The simulation, analysis and calculation by the finite element method (FEM) allows to know the mechanical behavior of the element, in relation to displacements, deformations, stresses, helping to optimize its geometry.
Simulation and calculation of metallic elements of any geometry, no matter how complex the model, made up of sheets of different sizes and thicknesses.
![ROBOBEAM TIPO 02_2b [VISTA EXPLOSIONADA TENSIONES]](https://static.wixstatic.com/media/b32594_35185a69daa9431b84c7df74e9229891~mv2.jpg/v1/fill/w_980,h_706,al_c,q_85,usm_0.66_1.00_0.01,enc_auto/b32594_35185a69daa9431b84c7df74e9229891~mv2.jpg)
![ZONA PRENSAS_1a [CÁMARA 01 - TENSIONES] 01.01](https://static.wixstatic.com/media/b32594_a43bf5cbf70f4a7ebe5df7f7d93f919a~mv2.jpg/v1/fill/w_980,h_556,al_c,q_85,usm_0.66_1.00_0.01,enc_auto/b32594_a43bf5cbf70f4a7ebe5df7f7d93f919a~mv2.jpg)
![AGITADOR [TENSIONES 08]](https://static.wixstatic.com/media/b32594_75bfeff583034684b8cc557eab9f508d~mv2.jpg/v1/fill/w_980,h_556,al_c,q_85,usm_0.66_1.00_0.01,enc_auto/b32594_75bfeff583034684b8cc557eab9f508d~mv2.jpg)
![VIGA CELOSIA FINK TIPO 2.3.3 [TENSIONES 04]](https://static.wixstatic.com/media/b32594_5ae83cbc54024ab79cd23c07e3051fcc~mv2.jpg/v1/fill/w_838,h_344,al_c,q_80,enc_auto/b32594_5ae83cbc54024ab79cd23c07e3051fcc~mv2.jpg)
![VIGA CELOSIA FINK TIPO 2.3.3 [TENSIONES 02]](https://static.wixstatic.com/media/b32594_f398271bed40493cb3300dbca7db10c5~mv2.jpg/v1/fill/w_980,h_336,al_c,q_80,usm_0.66_1.00_0.01,enc_auto/b32594_f398271bed40493cb3300dbca7db10c5~mv2.jpg)
![VIGA CELOSIA FINK TIPO 1.4.0 [TENSIONES 02]](https://static.wixstatic.com/media/b32594_0ee3daa5a7844f42aa966827153c8e0b~mv2.jpg/v1/fill/w_980,h_348,al_c,q_80,usm_0.66_1.00_0.01,enc_auto/b32594_0ee3daa5a7844f42aa966827153c8e0b~mv2.jpg)
The simulation and calculation of metallic structuresformed based on commercial structural steel profiles, either rolled and/or shaped profiles, allows us to study conventional elements such as pillars, beams, trusses and latticework, support corbels, joints, etc.
The main types of structural simulation are elastic analysis (linear analysis) based on the theory that the stress-strain behavior of the material is linear, that is, the plastic zone of the material is not taken into account in the study, and the plastic analysis (non-linear) where the entire stress curve is taken into account -deformation of the material, which is ideal when you want to analyze the breakage of a product subjected to high loads and/or materials in which there is a plastic zone
![DECANTADOR [TENSIONES 01]](https://static.wixstatic.com/media/b32594_0dc6546ddf354ad895a9874cd8f74d1c~mv2.jpg/v1/fill/w_585,h_429,al_c,q_80,enc_auto/b32594_0dc6546ddf354ad895a9874cd8f74d1c~mv2.jpg)
Analysis and simulation forprocess equipment as tanks, pressure vessels, managing to obtain the optimal geometry, optimizing the material used.
In finite element method (FEM) analysis, it can also be applied to other materials such as wood, plastic, predicting the areas susceptible to breakage of the products, with the intention of anticipating and making the corresponding modifications prior to industrial manufacturing.
![SILLA S04 [DESPLAZAMIENTOS 01]](https://static.wixstatic.com/media/b32594_dcee44083dd44d65916262d07e17a2f7~mv2.jpg/v1/fill/w_610,h_477,al_c,q_80,enc_auto/b32594_dcee44083dd44d65916262d07e17a2f7~mv2.jpg)
![SILLA S04 [TENSIONES 02]](https://static.wixstatic.com/media/b32594_3ba19c8adecc4097946d15a2b9c16a4c~mv2.jpg/v1/fill/w_636,h_409,al_c,q_80,enc_auto/b32594_3ba19c8adecc4097946d15a2b9c16a4c~mv2.jpg)
