Presentation is loading. Please wait.

Presentation is loading. Please wait.

Buckling of Column With Two Intermediate Elastic Restraints Thesis Presentation 15.11.2007 Author:Md. Rayhan Chowdhury Mohammad Misbah Uddin Md. Abu Zaed.

Published byIris Chase Modified over 8 years ago

Similar presentations

Presentation on theme: "Buckling of Column With Two Intermediate Elastic Restraints Thesis Presentation 15.11.2007 Author:Md. Rayhan Chowdhury Mohammad Misbah Uddin Md. Abu Zaed."— Presentation transcript:

1 Buckling of Column With Two Intermediate Elastic Restraints Thesis Presentation 15.11.2007 Author:Md. Rayhan Chowdhury Mohammad Misbah Uddin Md. Abu Zaed Khan Md. Monirul Islam Masud Supervisor: Dr. Mohammad Nazmul Islam P RESIDENCY U NIVERSITY

2 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-152 P RESIDENCY U NIVERSITY Introduction  Background –In a laterally loaded cross-bracing system, one bracing member will be under compression while the other member subjected to tension. The tension brace may be modeled as a discrete, lateral elastic spring attached to the compression member. Thus, the prediction of the elastic buckling loads of columns with two intermediate elastic restraints is therefore of practical interest.  Objectives –The main objective of this theoretical research is to find a set of stability criteria for Euler columns with two intermediate elastic restraints.  Scope –The scope of this thesis is the derivation of Euler column buckling theory.

3 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-153 P RESIDENCY U NIVERSITY Model Fig. Column with two intermediate elastic restraints P z, w x c1c1 c2c2 L a2La2L a1La1L Spring 1 Spring 2 Here,  Column Length, L  Flexural Rigidity, EI  Spring 1 –Stiffness, c 1 –Located at a 1 L (a 1 < L)  Spring 2 –Stiffness, c 2 –Located at a 2 L (a 1 ≤ a 2 ≤ L)  The entire column can be divided into three segments as –Segment-1: 0 ≤ x ≤ a 1 L –Segment-1: a 1 L ≤ x ≤ a 2 L –Segment-1: a 2 L ≤ x ≤ L

4 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-154 P RESIDENCY U NIVERSITY Governing equation for column buckling  Where i = 1, 2, 3 denote the quantity belonging to segment 1, segment 2 and segment 3.  and (1)for (2)for (3)for General Solution:

5 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-155 P RESIDENCY U NIVERSITY Continuity condition at a 1 (4) (5) Where, (6) (For deflection, slope, bending moment and shear force ) (7)

6 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-156 P RESIDENCY U NIVERSITY Continuity condition at a 2 (8) (9) Where, (10) (For deflection, slope, bending moment and shear force ) (11)

7 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-157 P RESIDENCY U NIVERSITY Continuation… (12) (13) (14) (15) Substituting Eqs. (1) and (2) into Eqs. (4)-(7), a set of homogeneous equations is obtained which may be expressed in forms of B i in terms of A i, i.e.,

8 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-158 P RESIDENCY U NIVERSITY Continuation… (16) (17) (18) (19) Substituting Eqs. (2) and (3) into Eqs. (8)-(11), another set of homogeneous equations is obtained which may be expressed in forms of C i in terms of B i, i.e.,

9 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-159 P RESIDENCY U NIVERSITY Continuation… (20) (21) (22) (23) Hence, Substituting Eqs. (12) - (15) into Eqs. (16)-(19), we get C i in terms of A i

10 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-1510 P RESIDENCY U NIVERSITY Boundary Condition (fixed – free) (24) (25) (26) (27) At the fixed end: Fig. Boundary condition, fixed - free P z, w x c1c1 c2c2 L a2La2L a1La1L Spring 1 Spring 2 At the free end:

11 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-1511 P RESIDENCY U NIVERSITY B. C. (fixed – free) continuation (24) (25) (26) (27) Differentiating the boundary equation: If we substitute the value of C i into Eqs. (26) and (27), the buckling problem involves only four constants A i (i = 1,2,3,4). a. Hence, we can develop the Eigen value equation from the boundary equation in form b. Where {A} = (A 1, A 2, A 3, A 4 ) and [M] is the coefficient matrix of {A}. Finally the determinant of matrix[M] yields the stability criteria.

12 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-1512 P RESIDENCY U NIVERSITY B. C. (fixed – free) continuation ξ 1 =20, ξ2=20: (ξ 1 =c 1 L 3 and ξ 2 =c 2 L 3 ) ξ 1 =20, ξ2=20: (ξ 1 =c 1 L 3 and ξ 2 =c 2 L 3 ) λ 2 = PL 2 /(EI) a2 α = 0 α = 0.2 α = 0.4 α = 0.6 α = 0.8 α = 1 0.14.71014.71014.714.70984.70914.7078 0.34.56674.56634.56094.53954.48884.4004 0.54.14764.14464.1073.98553.7943.642 0.74.10444.09624.00593.8073.69133.7816 0.94.46024.43964.24323.99094.07484.3574 The following tables present the buckling load parameter for different locations and stiffness of the intermediate restraints:

13 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-1513 P RESIDENCY U NIVERSITY Conclusions  Exact stability criteria for columns with two intermediate elastic restraints at arbitrary location along the column length are derived.  This stability criteria can be used to determine the buckling capacity of compressive member in a cross- bracing system.

14 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-1514 P RESIDENCY U NIVERSITY ?

15 Top right corner for field-mark, customer or partner logotypes. See Best practice for example. Slide title 40 pt Slide subtitle 24 pt Text 24 pt Bullets level 2-5 20 pt Department of Civil EngineeringUndergraduate Thesis Presentation2007-11-1515 P RESIDENCY U NIVERSITY Thank you all. P RESIDENCY U NIVERSITY

Download ppt "Buckling of Column With Two Intermediate Elastic Restraints Thesis Presentation 15.11.2007 Author:Md. Rayhan Chowdhury Mohammad Misbah Uddin Md. Abu Zaed."

Similar presentations

ENCE 455 Design of Steel Structures

ENCE 455 Design of Steel Structures
CHAPTER OBJECTIVES Discuss the behavior of columns.

CHAPTER OBJECTIVES Discuss the behavior of columns.
Beams Stephen Krone, DSc, PE University of Toledo.

Beams Stephen Krone, DSc, PE University of Toledo.
ENCE 710 Design of Steel Structures

ENCE 710 Design of Steel Structures
Definition I. Beams 1. Definition

Definition I. Beams 1. Definition
Beam-Columns.

Beam-Columns.
Spring 2007 Dr. D. M. McStravick Rice University

Spring 2007 Dr. D. M. McStravick Rice University
Introduction to Axially Loaded Compression Members

Introduction to Axially Loaded Compression Members
Beams and Frames.

Beams and Frames.
Copyright Joseph Greene 2003 All Rights Reserved 1 CM 197 Mechanics of Materials Chap 16: Deflections of Beams Professor Joe Greene CSU, CHICO Reference:

Copyright Joseph Greene 2003 All Rights Reserved 1 CM 197 Mechanics of Materials Chap 16: Deflections of Beams Professor Joe Greene CSU, CHICO Reference:
LRFD-Steel Design Dr. Ali Tayeh Second Semester 2010-2011.

LRFD-Steel Design Dr. Ali Tayeh Second Semester
Chapter 13 Buckling of Columns

Chapter 13 Buckling of Columns
Compression Members. Compression Members: Structural elements subjected only to axial compressive forces Stress:Uniform over entire cross section.

Compression Members. Compression Members: Structural elements subjected only to axial compressive forces Stress:Uniform over entire cross section.
CHAPTER 7 TRANSVERSE SHEAR.

CHAPTER 7 TRANSVERSE SHEAR.
Slide title In CAPITALS 50 pt Slide subtitle 32 pt Ericsson satsning på Public Safety - National Security HIØ Personalseminar – 9. mai 06 - Ed.

Slide title In CAPITALS 50 pt Slide subtitle 32 pt Ericsson satsning på Public Safety - National Security HIØ Personalseminar – 9. mai 06 - Ed.
Compression Members.

Compression Members.
ENGR 220 Section 13.1~13.2.

ENGR 220 Section 13.1~13.2.
CHAP 4 FINITE ELEMENT ANALYSIS OF BEAMS AND FRAMES

CHAP 4 FINITE ELEMENT ANALYSIS OF BEAMS AND FRAMES
Mechanics of Materials – MAE 243 (Section 002) Spring 2008 Dr. Konstantinos A. Sierros.

Mechanics of Materials – MAE 243 (Section 002) Spring 2008 Dr. Konstantinos A. Sierros.
CHAPTER OBJECTIVES Discuss the behavior of columns.

CHAPTER OBJECTIVES Discuss the behavior of columns.

Similar presentations

Ads by Google