Description
Abaqus CREEP Tutorial-Abaqus CREEP Subroutine
The Abaqus CREEP tutorial package (Abaqus CREEP subroutine-Abaqus user creep)) contains videos and files that make CREEP training easier and faster. Consequently, the adopted strategy was starting from the simplest case and gradually brings complexities. Hence, It helps researchers and students to learn the Abaqus CREEP subroutine in a more organized approach, even for those without any experience in Fortran coding and Abaqus modeling. Thus, We organized the CREEP training through three practical examples:
Abaqus CREEP Example#1: Basics of Abaqus CREEP Subroutine
Generally, the basics of Abaqus CREEP (Abaqus user creep) are constant in all written CREEPs and sometimes a small mistake can waste a huge amount of your time. In addition, a robust understanding of these basics is necessary to write well-working CREEPs. Therefore, In Example#1, we selected a model to apply in CREEP and explained in the videos all the required basics such as Abaqus CREEP variables (inputs, outputs).
Example#2: Details of Abaqus CREEP Tutorial
Afterward, a medium Abaqus CREEP in Example#2 enables understanding more details, more techniques, and converting formulations to Fortran CREEP code. Furthermore, you will learn to manipulate the CREEP code, change parameters, run it abacus, and add new formulations.
Example#3: Complexities of Abaqus CREEP Tutorial
Finally, the complexities of the Abaqus CREEP subroutine are explained line by line in the videos of Example#3. Then, with the training you got from the previous example, you will easily understand and handle the difficulties in Abaus CREEP writing. Now, it is the time you write any CREEP and of course, we are here always to help.
Do you need more support to write CREEP subroutine in Abaqus?
Additionally, we provide full 24/7 support for our customers. You can contact us easily, we typically answer in a minute. We can also do your projects and write your Abaqus CREEP subroutine, test it with published results, and teach it to you through Abaqus CREEP tutorial videos (order Abaqus UMAT project).
Other Abaqus Subroutines
In addition to the Tutorial for CREEP Abaqus, FEAassist provides training packages for other Abaqus Subroutines, [1] that whose applications and links can be found here. Do not hesitate to ask questions from our experts on the Abaqus CREEP tutorial.
Application | FEAassist tutorials | More | Application | FEAassist tutorials | More |
Mechanical property | UMAT | Ex. Link | – | UMDFLUX | Ex. Link |
Mechanical property | VUMAT | Ex. Link | Mesh motion | UMESHMOTION | Ex. Link |
Creep and swelling | CREEP | Ex. Link | Cavity motion | UMOTION | Ex. Link |
Nonuniform fluid | DFLOW | Ex. Link | Damage variable | UMULLINS | Ex. Link |
Nonuniform flux | DFLUX | Ex. Link | Initial fluid pres | UPOREP | Ex. Link |
Prescribed BC | DISP | Ex. Link | Prescribed pres | UPRESS | Ex. Link |
Nonuniform loads | DLOAD | Ex. Link | Frequency | UPSD | Ex. Link |
Nonuniform film | FILM | Ex. Link | Read result | URDFIL | Ex. Link |
Nonuniform consolidation | FLOW | Ex. Link | Redefine field | USDFLD | Ex. Link |
Friction | FRIC | Ex. Link | Prescribed temp | UTEMP | Ex. Link |
Friction coefficient | FRICCOEF | Ex. Link | Nonuniform traction | UTRACLOAD | Ex. Link |
Conductance | GAPCON | Ex. Link | Viscoelastic | UTRS | Ex. Link |
Cross-correlation prop. | UCORR | Ex. Link | Element output | UVARM | Ex. Link |
Time-dependent creep | UCREEPNETWORK | Ex. Link | |||
Nonuniform current | UDECURRENT | Ex. Link | – | VDFLUX | Ex. Link |
Nonuniform magnetic | UDEMPOTENTIAL | Ex. Link | Prescribed BC | VDIS | Ex. Link |
Damage initiation | UDMGINI | Ex. Link | Nonuniform loads | VDLOAD | Ex. Link |
User element | UEL | Ex. Link | User external DB | VEXTERNALDB | Ex. Link |
User element prop | UELMAT | Ex. Link | Fabric material | VFABRIC | Ex. Link |
Thermal strains | UEXPAN | Ex. Link | Friction | VFRIC | Ex. Link |
User external DB | UEXTERNALDB | Ex. Link | Friction coefficient | VFRIC_COEF | Ex. Link |
Predefined field V | UFIELD | Ex. Link | Friction | VFRICTION | Ex. Link |
Fluid density | UFLUID | Ex. Link | – | VOIDRI | Ex. Link |
Mechanical shell | UGENS | Ex. Link | Amplitudes | VUAMP | Ex. Link |
Yield & hardening | UHARD | Ex. Link | User element | VUEL | Ex. Link |
Hypoelastic | UHYPEL | Ex. Link | Equation of state | VUEOS | Ex. Link |
Hyperelastic | UHYPER | Ex. Link | Thermal strains | VUEXPAN | Ex. Link |
Surface interaction | UINTER | Ex. Link | Yield & hardening | VUHARD | Ex. Link |
Mass flow | UMASFL | Ex. Link | Surface interaction | VUINTER | Ex. Link |
Material’s thermal | UMATHT | Ex. Link | Damage variable | VUMULLINS | Ex. Link |
VUSDFLD | Ex. Link | Crystal plasticity | CPFEM | Ex. Link |
Claire –
They did good work for the simulation. It really helpful to study about the FEM!
S.dindarlou (verified owner) –
Thank you.