Graduates can find employment primarily in engineering companies with design, development, or research departments, as well as in any engineering-oriented firms that emphasise innovation and optimisation trends. An added value is their focus on sustainable engineering and environmental responsibility. Typical job positions include simulation engineer (FEM analyst, design engineer) or specialist in experimental measurement. The graduate will also be qualified to lead work teams or assume managerial positions.

The study programme Design and Simulation of Machines prepares students to master the principles of sustainable machine design and operation, focusing on reducing manufacturing and operating costs and minimising environmental impact. Students learn to design machines with regard to their energy intensity, repairability, and recyclability at the end of their service life, all with the smallest possible environmental footprint.The study programme will be internally divided into the following two specialisations: Applied Mechanics and Machine Parts and Mechanisms.

A graduate of the study programme acquires broad physical and technical knowledge. This includes kinematic and dynamic analysis of mechanisms, structural analysis, assessment of stress and deformation in bodies, application of fracture mechanics principles, and mathematical modelling of fluid flow. The graduate is familiar with currently used experimental and numerical methods, enabling effective collaboration with specialists from related engineering fields. Furthermore, students learn the principles of machine and component design, including the selection of sustainable materials and approaches to reducing component weight, with an emphasis on circular-economy principles and recyclability. During their studies, they also focus on analysing operational data of machine components, including load spectra and service-life prediction, and acquire skills to ensure durability and extend the lifespan of parts. In addition to technical knowledge, the study programme also covers topics of sustainable development, such as assessing energy demands, recyclability, and compliance with standards for the green transition. The graduate demonstrates their knowledge by passing the state final examination and defending their master’s thesis.

A graduate of this study programme acquires comprehensive professional skills in the field of machine and equipment design, including the analysis of the mechanical behaviour of materials and structures. They master the methodology of designing and verifying machine components using analytical and simulation methods and can optimise designs so that individual parts have balanced service life and minimised weight. The graduate is capable of designing and conducting experiments to obtain load spectra of machines, evaluating measured data, and predicting the service life or degree of damage of components. They are also proficient in selecting materials based on functional requirements, recyclability, and operating conditions. Furthermore, they are familiar with normative requirements concerning ergonomics, safety, and the operation of machine components. The graduate is additionally equipped with skills for analysing and optimising the energy demands of equipment and for designing technologies that minimise energy consumption and carbon footprint. Emphasis is placed on ensuring the recyclability of equipment and compliance with environmental standards supporting sustainable development. In the area of simulation and experimental methods, the graduate is capable of developing and evaluating computer models of the mechanical behaviour of materials and structures, as well as conducting laboratory and operational experiments focusing on modal properties, stress–strain responses, and other key phenomena. Overall, the graduate possesses the skills necessary for designing and optimising machinery that is environmentally friendly, energy-efficient, and sustainable throughout its entire life cycle.

A graduate of this study programme demonstrates the ability to work both independently and as part of a team, particularly when solving individual and group projects. They are capable of effectively interpreting the results of calculations and experiments in the context of physical laws and other relevant properties of the evaluated structures. The graduate is qualified to apply analytical and simulation methods in design processes, in the analysis of operating conditions, and in the optimisation of components and mechanisms. They are prepared to promote and implement principles of sustainability and environmentally responsible thinking in technical design and work procedures, thereby contributing to environmental protection. In addition, they are able to solve complex engineering problems independently as well as through team collaboration, communicate the results of their work, and present them effectively. The graduate also demonstrates the capability for further education, which is essential for continuous professional development and for adapting to emerging technological and environmental challenges in the fields of design engineering and sustainable development.