Innovative materials, such as composite materials, enable revolutionary solutions and significant improvements in various industrial sectors. Composite materials are composed of two or more different materials, and thanks to the ability to combine the properties of individual components, materials with enhanced characteristics are obtained. Composite materials have particular significance in specialized areas such as ballistics, where they offer innovative solutions for the design and manufacture of antiballistic plates, which are key components in ballistic protection. Additionally, in recent decades, with the development of technology, there has been an increasing use of nanoparticles in industrial processes, where they play a particularly important role in the production of polymeric matrices for composite materials. The aim of this master's thesis is to determine the influence of different volume fractions of SiO2 and TiO2 nanoparticles on the mechanical properties of epoxy resin, which represents the polymeric matrix of the future composite material. By comparing test samples of epoxy plates reinforced with SiO2 and TiO2 nanoparticles with test samples of reference plates without reinforcements, conclusions will be drawn regarding the influence of nanoparticles on the mechanical properties of epoxy resin, as well as on the future application of reinforced epoxy polymer matrices for the production of antiballistic plates. The master's thesis is divided into two parts: theoretical and experimental. Firstly, in the theoretical part of the work, composite materials are generally described, their division is outlined, and composite materials with a matrix of polymeric materials are described in more detail, with a focus on epoxy resin matrices. Then, nanoparticles are described in the work, including their basic division, production process, and list of applications. In the theoretical part, ballistics are briefly described, along with a list of materials and various fiber materials used in the production of antiballistic plates. Finally, the mechanical tests conducted in this work are described. In the experimental part of the work, the course of tensile testing, bending testing, and impact fracture testing are described. The results of the tests are presented along with their analysis, accompanied by images and graphs obtained after the mechanical testing.