Laser additive technology

Description: Lays the knowledge necessary for the study of the main types of laser systems, their element base, safety techniques when working with laser radiation sources, methods and techniques for measuring the characteristics of laser radiation, the basics of invention

Amount of credits: 4

Пререквизиты:

• Physical Methods of Research

Course Workload:

Component: Component by selection

Cycle: Base disciplines

Goal

• The purpose of mastering the discipline is to form students a holistic understanding of a powerful pulsed laser, their active environment, methods of excitation, methods of forming qualitative radiation and the field of their application. Training of highly qualified personnel for enterprises and research centers of the industrial complex engaged in production and research activities in the field of laser and additive technologies. The emphasis of the program is on deep natural-scientific and professional training using modern information technologies.

Objective

• The objectives of teaching the discipline are:-solving research problems: the search and implementation of methods for the formation of high-power laser pulses and its necessary distribution by Beam section, methods for converting and transporting such pulses without energy losses and spatial-angular characteristics; - production and technological work in the field of the element base of technological and research lasers, in the approaches to-search and analysis of specialized scientific and technical information necessary to solve specific engineering tasks, including the selection of typical assemblies for the creation of lasers for various purposes, correction of Laser Systems, laser installation

Learning outcome: knowledge and understanding

• - methods and techniques for measuring the characteristics of laser radiation; - the main types of laser systems, their element base; - the main types of additive production systems, their element base;

Learning outcome: applying knowledge and understanding

• It is necessary to be able to: - independently learn new research methods; - independently choose the most suitable methods and equipment for research, analyze the information received; - independently choose the most suitable methods and equipment for research, analyze the information received; - correctly interpret the information received in order to make the optimal decision in a given situation; - correlate the Acquisition of skills: - the ability to search for information on the Internet and in Special Libraries. - skills in working with pulsed electrical and laser equipment, specialized software

Learning outcome: formation of judgments

• - to understand the depth and complexity of laser technology, the commonality and interconnection of phenomena in micro and macromir; - to be ready to work independently as a team member on an interdisciplinary topic, to be a leader in a team; - to understand the need for independent training and advanced training at all stages of professional activity.

Learning outcome: communicative abilities

• develop communication skills necessary for working in a team.

Learning outcome: learning skills or learning abilities

• - The ability to provide professional knowledge in the field of medical and Biological Physics; - readiness to apply the ideas and methods of medical and Biological Physics in other areas of human activity. - The ability to apply professional knowledge and skills acquired during the study of profile physical disciplines in practice.

Key reading

• 1.Полимеры медико-биологического назначения. Штильман М.И. М.: ИКЦ «Академкнига», 2006. – 400 с. [Электронный ресурс] Режим доступа http://www.twirpx.com/file/1317750/ 2. Биокерамика на основе фосфатов кальция. Баринов С.М., Комлев В.С. М.: Наука, 2005. – 2004 с. . [Электронный ресурс] Режим доступа. http://www.bibliofond.ru/view.aspx?id=484608 3.Биосовместимые наноматериалы: Снегин Э.А. М.:НОУДПО "Институт АйТи",2011.-135 с 5. Биоматериалы и биоминерализация Матиас Эппле. Пер.с нем. под ред. В.Ф. Пичугина, Ю.П. Шаркеева, И.А. Хлусова. Томск: издательство «Ветер», 2007 5. Биоматериалы, искусственные органы и инжиниринг тканей. Хенч Л., Джонс. М.: Техносфера, 2007. – 304 с. 6. Медицинские материалы и имплантаты с памятью формы. Гюнтер В.Э., Дамбаев Г.Е., Сисолятин П.Г. Изд. ТГУ, 1998 7. Основы биомеханики. Бранков Г. М.: Мир. 1981 8. Эффекты памяти формы и их применение в медицине. Гюнтер В.Э., Итин В.И., Монасевич Л.А. и др. Новосибирск: Наука. 1992 9. Микродуговое оксидирование (теория, технология, оборудование) Суминов И.В. и др. М:ЭКОМЕТ, 2005