Modern problems of metallurgy and metal science

Abdulina Saule Amangeldyevna

The instructor profile

Description: To give students an idea of the state and problems of metallurgy and metallurgy of non-ferrous metals. Due to the depletion of ore raw materials and an increase in the content of impurity elements, the issue of involving alternative sources of raw materials in processing becomes urgent. The production of finished metal products and the production of ultrapure metals for radioelectronic and other industries also remains a problem.

Amount of credits: 5

Пререквизиты:

  • Special chapters of the theory and practice of thermal and chemical-thermal treatment

Course Workload:

Types of classes hours
Lectures 15
Practical works 30
Laboratory works
SAWTG (Student Autonomous Work under Teacher Guidance) 75
SAW (Student autonomous work) 30
Form of final control Exam
Final assessment method oral

Component: University component

Cycle: Profiling disciplines

Goal
  • The purpose of studying the discipline: Presentation of up-to-date information to students about the state and problems in metallurgy of non-ferrous metals and metal science.
Objective
  • Formation of students' skills to review and analyze modern problems of non-ferrous metals production and metal science, including their solutions based on promising technologies.
Learning outcome: knowledge and understanding
  • Critically analyze, evaluate and synthesize new and complex ideas and make strategic decisions in the field of metallurgy
Learning outcome: applying knowledge and understanding
  • The student should know: The current state of production of non-ferrous and rare metals, problems in production and ways to solve these problems.
  • The knowledge can be applied in the process of analyzing the state and prospects for the development of the production of non-ferrous metals and their alloys.
Learning outcome: formation of judgments
  • As a result of training, students develop skills and abilities to analyze both the results of experiments and technological processes of metal production.
Learning outcome: communicative abilities
  • Formation of communicative abilities of teamwork.
Learning outcome: learning skills or learning abilities
  • The teacher must be capable of self-improvement of knowledge. As a result of training, students develop skills and abilities to analyze both the results of experiments and technological processes of metal production.
Teaching methods

When studying the discipline, problem-based and problem-oriented learning technologies are used. In the course of training, problems are put forward on each topic, the solutions of which are considered jointly with the student

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
1  rating Индивидуальное задание 1 0-100
Индивидуальное задание 2
Тестовый контроль
Устный опрос
2  rating Индивидуальное задание 1 0-100
Индивидуальное задание 2
Тестовый контроль
Устный опрос
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
  • Современные проблемы и тенденции развития металлургии чугуна и стали
  • Современные проблемы в процессах плавки и обработки расплавов на основе алюминия
  • Современные достижения и проблемы в металлургии меди и никелевых сплавов
  • Современные проблемы в области внепечной обработки расплавов
  • Современные проблемы технологии переплавных процессов
  • Современные проблемы при разработке новых материалов
  • Современные проблемы производства материалов с наноструктурой
  • Современные проблемы производства керамических материалов
  • Проблемы разработки и применения новых композиционных материалов
  • Современные проблемы в разработке материалов покрытий
Key reading
  • Материаловедение и технология материалов: Учебное пособие / Под ред. А.И. Батышева, А.А. Смолькина.- М.: ИНФРА-М, 2011. — 288 с.
  • Материаловедение и технология конструкционных материалов. Учебник для студентов высших учебных заведений / Арзамасов В.Б., Волчков А.Н., Головин В.А., Кузнецов В.А.. Смирнова Э.Е., Черепахин А.А., Шпунькин Н.Ф., под редакцией Арзамасова В.Б. и Черепахина А.А. – 2-е изд., стер. – М.: Академия, 2010. – 446 с.
  • Кудрин В.А. Ресурсосбережение в металлургии и охрана природы: учебник для студ. вузов, обуч. по направлению "Металлургия" (УМО) М.: МГВМИ, 2012. – 103 с.
  • Сырьевая и топливная база черной металлургии. / Л.И. Леонтьев, Ю.С. Юсфин, Т.Я. Малышева – М.: Академкнига, 2007. – 304 с.
  • Скляр В. О. Инновационные и ресурсосберегающие технологии в металлургии: Учебное пособие. – Донецк: ДонНТУ, 2014. – 224 с.
  • Энергоэффективные и ресурсосберегающие технологии черной металлургии / Ю.Г. Ярошенко, Я.М. Гордон, И.Ю. Ходоровская. Под ред. Ю.Г. Ярошенко. – Екатеринбург: УИПЦ, 2012. – 670 с.
  • Новые процессы получения металла. Металлургия железа. / Ю.С. Юсфин, А.А. Гиммельфарб, Н.Ф. Пашков. – М.: Металлургия, 1994. – 320 с
Further reading
  • Носова, Е. А. Современные проблемы металлургии и материаловедения: электрон. учеб. пособие / Е.А.Носова; Минобрнауки России, Самар. гос. аэрокосм. ун-т им. С. П. Королева (нац. исслед. ун-т). - Самара, 2012. – 48 с.
  • Применение ЭВМ для управления технологическими процессами в металлургии / Г.Б. Даныкина [и др.]; Сиб. федерал. ун-т. – Красноярск: ИПК СФУ, 2008.
  • Yin R. Metallurgical Process Engineering. – Metallurgical Industry Press, Beijing and Springer-Verlag Berlin, 2011, 328 pages