STEEL DESIGN KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS STEEL DESIGN REVIEW OF TIMBER DESIGN BEARING PROBLEM TIMBER DESIGN SOIL MECHANICS REVIEW OF.

Slides:

Advertisements

Similar presentations

BEAMS (FLEXURE) BEAM- COLUMNS SHEAR / CONC. LOADS

Advertisements

Beam Design Beam Design Civil Engineering and Architecture

Design of Steel Flexural Members

Limit States Flexure Shear Deflection Fatigue Supports Elastic Plastic

Beams Stephen Krone, DSc, PE University of Toledo.

ENCE 710 Design of Steel Structures

REVIEW OF STEEL DESIGN KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS

Advanced Flexure Design COMPOSITE BEAM THEORY SLIDES

Lecture 15- Bar Development

LRFD-Steel Design Dr. Ali Tayeh Second Semester

ONE-WAY SLAB. ONE-WAY SLAB Introduction A slab is structural element whose thickness is small compared to its own length and width. Slabs are usually.

Wall Form Design Example (Continued)

WOOD, SOILS, AND STEEL INTRO KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS STEEL DESIGN SOIL MECHANICS REVIEW OF TIMBER DESIGN BENDING MEMBERS DEFLECTION.

ENCE 455 Design of Steel Structures

Unless otherwise noted, the content of this course material is licensed under a Creative Commons Attribution 3.0 License.

Chap. (6) Compression Members Columns: Beam-Columns: Columns Theory:

BEARING OR CRUSHING Bearing Stresses (Compression Perpendicular to the Grain) Allowable stresses for compression perpendicular to the grain are available.

B-14 1 – Full section Yielding (L b ≤ L p ): M n = M p = FyZ x (AISC F 2.1) 2 – Inelastic Lateral Torsional Buckling ( L p < L b ≤ L r ): 3 – Elastic Lateral.

Compression Members.

Compression Members.

BC-11 The horizontal beam column shown below is subjected to service live loads as shown. The member is laterally braced at its ends. Check its capacity.

Copyright © 2011 Pearson Education South Asia Pte Ltd

Combined Bending & Axial Forces (BEAM – COLUMNS)

Copyright Joseph Greene 2003 All Rights Reserved 1 CM 197 Mechanics of Materials Chap 15: Design of Beams for Strength Professor Joe Greene CSU, CHICO.

Beam-Columns. Members Under Combined Forces Most beams and columns are subjected to some degree of both bending and axial load e.g. Statically Indeterminate.

Chap. (7) BEAMS Beams are an essential element of any structure, they carry loadings transversely applied to their axis. Various types of beams are encountered.

Compression Members.

Combined Bending & Axial Forces (BEAM – COLUMNS)

Ø = resistance factor for shear = 0.90 Vn = nominal shear strength

LRFD-Steel Design 1.

Beams. BEAMS A structural member loaded in the transverse direction to the longitudinal axis. Internal Forces: Bending Moments and Shear.

Dr. Ali I. Tayeh First Semester

LRFD- Steel Design Dr. Ali I. Tayeh First Semester Dr. Ali I. Tayeh First Semester.

Jurg Conzett – Traversina Bridge

CTC 422 Design of Steel Structures

LRFD – Floor beam Unbraced top flange. Lateral Torsion Buckling  We have to check if there is plastic failure (yielding) or lateral-torsion buckling.

LRFD- Steel Design Dr. Ali I. Tayeh second Semester Dr. Ali I. Tayeh second Semester.

Session 15 – 16 SHEET PILE STRUCTURES

Department of Building Engineering An-Najah National University

WOOD DESIGN REVIEW KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS STEEL DESIGN SOIL MECHANICS REVIEW OF TIMBER DESIGN BENDING MEMBERS DEFLECTION MEMBERS.

REVIEW LECTURE #1 KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS

Structural Curriculum for Construction Management and Architecture Students 1 Prepared by: Ajay Shanker, Ph.D., P.E. Associate Professor Rinker School.

Beam Design Beams are designed to safely support the design loads.

SOIL DESIGN REVIEW KNOWLEDGE BASE REQUIRED: SOIL MECHANICS.

General Comparison between AISC LRFD and ASD

N.W.F.P. University of Engineering and Technology Peshawar 1 By: Prof Dr. Akhtar Naeem Khan Lecture 09: Compression Members.

WOOD DESIGN REVIEW KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS STEEL DESIGN SOIL MECHANICS REVIEW OF TIMBER DESIGN BENDING MEMBERS DEFLECTION MEMBERS.

The Engineering of Foundations

Structures Agenda: Forces & Architectural Form - review

62323: Architectural Structures II

Design of Beams for Flexure

AISC Design Aids for Bending (Long Version)

Outline: Introduction: a ) General description of project b) Materials

Design of Steel Beams Dr. Bashar Behnam.

contents Design of beams (week 11,12,13), (10,17,24 Nov.)

Columns and Other Compression Members

Mahesh Dhakal Stud Wall Design Mahesh Dhakal

Design of Beams - Limit States

Compression Members.

REVIEW OF STEEL DESIGN KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS

EAT 415 :ADVANCED STEEL BUILDING DESIGN PLATE GIRDER

Find: Lightest I Beam fy=50,000 [lb/in2] unfactored axial

Design of Steel Beams Dr. Bashar Behnam.

Reinforced concrete column

KNOWLEDGE BASE REQUIRED:

KNOWLEDGE BASE REQUIRED:

Deflection of Beams In addition to being safe, the structure must be serviceable ; Serviceable structure is one that performs satisfactorily, not causing.

Presentation transcript:

STEEL DESIGN KNOWLEDGE BASE REQUIRED: STRENGTH OF MATERIALS STEEL DESIGN REVIEW OF TIMBER DESIGN BEARING PROBLEM TIMBER DESIGN SOIL MECHANICS REVIEW OF SOIL MECHANICS vertical stresses lateral stresses

LECTURE #4(CONT) BASIC SOIL MECHANICS REVIEW: = - VERTICAL STRESSES: = VERTICAL STRESS (PSF, TSF,KN/m 2 ) CALCULATE TOTAL LATERAL STRESS, (TOTAL STRESS) Ka=0.307 (EFFECTIVE STRESS) q=100 kPa or KN/m 2 Draw stress diagram, calculate resultant & location CLASS PROBLEM:

LECTURE #4(CONT) BASIC SOIL MECHANICS REVIEW: LATERAL STRESSES: 30.7KN/m KN/m 2

LECTURE #4(CONT) BASIC SOIL MECHANICS REVIEW: LATERAL FORCE: 30.7KN/m KN/m KN 30.98KN R= =138.43KN KN 1.62m

LECTURE #4(CONT) BASIC STEEL DESIGN REVIEW: Review of AISC Construction Manual (cont): Compact vs. Non- Compact Compact Beam are rolled beam that can achieve the plastic moment. Stress Distribution of I Beam

LECTURE #4(CONT) BASIC STEEL DESIGN REVIEW: Review of AISC Construction Manual (cont): Compact Sections- are symmetrical about the y-y axis webs/flanges must have certain width-thickness ratios (Spec Section - Table B5.1,P.5-36) compression flange must be adequately braced against lateral buckling When the theoretical yield stress F’y is equal to or exceeded by the yielding stress than the section is no longer compact.

LECTURE #4(CONT) BASIC STEEL DESIGN REVIEW: Design Procedure for Bending(using Sx) 1. Determine the Maximum Bending Moment 2. Compute the Required Section Modulus based on allowable stresses Fb=.66Fy (compact) [equat. F1-1,Chapt. F1.1] or Fb=.60 Fy (for non compact)[equat. F1-5,Chapt. F1.2] 3. Enter the ASD selection table and find the nearest tabulated value of Sx. The lightest weight and the most economical section that will serve for the yield strength stated is in bold face, and should be selected adjacent to or above the required Sx. 4. Check F’y column to be sure of compact section. 5. Check the lc & lu to make sure of adequate bracing.

LECTURE #4(CONT) BASIC STEEL DESIGN REVIEW: Note:For Members with Compact or Non-compact sections. Recall lc is the max. unbraced length in feet of the compression flange at which the allowable bending is taken at 0.66 Fy Recall lu is the max. unbraced length in feet of the compression flange for which allowable bending stress may be taken at 0.60 Fy when Cb=1

LECTURE #4(CONT) BASIC STEEL DESIGN REVIEW: Recall l, lc, and lu if l is the given length between lateral supports then, lc>l use Fb=.66Fy (assuming compact section) lu>l>lc use Fb=.60Fy l>lu use the charts of allowable moments in beams (p to 2-212) where Cb=1 Note: Cb is the bending coefficient dependent upon moment gradient (F1.3) Cb=1 when the bending moment at any point within an unbraced length is larger than that at both ends of this length when frames are braced against joint translation. when considering a conservative value for cantilever

LECTURE #5 BASIC STEEL DESIGN REVIEW: Given: Select a beam of Fy=36ksi steel subjected to a bending moment of 125 kip-ft., having its compression flange braced at 6 ft. intervals. Solution: Assume compact section, Fb=0.66Fy=23.8ksi 1. Maximum Bending Moment Given in Problem 2. Sx(reqd)=M/Fb=(125x12)/23.8=63 cu.in. 3. Nearest Tabulated Value W16x W12x Since W16x40 is bold face, it is the lightest suitable section that will serve for that yield strength.

LECTURE #5 BASIC STEEL DESIGN REVIEW: Given: Select a beam of Fy=36ksi steel subjected to a bending moment of 125 kip-ft., having its compression flange braced at 6 ft. intervals. 5. From the table, Lc=7.4 ft. >6.0 ft. so the bracing is adequate and the assumed allowable stress of.66Fy is correct. Use W16x40 Solution contd: 4. A check of the F’y column shows a dash, indicating that F’y is greater than 65 ksi. Therefore, the shape is compact.

LECTURE #5(CONT) BASIC STEEL DESIGN REVIEW: Design Procedure for Bending(using Mr) 1. Enter the ASD selection table and find the nearest tabulated value of Mr. The lightest weight and the most economical section that will serve for the yield strength stated is in bold face, and should be selected adjacent to or above the required Mr. Recall: Mr is the beam resisting moment if shape has non compact flanges if shape has compact sections

LECTURE #5 BASIC STEEL DESIGN REVIEW: 2. Check F’y column to be sure of compact section. 3. Check the lc & lu to make sure of adequate bracing. Given: Select a beam of Fy=36ksi steel subjected to a bending moment of 125 kip-ft., having its compression flange braced at 6 ft. intervals. Solution: Assume compact section, Fb=0.66Fy=23.8ksi 1. Enter Bending Moment Given in Problem Nearest Tabulated Value W16x k-ft W12x k-ft Since W16x40 is bold face, it is the lightest suitable section that will serve for that yield strength.

LECTURE #5 BASIC STEEL DESIGN REVIEW: 3. Check F’y column to be sure of compact section. OK the same as before 4. Check the lc & lu to make sure of adequate bracing. Lc=7.4ft > 6.0ft therefore Mr is valid Given: Select a beam of Fy=36ksi steel subjected to a bending moment of 125 kip-ft., having its compression flange braced at 6 ft. intervals. Use W16x40