Continuum mechanics (NMMO 401)
Webpages of the lecture "Continuum mechanics" (NMMO 401), winter semester 2015/2016.
Announcement
There is no lecture/tutorial on 22nd October!
Introduction
Contact
If you need something, please let me know. You can talk to me after the lecture, or we can fix an appointment via email (prusv@karlin.mff.cuni.cz).
Schedule
See the study information system SIS.
Consultations
I am ready to talk to you each Thursday after the lecture/tutorial. If you are not fine with that, please write me an email (prusv@karlin.mff.cuni.cz), and we meet at a time suitable for you. Whenever you think that you do not understand something, please speak up. I really mean it. The main objective of the lectures and tutorials is to explain things that can be hardly read from books, and to help you to understand the subject. Consultations are a natural part of the process of learning!
Do not forget to talk to your peers! If you think that the homework problems are too difficult, you can try to ask your friends for an advice. (Note that advice is something else that "copy & paste".)
Tutorials
If you want to get the credits for the tutorial you must:
- solve the homework problems on time,
- attend the tutorials.
If you are not happy with the rules, we can talk about alternatives. (For example, if you find the tutorial extremely boring, then we can make an agreement that you do not need to attend the tutorials provided that you will solve some extra problems.) I am ready to talk about such things only at the beginning of the semester. There is no chance to discuss these rules at the end of the semester. (Except, of course, of emergency situations such as a long illness.)
Homeworks
Please submit the homeworks on time. You can even scan your solution and send it to me via email (prusv@karlin.mff.cuni.cz).
- Set A, please hand in the homework on 15th October.
- Set B, please hand in the homework on 29th October.
- Set C, please hand in the homework on 5th November.
- Set D, please hand in the homework on 12th November.
- Set E, please hand in the homework on 19th November.
- Set F, please hand in the homework on 26th November.
- Set G, please hand in the homework on 3rd December.
- Set H, please hand in the homework on 10th December.
- Set I, please hand in the homework on 17th December.
- Set J, please hand in the homework on 7th January.
- Set K, please hand in the homework on 14th January.
Problems
You can find some problems in the traditional set of problems. (In Czech.) If you are not fluent in Czech, do not worry, you still have a chance to practice. Many problems can be found for example in the textbook by Gurtin, M. E.; Fried, E.; Anand, L.: The mechanics and thermodynamics of continua, Cambridge University Press, Cambridge, 2010.
Literature
The first part of the lecture in mostly covered in the book by Gurtin, M. E.; Fried, E.; Anand, L.: The mechanics and thermodynamics of continua, Cambridge University Press, Cambridge, 2010. (I try to follow their notation.) Another good book is the book by Ogden, R.: Nonlinear elastic deformations, Dover, 1997. If you want a Czech textbook, you can try the book by Maršík, F.: Termodynamika kontinua, Academia, Praha, 1999.
Exam
Organisation of the exam
The exam is an oral exam, and it consists of three parts.
- Proof of some simple theorem.
(The theorem will be specified later. For example, in 2014/2015 the students were asked to prove the Cauchy stress theorem.) This year your are requested to prove Hadamard compatibility condition, that is you are asked to prove that the jump of the gradient of a continuous vector field is normal to the singular surface. You should interpret this statement---that in fact says that $\mathbf{F} = \mathbf{a} \otimes \mathbf{n}$---in the context of continuum mechanics. The proof can be found for example in Šilhavý: The Mechanics and Thermodynamics of Continuous Media, Springer, 1997 or in Truesdell, Rajagopal: An Introduction to the Mechanics of Fluids, Birkhäuser, 1999. You can use your own notes.
- Presentation of a solution to a problem discussed in some scientific paper, see below. The objective is to show that you know what is the paper about, and what are the used methods and conclusions.
(The paper will be specified later. For example, in 2014/2015 the students were asked to present paper Abbott, Walters: Theory for the orthogonal rheometer, including an exact solution of the Navier--Stokes equations or paper Kovasznay: Laminar flow behind a two-dimensional grid.) You can use your own notes.
- During our conversation we will definitely encounter some notions from the field of continuum mechanics. You could be asked to explain some of the notions. (Expect questions of the type "What is the Cauchy stress tensor" and so on.) Detailed list of the definitions/theorems you are expected to know can be found below. (Will be specified at the end of the semester.)
Once you sign up for the exam in the Study Information System please let me know the title of the chosen scientific paper we shall discuss.
Scientific paper
You must be able, using your own notes, describe the problem that is being solved and its solution. You must show that you
- understand the problem setting,
- understand the assumptions used in the solution (assumptions concerning boundary conditions, omission of some apparently small terms in the equations and so on),
- can explain in detail the whole solution process,
- can interpret the solution.
I do not want you to reproduce, unless stated otherwise, the numerical computations used in the papers. In this respect you can trust the authors.
List of problems/papers/sources
Will be specified later. For example, in 2014/2015 the students were asked to present paper Abbott, Walters: Theory for the orthogonal rheometer, including an exact solution of the Navier--Stokes equations or paper Kovasznay: Laminar flow behind a two-dimensional grid.
You can choose from the following problems/papers/sources:
- Drag acting on a sphere moving with constant velocity in incompressible Navier--Stokes fluid. ("Stokes drag".) The calculation is described in Landau, Lifschitz: Fluid mechanics, Pergamon Press, Oxford, 1966 or in Brdička: Mechanika kontinua, Academia, Praha, 2011. (The approach presented in Brdička is, in my opinion, a better one.) I would say that this problem is of medium difficulty.
- Flow in orthogonal rheometer (Navier--Stokes fluid only). The calculation is described in T. N. G. Abbott and K. Walters (1970). Rheometrical flow systems Part 2. Theory for the orthogonal rheometer, including an exact solution of the Navier-Stokes equations. Journal of Fluid Mechanics, 40, pp 205-213 doi:10.1017/S0022112070000125. I would say that the problem is easy.
- Pressure singularity in reentrant corners. The calculation is described in W. R. Dean and P. E. Montagnon (1949). On the steady motion of viscous liquid in a corner. Mathematical Proceedings of the Cambridge Philosophical Society, 45, pp 389-394. doi:10.1017/S0305004100025019. I would say that the problem is easy.
- Deformation of a cylinder by its own weight. The calculation is described in Brdička: Mechanika kontinua, Academia, Praha, 2011, however, you should work in cylindrical coordinates, this will help you to save time and paper. I would say that this problem is of medium difficulty.
- Finite strain solutions for a compressible elastic solid. The calculation is described in Carroll, M. M., & Horgan, C. O. (1990). Finite strain solutions for a compressible elastic solid. Quarterly of applied mathematics, 48(4), 767-780. (Discuss only one of the deformations described in the paper. The choice is yours.) I would say that the problem is difficult.
Syllabus
Detailed syllabus that exaclty matches the lecture is available here.
Last modified: Thu Jan 14 11:13:34 CET 2016