appendices:a9
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appendices:a9 [2024/03/22 10:17] sophie |
appendices:a9 [2024/03/22 11:15] (current) sophie [Appendix 9: Printing files *.ipn, *.ipe, *.ipr, *.ipc, *.ips] |
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| - | The IPCON number, is function of the number of DOF in the simulation. If there are 5 DOF, | + | The IPCON number, is function of the number of DOF in the simulation. <imgref image2> displays in red the IPCON number to enter for each variable if the DOF of the simulation is 5. <imgref image3> displays in red the IPCON number to enter for each variable if the DOF of the simulation is 3 (Hydro-mechanical behaviour). |
| <imgcaption image2|Written in red are the IPCON if 5 DOF>{{:appendices:indic1_5dof.png?nolink&390|}}</imgcaption> <imgcaption image3|Written in red are the IPCON if 3 DOF>{{:appendices:indic1_3dof.png?nolink&240|}}</imgcaption> | <imgcaption image2|Written in red are the IPCON if 5 DOF>{{:appendices:indic1_5dof.png?nolink&390|}}</imgcaption> <imgcaption image3|Written in red are the IPCON if 3 DOF>{{:appendices:indic1_3dof.png?nolink&240|}}</imgcaption> | ||
| + | |||
| + | The IPSIG number is function of the Heat or/and Fluid flow constitutive law and of the mechanical constitutive law. | ||
| + | **For a purely mechanical behaviour** (IP = Integration Point):\\ | ||
| + | |$IP_{1}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$| IPSIG: 1 to 4| | ||
| + | |$IP_{2}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$| IPSIG: 5 to 8| | ||
| + | |$IP_{3}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$| IPSIG: 9 to12| | ||
| + | |$IP_{4}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$| IPSIG: 13 to 16| | ||
| + | |||
| + | It means that for printing a State Variable, IPSIG = 16 + N(state variable). For example, if it is a 2D simulation, using EP-PLASOL as mechanical constitutive law, in order to print the deformation in Y, IPSIG = 16 + 9 = 25. | ||
| + | |||
| + | **For a Hydro-mechanical behaviour**, the stresses link to the fluid flow law must be added (for example: with ECOUS-S in 2D, 4 stresses have to be added ): | ||
| + | |||
| + | |$IP_{1}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +4| IPSIG: 1 to 8| | ||
| + | |$IP_{2}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +4| IPSIG: 9 to 16| | ||
| + | |$IP_{3}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +4| IPSIG: 17 to 24| | ||
| + | |$IP_{4}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +4| IPSIG: 25 to 32| | ||
| + | |||
| + | In this case, IPSIG = 32 + N(state variable). | ||
| + | |||
| + | **For a Thermo-hydro-mechanical behaviour**, the stresses link to the heat and fluid flow law must be added (for example: with WAVAT, 24 stresses have to be added): | ||
| + | |||
| + | |$IP_{1}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +24| IPSIG: 1 to 28| | ||
| + | |$IP_{2}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +24| IPSIG: 29 to 56| | ||
| + | |$IP_{3}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +24| IPSIG: 57 to 84| | ||
| + | |$IP_{4}$|$\sigma_x$,$\sigma_y$,$\sigma_{xy}$,$\sigma_z$, +24| IPSIG: 85 to 112| | ||
| + | |||
| + | In this case, IPSIG = 112 + N(state variable). | ||
| + | |||
| ===== Printing of nodal values in a *.ipn file ===== | ===== Printing of nodal values in a *.ipn file ===== | ||
appendices/a9.1711099075.txt.gz · Last modified: 2024/03/22 10:17 by sophie
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