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The course ensures the understanding and use of notions such as limits, derivatives or integrals, elements based on which mechanical engineering quantities are defined.

The course offers knowledge about the operation with vectors and matrices, elements that are the basis of the development of algorithms for numerical modeling the processes and phenomena of mechanical engineering.

Any engineering phenomena or process can be described by differential equations with total or partial derivatives. Therefore, the knowledge of the methods for analyzing and solving differential equations, presented in this course, are an asset in engineering practice.

Many activities in mechanical engineering are based on algorithms and computer programs, so knowledge about programming languages, the structure of a program and programming symbols are necessary for the student and the practicing engineer. The course offers programming knowledge in Python.

The mechanical engineer uses the graphic representation of the objects to visualize and transmit the created information. This activity is based on the technique of planar projections of a three-dimensional body, presented in this course.

The course provides knowledge about making technical drawings and the use of CAD software in modeling and drawing mechanical components.

The course introduces the students to the principles of static and kinematic mechanics, giving them knowledge about the analysis of systems of forces and moments, respectively the description of different types of motions of rigid bodies.

The course provides the necessary knowledge for the student to understand the physical principles underlying engineering processes.

The course provides knowledge about the structure of ferrous, non-ferrous, plastics and composite materials, their composition and applied heat treatments.

The course provides students with knowledge about the technologies of elaboration and processing of different classes of materials.

The course provides knowledge about the principles and chemical reactions that form the basis of engineering materials.

It is an activity that contributes to the physical and mental health of people.

The course introduces basic notions of electrical engineering, characteristic of different types of electrical circuits (single-phase or three-phase).

Strength of materials, in addition to the mechanical characterization of materials, allows the dimensioning of mechanical parts from the conditions of strength and stiffness to the action of mechanical loads.

The course presents the principles and dynamic characteristics of rigid bodies in motion.

Mechanical systems work based on the laws of thermodynamics, which establish the relationships between heat, work, temperature and energy. All of these are systematically described in the course.

Numerical methods are an effective tool in solving differential equations and not only that. Numerical methods such as Newton's, Euler's and Runge-Kutta's are described in this course and used in applications run in the Matlab environment.

Mechanical installations and equipment are assemblies of components in motion. These configurations represent mechanisms with different technical and movement characteristics that are described in this course.

Surface topography and dimensional deviations are essential elements in the functional assembly of mechanical parts. The course describes the characteristics of adjustments and their dimensional tolerance methods.

Polymers are a class of materials very often used in the manufacture of mechanical parts. For this, the course offers a synthesis characterization together with the description of the elaboration and processing technologies.

The course describes the concepts of fluid, along with its characteristics and flow.

It is an activity that contributes to the physical and mental health of people.

Students experience engineering work through practical activities carried out in laboratories.

The course describes methods of calculation and construction of various components and mechanical assemblies such as shafts, bearings, couplings, mechanical transmissions, belt drives, gears and gear boxes, etc.

Using the principles of fluid flow, hydraulic machines can be developed that convert fluid energy into mechanical and electrical energy. All of these are described in the course.

The course offers a presentation, construction and dimensioning of specific elements of hydropneumatics actuation systems for fixed and mobile technological machines.

This course offers very useful tool in the analysis of any engineering phenomenon and process. From structural, dynamic or thermal analyzes of mechanical components to magnetic and electrical phenomena, all can be modeled and solved numerically, using the finite element method.

The course offers an introduction into applied electronics, measurements and instrumentation general concepts and principles; presentation of electronic components, and devices; presentation of general data processing techniques with direct applications in the fields of electronics, instrumentation, and measurements.

The course introduce knowledge of the basic concepts of machine learning such as: linear models, nonparametric models, decision trees and ensemble methods, dimensionality reduction, clustering, multilayer perceptron, convolutional neural networks, recurrent neural networks, attention mechanisms, and computer vision applications, and their implementation using Scikit-learn and PyTorch.

The course offers knowledge of mechanical manufacturing processes, equipment and machine tools.

The course describes the theory of conceptualization and design of machines and installations.

The course provides knowledge about the automation of mechanical systems

The complex geometries of the mechanical components introduce areas with stress concentrations that favor material cracking. In these conditions, the strength calculation of the cracked component require an approach based on Fracture Mechanics. The course describes the concepts of integrity and strength of structures with crack like defects and definition of fracture mechanics parameters for strength calculation.

The course presents the students with the rules of ethics and academic deontology, copyrights and academic writing.

In this semester project, students have the opportunity to apply the knowledge they have learned in concrete equipment and machine design applications.

The course provides the basic knowledge in the field of life cycle of complex engineering process systems, with reference to the design and integration needs of the processes and the implications on the environment

Thermal equipment are systems based on the principle of heat transfer between two environments, being used on a large scale both industrially and domestically. The course offers useful knowledge about the components of thermal systems, analysis and design methodologies.

Modal analysis represents an essential problem in the behavioral analysis of mechanical systems in motion.

Electric machines and drives are component parts of mechanical equipment and installations, and therefore it is very useful to know their constructive and design principles.

The course provides skills and knowledge for solving practical problems of operating hydraulic machineries and systems, using computational methods.

The course ensures acquiring, understanding and using knowledge specific to sensor and actuators used in mechanical engineering, in order to solve practical problems and conduct research efficiently. The course is useful for understanding functional principles of sensors and actuators, integration of sensors and actuators with mechanical devices and data acquisition from sensors and control methods of actuators.

CNC technologies together with CAM programming dominate the manufacturing industry. In this sense, the course offers knowledge about the programming and operation of numerically controlled mechanical processing machines.

The course provides knowledge for implementation of different algorithms for functional modeling and simulating mechanical systems, using Matlab.

The general objective of the course is to increase the students’ level of knowledge regarding the advanced materials and their mechanical behavior modeling.

Engineering is based on measurements, thus the course ensures acquiring the main experimental methods and approaches (such as measurement of forces, displacements, speeds, vibrations, flows, pressures, temperature, etc.) used in the field of mechanical engineering.

The course ensure specific skills in designing rational models of mechanical structures that meet the criteria of minimum weight, durability and maximum operational safety.

Students experience engineering work through practical activities carried out in laboratories.

Students develop an engineering project theme, under the guidance of a supervising teacher.