters are not used if the nonlinear functions (fct_ID_{1}, fct_ID_{2}, fct_ID_{4} and fct_ID_{5}) are specified. However, the values E_{1}, E_{2}, are still required to calculate the prestress from the reference geometry and evaluate material stiffness used in contact. In such cases, E_{1}, E_{2} should correspond to average stiffness (average slope) of the corresponding loading functions.
 For Loading
$\frac{d\sigma}{d\epsilon}>0$
 When nonlinear functions are used.
 Initial straightening
effect of the woven fabric.This material allows you to account for the initial straightening effect of the woven fabric.
 It is assumed to be softer in the tensile direction during
the straightening phase. In biaxial tension there is no
straightening phase and the fibers bear loads from the
beginning of the loading phase.
Use factor Flex_{i} to scale the E modulus or function ${\mathrm{f}}_{i}$ (fct_ID_{1} or fct_ID_{2}) in corresponding direction.
${\mathrm{f}}_{ft\_i}=Fle{x}_{i}\cdot {\mathrm{f}}_{i}$ (function input)
${E}_{ft}=Fle{x}_{i}\cdot {E}_{i}$ (parameter input) If the value of Flex_{1} or Flex_{2} is equal to zero, then the value of Flex will be used.
 The straightening portion of the strain is given by the strains S_{1} and S_{2} for direction 1 and 2 correspondingly.
 The functions fct_ID_{1} and fct_ID_{2} correspond to biaxial tension, where the initial straightening is not taken into account. In uniaxial tension, the straightening effect is accounted for by using Flex_{1} and Flex_{2} in the stress calculation. It is similar to the case when E_{1} and E_{2} are specified instead of the curves.
 In compression, the Young's modulus is always:$E=Fle{x}_{i}\cdot {E}_{i}$
 It is assumed to be softer in the tensile direction during
the straightening phase. In biaxial tension there is no
straightening phase and the fibers bear loads from the
beginning of the loading phase.
 Stressstrain
relation in shear.
 When tabulated input is present fct_ID_{3} is used for loading and fct_ID_{6} for unloading.
 If fct_ID_{6} is not specified, the material is assumed to be hyperelastic, and the loading and unloading paths are the same.
 If fct_ID_{6} is given, the material shows hysteresis behavior with different path for loading and unloading in shear directions.
 The nonlinear functions (fct_ID_{3}, fct_ID_{6}) are not mandatory. If these functions are not specified, the corresponding values of G_{0}, and G_{T} are used to calculate the stressstrain relationship of the material.
 For function fct_ID_{3}, fct_ID_{6}, which determine loading and unloading in shear the abscissa should be set in degrees. The functions should be specified both for negative and positive values of the angle (normally the functions are symmetrical).
 Absolute value of the angle, and its value should be less than 90 degrees, $\left\alpha \right<{90}^{\circ}$ .
 Loading and unloading functions should pass through
point (0,0). Loading and unloading curves should have
exactly one intersection point for negative angle and
another intersection point for positive angle.
The anisotropy complementary angle $\alpha $ which is equal to the difference between 90 degrees and the current angle between the anisotropy axes.
 When parameters are used to describe relation between shear stress
and angle, two different shear situations could be described:
 In plane (1  2) shear:Before shear locking angle $\alpha \le {\alpha}_{T}$ :
(3) $$\tau ={G}_{0}\mathrm{tan}(\alpha ){\tau}_{0}$$After shear locking angle $\alpha >{\alpha}_{T}$ :(4) $$\tau =G\mathrm{tan}(\alpha )+{G}_{A}{\tau}_{0}$$Where, ${G}_{A}=({G}_{0}G)\mathrm{tan}({\alpha}_{T})$
 $G=\frac{{G}_{T}}{1+{\mathrm{tan}}^{2}({\alpha}_{T})}$
 ${\tau}_{0}={G}_{0}\mathrm{tan}({\alpha}_{0})$
 ${\alpha}_{T}$
 Shear locking angle
 G_{T}
 Shear modulus at ${\alpha}_{T}$
 G_{0}
 Shear modulus at $\alpha ={\alpha}_{0}$
 If the G_{0} = 0, then its value is calculated to avoid discontinuity of the shear modulus at ${\alpha}_{T}$ : G_{0} = G
 The values of G_{0} and G_{T} are ignored if the nonlinear functions (fct_ID_{3} and fct_ID_{6}) are specified. However, the values G_{0} is still required to calculate the prestress from the reference geometry and evaluate material stiffness used in contact. In such cases, G_{0} should correspond to average stiffness (average slope) of the corresponding loading functions.

${\alpha}_{T}$
is an initial
complementary angle, which is equal to the difference
between 90 degrees and the initial angle between the
anisotropy axes defined in the shell property (/PROP/TYPE16 (SH_FABR)). Note: Initial prestress exists in the fabric material if initial angle between the fiber axes specified in the property is not equal to 90 degrees.
 It is also possible to describe interaction shear stress between fibers. Use G_{frot} (the shear modulus) to calculate interaction shear stress ( ${G}_{\mathit{frot}}*(\dot{\alpha})$ ) between fibers. The friction inplane shear stress between the fibers is calculated as ${D}_{s}*{G}_{\mathit{frot}}*(\dot{\alpha})$ .
 Outofplane shear:
It is possible to describe transverse shear between multilayers (plies) with shear modulus ${G}_{sh}$ .
 In plane (1  2) shear:
 When tabulated input is present fct_ID_{3} is used for loading and fct_ID_{6} for unloading.
 The ZeroStress flag is used to remove initial stresses in the folded airbag. These initial stresses arise during the folding process. Numerically this prestress is specified through a reference airbag geometry which represents an unfolded airbag state. If ZeroStress=1, then compressive and tensile initial stresses are set to zero and then gradually increase to the actual value after deployment begins.
 sens_ID is used only with ZeroStress =1 and reference airbag geometry. It activates the prestress based on the values output from the sensor. This is useful for airbags with time to fire > 0.
 Output for
postprocessing:This material uses the anisotropic coordinate system, with the angle between the material coordinate system axes (anisotropy angle) updated based on the element deformation. Special userdefined output should be used to evaluate stresses, strains, and the shear angle alpha. In the /TH/SHEL and /TH/SH3N entries in the Starter file and in /H3D/SHELL or /ANIM/SHELL in the Engine file, you should specify the following:
 /H3D/SHELL/USER/UVAR=1 or /ANIM/SHELL/USR1  stress in fiber direction 1
 /H3D/SHELL/USER/UVAR=2 or /ANIM/SHELL/USR2  stress in fiber direction 2
 /H3D/SHELL/USER/UVAR=3 or /ANIM/SHELL/USR3  stress in shear direction
 /H3D/SHELL/USER/UVAR=4 or /ANIM/SHELL/USR4  strain in fiber direction 1
 /H3D/SHELL/USER/UVAR=5 or /ANIM/SHELL/USR5  strain in fiber direction 2
 /H3D/SHELL/USER/UVAR=6 or /ANIM/SHELL/USR6  tan(α)
 /H3D/SHELL/ALPHA  Shear angle alpha of material /MAT/LAW58 in degrees.
Due to special material formulation (decoupled DOF with special interaction between fibers), the stress component does not form a stress tensor; therefore, usual tensor evaluations such as von Mises stress, principal stresses, and so on, have no meaning for the material.