Course Details
Selected Chapters of Structural Mechanics 2 (S)
Academic Year 2023/24
NDB021 course is part of 1 study plan
NPC-SIS Summer Semester 1st year
Textile reinforced concrete, fiber concrete, ECC and composites characterized by a synergetic combination of short fiber reinforcement with aligned (structured) reinforcement in a brittle matrix. Consideration of the natural heterogeneity and randomness of composites. Modeling of the mechanical response of composites to tensile test. Modeling of the mechanical response of multifilament yarns under tension. Statistical characterization of the sources of randomness in yarns. Probabilistic distribution of strength of yarns and composites.
Course Guarantor
Institute
Objective
Textile reinforced concrete, fiber concrete, ECC and composites characterized by a synergetic combination of short fiber reinforcement with aligned (structured) reinforcement in a brittle matrix. Consideration of the natural heterogeneity and randomness of composites. Modeling of the mechanical response of composites to tensile test. Modeling of the mechanical response of multifilament yarns under tension. Statistical characterization of the sources of randomness in yarns. Probabilistic distribution of strength of yarns and composites.
Knowledge
Students will master the subject targets, it being the knowledge about textile reinforced concrete, fiber concrete, ECC and composites characterized by a synergic combination of short fiber reinforcement with aligned (structured) reinforcement in a brittle matrix. He/she will get a basic backgroung on the consideration of the natural heterogeneity and randomness of composites. Modeling of the mechanical response of composites to tensile test. Modeling of the mechanical response of multifilament yarns under tension. Statistical characterization of the sources of randomness in yarns. Probabilistic distribution of strength of yarns and composites.
Syllabus
1. Introduction to fiber reinforced composites. Application sphere, comparison with steel-reinforced concrete and other traditional materials.
Characterization of the main features influencing the mechanical response.
2. Insight into the mechanisms of energy dissipation and mechanisms of stress redistristribution during progressive failure. Connections to fracture mechanics.
3. Characterization of various fiber types and materials for fiber production (such as steel, glass, carbon, aramid, polyester etc.).
4. Characterization of fiber types and of yarn types, yarn production and yarn testing. Influence of strain rate and amount of twist.
5. Classical model of yarn based on the FEM. Model of the mechanical response based on sorting algorithms.
6. Probabilistic model of the yarn response. Definition , explanation of the paradigm, revision of the main ingredients and basic transformations of the model.
7. Study of the influence of basic sources of heterogeneity and randomness on random yarn response.
8. Modeling approaches exploiting the theory of random fields. Comparison of all the studied models.
9. Distribution of strength of multifilament yarns. Daniels' theorem. Transition of the strength tail to the distribution core. Recursive formulas.
10. Asymptotic strength.
11. Extension to the strength of composites with chained crack bridges.
Theory of extreme values and the associated weakest-link model.
12. Advances questions in the theory of composites.
13. Extreme value theory and its application to statistical strength of materials and structures. Revision.
Characterization of the main features influencing the mechanical response.
2. Insight into the mechanisms of energy dissipation and mechanisms of stress redistristribution during progressive failure. Connections to fracture mechanics.
3. Characterization of various fiber types and materials for fiber production (such as steel, glass, carbon, aramid, polyester etc.).
4. Characterization of fiber types and of yarn types, yarn production and yarn testing. Influence of strain rate and amount of twist.
5. Classical model of yarn based on the FEM. Model of the mechanical response based on sorting algorithms.
6. Probabilistic model of the yarn response. Definition , explanation of the paradigm, revision of the main ingredients and basic transformations of the model.
7. Study of the influence of basic sources of heterogeneity and randomness on random yarn response.
8. Modeling approaches exploiting the theory of random fields. Comparison of all the studied models.
9. Distribution of strength of multifilament yarns. Daniels' theorem. Transition of the strength tail to the distribution core. Recursive formulas.
10. Asymptotic strength.
11. Extension to the strength of composites with chained crack bridges.
Theory of extreme values and the associated weakest-link model.
12. Advances questions in the theory of composites.
13. Extreme value theory and its application to statistical strength of materials and structures. Revision.
Prerequisites
fundamentals of the structure mechanics and the theory of elasticity and plasticity, fundamentals of the finite element method, infinitesimal calculus, matrix algebra, fundamentals of numerical mathematics, nonlinear mechanics
Language of instruction
Czech
Credits
5 credits
Semester
summer
Forms and criteria of assessment
course-unit credit and examination
Specification of controlled instruction, the form of instruction, and the form of compensation of the absences
Extent and forms are specified by guarantor’s regulation updated for every academic year.
Offered to foreign students
Not to offer
Course on BUT site
Lecture
13 weeks, 2 hours/week, elective
Syllabus
1. Introduction to fiber reinforced composites. Application sphere, comparison with steel-reinforced concrete and other traditional materials.
Characterization of the main features influencing the mechanical response.
2. Insight into the mechanisms of energy dissipation and mechanisms of stress redistristribution during progressive failure. Connections to fracture mechanics.
3. Characterization of various fiber types and materials for fiber production (such as steel, glass, carbon, aramid, polyester etc.).
4. Characterization of fiber types and of yarn types, yarn production and yarn testing. Influence of strain rate and amount of twist.
5. Classical model of yarn based on the FEM. Model of the mechanical response based on sorting algorithms.
6. Probabilistic model of the yarn response. Definition , explanation of the paradigm, revision of the main ingredients and basic transformations of the model.
7. Study of the influence of basic sources of heterogeneity and randomness on random yarn response.
8. Modeling approaches exploiting the theory of random fields. Comparison of all the studied models.
9. Distribution of strength of multifilament yarns. Daniels' theorem. Transition of the strength tail to the distribution core. Recursive formulas.
10. Asymptotic strength.
11. Extension to the strength of composites with chained crack bridges.
Theory of extreme values and the associated weakest-link model.
12. Advances questions in the theory of composites.
13. Extreme value theory and its application to statistical strength of materials and structures. Revision.
Exercise
13 weeks, 2 hours/week, compulsory
Syllabus
1. Submission of individual problems to be solved on computer.
2.–12. Work on the tasks with the help of the teacher.
13. Presentation of the results, credits.