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[http://stbl.stanford.edu/Marc_Levenston marc levenston] - levenston.at.stanford.edu <br> | [http://stbl.stanford.edu/Marc_Levenston marc levenston] - levenston.at.stanford.edu <br> | ||
[mailto:bhargav@stanford.edu addala bhargav] - bhargav.at.stanford.edu <br> | [mailto:bhargav@stanford.edu addala bhargav] - bhargav.at.stanford.edu <br> | ||
+ | [mailto:kimnk@stanford.edu namkeun kim] - kimnk.at.stanford.edu <br> | ||
winter 2008 <br> | winter 2008 <br> | ||
tue thu 9:30-10:45 <br> | tue thu 9:30-10:45 <br> | ||
− | 530-127 | + | 530-127<br> |
+ | |||
+ | this course has originally been developed by <br> | ||
+ | [http://me.stanford.edu/me_profile.php?sunetid=sheppard sheri shepard] | ||
+ | |||
|} | |} | ||
</div> | </div> | ||
<div class="spacer"> </div> | <div class="spacer"> </div> | ||
+ | |||
==goals== | ==goals== | ||
− | + | basic concepts of finite elements, with applications to problems confronted by mechanical designers. linear static, modal, and thermal formulations; nonlinear and dynamic formulations. students implement simple element formulations. application of a commercial finite element code in analyzing design problems. issues: solution methods, modeling techniques features of various commercial codes, basic problem definition. Individual projects focus on the interplay of analysis and testing in product design and development. prerequisite: math103, or equivalent. recommended: me80, or equivalent in structural and/or solid mechanics; some exposure to principles of heat transfer. | |
==grading== | ==grading== | ||
− | * | + | * 50 % homework - 4 homework assignments, 12.5% each <br> |
− | * 30 % midterm - open | + | * 30 % midterm - open book, open notes <br> |
− | * | + | * 20 % project - final homework project |
==syllabus== | ==syllabus== | ||
− | |||
− | |||
{| class="wikitable" style="text-align:center; width: 100%" | {| class="wikitable" style="text-align:center; width: 100%" | ||
|- | |- | ||
− | ! day !! date !! !! topic !! notes !! | + | ! day !! date !! !! topic !! notes !! hw !! |
− | + | ||
− | + | ||
|- | |- | ||
− | | | + | | tue || jan || 08 || introduction || [http://biomechanics.stanford.edu/me309/me309_c00.pdf c00] [http://biomechanics.stanford.edu/me309/me309_c01.pdf c01] || || kuhl |
+ | |- | ||
+ | | thu || jan || 10 || 1d bar elements || [http://biomechanics.stanford.edu/me309/me309_c02.pdf c02] || [http://biomechanics.stanford.edu/me309/me309_h01.pdf h01] || kuhl | ||
|- | |- | ||
− | | tue || jan || 15 || | + | | tue || jan || 15 || ansys - introduction (in terman 104) || [http://biomechanics.stanford.edu/me309/me309_c03a.pdf t01] [http://biomechanics.stanford.edu/me309/me309_c03b.pdf t02] [http://biomechanics.stanford.edu/me309/me309_c03c.pdf t03] || || bhargav |
|- | |- | ||
− | | thu || jan || 17 || | + | | thu || jan || 17 || 1d bar elements || [http://biomechanics.stanford.edu/me309/me309_c04.pdf c04] || || kuhl |
|- | |- | ||
− | | tue || jan || 22 || | + | | tue || jan || 22 || 1d beam elements || [http://biomechanics.stanford.edu/me309/me309_c05.pdf c05] || || kuhl |
|- | |- | ||
− | | thu || jan || 24 || | + | | thu || jan || 24 || 1d beam elements || [http://biomechanics.stanford.edu/me309/me309_c05.pdf c06]|| [http://biomechanics.stanford.edu/me309/me309_h02.pdf h02] || kuhl |
|- | |- | ||
− | | tue || jan || 29 || | + | | tue || jan || 29 || 2d trianglular elements || m03 || h05 || levenston |
|- | |- | ||
− | | thu || jan || 31 || | + | | thu || jan || 31 || ansys - modeling || m03 || || levenston |
|- | |- | ||
− | | tue || feb || 05 || | + | | tue || feb || 05 || 2d quadrilaterial elements || m04 || || |
|- | |- | ||
− | | thu || feb || 07 || | + | | thu || feb || 07 || isoparametric concept || m04 || h03,h04 || |
|- | |- | ||
− | | tue || feb || 12 || | + | | tue || feb || 12 || stress calculation - error analysis || m05 || || |
|- | |- | ||
− | | thu || feb || 14 || | + | | thu || feb || 14 || stress calculation - error analysis || m06 || || |
|- | |- | ||
− | | tue || feb || 19 || | + | | tue || feb || 19 || thermal analysis || m08 || || |
|- | |- | ||
− | | thu || feb || 21 || | + | | thu || feb || 21 || thermal analysis || m08 || || |
|- | |- | ||
− | | tue || feb || 26 || | + | | tue || feb || 26 || modeling errors - validation || m09 || || |
|- | |- | ||
− | | thu || feb || 28 || | + | | thu || feb || 28 || special topics in finite element analysis || || || |
|- | |- | ||
− | | tue || mar || 04 || | + | | tue || mar || 04 || midterm || || || |
|- | |- | ||
− | | thu || mar || 06 || | + | | thu || mar || 06 || special topics in finite element analysis || || || |
|- | |- | ||
− | | tue || mar || 11 || | + | | tue || mar || 11 || special topics in finite element analysis || || || |
|- | |- | ||
− | | thu || mar || 13 || | + | | thu || mar || 13 || special topics in finite element analysis || || || |
|- | |- | ||
− | | fri || mar || | + | | fri || mar || 14 || final projects due || || || |
|- | |- | ||
|} | |} | ||
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==additional reading== | ==additional reading== | ||
− | (1) | + | (1) cook rd: finite element modeling for stress analysis, john wiley & sons, 1995 <br> |
− | (2) | + | (2) buchanan gr: schaum's outline of finite element analysis, mc graw hill, 1994 <br> |
− | (3) | + | (3) logan dl.: a first course in the finite element method, cengage engineering, 2006 |
Latest revision as of 23:38, 13 February 2008
Contents |
[edit] me309 - finite element analysis in mechanical design
ellen kuhl - ekuhl.at.stanford.edu winter 2008 this course has originally been developed by |
[edit] goals
basic concepts of finite elements, with applications to problems confronted by mechanical designers. linear static, modal, and thermal formulations; nonlinear and dynamic formulations. students implement simple element formulations. application of a commercial finite element code in analyzing design problems. issues: solution methods, modeling techniques features of various commercial codes, basic problem definition. Individual projects focus on the interplay of analysis and testing in product design and development. prerequisite: math103, or equivalent. recommended: me80, or equivalent in structural and/or solid mechanics; some exposure to principles of heat transfer.
[edit] grading
- 50 % homework - 4 homework assignments, 12.5% each
- 30 % midterm - open book, open notes
- 20 % project - final homework project
[edit] syllabus
day | date | topic | notes | hw | ||
---|---|---|---|---|---|---|
tue | jan | 08 | introduction | c00 c01 | kuhl | |
thu | jan | 10 | 1d bar elements | c02 | h01 | kuhl |
tue | jan | 15 | ansys - introduction (in terman 104) | t01 t02 t03 | bhargav | |
thu | jan | 17 | 1d bar elements | c04 | kuhl | |
tue | jan | 22 | 1d beam elements | c05 | kuhl | |
thu | jan | 24 | 1d beam elements | c06 | h02 | kuhl |
tue | jan | 29 | 2d trianglular elements | m03 | h05 | levenston |
thu | jan | 31 | ansys - modeling | m03 | levenston | |
tue | feb | 05 | 2d quadrilaterial elements | m04 | ||
thu | feb | 07 | isoparametric concept | m04 | h03,h04 | |
tue | feb | 12 | stress calculation - error analysis | m05 | ||
thu | feb | 14 | stress calculation - error analysis | m06 | ||
tue | feb | 19 | thermal analysis | m08 | ||
thu | feb | 21 | thermal analysis | m08 | ||
tue | feb | 26 | modeling errors - validation | m09 | ||
thu | feb | 28 | special topics in finite element analysis | |||
tue | mar | 04 | midterm | |||
thu | mar | 06 | special topics in finite element analysis | |||
tue | mar | 11 | special topics in finite element analysis | |||
thu | mar | 13 | special topics in finite element analysis | |||
fri | mar | 14 | final projects due |
[edit] additional reading
(1) cook rd: finite element modeling for stress analysis, john wiley & sons, 1995
(2) buchanan gr: schaum's outline of finite element analysis, mc graw hill, 1994
(3) logan dl.: a first course in the finite element method, cengage engineering, 2006