| Course code |
06 21 1901 00 |
| Number of ECTS points |
2 |
| Course title in the language of instruction |
Computer structure analysis |
| Course title in Polish |
Computer structure analysis (Komputerowa analiza konstrukcji) |
| Course title in English |
Computer structure analysis |
| Language of instruction |
English |
| Form of classes |
|
Lecture |
Tutorials |
Laboratory |
Project |
Seminar |
Other |
Total of teaching hours during semester |
| Contact hours |
|
|
30 |
|
|
0 |
30 |
| E-learning |
No |
No |
No |
No |
No |
No |
|
| Assessment criteria (weightage) |
|
|
1.00 |
|
|
0.00 |
|
|
| Unit running the course |
Katedra Budownictwa Betonowego |
| Course coordinator |
mgr inż. Łukasz Sowa, dr inż. Tomasz Waśniewski |
| Course instructors |
dr inż. Ewelina Kołodziejczyk, mgr inż. Łukasz Sowa, dr inż. Tomasz Waśniewski |
| Prerequisites |
Prior to the course, students should be able to:
- Know the general knowledge in the field of structural mechanics and strength of materials,
- Collect the load on the individual elements of the structure in accordance with applicable
codes,
- Create standardized load combinations in accordance with applicable codes,
- Be able to calculate RC cross sections and reinforced concrete elements,
- Knowledge of the design requirements according to applicable codes,
- The ability to create a technical drawings, |
| Course learning outcomes |
- Student can define concepts of idealization and modeling of reinforced concrete structures in spatial terms
- Student can evaluate the accuracy of the spatial model building or part
- Student can create computational spatial models of the selected structure
- Student can discuss the results of the analysis of spatial model
- Student can justify the concept and of the computational model
- Student can calculate the reinforcement of the RC shells
|
| Programme learning outcomes |
- an ability to combine knowledge in the field of mathematics, physics and chemistry with complex theoretical and technical issues in the field of construction, and then ability to identify, formulate and solve advanced engineering and mathematical problems
- an ability to use engineering projects to create solutions that fulfill specific needs, taking into account public health, safety and well-being as well as global, cultural, social, environmental and economic factors, puts forward and examines hypotheses regarding simple research problems
- an ability to effectively communicate with many recipients, referring specialist topics in both Polish and foreign languages, skilfully conducts the debate
- an ability to gain and apply new knowledge as needed, using appropriate learning strategies, also in the field of advanced specialist and scientific knowledge
- an ability to critically assess knowledge and skills, recognize the importance of knowledge and international expert opinions in the right field
|
| Programme content |
1. The aim of the course is to enable the acquisition of knowledge in the field of optimization and dimensioning of reinforced concrete structures and reinforced concrete - steel using 3D numerical models.
2. The aim of the course is to enable the acquisition of spatial modeling design reinforced concrete. |
| Assessment methods |
Learning outcomes 1,2,3,4,5,6 - laboratory reports, participation in the discussion
|
| Grading policies |
The final grade is composed of:
- Reports from individual exercises - 90%
- Final discussion - 10%
|
| Course content |
Modelling of the geometry of the spatial RC structures (beams, columns, shells) with
steel elements. Analysis of the influence of the different ways of connections between the
steel and concrete at the internal forces.
Spatial analysis of RC tank with domed overlap:
- Modeling of shell structures using FEM
- Calculation of reinforcement including the methods of work of the tank,
- Applying the load - water pressure
Analysis of the spatial stiffness of the 3D model (3D frame):
- loads distribution at the particular elements,
- advanced properties of the elements (braces),
- releasing the deegrees of freedom in rod nodes nad analysis of the internal forces
variations,
- working with the 3D surface elements for load distribution at the elements,
Introducing of the principles of the RC structures idealization in the finite element method.
Presentation of the Robot Millennium suite, the particular modules of this software,
configuration and the personalisation of the user menu. Presentation of the main options.
Analysis and modelling of the columns - slab structure:
- modelling of the 3D model of the slab with columns and walls taking into account spring
supports, modelling cuts and openings,
- loading with edge load, surface and point loads, creating the load cases and
combinations,
- advanced meshing methods,
- definition of the reinforcement parameters of the shells,
- calculations of the reinforcement and preparing of slab drawings, |
| Basic reference materials |
- Technical documentation of Autodesk Robot Structural Analysis and ABC software
- Starosolski W., Konstrukcje żelbetowe według EUROKODU 2 i norm związanych Tom 1-4. PWN 2011
- Starosolski W., Komputerowe modelowanie betonowych ustrojów inżynierskich. Wybrane zagadnienia. Tom 1 i 2 Wydawnictwa Politechniki Śląskiej, Gliwice 2009
- Kobiak J., Stachurski W.; Konstrukcje żelbetowe. Arkady, Warszawa 1984
- Own materials
|
| Other reference materials |
- None
|
| Average student workload outside classroom |
26 |
| Comments |
|
| Updated on |
2019-06-03 12:40:27 |
| Archival course yes/no |
no |