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Lecturer(s)
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Rusnáková Soňa, doc. Ing. Ph.D.
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Course content
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- Modern technical materials and their distribution. Optimalization of material properties. Homogenous and heterogeneous materials. Surface phenomenon and their function. Weltability. Adhesion and their measurement. Influences on lubrication adhesion. - Composites - definition and their distribution. Synergic action in composites. - Fibre for composites. Properties of long-fibre composites. Oriented and non-oriented fibres of structure 1D, 2D and 3D. Properties of short-fibre composites. Term of critical length of fibres. Aspect ration of fibres. Kind of fibres. Properties and kinds of particular composites. Dispersion strengthening in composites. Reinforced strengthening. - The type of products from fibres. Glass fibres. Composition. The modification of surface of glass fibres. - Carbon fibres. The main kind of carbon fibres. Polymer fibres. Basalt fibres. Fibres to high-temperature applications. - Matrix. Polymer matrix. Unsaturated matrix. Epoxy matrix. Special kind of matrix to high-temperature applications. - Methods to preparation thermoplastic pre-preg materials. - Laminate. Orthotropic ply. Part by volume of fibre. Calculation of elastic constant of orthotropic ply. - Experimental determination of elastic characteristics of orthotropic ply. Hook low to special orthotropic plies. General orthotropic ply. Strength of orthotropic ply. - Superposition of laminate. Modulus of elasticity of isotropic ply (laminate from mat). - Constitutive equation of laminate. Fundamentals of sequence option of plies. - Other factors influenced tensile strength. Influence of freeboards of laminate. Thermal tension. - Metal composite materials - kind, basic properties and applications. Ceramic composite materials - kind, basic properties and applications. - Other type of modern composites. Composites with more than two constituent. Plate composites. Applications and perspective of composites. Other type of heterogeneous materials.
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Learning activities and teaching methods
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Dialogic (Discussion, conversation, brainstorming), Methods for working with texts (Textbook, book), Individual work of students
- Preparation for examination
- 90 hours per semester
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| prerequisite |
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| Knowledge |
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| Knowledge of mathematic, physic and chemistry. |
| Knowledge of mathematic, physic and chemistry. |
| learning outcomes |
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| Students are well informed in the standardization, the quality control of composite parts and the recycling problematic. |
| Students are well informed in the standardization, the quality control of composite parts and the recycling problematic. |
| Students have detailed knowledge about composite materials. |
| Students have detailed knowledge about composite materials. |
| Students define the conditions for the implementation of experimental techniques for measuring individual quantities. |
| Students define the conditions for the implementation of experimental techniques for measuring individual quantities. |
| Describe the mechanics of composite materials using basic equations and rules. |
| Describe the mechanics of composite materials using basic equations and rules. |
| Establish criteria for the selection of technical fibers for the defined load and the chosen application. |
| Establish criteria for the selection of technical fibers for the defined load and the chosen application. |
| Skills |
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| Carry out experimental measurements of technical quantities and their evaluation. |
| Carry out experimental measurements of technical quantities and their evaluation. |
| Planning and cooperation on the implementation of a group project and its presentation. |
| Planning and cooperation on the implementation of a group project and its presentation. |
| Determining the appropriate composition of a composite system using mechanical criteria. |
| Determining the appropriate composition of a composite system using mechanical criteria. |
| Perform fiber selection based on design requirements. |
| Perform fiber selection based on design requirements. |
| To carry out an experimental determination of the elastic properties of the orthotropic layer. |
| To carry out an experimental determination of the elastic properties of the orthotropic layer. |
| teaching methods |
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| Knowledge |
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| Individual work of students |
| Individual work of students |
| Methods for working with texts (Textbook, book) |
| Methods for working with texts (Textbook, book) |
| Dialogic (Discussion, conversation, brainstorming) |
| Dialogic (Discussion, conversation, brainstorming) |
| Skills |
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| Individual work of students |
| Individual work of students |
| Practice exercises |
| Practice exercises |
| assessment methods |
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| Knowledge |
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| Oral examination |
| Oral examination |
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Recommended literature
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Composite Materials, Science and Engineering. 1987.
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Barbero, E.J. Introduction to Composite Materials Design. London: Taylor and Francis, 1999.
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Bareš, R.A. Kompozitní materiály. Praha, SNTL, 1988.
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Černý, M. Vláknové kompozity. Praha : ČVUT, 2001. ISBN 80-01-02464-4.
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Datoo, M.H. Mechanics fo Fibrous Composites. Elsevier Science Publishers, 1991. ISBN 1-85166-600-1.
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Ehrenstein, Gottfried W.: . Polymerní kompozitní materiály. Scientia, 2009.
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Geier, M.H. Quality Handbook for Composite Material. ASM International, 1999.
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Kolařík, J. Vysokomodulová polymerní vlákna a vláknové kompozity. ACADEMIA, Praha, 1984.
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Mazumdar, S.K. Composites Manufacturing: Materials, Products and Processing. London: Crc Press, 2002.
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Middelton, D.H. Compozite materials in aircraft structures, 1st ed. London: Longman Grup, 1990. ISBN 0-582-01712-2.
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Pancl, J. a kol. Kompozitní materiály. Praha, Conmat, 1992.
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Táborský, L., Šebo, P. Konštrukčné materiály se spevnenými vláknami, . Bratslava, Alfa, 1982.
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