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2 | INSTITUTE | PROGRAM TITLE | COURSE TITLE | COURSE DESCRIPTION | ECTS | SEMESTER | ||||||||||||||||||||
3 | Institute of Civil Engineering | Civil Engineering | Digital Resources in Scientific Research | The aim is to study modern methods of working with various information sources during scientific research. A separate topic of the course is the analysis and synthesis of information. The section discusses the methods of compiling annotations and reviews, the rules for compiling keywords, and designing a list of references for scientific papers | 3 | 1 (Autumn 2022) | ||||||||||||||||||||
4 | Institute of Civil Engineering | Civil Engineering | Foreign Language in Professional Communication, English | 1. Technology and Society. Branches of technology. Technology and work. Technological innovations. 2. Design and CAD systems. The design process. Famous designers. Principles and advantages of CAD. Modern CAD systems. 3. Manufacturing. Modern manufacturing processes. Machine tools and process planning. 4. Power Machines. Different types of power machines. Design and field of application. 5. Transport. Different forms of transport (1and, sea and air transport). Safety and efficiency of transport. 6. The Future of Technology. Predictions and future developments in technology. | 3 | 1 (Autumn 2022) | ||||||||||||||||||||
5 | Institute of Civil Engineering | Civil Engineering | Digital Modeling of Buildings and Structures | This course is designed to cover all basic questions concerning BIM technology and main software. What is BIM, why should we use it, which software can gain us maximum performance? You would find answers on these and many other questions during this course. The main part of our training is devoted to practice questions based on actual software. 1. Getting started with BIM 2. Autodesk Revit Basics 3. Conceptual design, Mass modeling, Starting with AutoCAD drawings 4. Documentation, visualization, tips and tricks 5. Engineering systems 6. Collaboration 7. Finite elements analysis in SCAD / SOFiSTiK 8. Project coordination in Navisworks | 2 | 1 (Autumn 2022) | ||||||||||||||||||||
6 | Institute of Civil Engineering | Civil Engineering | Mathematical Modeling | 1. Theoretical basics of solving scientific and technical problems. a. Contradictions and Problems. Scientific and technical problems solving as a way for professional development and growth for future engineers. Approaches in solving technical problems. Administrative conflicts. Technical Difficulties. Physical Limitations. Heuristic value of the differences. Overcoming obstacles in resolving of problematic situations. b. Theory of solving scientific and engineering problems. Theory of scientific and engineering concepts. Compromises. Information repository of standard solutions. Problem solving techniques. Resources to eliminate conflicts. 2. Methodology for solving scientific and technical problems. a. Methods of solving scientific and engineering problems.Fundamentals of designing scientific and technical systems. Material object-field (obfield) analysis. Alternative approaches. Method of trial and error. Brainstorming. Synectics method. Morphological analysis. Method of focal objects. Method of test questions. b. Stages of solving scientific and technical problems Formulation of problems. Analysis of model of the problem. Finding a principal solution of the scientific and technical problem. Evaluation of solution for scientific and technical problems. c. Modeling as means of experimental research and analysis. Physical modeling. Practical methods of scientific and technical creativity. Heuristic analogy. Heuristic inversion. Heuristic complex. | 3 | 1 (Autumn 2022) | ||||||||||||||||||||
7 | Institute of Civil Engineering | Civil Engineering | International Communication in Construction Business | 1. Сonstruction contracts. Types of construction contracts. Concession contracts. Standard contracts of international organizations. FIDIC contracts. The structure of the construction contract. Documentation of the construction contract. Correspondence on the construction contract. Reporting on the construction contract. 2. Construction risks. Risk management. 3. The quality of construction work. Quality management. System of quality management. 4. International competitive bidding. Regulations and documents of international competitive bidding. Preparation of tender documentation. 5. Occupational health and safety. Safety management system. 6. Environmental aspects of construction projects. Key documents on environmental protection. 7. Management of construction. The structure of the building project. The implementation of the construction project. | 3 | 1 (Autumn 2022) | ||||||||||||||||||||
8 | Institute of Civil Engineering | Civil Engineering | Cross-cultural communication and Self-Management | Discipline is devoted to the development of professional competencies Master program students. This discipline is focused on the development of social and personal competencies of learners, which they would need in their further professional activities. Discipline is one of the basic for such disciplines as project management, research methodology, Scientific and Research Students Work and English for Professional activity. Teaching discipline aims are to develop the following skills: organizing and conducting the effective communications, presentations, conflict management, team work, negotiating, designing teaching materials sciences, design scenario of the training session with the using of active learning methods, planning methodical work on the application of the active methods in the learning process, organization and implementation of a command-group teaching methods, use of interactive learning technology, goal setting and time management. As a result of the discipline of the students will form the ability to solve a variety of application tasks on the proposed themes and apply modern educational technology in teaching and develop collective group solutions. | 2 | 1 (Autumn 2022) | ||||||||||||||||||||
9 | Institute of Civil Engineering | Civil Engineering | Landscape Architecture | Projects designing, the main purpose of which is the volumetric and spatial organization of the territory, the combination of natural, building and architectural components into an integral composition carrying a certain artistic image | 2 | 1 (Autumn 2022) | ||||||||||||||||||||
10 | Institute of Civil Engineering | Civil Engineering | Special course on building materials | The course includes an in-depth introduction to geosynthetics materials, their description and application in civil engineering. Classification and definitions, raw materials and manufacturing processes for different types of geosynthetics will be presented. These types include geotextiles, geogrids, geonets, geomembranes, geocells, geocomposites, etc. History of geosynthetics will be explored. The latest developments and important innovations, various economic and the others aspects of production and application of geosynthetics will be emphasized.Basic functions of geosynthetics such as reinforcement, separation, filtration, drainage, erosion will be analyzed. Application areas of geosynthetics include retaining walls, embankments, foundations, roads, slopes, erosion control, landfills, earth dams, tunnels, hydraulic applications, etc. will be presented. Properties of geosynthetics, their characterization and basic characteristics including physical properties, mechanical properties,hydraulic, endurance and degradation properties will be analyzed and compared to other building materials. Durability of geosynthetics, causes and mechanisms of degradation including mechanical damage during installation, creep, resistance to weathering, chemical and biological degradation will be analyzed and discussed. Design principles, concepts and methodologies of geosynthetics combined with material properties requirements including safety factors, service life, and long-term strength will be presented and debated. Geosynthetics standards, quality assurance for geosynthetics and manufacturing and on site quality control will be given and discussed. | 2 | 1 (Autumn 2022) | ||||||||||||||||||||
11 | Institute of Civil Engineering | Civil Engineering | Information technologies for the development of territories | 1. BIM technologies have become an integral part of computer-aided design in the construction industry. Knowledge of the principles of parametric modeling in construction and the possession of basic skills in computer-aided design systems provides the student with a significant competitive advantage in the labor market. 2. The purpose of the discipline is to obtain basic skills for designing areal and linear objects, as well as preparing territory plans and designing land management objects using Autodesk Civil 3D, hybrid software that includes GIS elements and CAD graphics. 3. In the process of studying the discipline, the student receives the following knowledge, skills and experience: 4. Understanding what is Civil 3D, based on current knowledge, the scope of the program 5. Understanding how Civil 3D works, the organization of working environments, setting up the interface, the object model 6. Creation of digital elevation models, preparation of plans based on them and vertical planning of the territory 7. Creation of elements of land management on the basis of geodetic data. | 2 | 1 (Autumn 2022) | ||||||||||||||||||||
12 | Institute of Civil Engineering | Civil Engineering | Introductory practice [practical training] | Practical training can be carried out at the organizations and enterprises of various business organizations and also within the structural units of the FSAEI HE “SPbPU”. The specific assignment for practical training is formalized in a SPbPU order. Practical training might be carried at an assigned site or on a visiting basis. The specific type of holding practical training foreseen by the degree program developed on the basis of the SEBO SPbPU are established by the University with consideration of the SEBO SPbPU requirements. The students, who study alongside employment, may take the practical training at the place of employment if their work activities correspond with the content of the practical training. | 6 | 1 (Autumn 2022) | ||||||||||||||||||||
13 | Institute of Civil Engineering | Civil Engineering | Scientific and research work of master in semester [practical training] | The concept of science and the classification of sciences. Problems of science. Elements of science. Classification of the sciences. Management in the field of science. Academic degrees and academic titles. Forms of scientific and scientific-pedagogical personnel in Russia. Types of papers. Classification research. Stages of research. Choice of research topics. Concepts of the method and the methodology of scientific research. Scientific methods of research. Basic methods of scientific investigation. The methodology of scientific research. Determine the techniques and methods of scientific research. Group of scientific methods. Planning research. The work programs of research. An object of the study. The aims and objectives of the study. The main sources of scientific information. Types of educational and scientific publications. Information and reference publications. Work with literature. Internet resources (search portals, information and educational portals, digital libraries, patent databases). Searching for information on the subject of research on the internet portals. Searching for information in foreign languages. The structure of the teaching and research work. Contents. UDC. SRSTI. How to write text. The language and style of speech. Graphical method of presenting illustrations. Making bibliographic apparatus. References. Requirements for printing manuscripts. Reporting on the research work, presentations, essays, reports, term papers and dissertations. | 7 / 7 / 7 | 1 (Autumn 2022) / 2 (Spring 2023) / 3 (Autumn 2023) | ||||||||||||||||||||
14 | Institute of Civil Engineering | Civil Engineering | Project Management for Industrial and Civil Engineering [elective course] | 1. Introduction to Project Management and the Project Cycle. 2. Organizational Structure and the Role of the Project Manager. 3. Project Phases. Project Management Process Groups. 4. Organizational Influences on Project Management. 5. Project Scope. Project Requirements. Project Breakdown Structure. 6. Project Communications. Project Schedule. 7. Budgeting and Cost Control. Project Quality. 8. Project Human Resources. Project Reporting and Management. Project Risks. Project Procurements | 4 | 3 (Autumn 2022) | ||||||||||||||||||||
15 | Institute of Civil Engineering | Civil Engineering | Project management for road construction [elective course] | The purpose is to study the theoretical foundations of the use of modern technologies in solving problems of project management in road activities, as well as the theory and practice of organizing, planning and managing road activities. | 4 | 3 (Autumn 2022) | ||||||||||||||||||||
16 | Institute of Civil Engineering | Civil Engineering | International Communication in Construction Business | 1. Сonstruction contracts. Types of construction contracts. Concession contracts. Standard contracts of international organizations. FIDIC contracts. The structure of the construction contract. Documentation of the construction contract. Correspondence on the construction contract. Reporting on the construction contract. 2. Construction risks. Risk management. 3. The quality of construction work. Quality management. System of quality management. 4. International competitive bidding. Regulations and documents of international competitive bidding. Preparation of tender documentation. 5. Occupational health and safety. Safety management system. 6. Environmental aspects of construction projects. Key documents on environmental protection. 7. Management of construction. The structure of the building project. The implementation of the construction project. | 3 | 3 (Autumn 2022) | ||||||||||||||||||||
17 | Institute of Civil Engineering | Civil Engineering | Business-Planning for Construction | The course includes development of the plan of activity of the construction company containing: ‒ description of a kind of activity; ‒ the nomenclature of the made production, works and services; ‒ definition of a target segment; ‒ resources to which the company has; ‒ personnel of the company; ‒ organizational control system; ‒ financing and crediting. Options of implementation of the project with an assessment of chances of the company of success are developed. | 2 | 3 (Autumn 2022) | ||||||||||||||||||||
18 | Institute of Civil Engineering | Civil Engineering | Reliability of Building Structures | Limit state design and classification. Characteristic and design strengths and load. Limit state groups. Reinforced concrete beams and slabs. Shear reinforcement. Inclined steel bars and stirrups. Redistribution of the bending moments at formation of plastic hinges. Prestressed reinforced concrete. Prestressed cover beams and undercrane beams. Design of nuclear power plans containment, concrete tanks and silos. Crack resistance and the disclosure of cracks in concrete. Masonry, brickwork and blockwork. The main properties of stones and mortar. Limit state design. | 3 | 3 (Autumn 2022) | ||||||||||||||||||||
19 | Institute of Civil Engineering | Civil Engineering | Special course on building materials | The course includes an in-depth introduction to geosynthetics materials, their description and application in civil engineering. Classification and definitions, raw materials and manufacturing processes for different types of geosynthetics will be presented. These types include geotextiles, geogrids, geonets, geomembranes, geocells, geocomposites, etc. History of geosynthetics will be explored. The latest developments and important innovations, various economic and the others aspects of production and application of geosynthetics will be emphasized.Basic functions of geosynthetics such as reinforcement, separation, filtration, drainage, erosion will be analyzed. Application areas of geosynthetics include retaining walls, embankments, foundations, roads, slopes, erosion control, landfills, earth dams, tunnels, hydraulic applications, etc. will be presented. Properties of geosynthetics, their characterization and basic characteristics including physical properties, mechanical properties,hydraulic, endurance and degradation properties will be analyzed and compared to other building materials. Durability of geosynthetics, causes and mechanisms of degradation including mechanical damage during installation, creep, resistance to weathering, chemical and biological degradation will be analyzed and discussed. Design principles, concepts and methodologies of geosynthetics combined with material properties requirements including safety factors, service life, and long-term strength will be presented and debated. Geosynthetics standards, quality assurance for geosynthetics and manufacturing and on site quality control will be given and discussed. | 2 | 3 (Autumn 2022) | ||||||||||||||||||||
20 | Institute of Civil Engineering | Civil Engineering | Educational Foresight | The course consists of 2 parts. The first part consists of lectures and a test on them and located on the Central server of SPbPU. The second part is a self-taught online course from the list established by the head of educational program. Most of the courses are available on the Open Education portal. | 5 | 3 (Autumn 2022) | ||||||||||||||||||||
21 | Institute of Civil Engineering | Civil Engineering | Career Adaptability | Allows to set-off the learning outcomes obtained in the framework of academic mobility and/or in other organizations, etc. | 5 | 3 (Autumn 2022) | ||||||||||||||||||||
22 | Institute of Civil Engineering | Civil Engineering | Real estate economics | Bases of the real estate management: concept of the real property, signs of the real estate, markets of the real estate, issues relating to land use, including wider social issues such as the impact and sustainability of new build. Budget of property objects: structure of profits and incomes, concept of rent and rent contract, financial assets, composition and structure of operational expenses, reversion. Tax system: various forms of taxation in relation to property investment and development, income tax, profit tax, capital gains tax, depreciation allowances, land tax, water tax. Operational and tactical: primary foundations of real estate management, structure of real estate model, operational and tactical management levels. Property finance sources and types of property finance: debt equity, financing techniques, evaluation techniques, risk management. Property valuation: aims and tasks of valuation, principles, methods and technologies of valuation, valuation of machines and equipment, valuation of buildings and constructions, valuation of non-material assets and intellectual property, the best and more effective utilization property analysis. | 2 | 2 (Spring 2023) | ||||||||||||||||||||
23 | Institute of Civil Engineering | Civil Engineering | Project Management for Construction | 1. Сonstruction contracts. Types of construction contracts. Concession contracts. Standard contracts of international organizations. FIDIC contracts. The structure of the construction contract. Documentation of the construction contract. Correspondence on the construction contract. Reporting on the construction contract. 2. Construction risks. Risk management. 3. The quality of construction work. Quality management. System of quality management. 4. International competitive bidding. Regulations and documents of international competitive bidding. Preparation of tender documentation. 5. Occupational health and safety. Safety management system. 6. Environmental aspects of construction projects. Key documents on environmental protection. 7. Management of construction. The structure of the building project. The implementation of the construction project. | 2 | 2 (Spring 2023) | ||||||||||||||||||||
24 | Institute of Civil Engineering | Civil Engineering | Building engineering systems BIM | Design of ventilation and air conditioning systems. Creating and maintaining a microclimate comfortable for humans, plants, animals or material objects (equipment, works of art, etc.) within a building or structure; saving energy spent on creating and maintaining a microclimate. | 2 | 2 (Spring 2023) | ||||||||||||||||||||
25 | Institute of Civil Engineering | Civil Engineering | Designing energy-efficient buildings | Formation of knowledge on regulatory and guidance documents on energy saving, theoretical foundations and principles of rational use of energy resources in Russia and in the world, means and methods of energy conservation in civil construction. - Energy consumption in the residential sector. Heat losses of buildings. - Types and classification of environmentally friendly building materials. - Determination of the energy efficiency class of buildings. - Economic and environmental aspects of energy efficiency, etc. | 2 | 2 (Spring 2023) | ||||||||||||||||||||
26 | Institute of Civil Engineering | Civil Engineering | GIS technologies for construction | 1. Introduction to GIS. Basic concepts. Socioeconomic challenges. Users of GIS. Understand what GIS is, what it can do, and how others are using it. 2. Introduction to ArcGIS software. Introduction to GIS and model design. Introducing ArcCatalog. Viewing data in ArcCatalog. Connecting to your data. Introducing ArcMap. Working with maps. Exploring a map. Adding a layer to a map. Adding features from a database. Changing the way features are drawn. Adding labels to a map. Working with the map layout. Saving a map. Printing a map. 3. Exploring GIS data. Vector data model. Raster data models. Vector versus raster models. Formats of feature data. 4. Conducting a GIS project. Phases of organization issues. Development of business concept and the identification of goals. Identification of users requirements. The steps in a GIS project. Planning your project. Assembling the database. Preparing data for analysis. Performing the analysis. Presenting the results. 5. Introduction to River Basin Modelling. Introduction to the MIKE BASIN modelling framework. Operational framework and water user allocation rules. Reservoir operating rules and hydropower modeling. Groundwater and river routing modeling. Detailed irrigation demand and management analysis. Hydrological modeling. | 2 | 2 (Spring 2023) | ||||||||||||||||||||
27 | Institute of Civil Engineering | Civil Engineering | Substantiation of parameters and design of power facilities [elective course] | The course includes priority technical aspects of the energy efficiency of buildings and structures: Improving energy efficiency in engineering systems of the individual and the public buildings, including electrical networks, heating networks, air-conditioning systems, of water supply and canalization. Using renewable energy sources for independent electricity and heat supplying, including solar photovoltaic modules, solar collectors, heat pumps and wind turbines. In practice students makes a project of energy efficiency building, using independent renewable energy sources. | 5 | 2 (Spring 2023) | ||||||||||||||||||||
28 | Institute of Civil Engineering | Civil Engineering | Energy efficient building materials [elective course] | The course considers the modern construction technologies and materials: - Regulatory and technical regulation in the field of energy conservation and energy efficiency. - Properties and types of energy-efficient building materials. Options for insulation of enclosing building structures. - Energy efficiency of buildings and structures. - Methods for improving the energy efficiency of buildings. - Thermal insulation of buildings, etc. | 5 | 2 (Spring 2023) | ||||||||||||||||||||
29 | Institute of Civil Engineering | Civil Engineering | Russian as a foreign language [optional course] | Fundamentals of vocabulary and grammar of the Russian language | 1 | 2 (Spring 2023) | ||||||||||||||||||||
30 | Institute of Civil Engineering | Civil Engineering | Water Supply and Water Efficiency [optional course] | Raw water resources. Water contaminants and potable water quality regulations. Water supply systems: types and components. Drinking water treatment plant: components and processes. Equipment and constructions on pipelines. Waste waters: types and contaminants. Sewerage systems: types and components. Peculiarities of sewage and rainfall pipelines. Waste water treatment plant: components and processes. | 2 | 2 (Spring 2023) | ||||||||||||||||||||
31 | Institute of Civil Engineering | Civil Engineering | Project practice [practical training] | Practical training is held at organizations or enterprises which the FSAEI HE “SPbPU” has signed agreements with on holding practical training for students. The goal of the on-the-job training is acquiring experience of practical work, including independent activity at an enterprise (organization), and competences in the areas and(or) spheres of professional activities. The task of the practical training is the formation of competencies through which the student: determines the parameters of numerical analysis for the production of works connected to calculated justification of design and monitoring of load-bearing constructions of buildings and structures; сarries out the coordination of the project, working documentation, defense of the project decisions in the coordinating and expert instances, drawing up the acts of acceptance-transfer of the project, working documentation for the capital construction object (construction, reconstruction, major repairs); сonducts a technical and economic analysis of the results of measures connected to the improvement of the efficiency of production and economic activity at the capital construction object; presents publicly the results of the project (or its individual stages) in the form of reports, articles, speeches at research and scientific seminars and conferences. Specific tasks are set by the curators of practical training from the university and from the enterprise with taking into account of the specifics of production. | 6 | 4 (Spring 2023) | ||||||||||||||||||||
32 | Institute of Civil Engineering | Civil Engineering | Pre-diploma practice [practical training] | 9 | 4 (Spring 2023) | |||||||||||||||||||||
33 | Institute of Civil Engineering | Civil Engineering | Scientific and Research Work | The concept of science and the classification of sciences. Problems of science. Elements of science. The concept of science and the classification of sciences. Problems of science. Elements of science. Classification of the sciences. Management in the field of science. Academic degrees and academic titles. Forms of scientific and scientific-pedagogical personnel in Russia. Types of papers. Classification research. Stages of research. Choice of research topics. Concepts of the method and the methodology of scientific research. Scientific methods of research. Basic methods of scientific investigation. The methodology of scientific research. Determine the techniques and methods of scientific research. Group of scientific methods. Planning research. The work programs of research. An object of the study. The aims and objectives of the study. The main sources of scientific information. Types of educational and scientific publications. Information and reference publications. Work with literature. Internet resources (search portals, information and educational portals, digital libraries, patent databases). | 12 | 4 (Spring 2023) | ||||||||||||||||||||
34 | Institute of Energy | Power Plant Engineering | Numerical Methods in Heat and Mass Transfer (part I) | The first part of the course is theoretical, covers the following chapters: 1. Introduction to numerical modeling for heat and mass transfer process description. 2. The main equations of convective heat and mass transfer: Integral conservation equations. Differential conservation equations. The dimensionless form of writing equations and basic criteria similarities in heat and mass transfer theory. 3. Fundamentals of the numerical method for solving the Navier-Stokes equations: The main components of the numerical method. Spatial sampling methods. Sampling schemes. Methods for solving the Navier-Stokes equations. Ways to accelerate convergence. 4. Methods for solving systems of algebraic equations. 5. Setting the boundary conditions: Theoretical foundations of setting boundary conditions. Implementation of boundary conditions. 6. Turbulence modeling: Theoretical Foundations of Turbulence Modeling. Turbulence Models. Alternative turbulence modeling approaches. | 4 | Autumn 2022 | ||||||||||||||||||||
35 | Institute of Energy | Power Plant Engineering | Numerical Methods in Heat and Mass Transfer (part II) | The second part of the course is practical training, consists of practical works: Task #1 Numerical simulation of steady flow in a circular pipe. Task #2 Numerical simulation of transient laminar flow around a cylinder (Von Karman vortex street). Task #3 Numerical simulation of turbulent flow and heat transfer in a tube bank. Task #4 Natural convection in a square cavity. Task #5 Turbulent flow around an airfoil. Task #6 Turbulent flow in an asymmetric diffuser | 3 | Spring 2023 | ||||||||||||||||||||
36 | Institute of Energy | Power Plant Engineering | Renewable Energy | This is an engineering introduction to renewable energy technologies and potentials. The course is aimed at introduction students to the basic concepts of renewable energy. Students will learn about state-of-the-art in renewable energy applications including biomass gasification for heat, electric power, liquid fuels, and bio-SNG as well as wind energy, solar energy, and hydropower. Status of renewable energy in different countries will be outlined. For understanding perspectives of renewable energy in any country renewable energy policy will be discussed within the course. | 4 | Autumn 2022 | ||||||||||||||||||||
37 | Institute of Energy | Power Plant Engineering | Steam and Gas Turbines | Convergent and divergent flows in turbomachines. Kinematic schemes of turbomachines. Power interaction between the stream and the blade ring. Kinematic and thermodynamic characteristics of the flow in turbomachines. Choice of the optimum peripheral speed of turbomachine stage. Basic principles of design of turbomachinery blading along the radius. The loss of kinetic energy in the flowing parts of turbomachines. Characteristics of radial and radial-axial wheels. The influence of rotor speed on the characteristics turbine stage. Basic principles of steam turbines design. Gas turbines. | 4 | Autumn 2022 | ||||||||||||||||||||
38 | Institute of Energy | Power Plant Engineering | Combined Cycle Power Plants | History of combined cycle technology. Basics of thermodynamics: steam cycle, gas cycle and combined cycle. Gas turbine plant, steam plant, combined cycle power plant. Combined cycle power plant: main equipment, flow diagram, available parameters, implementation. Gas and steam turbines for combined cycle power plants, waste-heat recovery boilers. Basic equations for manual and computer calculations. Indicators of Overall and Thermal Efficiency of Combined Cycle Power Plant. Major benefits of Combined Cycle Power Plant, its perspectives for world energy sector. | 5 | Autumn 2022 | ||||||||||||||||||||
39 | Institute of Energy | Power Plant Engineering | Operating Modes of Thermal Power Plants | Classification of heat end electric energy sources. Seasonal and all-year-round heat loads. Transportation of heat energy. Elementary schemes of thermal and electric energy. Heat supply, heating systems, cogeneration. Technological scheme of a thermal power plant. General plan of a power station. Thermodynamic cycles of steam turbines and gas turbines. Rankine Cycle. Joule - Brayton cycle. The layout of the main building of a power station (block layout, crosslinked layout). Boiler room. Steam boilers. Water boilers. Technical and economic parameters of boilers. Turbines. Classification of steam turbines. Thermal scheme of a steam turbine. The system of regenerative heating of feedwater. The condensing unit. Ventilation-nutritive installation. Fuel supply to thermal power plants and nuclear power plants. Ash removal system. TPP technical water supply system. Technical and economic indicators of TPP. Water treatment modules of TPP. Pre-treatment of raw water. Coagulation of raw water. The methods softening of additional and feed water. Thermal deaeration. Thermal scheme of a steam turbine plant with a turbine-type T. Thermal scheme of a steam turbine plant with a turbine-type TP. Thermal scheme of a CCGT block. Example of calculating of the steam turbine thermal scheme. Example of calculation of a group of high-pressure heaters. Example of calculation of deaerating - feeding unit. Example of calculation of the group of low-pressure heaters | 3 | Autumn 2022 | ||||||||||||||||||||
40 | Institute of Energy | Power Plant Engineering | Logistics in Energy | Economic analysis. Types of analysis and methodology: Types of economic analysis and classification. The methodology of the analysis. Analysis of financial conditions: Assessment of financial conditions. Analysis of economic and production results: Analysis of the implementation of the financial plan. Analysis of production volumes. Analysis of the status and use of fixed and working capital: Analysis of the status and use of basic production means. Analysis of the use of material resources, their condition and stocks. Analysis of the use of labor resources. Cost analysis for the production and sale of products: Cost analysis of energy enterprises. Analysis and assessment of the effectiveness of the enterprise: Profit generation and analysis. Analysis of the influence of external and internal factors on enterprise performance. | 2 | Autumn 2022 | ||||||||||||||||||||
41 | Institute of Energy | Power Plant Engineering | Network Problems and Electrical Systems | High voltage transmission lines series and shunt compensation. Equations of power transmission lines. Loss-less line. Schematic diagram of power transmission line taking into account its wave properties. No load and surge impedance load modes of power transmission line. The effect of shunt and series compensation on transmission line characteristics. Static VAR systems. Construction, types and efficiency of static VAR systems application. The effect of static VAR systems on power systems stability. Transmission lines’ controllable and uncontrollable series compensation. Construction, types and efficiency of transmission lines’ series compensation. The issues of series compensation application. VSC-based compensators. Static compensators (STATCOM), their construction and different control strategies. High voltage cable lines application issues. Transmission capacity of power cable lines. Screen grounding of XLPE cables. Reactive power compensation of power cable lines. SF6 high voltage circuit breakers application issues. Types of circuit breakers. Specific conditions of their operation in schemes with transmission lines compensated by shunt reactors. System blackouts. Examples of blackouts. Investigation of triggering events. Prevention of system blackouts. | 3 | Autumn 2022 | ||||||||||||||||||||
42 | Institute of Energy | Power Plant Engineering | Investment Management | Innovations. Company with main actors of its activities (customers, suppliers, top management, resources). Company and its stockholders. Universal production process. Peculiarities of Japanese mentality in comparison with European or US (on example of Global competition in Quality). Role of investment management. Decision-making as the most important way to provide proper running of processes. Hints from ISO 9000 series. | 3 | Autumn 2022 | ||||||||||||||||||||
43 | Institute of Energy | Power Plant Engineering | Energy Economics | Industrial enterprise planning system. Operations strategy and its linkage with corporate and business strategy. Operations strategy development. Manufacturing strategies/Product positioning strategies. Sales & Operations planning (S&OP process structure, planning parameters, Resource Requirements Planning – RRP). Manufacturing planning and scheduling (MPS, MRP, RCCP, CRP), Production Activity Control (functions; manufacturing reporting, count points, data collection). Productivity systems and Quality Management Systems (Lean/ JIT), 6 Sigma, Theory of Constraints, QFD, TQM). | 3 | Autumn 2022 | ||||||||||||||||||||
44 | Institute of Energy | Power Plant Engineering | High Voltage Technologies | Basics in physics of HV discharge in gases. Electric strength and breakdown in solid dielectrics. Construction of internal insulation of high voltage equipment. Overvoltages in electric grids and limiting methods. High voltage testing and measuring. | 2 | Autumn 2022 | ||||||||||||||||||||
45 | Institute of Energy | Power Plant Engineering | Mathematical Physics | Formulation of problems in mathematical physics. Fourier method. Special functions and their applications. Mathematical physics problems with the continuous spectrum. | 3 | Autumn 2022 | ||||||||||||||||||||
46 | Institute of Energy | Power Plant Engineering | Information Resources in Scientific Research | SPbPU Public Library. Bibliographic, reference and full-text databases. Search algorithms. Copyright for intellectual property. Bibliographic references standards. Analytic and synthetic processing of scientific documents | 2 | Autumn 2022 | ||||||||||||||||||||
47 | Institute of Energy | Power Plant Engineering | History and Methodology of Science | This course includes the brief overview of the history of power engineering from Ancient times to the present. History of development of major energy cycles, machines and transport units: gas and steam turbines and its cycles; steam boilers; engines; steam locomotive, aircraft, steamship; the first power plant; technology of combustion and gasification of solid fuels, etc. | 3 | Autumn 2022 | ||||||||||||||||||||
48 | Institute of Energy | Power Plant Engineering | Scientific Discourse | Scientific discourse as a subject of methodological analysis. Scientific problem and goals of scientific research. Methodology pf scientific research. Scientific hypothesis and scientific theories. Methodology of experimental research. Natural, artificial and exploratory (heuristic) experiments. Modeling as a general method of experimental and theoretical studies. Evaluation of adequacy of theoretical and experimental research. Specifics of testing scientific experiments, scientific hypotheses and theories. Analysis and presentation of results of scientific research, their public approbation. Efficiency and usage (implementation) of results of scientific research. Organization and planning of scientific experiments. Preparation and attestation of scientific staff. Prospects of scientific development. | 3 | Autumn 2022 | ||||||||||||||||||||
49 | Institute of Energy | Power Plant Engineering | Thermal Power Plants | Modern power plants, co-generation, small scale CHP, gasifiers, co-firing, stirling, improving efficiency; energy performance of solid fuel thermal power plants; initial and final steam parameters, intermediate superheating; regenerative feedwater heating; balances of steam and water and ways to replenish them; release of process steam at the CHPP, the release of heat to heating; deaeration and feeding equipment; energy characteristics of equipment; compilation and methodology for calculating principal thermal schemes of solid fuel thermal power plants; selection of main and auxiliary equipment; detailed thermal scheme and pipelines of power plants; layout of the main building of the power plant; technical water supply; fuel economy of power plants. | 3 | Spring 2023 | ||||||||||||||||||||
50 | Institute of Energy | Power Plant Engineering | Power Sypply Systems for Enterprises | Fuel and energy resources. Fuel and energy balance of the enterprises. Fuel resources. Classification of fuel resources. Conditional fuel. Extraction, processing, transportation, storage and fuel consumption. Fuel gas. Liquid hydrocarbon fuel. Solid fuel. Electric power. Unified energy system. Electric consumers. Consume electricity. Heat energy. Systems of heat supply. Heat carriers. Heat and heat transfer media consumption. Water supply and water disposal. Water supply systems. Water treatment and water consumption. Reverse systems. Water disposal systems. Compressed air, compressed and liquefied gases. Production of compressed and liquefied gases. Gas mixture separation plants. Storage, transportation and consumption of gases. | 2 | Spring 2023 | ||||||||||||||||||||
51 | Institute of Energy | Power Plant Engineering | Modeling of Vaporization Processes | Main two-phase flow parameters for description of steam generation. Empirical formulas and basic models for pool boiling. Heat transfer by forced flow boiling. Deterioration of heat transfer at dryout. Computer programs for the best estimation of thermohydraulics in the power equipment flow circuits. | 2 | Spring 2023 | ||||||||||||||||||||
52 | Institute of Energy | Power Plant Engineering | Turbine-Driven Compressors | The course gives the picture of turbine-driven compressors design and operation modes. The aim of the course is - to introduce the general principles of turbine driven compressors, - to teach the basic calculations and basic methods of equipment selection, - to introduce modern usage of turbocompressors systems and their role in energy sector. | 4 | Spring 2023 | ||||||||||||||||||||
53 | Institute of Energy | Power Plant Engineering | Thermal Hydraulics | Heat exchanger classification. Heat exchanger design methods. Overall heat transfer coefficient. The log mean temperature difference method. Heat exchanger pressure drop. Analysis of extended surfaces. Thermal and hydraulic calculations of heat exchangers of compressor units (practical calculations performed by students). | 2 | Spring 2023 | ||||||||||||||||||||
54 | Institute of Energy | Electrical Engineering | Theoretical Basis of Electrical Engineering, Additional Chapters | Theoretical introduction: Maxwell's equations as the basis of computational models. Material equations of different degrees of complexity. Concept of potential, scalar and vector potentials, existence conditions. Particular systems of the Maxwell equation, field formulations. Discretization in space and in time. Numerical simulation workflow of a standard engineering problem. QuickField fundamentals: Understanding of field formulation and model classes. Drawing the model geometry; geometric primitives. Setting up the boundary condition and material properties. Triangulation, control of mesh density. Review and analyzing the solution: control the field picture, extraction of the local and integral field quantities. Electrostatics: Plane capacitor: an idealized and more elaborated model. Calculation of average and maximal electric field, field energy and capacitance. Using symmetry by means of boundary condition. Multiple conductors, capacitance matrix (individual homework offered). Microstrip: Calculation of characteristic impedance and propagation velocity of a microstrip by means of electrostatic analysis. Comparison with professional microwave engineering software (individual homework offered). Magnetostatics: Applicable Maxwell equations, magnetic shielding (externally applied magnetic field). Simulation of a permanent magnet (single magnet, Hallbach array). Magnetic field created by a current. Transformer: no-load test, short-circuit test, extraction of short-circuit impedance. AC Magnetics: Solid and stranded conductors. Externally applied uniform and rotation field. Skin and proximity effects. Coupling of electric circuit equations with Maxwell equations. Taking into account of magnetic saturation. Magnetic shielding in AC conditions. Transient analysis: discretization in time, control of a time step.Transient electric field, transient thermal analysis. Initial conditions. Extracting engineering data from a time trend. Two wires power line: Complex analysis of a simple object including electrostatic, magnetostatic and AC-magnetic analysis. Different approaches of extracting equivalent circuit parameters (the examination assignment. Underground cable power line: AC losses due to skin and proximity effects. Coupling of electromagnetic and thermal analysis. Understanding of a heat transfer in solids. Boundary conditions for EM and HT analysis, review of assumptions and simplifications (course project offered). | 4 | Autumn 2022 | ||||||||||||||||||||
55 | Institute of Energy | Electrical Engineering | Electrical Systems and Power Transmission (Part I) | Lections cover general terms of power systems. Basic concept of power system stability is given. Fundamental terms of short-circuit currents calculations are introduced. Temporary and surge overvoltages, reactive power compensation means and high voltage cable lines application issues are also considered. The course also covers load flow analysis methods, synchronous machines’ excitation systems and automatic voltage regulators principles of operation and root causes of power system blackouts. | 2 | Autumn 2022 | ||||||||||||||||||||
56 | Institute of Energy | Electrical Engineering | Computer-aided Technologies in Electrical Power Engineering (Part I) | Differential equations of physical fields of high voltage electrical equipment. Computer finite element models of high-voltage voltage divider. Computer finite element models of nonlinear surge arresters (arrester) | 2 | Autumn 2022 | ||||||||||||||||||||
57 | Institute of Energy | Electrical Engineering | Contemporary Problems of Electric Power Engineering and Electrical Engineering | High voltage transmission lines series and shunt compensation. Equations of power transmission lines. Lossless line. Schematic diagram of power transmission line taking into account its wave properties. No load and surge impedance load modes of power transmission line. The effect of shunt and series compensation on transmission line characteristics. Static VAR systems. Construction, types and efficiency of static VAR systems application. The effect of static VAR systems on power systems stability. Transmission lines’ controllable and uncontrollable series compensation. Construction, types and efficiency of transmission lines’ series compensation. The issues of series compensation application. VSC-based compensators. Static compensators (STATCOM), their construction and different control strategies. High voltage cable lines application issues.Transmission capacity of power cable lines. Screen grounding of XLPE cables. Reactive power compensation of power cable lines. SF6 high voltage circuit breakers application issues. Types of circuit breakers. Specific conditions of their operation in schemes with transmission lines compensated by shunt reactors. System blackouts. Examples of blackouts. Investigation of triggering events. Prevention of system blackouts. | 4 | Autumn 2022 | ||||||||||||||||||||
58 | Institute of Energy | Electrical Engineering | High Voltage Technologies | Basics in physics of HV discharge in gases. Electric strength and breakdown in solid dielectrics. Construction of internal insulation of high voltage equipment. Overvoltages in electric grids and limiting methods. High voltage testing and measuring. | 2 | Autumn 2022 | ||||||||||||||||||||
59 | Institute of Energy | Electrical Engineering | Information Resources in Scientific Research | SPbPU Public Library. Bibliographic, reference and full-text databases. Search algorithms. Copyright for intellectual property. Bibliographic references standards. Analytic and synthetic processing of scientific documents | 2 | Autumn 2022 | ||||||||||||||||||||
60 | Institute of Energy | Electrical Engineering | Automation of Electrical Substations | Symmetrical components. Theory of protection. Voltage instrument transformers. Current instrument transformers. Overcurrent relays. Distance protection. Differential protection. Transformer protection. Generator protection | 2 | Autumn 2022 | ||||||||||||||||||||
61 | Institute of Energy | Electrical Engineering | Modern Equipment of High Voltage Electrical Substations | The main challenges of creating powerful DC switches. The physics of the DC arc. Domestic and foreign powerful electric equipment, serially produced by industry. Combined powerful electrical devices using semiconductors. Includes performing a practical individual task and making a report on calculating the parameters of a combined switch. Powerful DC multi-use switches. Powerful single-action defenses. Electric devices developed for the international thermonuclear experimental reactor ITER. | 3 | Autumn 2022 | ||||||||||||||||||||
62 | Institute of Energy | Electrical Engineering | Foundations of Overhead Line Design | The main elements of the overhead lines (OHL). Conductor types. Power losses on the conductor. Corona phenomena. Electrical clearances. Insulators. Definitions of mechanical design of OHL. Conductor loads. Curve of the OHL conductor. OHL conductor calculation. Verification of supports and selection of insulators | 2 | Autumn 2022 | ||||||||||||||||||||
63 | Institute of Energy | Electrical Engineering | Energy Economics | Industrial enterprise planning system. Operations strategy and its linkage with corporate and business strategy. Operations strategy development. Manufacturing strategies/Product positioning strategies. Sales & Operations planning (S&OP process structure, planning parameters, Resource Requirements Planning – RRP). Manufacturing planning and scheduling (MPS, MRP, RCCP, CRP), Production Activity Control (functions; manufacturing reporting, count points, data collection). Productivity systems and Quality Management Systems (Lean/ JIT), 6 Sigma, Theory of Constraints, QFD, TQM). | 3 | Autumn 2022 | ||||||||||||||||||||
64 | Institute of Energy | Electrical Engineering | Designing of High Voltage Insulation (Part II) | Partial discharge. Calculation and practical measurement of partial discharge characteristics in high-voltage electrical insulation structures. Interpretation of measurement results. Methods for calculating the permissible operating electric field strength based on the results of accelerated resource tests | 3 | Autumn 2022 | ||||||||||||||||||||
65 | Institute of Energy | Electrical Engineering | Business Planning and Efficiency Evaluation of Innovative Projects | Within this course, students will obtain: Knowledge of terms, definitions, formulations and processes. Highlights of the history of quality management in the development of productive forces in the world. Control of the quality of a single product, selective quality control, quality management systems, total quality management (TQM). The study of the section develops knowledge, skills and abilities in analyzing, classifying and describing concepts of quality management and innovative management. Knowledge of how to organize the processes of group development of management decisions to improve management systems. The ability to analyze primary information in the organization's processes, provide integrated information of the system of innovative management for management decisions, organize group work to identify, structure and eliminate problems. Knowledge of the specifics of applying international ISO 9000 series standards on quality management systems. Possession of the basic methods of group decision-making. Ability to organize group work to identify, structure and fix problems. Possession of a methodology for evaluating and improving the quality of operations. | 2 | Autumn 2022 | ||||||||||||||||||||
66 | Institute of Energy | Electrical Engineering | Modeling of Electric Power and Electrical Engineering Objects | 1. Application of the Matlab software package in solving mathematical problems of electrical engineering and electric power industry. Solutions of equations for steady modes of electric circuits of alternating current. 2. Application of the Matlab software package in solving mathematical problems of electrical engineering and electric power industry. Graphic methods for solving electrical problems. 3. Application of the Matlab package in solving mathematical problems of electrical engineering and electric power industry. Analytical approximation of experimental data. 4. Application of the Matlab package in solving mathematical problems of electrical engineering and electric power industry. Integration and Solution of differential equations in problems of electrical engineering. 5. Application of the Matlab package in solving mathematical problems of electrical engineering and electric power industry. Visual Simulink simulation. Main blocks and operations. 6. Application of the Matlab package in solving mathematical problems of electrical engineering and electric power industry. Visual Simulink simulation. The solution of differential equations for electromechanical processes. 7. Application of the Matlab package in solving mathematical problems of electrical engineering and electric power industry. Visual Simulink simulation. Powersys package for calculation of electric power and electrical circuits. 8. Application of the Matlab package in solving mathematical problems of electrical engineering and electric power industry. Visual Simulink simulation. Powersys package. Surge protection calculations for electric substations. | 5 | Autumn 2022 | ||||||||||||||||||||
67 | Institute of Energy | Electrical Engineering | Technical Superconductivity | Properties of the materials at low temperatures. Superconductivity and superconductors. Classical electrodynamics and thermodynamics of superconductors. Surface energy of superconductors. Superconductors of the 1st and 2nd types. Main properties of the 2nd type superconductors. Second type superconductors in the current state. Resistance of the ideal 2nd type superconductors. Pinning. Critical state theory of the hard superconductors. Penetration of the magnetic field into hard superconductors. Adiabatic and dynamic stability of the hard superconductors. Power losses in composite superconductors. High temperature superconductors. Protection of superconducting devices. Training. Industrial application of the superconductivity. | 4 | Spring 2023 | ||||||||||||||||||||
68 | Institute of Energy | Electrical Engineering | Human Resources Management | Development of the HR management system. Goals, functions and organizational structure of the HR management system. Corporate HR policies. HR planning. Recruiting and hiring technologies. Professional orientation and labor adaptation of personnel. Teaching and development of personnel. Attestation and business evaluation of personnel. | 4 | Spring 2023 | ||||||||||||||||||||
69 | Institute of Energy | Electrical Engineering | Electrical Systems and Power Transmission (Part II) | Lections cover general terms of power systems. Basic concept of power system stability is given. Fundamental terms of short-circuit currents calculations are introduced. Temporary and surge overvoltages, reactive power compensation means and high voltage cable lines application issues are also considered. The course also covers load flow analysis methods, synchronous machines’ excitation systems and automatic voltage regulators principles of operation and root causes of power system blackouts. | 3 | Spring 2023 | ||||||||||||||||||||
70 | Institute of Energy | Electrical Engineering | Electrical Power Systems | General terms of power systems. Basic concept of power system stability. Fundamental terms of short-circuit currents calculations. Temporary and surge overvoltages, reactive power compensation means. Load flow analysis methods. Synchronous machines’ excitation systems and automatic voltage regulators principles of operation. Root causes of power system blackouts. | 6 | Spring 2023 | ||||||||||||||||||||
71 | Institute of Energy | Electrical Engineering | Computer-aided Technologies in Electrical Power Engineering (Part II) | Computer finite element models of electrophysical devices of high currents and strong magnetic fields. The effect of high voltage power transmission on communication lines. Computer finite element models of modern cable power transfer. | 3 | Spring 2023 | ||||||||||||||||||||
72 | Institute of Energy | Electrical Engineering | Electromagnetic Compatibility | Electromagnetic environment. High frequency impulse fields. Lightning impulse overvoltages. Switching impulses. Low and medium frequency interferences. EMC design criteria. Protection against direct lightning strikes. Potential grounding. Screening. Overvoltage protection. Filters. EMC system planning. Zone concept. Interface definition. EMC measuring and testing technique. | 3 | Spring 2023 | ||||||||||||||||||||
73 | Institute of Energy | Electrical Engineering | Designing of High Voltage Insulation (Part I) | Conditions of the electrical insulation in use: Long-term heating during operation. Overheating of emergency and forced modes. Long time exposure to work electric stress at operating voltage. Overvoltage. Standardization. Overvoltages in high voltage installations. External overvoltage, lightning strike. Internal overvoltages, switching, ferranti-effect, overvoltages and grounding. Overvoltage protection, construction, mode of operation, calculation and design of protection. Properties of solid and liquid dielectric materials, the influence of various factors on the electrical strength of insulation. Calculation of changes in the electrical strength of the insulation when the area of the electrodes increases. | 2 | Spring 2023 | ||||||||||||||||||||
74 | Institute of Energy | Nuclear Power Engineering | Mathematical Physics | Formulation of problems in mathematical physics. Fourier method. Special functions and their applications. Mathematical physics problems with the continuous spectrum. | 2 | Autumn 2022 | ||||||||||||||||||||
75 | Institute of Energy | Nuclear Power Engineering | Nuclear Knowledge Management | Types of nuclear knowledge. Aims and problems of nuclear knowledge management. Tacit knowledge management. Explicit knowledge management. Methods of preserving nuclear knowledge. Evaluating of nuclear knowledge management. | 2 | Autumn 2022 | ||||||||||||||||||||
76 | Institute of Energy | Nuclear Power Engineering | Advanced Nuclear Reactors | Generation IV reactors. SCWR. LFR. SFR. VHTR. GFR. MSR. SMR. | 2 | Autumn 2022 | ||||||||||||||||||||
77 | Institute of Energy | Nuclear Power Engineering | NPP Steam Generators | Thermohydraulics of boiling. Separation of steam. Design of horizontal steam generators. Design of vertical steam generators. Operational issues of steam generators | 2 | Autumn 2022 | ||||||||||||||||||||
78 | Institute of Energy | Nuclear Power Engineering | Physics of Nuclear Reactors | Types of nuclear reactors. Nuclei fission process. Moderation of neutrons. Diffusion of neutrons. Fission factor calculations. | 3 | Autumn 2022 | ||||||||||||||||||||
79 | Institute of Energy | Nuclear Power Engineering | Steam and Gas Turbines | Steam turbine units. Turbine stage. Multistage turbines. Design of steam turbines. Gas turbine units. Design of steam turbines | 2 | Autumn 2022 | ||||||||||||||||||||
80 | Institute of Energy | Nuclear Power Engineering | Safety of Nuclear Sites | Principles of NPP safety. Regulations for NPP safety. NPP disasters. NPP safety during operation. Probabilistic Safety Assessment | 4 | Autumn 2022 | ||||||||||||||||||||
81 | Institute of Energy | Nuclear Power Engineering | Operation of NPP | Reliability of NPP equipment. Modes of NPP operation. Technical documentation on NPP. Maintenance on NPP. Outage on NPP | 4 | Autumn 2022 | ||||||||||||||||||||
82 | Institute of Energy | Nuclear Power Engineering | Modelling of NPP Heat Balances | Principles of NPP heat balance modelling using United Cycle software. Modes of NPP heat balances. Analyse the results of calculations | 3 | Autumn 2022 | ||||||||||||||||||||
83 | Institute of Energy | Nuclear Power Engineering | Reactor Control and Protection Systems | Control parameters of nuclear reactors. Response relationship of nuclear reactor. Design of control rods. Design of servo units. Automatically control and protection systems of nuclear reactors | 3 | Spring 2023 | ||||||||||||||||||||
84 | Institute of Energy | Nuclear Power Engineering | Kinetics of Nuclear Reactors | Dynamical characteristics of nuclear reactors. Effects on reactions coefficients. Poisoning of nuclear reactor. Breeding ratio for nuclear reactors | 2 | Spring 2023 | ||||||||||||||||||||
85 | Institute of Energy | Nuclear Power Engineering | Nuclear Power Plants | NPP heat balances. NPP nuclear reactor systems. Steam turbine systems. Water supply systems. Arrangement of NPP. | 3 | Spring 2023 | ||||||||||||||||||||
86 | Institute of Energy | Nuclear Power Engineering | Thermo-Hydraulics of Nuclear Reactors | Design of nuclear reactors. Nuclear core power density. Temperature distribution. Hydraulics resistance. Strength calculations of nuclear reactors | 2 | Spring 2023 | ||||||||||||||||||||
87 | Institute of Energy | Nuclear Power Engineering | NPP Pumps | Pumps units. Pumps characteristics. Impeller pumps. Rotary vane pumps. Pumps on NPP | 2 | Spring 2023 | ||||||||||||||||||||
88 | Institute of Energy | Nuclear Power Engineering | Modelling of Steam Generation Processes | Main two-phase flow parameters for description of steam generation. Empirical formulas and basic models for pool boiling. Heat transfer by forced flow boiling. Deterioration of heat transfer at dryout. Computer programs for the best estimation of thermohydraulics in the power equipment flow circuits. | 2 | Spring 2023 | ||||||||||||||||||||
89 | Institute of Energy | Nuclear Power Engineering | Economics of Nuclear Power Engineering | Nuclear Power Engineriing as a part of fuel and energy sector. NPP fuel. Economic efficiency of NPP. Techno-economical criteria of NPP. | 2 | Spring 2023 | ||||||||||||||||||||
90 | Institute of Energy | Nuclear Power Engineering | Numerical Methods in Heat and Mass Transfer | Navie-Stoks equation. CFD modelling. Numerical algorithm properties. Accuracy of solving. Control volumes method. | 4 | Autumn 2022 | ||||||||||||||||||||
91 | Institute of Computer Science and Technology | Information System Mathematical Software and Administration | Information System Administration (part I) | The first part of the course (fall 2022/23) covers introduction to networks and consists of the following chapters: 1. Explore a Network; 2. Configure a Network; 3. Operating System; 4. Network Protocols and Communications; 5. Network Access 5 Ethernet 6 Network Layer; 6. IP Addressing; 7. Subnetting IP Networks; 8. Transport Layer; 9. Application Layer; 10. Build a Small Network. | 4 | Autumn 2022 | ||||||||||||||||||||
92 | Institute of Computer Science and Technology | Information System Mathematical Software and Administration | Information System Administration (part II) | The second part of the course (spring 2022/23) covers routing & switching essentials and consists of the following chapters: 1. Routing Concepts; 2. Static Routing; 3. Dynamic Routing; 4. Switched Networks; 5. Switch Configuration; 6. VLANs; 7. Access Control Lists; 8. DHCP; 9. NAT for IPv4; 10. Device Discovery, Management, and Maintenance. | 4 | Spring 2023 | ||||||||||||||||||||
93 | Institute of Computer Science and Technology | Applied Informatics | Web Application Programming | The course provides an overview of different technologies that are needed to develop a so-called Internet Applications or Dynamic WEB sites. Such knowledge and skills are in great demand now, thus, about 50% of all job offers in IT industry deal with different aspects of WEB programming. Goal of the course: the course provides an overview of modern technological approaches to constructing different kinds of Internet-based information systems. The course provides an overview of different technologies that are needed to develop a so-called Internet Applications or Dynamic WEB sites. Such knowledge and skills are in great demand now, thus, about 50% of all job offers in IT industry deal with different aspects of WEB programming. Goal of the course: the course provides an overview of modern technological approaches to constructing different kinds of Internet-based information systems. | 3 | Autumn 2022 | ||||||||||||||||||||
94 | Institute of Computer Science and Technology | Development and Maintenance of a High-Quality Software Product | Software Engineering Tools. Part I | The course explores modern development environments, examples of their use, advantages and disadvantages. We study the models and tools used to solve various problems based on machine learning methods. | 2 | Autumn 2022 | ||||||||||||||||||||
95 | Institute of Computer Science and Technology | Development and Maintenance of a High-Quality Software Product | Software Engineering Tools. Part II | The course provides an overview of approaches and methods for managing the software development process and its life cycle. We study the models and tools used to solve various problems based on machine learning methods. | 3 | Spring 2023 | ||||||||||||||||||||
96 | Institute of Computer Science and Technology | Development and Maintenance of a High-Quality Software Product | Professional English | The course provides knowledge and skills in network and internet technology. It consists of the following topics: 1. Introduction to Computer Networks and Data Communications. 2. Fundamentals of Data and Signals. 3. Conducted and Wireless Media. 4. Making Connections. 5. Making Connections Efficient: Multiplexing and Compression. 6. Errors, Error Detection, and Error Control. 7. Local Area Networks: Part 1. 8. Local Area Networks: Part 2. 9. Introduction to Metropolitan Area Networks and Wide Area Networks. 10. The Internet. 11. Voice and Data Delivery Networks. 12. Network Security. 13. Network Design and Management. | 4 | Autumn 2022 | ||||||||||||||||||||
97 | Institute of Computer Science and Technology | 1) Information Systems and Technology; 2) System Analysis and Control | Database Systems | The course is based on materials of Database Foundations course of Oracle Academy program. This course introduces students to database concepts. Main topics: 1) Introduction to Databases. 2) Types of Database Models. 3) Relational Databases. 4) Data Modeling. Oracle SQL Developer Data Modeler as an example of the software tool for data modeling. 5) Introduction to Structured Query Language (SQL): Data Definition Language (DDL); Data Manipulation Language (DML); Transaction Control Language (TCL); Retrieving Data Using SELECT. | 4 | Spring 2023 | ||||||||||||||||||||
98 | Institute of Computer Science and Technology | Intelligent Systems | High-Level Design of Information Control Systems | Course objectives: 1. Carry out initial data collection and analysis for hardware and software design; 2. 2. Determine methods and ways for the complex software and hardware design according to the price, performance, reliability, and quality criteria; 3) 3. Determine the system architecture and its particular elements specification by means of system high-level simulation and verification methods; and 4) 4. Create the analytic review and scientific and technical report on the research and development results. Content: 1. Modern approaches to the software and hardware design; 2. Designed hardware and software methods and models justification selection; 3. The digital counterpart and digital models application templates and scripts; 4. Software and hardware digital models creation method; 5. Scientific and technical report on the research and development results. | 4 | Spring 2023 | ||||||||||||||||||||
99 | Institute of Computer Science and Technology | Intelligent Systems | Neuroinformatics and Neural Control | The course aim is to form specialists who are able to apply the existing technologies in a reasonable and effective manner and master new building intelligent control systems methods based on the machine learning, neuroinformatics, logic algebra, interval algebra, fuzzy sets concepts for information processing and control problems solving in professional fields; to form specialists which are able to explain in correct mathematical manner the used mathematical methods and models essence, and to validate their application necessity. Content: 1. Neuroinformatics, distributed systems, programmable logic controllers and SCADA systems for automated control systems, intelligent control system. 2. Programmable controllers. Architecture, operation principle, memory organization, embedded operation system. 3. International standard IEC 61131-3, purpose and development history, programming languages general characteristics, the executive system model. 4. Data concept, strict typing idea, incapsulation and others object-oriented programming features. Industrial communication networks classification and data exchange capabilities. Industrial Internet of Things (IoT). 5. International standard IEC 61499. Calculations with "guards". Distributed computing concept. 6. Neurocontrol and machine learning. 7. Abstract models used for the neuro-control organization: finite automata, Petri networks, Kripke models, fuzzy sets. The UML language application for the management models descriptions. 8. Agent-based intelligent control and distributed systems: various models implementation capabilities of and data exchange. | 5 | Autumn 2022 | ||||||||||||||||||||
100 | Institute of Computer Science and Technology | Intelligent Systems | Project Work | Course objectives: 1. The initial data for intelligent control system design collection and analysis. 2. The research object management task formulation. 3. The quality criteria for the designed intelligent control system development. 4. The control objects and processes models and methods choice. 5. An analytical report and scientific and technical report on the research and development results. Content: 1. The raw data for the control system calculation and design collection and analysis; 2. The designed intellectual control system (ICS) methods and models selection and justification; 3. Terms of reference and project documentation for the model design; 4. The quality criteria for the designed ICS selection and justification; 5. Scientific and technical report on research and development results. | 7 | Autumn 2022 |