| Statuss(Aktīvs) | Izdruka | Arhīvs(0) | Studiju plāns Vecais plāns | Kursu katalogs | Vēsture |
| Course title | Structural Analysis II |
| Course code | BūvZ3078 |
| Credit points (ECTS) | 4.5 |
| Total Hours in Course | 121.5 |
| Number of hours for lectures | 16 |
| Number of hours for seminars and practical classes | 32 |
| Independent study hours | 72 |
| Date of course confirmation | 10/03/2021 |
| Responsible Unit | Institute of Civil Engineering and Wood Processing |
| Course developers | |
| Dr. sc. ing., Bruno Ķirulis |
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| Prior knowledge | |
| BūvZ2039, Selected Topics in Strength of Materials BūvZ2040, Structural Analysis I BūvZ2048, Basic Theory of Structures Fizi2006, Physics II Fizi2007, Physics I Mate1023, Mathematics I |
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| Replaced course | |
| BūvZB019 [GBUVB019] Structural Analysis II |
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| Course abstract | |
| Conditions for structural composition, model analysis methods of statically undeterminate systems (beams, trusses, frames) are gained. Methods for determination of internal forces in elements of statically indeterminate systems and system displacements, produced by external loads and temperature changes are acquired. | |
| Learning outcomes and their assessment | |
| Understanding of essential features of statically determinate and statically indeterminate systems. Skills to put into calculations a Force method for analysis of statically indeterminate systems. Test Nr. 1, Homework Nr. 1.
Skills to put into calculations a Displacement method for analysis of statically indeterminate systems. Test Nr. 2, Homework Nr. 2. Competence to assess adequacy of results obtained. |
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| Course Content(Calendar) | |
| Comparison of statically determinate and statically indeterminate systems, degrees of indeterminacy. 4 h.
2. Force Methods compatibility equation system. 2 h. 3. Determination of compatibility equation systems coeficients and unknown parameters. 3 h. 4. Choice of basic systems, symmetric structures as basic systems. 3 h. 5. Statically indeterminate frames. Analysis by means of Force Method. 4 h. 6. Obtaining shear forces from bending moment diagrams. 2 h. 7. Statical and kinematic compatibility tests for internal forces diagrams. 3 h. 8. Analysis of statically indeterminate trusses by means of Force Method. 3 h. 9. Statically indeterminate arches, their analysis by means of Force Method. 2 h. 10. Statically indeterminate structures, subjected to temperature differences and support deflections. Analysis by means of Force Method. 4 h. 11. Deflection methods equation system, determination of coeficients. 4 h. 12. Effectiveness comparison of Force and Deflection Methods for different types of structures. 2 h. 13. Adwanced analysis of symmetric statically indeterminate structures. 3 h. 14. Analysis of statically indeterminate structures by means of numerical approximation methods. 3 h. 15. Finite Element Method’s algorithms for structural analysis. 3 h. 16. Structural analysis software based on Finite Element Method. 3 h. |
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| Requirements for awarding credit points | |
| Credit test will be enrolled, if student know basic definitions of static, and he/she is able to discuss on results of calculations and to verify the results by alternative approach. It is required positive assessment of two classroam tests and two homeworks. The course ends with examination including two calculation tasks in writing and one selected topic from theory (answer orally). | |
| Description of the organization and tasks of students’ independent work | |
| The first homework, 1st test. Analysis of statically indeterminate beam or frame by mean of Force Method. The second homework, 2nd test. Analysis of statically indeterminate beam or frame by mean of Deflection Method. | |
| Criteria for Evaluating Learning Outcomes | |
| Student will have positive assessment of test, if at least 50% of calculation records are correct. The home work will be assessed basing on two criteria: 1) fulfilment of equilibrium conditions between internal and external forces and correct force diagramms; 2) ability to discuss on results of calculations and to verify the results by alternative approach. For each of three examination tasks 0-3 scoring points will be enrolled. Additional point (in case of existing 9 points) if student answer on additional question, not included in current examination tasks. | |
| Compulsory reading | |
| Bulavs F., Radiņš I. Būvmehānikas ievadkurss. Rīga: RTU izdevniecība, 2010. 250 lpp.
2. Melderis I., Teters G. Būvmehānika: mācību grāmata. Rīga: Zvaigzne, 1977. 560 lpp. 3. Siliņš L. Būvstatika: mācību grāmata. Rīga: Zvaigzne, 1976. 232 lpp. |
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| Further reading | |
| 1. Hulse R., Cain J.A. Structural mechanics: worked examples. R. Hulse, J.A. Cain. Basingstoke: Palgrave Macmillan, 2009. Ir LLU FB 1 eks.
2. Stavridis L. T. Structural systems: behaviour and design. L.T. Stavridis. London: Thomas Telford, 2010. 2 sēj. 3. McKenzie, William M. C. Examples in structural analysis/ William M.C. McKenzie.- 2nd edition. - Boca Raton, FL: CRC Press, 2017., 819 p. |
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| Periodicals and other sources | |
| 1. Būvmehānika - palīglīdzeklis studentiem [tiešsaiste], [skatīts 10.04.2018.]. Pieejams: www.llu.lv/buvmehanika 2. Būvinženieris: Latvijas Būvinženieru savienības izdevums. Rīga: Latvijas Būvinženieru savienība, 2006- ISSN : 1691-9262 | |
| Notes | |
| Compulsory Course for the Professional Bachelor’s study programme “Civil Engineering” | |