In order to understand the complex interaction of carbon and metal fibers of a loaded hybrid composite, a micromechanical model of unidirectional and multiaxial laminates is build up using the structure generators of the software GeoDict. For each constituent material, separate user defined material models (UMAT) with individual failure criterions are developed and implemented to simulate the macroscopic material behavior. Through the modelling of the microscopic structure and damages, the strength of the laminate could be determined using the solver called FeelMath which is developed at the Fraunhofer Institute for Industrial Mathematics (ITWM). This fast and memory efficient solver is capable to handle the huge number of elements required for such accurate micromechanical simulations. Additionally, the electrical conductivity of the different laminates is simulated. The numerical study is validated with experimental test investigations on unidirectional and multiaxial laminates with different steelcarbon-fiber-ratios. The obtained results are in a good accordance with the experimental data and additionally provide a detailed insight into the micromechanics of such complex hybrid composite material.