Modern technologies in mechanical engineering
Description: The discipline introduces modern technologies for the production of machine-building products, gives an idea of the technological development and improvement of the machine-building complex, new machine-building materials and technologies for their production and processing, technological processes for the manufacture and assembly of machine-building products, including innovative directions and processes and progressive technologies in mechanical engineering, qualitative changes in machine-building production technology, as the most important directions of development of the industrial economy, improving the quality of mechanical engineering products and the economic efficiency of production, allows you to obtain and expand professional competencies, knowledge, skills and abilities to solve specific professional tasks of management and organization of production within this specialty.
Amount of credits: 3
Пререквизиты:
- Introduction to engineering education
- Физика. Школьный курс
Course Workload:
| Types of classes | hours |
|---|---|
| Lectures | 15 |
| Practical works | 15 |
| Laboratory works | |
| SAWTG (Student Autonomous Work under Teacher Guidance) | 15 |
| SAW (Student autonomous work) | 45 |
| Form of final control | Exam |
| Final assessment method | Exam |
Component: Component by selection
Cycle: Profiling disciplines
Goal
- The purpose of studying this discipline is to prepare students for independent practical professional activity in their specialty, to acquire knowledge, skills and abilities necessary to solve basic tasks in the field of economic organization and production management.
Objective
- Learning objectives: consistently master the theoretical knowledge of modern technologies in mechanical engineering, form a holistic view of this area of knowledge and achieve their understanding; to acquire and develop the skills and abilities of the multivariate practical application of the acquired knowledge and solving applied problems of the organization and management of production for the implementation of practical activities in the specialty; to form systematic professional knowledge, skills and abilities necessary both in the field of organization and management of production and beyond for independent search and informed decision-making, development and improvement of thinking and practical activities in the specialty
Learning outcome: knowledge and understanding
- collect and analyze the data necessary to ensure a modern technological production process, learn, recall, reproduce and demonstrate an understanding of the course information, be able to receive, summarize, transform, interpret, paraphrase and explain it with examples
Learning outcome: applying knowledge and understanding
- have the skills of organizing and managing technological processes, using modern management methods, be able to understand the essence of applied problems and tasks of the discipline and be able to explore and solve them, practically applying the acquired knowledge, skills and abilities for various professional activities, choosing solutions in relation to different contexts in familiar and new areas and situations for implementation practical activities in the specialty
Learning outcome: formation of judgments
- be able to explain processes, phenomena, general principles and logical relationships in the field of machine-building technology, break down and connect information, logically build it, comprehend, generalize, compare, evaluate, criticize, verify, explain, establish connections, make judgments, make and defend conclusions and conclusions, see the main thing
Learning outcome: communicative abilities
- to carry out oral and written communication, to be able to convey clearly and consistently information, ideas, problems and solutions on issues of machine-building production technology and their application in professional activities to an audience consisting of both specialists and non-specialists in the mode of monologue and dialogue
Learning outcome: learning skills or learning abilities
- to use modern means of searching, analyzing and interpreting information to fulfill the tasks of professional activity, to have the skills necessary to apply knowledge and skills in the field of machine-building production technology and to carry out further training in the specialty with a high degree of independence
Teaching methods
вовлечение обучающихся в поиск и управление знаниями; самостоятельное решение разнообразных задач; проблемно- и проектно-ориентированное обучение; учебно-исследовательская деятельность; коммуникативные технологии (дискуссия, мозговой штурм, учебные дебаты и др.); метод кейсов (анализ ситуации); информационно-коммуникационные технологии.
Assessment of the student's knowledge
Teacher oversees various tasks related to ongoing assessment and determines students' current performance twice during each academic period. Ratings 1 and 2 are formulated based on the outcomes of this ongoing assessment. The student's learning achievements are assessed using a 100-point scale, and the final grades P1 and P2 are calculated as the average of their ongoing performance evaluations. The teacher evaluates the student's work throughout the academic period in alignment with the assignment submission schedule for the discipline. The assessment system may incorporate a mix of written and oral, group and individual formats.
| Period | Type of task | Total |
|---|---|---|
| Total control | Exam | 0-100 |
The evaluating policy of learning outcomes by work type
| Type of task | 90-100 | 70-89 | 50-69 | 0-49 |
|---|---|---|---|---|
| Excellent | Good | Satisfactory | Unsatisfactory |
Evaluation form
The student's final grade in the course is calculated on a 100 point grading scale, it includes:
- 40% of the examination result;
- 60% of current control result.
The final grade is calculated by the formula:
| FG = 0,6 | MT1+MT2 | +0,4E |
| 2 |
Where Midterm 1, Midterm 2are digital equivalents of the grades of Midterm 1 and 2;
E is a digital equivalent of the exam grade.
Final alphabetical grade and its equivalent in points:
The letter grading system for students' academic achievements, corresponding to the numerical equivalent on a four-point scale:
| Alphabetical grade | Numerical value | Points (%) | Traditional grade |
|---|---|---|---|
| A | 4.0 | 95-100 | Excellent |
| A- | 3.67 | 90-94 | |
| B+ | 3.33 | 85-89 | Good |
| B | 3.0 | 80-84 | |
| B- | 2.67 | 75-79 | |
| C+ | 2.33 | 70-74 | |
| C | 2.0 | 65-69 | Satisfactory |
| C- | 1.67 | 60-64 | |
| D+ | 1.33 | 55-59 | |
| D | 1.0 | 50-54 | |
| FX | 0.5 | 25-49 | Unsatisfactory |
| F | 0 | 0-24 |
Topics of lectures
- Topic 1
Key reading
- 1. Антимонов А.М. Основы технологии машиностроения: учебник / А.М. Антимонов. - Екатеринбург: Изд-во Урал. ун-та, 2017. - 176 с. 2. Базров Б.М. Основы технологии машиностроения: учебник для вузов. - 2-е изд. - М.: Машиностроение, 2017. – 736 с. 3. Безъязычный В.Ф. Основы технологии машиностроения: учебник / В.Ф. Безъязычный. - 2-е изд. - Москва: Машиностроение, 2016. - 568 с. - 4. Безъязычный В.Ф. Основы технологии машиностроения. Изд. 2-е. М.: Инновационное машиностроение, 2020. 5. Евстигнеева А.Г. Новые технологии в машиностроении // Международный научный журнал «ВЕСТНИК НАУКИ» № 5 (14) Т.3. Май 2019 г. C. 347-351. 6. Инновационные технологии в машиностроении: сборник статей Международной научно-технической конференции (25 марта 2016 г., г. Владивосток). - Владивосток: ДВЦИТ, 2016. - 96 с. 7. Лабораторные и практические работы по технологии машиностроения: учебное пособие / В.Ф. Безъязычный, В.В. Непомилуев, А.Н. Семенов и др.; под общей редакцией В. Ф. Безъязычного. - 2-е изд. - Москва: Машиностроение, 2017. - 600 с. 8. Научные основы современного машиностроения: учеб. пособие / В.Л. Вейц [и др.] – СПб.: Изд-во СЗТУ, 2014. - 201 с. 9. Научные проблемы в технологии машиностроения: Конспект лекций / А.Н. Сутягин – Рыбинск: РГАТУ, 2016. – 137 с. 10. Новиков В.Ю. Технология машиностроения: в 2 ч. - Ч. 1: учебник для студ. учреждений сред. проф. образования / В.Ю. Новиков, А.И. Ильянков. - 4-е изд., стер. - М.: Издательский центр «Академия», 2014. - 352 с. 11. Новиков С.В., Рамазанов К.Н. Аддитивные технологии: состояние и перспективы: учебное пособие [Электронный ресурс]. - Уфимск. гос. авиац. техн. ун‐т. – Уфа: УГАТУ, 2022. URL:https://www.ugatu.su/media/uploads/MainSite/Ob%20universitete/Izdateli/El_izd. 12. Основы материаловедения (металлообработка): учебник для студ. учреждений сред. проф. образования / [В.Н. Заплатин, Ю.И. Сапожников, А.В. Дубов и др.]; под ред. В.Н. Заплатина. - 8-е изд., стер. - М.: Издательский центр «Академия», 2017. - 272 с. 13. Основы технологии производства (в машиностроении): учеб. пособие / Ю.А. Орлов [и др.]; Владим. гос. ун-т им. А.Г. и Н.Г. Столетовых. – Владимир: Изд-во ВлГУ, 2015. − 91 c. 14. Попелюх А.И., Тюрин А.Г., Плотникова Н.В. Перспективные способы обработки материалов: Учебное пособие. - Челябинск: Южно-Уральский государственный университет, 2014. - 49 c. 15. Попок Н. Н. Основы технологии машиностроения: учебное пособие / Н.Н. Попок, В.И. Абрамов. – Новополоцк: ПГУ, 2020. – 272 с. 16. Сергеев А.В. Технология машиностроения: Учебное пособие для студентов экономических специальностей вузов. – Тольятти: Изд-во Тольяттинского государственного университета, 2015 – 124 с. 17. Сысоев С.К. Технология машиностроения. Проектирование технологических процессов: учебное пособие / С.К. Сысоев, А.С. Сысоев, В.А. Левко. - 2-е изд., стер. - Санкт-Петербург: Лань, 2016. - 352 с. 18. Технология машиностроения: учебник и практикум для СПО / под общ. ред. А.В. Тотая. - М.: Издательство Юрайт, 2016. - 239 с. 19. Чекмарев В.В. Технологические инновации в машиностроении с элементами программирования станков с ЧПУ: Краткий курс лекций. - ФГБОУ ВО «Саратовский ГАУ». - Саратов, 2016. - 58 с. 20. Технология машиностроения: сборник задач и упражнений: учебное пособие для вузов / В.И. Аверченков [и др.]. Под общ. ред. В.И. Аверченкова и Е.А. Польского. М.: ИНФРА-М, 2020. - 286 с.
