Course syllabus

# Balkteori

Beam Theory

## VSMN35, 7,5 credits, A (Second Cycle)

## General Information

## Aim

## Learning outcomes

## Contents

## Examination details

## Admission

Admission requirements:## Reading list

## Contact and other information

Beam Theory

Valid for: 2019/20

Decided by: PLED V

Date of Decision: 2019-04-01

Elective for: V4-ko

Language of instruction: The course will be given in Swedish

The course shall give knowledge about the action of straight and curved beams and about theories for calculation of stiffness, deformations, stresses and instability of beams loaded in 3D, including influence of eigenstresses, and with cross-sections that may vary along the beam and have arbitrary geometrical shape, including thin walled cross-sections.

Knowledge and understanding

For a passing grade the student must

- Be able to give account of different kinds of beams, their mechanical action and performance, and phenomena that limit their servicabilty.
- Be able to give account of the beam theories of Bernoulli-Euler, Timoshenko, St Venant and Vlasov, and for the basics of analysis of instability of beams.
- Be able to explain the concepts, quantities and constants that are used in advanced beam calculations

Competences and skills

For a passing grade the student must

- Know how to calculate deformations, stresses and instability load for a straight linear elastic beam with constant or varying arbitrarily shaped cross-section and loaded in 3D by forces, bending moments, torque, secondary moment and eigenstress.
- Know how to calculate, exact or numerically approximately, the stiffness matrix and loading vector for beams of the above kind and how to use these for analysis of structures composed of beams.
- Know how to calculate the cross-section constants for a cross-section of arbitrary shape.
- Know how to make account of a beam design or analysis calculation.
- Know how to use tables and handbooks with information about beam constants and instabilities.

Judgement and approach

For a passing grade the student must

- Be able to assess the way of action and properties of a beam (deformation pattern, stiffness properties, stress distribution and instability phenomena) based on the geometrical shape and loading of the beam.
- Be able to assess appropriate method of calculation.

The course relates to methods of calculation elastic beams with symmetric/unsymetric, open/closed, solid/hollow constant/varying cross sections, exposed to loading in 3D, including distributed bending, torque, secondary moment and eigenstress:

- A summary of different types of beams, phenomena that limit structural serviceability and theories for beam analysis.
- The Bernoulli-Euler and Timoshenko theories for the response to bending moments, shear forces, normal force and eigenstress.
- The St Venants and Vlasov theories for analysis of torsion.
- Second order theory for instability phenomena like buckling in bending and torsion and transverse loading.
- Matrix formulation of beam stiffness and loading for computer based analysis of 3D framework structures.
- Second order theory for analysing instability phenomena such as 3D buckling and tilting.

The course comprises two hand-in tasks: they relate to experimental testing and theoretical calculation of deformations and instability loads.

Grading scale: TH - (U,3,4,5) - (Fail, Three, Four, Five)

Assessment: The course examination comprises two hand-in tasks and a written examination. Both parts have to be passed. The mark is based on the sum of the points of the two parts.

The examiner, in consultation with Disability Support Services, may deviate from the regular form of examination in order to provide a permanently disabled student with a form of examination equivalent to that of a student without a disability.

- VSMA05 Structural Mechanics

Required prior knowledge: VSMF05 Engineering Modelling: Analysis of Structures.

The number of participants is limited to: No

The course overlaps following course/s: VSM091, VSMF15

- Compendium,lecture notes, exercises and formulas. Instructions for assignments.
- Austrell. P.-E. et al.: CALFEM - A finite element toolbox to MATLAB. Studentlitteratur, 2004, ISBN: 9789188558237.

Course coordinator: Professor Per Johan Gustafsson, Per-Johan.Gustafsson@construction.lth.se

Course homepage: http://www.byggmek.lth.se

Further information: Lectures and exercises. It also includes experimental tests with documentation of experimental setups and results.