Purpose is an understanding and learning of manufacturing engineering for production of aviation engines and power plants.
Task is acquirement of knowledge on planning of manufacturing processes and manufacturing operations for production of parts of aviation engines and power plants.
Educational results: As the result of learning of the discipline a student should obtain the following competences:
General competences: ability to generate new ideas (creativity), ability to make the reasoned decisions; ability to learn and acquire modern knowledge.
Specialty competences: ability to develop and realize manufacturing processes for production of elements and objects of aviation, rocket and space engineering.
Program educational results: to explain his/her decisions and reasons for their making to specialists and to non-specialists in clear and single-meaning form; to observe the requirements of branch normative documents related to procedures of designing, manufacture, testing and(or) certification of elements and objects of aviation, rocket and space engineering at all stages of their life cycle; skills in determination of loads on structural elements of aviation, rocket and space equipment at all stages of its life cycle; to describe structure of metals and non-metals and to know methods for the modification of their properties. To assign optimal materials for elements and systems of aviation, rocket and space equipment taking into account their structures, physical, mechanical, chemical and exploitation properties, as well as economic factors; to describe experimental investigation methods for structural, physical, mechanical and manufacturing properties of materials and structures; to se in professional activity the modern methods of designing and manufacture of elements and systems of aviation, rocket and space equipment; to understand and substantiate a sequence for designing, manufacture, testing and(or) certification of elements and systems of aviation, rocket and space equipment; to understand theoretical principles and practical methods for tool provision of interchangeability of parts for aviation, rocket and space equipment; to acquire the skills in development of manufacturing processes including those with use of computer automated designing of production of structural elements and systems of aviation, rocket and space equipment.
Interdisciplinary relations: discipline “Manufacturing technology of engines and power plants” is to be delivered after the students’ acquirement of disciplines “Engineering and computer graphics”, “Engineering material science”, “Aviation material science”, “Higher Mathematics”, “Physics”, “Thermodynamics and heat exchange”, “Machines’ parts and designing fundamentals”, “Interchangeability and standardisation”, “Mechanics of materials and structures”, “Technologies of structural materials”, “Designing of aviation power plants and aggregates”, “Design and strength of aviation engines and power plants”, “Methods and parameters for machining of surfaces of various shapes” and other disciplines. Knowledge, abilities and skills obtained by students from discipline “Manufacturing technology of engines and power plants” are used for further learning of designing and technological disciplines such as “Designs of aviation engines”, “Exploitation, repair and application of aviation engines in ground-based plants”, “Aviation piston engines”, “Manufacturing technology of engine-building”, “Automation of manufacturing processes”, “Computer-aided development of manufacturing processes”, “Technological tooling” and other, at development of graduation bachelor paper, as well as term projects (papers).
- Teacher: Багмет Марія Миколаївна
- Teacher: Князєв Михайло Климович
Purpose is acquisition of fundamentals of interchangeability and standardization, obtaining the skills of application and observation of standards requirements, selection of fits for typical joints.
Task – main task of learning the discipline “Interchangeability and standardisation” depending on specialty is: to acquire the knowledge on theoretical principles and practical methods of tool provision for interchangeability of parts of aviation, rocket and space equipment; to create and theoretically substantiate designs of machines, mechanisms and their elements on the basis of general principles of designing, interchangeability theory, the unified calculations methods for machines’ parts; to perform works on standardisation, unification and technical preparation for certification of technical devices, systems, processes, equipment and materials, to organise metrological provision for thermal technological processes with use of typical methods for check of products quality in the energy machine-building branch.
Educational results:
know:
- basic terms in the field of interchangeability and standardisation;
- typical tasks solved by standardisation methods;
- standardisation methods (typification, unification, unitisation);
- categories and types of standards;
- complex systems of standards;
- standardisation fundamentals for accuracy of geometric parameters of machines’ parts;
- types of fits, their characteristics;
- systems of tolerances and fits for representative joints of machines parts;
- standardisation fundamentals for accuracy of form, position and roughness of parts surfaces;
- fundamentals of theory and methods for calculations of dimensional chains;
be able:
- to use terminology in the field of standardisation and interchangeability;
- to use standards for tolerances and limit deviations of parts dimensions of representative joints;
- to select standardised fits for joints of machine’s parts and specify them in drawings;
- to select means for measurements and check of geometric parameters of parts;
- calculate executive (manufacturing) dimensions and specify them on sketches;
- to determine quality of parts by results of measurements and check by plain gauges;
- to perform calculations for flat dimensional chains.
acquire skills:
- in measurements of geometric parameters of parts;
- in calculations of limit dimensions (maximum, minimum and mean);
- in calculations of interferences and clearances in slick joints;
- in specifying the accuracy of dimensions, roughness of surfaces, accuracy of relative position of surfaces in drawings.
Interdisciplinary relations: discipline “Interchangeability and standardisation” is related to the discipline “Machines’ parts”. Discipline “Interchangeability and standardisation” gives knowledge on accuracy of parts, character of joints, methods and techniques for calculations of joint parameters, specifying the accuracy parameters in drawings of parts and assembly units. Knowledge, abilities and skills obtained by students from discipline “Interchangeability and standardisation” are used for further learning of designing and technological disciplines such as “Designing of aviation power plants and aggregates”, “Designs and strength of aviation engines and power plants”, “Manufacturing technology of engines and power plants”, “Manufacturing technology of aviation engines”, “Methods and parameters for machining of various shapes”, “Technological tooling”, “Computer-aided development of manufacturing processes” and other, as well as at performance of term and diploma papers.
- Teacher: Князєв Михайло Климович
Кафедра технологій виробництва авіаційних двигунів (№ 204) /
Department of Manufacturing Technologies for Aviation Engines (No. 204)
Технологія двигунобудування /
Engine Manufacturing Technology
Галузь знань / Field of knowledge:
13 – Механічна інженерія / Mechanical Engineering
Спеціальність / Specialty:
134 – Авіаційна та ракетно-космічна техніка / Aviation and Rocket-Space Engineering
Освітня програма / Educational Program:
Авіаційні двигуни і енергетичні установки / Aviation Engines and Power Plants
Форма навчання: денна /
Education form: full time
Рівень вищої освіти / Level of higher education:
перший (бакалаврський) / the first (bachelor)
Харків / Kharkiv 2019 рік
- Teacher: Князєв Михайло Климович