M (kN.m)e.V (kN)A cantilevered beam has of length L = 10 m and is subjected to a vertical load P₁ = 50 kN, an axialload P₂ = 100 kN passing through the neutral axis, a moment M = 200 kN.m, and a uniformlydistributed load w = 30 kN/m, as shown. The cross-sectional view and dimensions are illustratedbelow, with point C representing the centroid of the cross-section.300 mmWP₁ولا25 mmNeutral Axis200 mmAxDP2MSupport Material50 mmSTRESS FORMULATION25 mmN2Normal stress:σN=Beam's cross-sectionM₂yL (m)Bending stress:ΤρTorsional shear stress:T=d.Draw the shear force diagram for the beam. Show all your work.V, QTransverse shear stress:T=Q=YA'orQ=PW1₂tBEAM SIGN CONVENTIONVVtywL(m)Neutral AxisPzM(w):Positive internal shearM MPositive internal momentBeam sign conventionCROSS-SECTIONAL MOMENTS OF INERTIA ABOUT THE CENTROIDybh³Quadratic (second)1, =l₁ =moment of inertia12hb312πρ1₂ = ly=4Polar moment ofinertia1x =bh3+hb312πρDraw the bending moment diagram for the beam. Show all your work.P₁Centroid location:Parallel axis theorem:Σχιλι= Al1c ==Σ (1c₁ + A₁ d₁²)AL42DL (m)Neutral AxisP₂Mx (m)

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Answered: M (kN.m) e. V (kN) A cantilevered beam…

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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M (kN.m) e. A cantilevered beam has of length L = 10 m and is subjected to a vertical load P₁ = 50 kN, an axial load P₂ = 100 kN passing through the neutral axis, a moment M = 200 kN.m, and a uniformly distributed load w = 30 kN/m, as shown. The cross-sectional view and dimensions are illustrated below, with point C representing the centroid of the cross-section. 300 mm W A x D W 2 L (m) P₁ ولا 25 mm Neutral Axis 200 mm P2 Support Material 50 mm M STRESS FORMULATION 25 mm N Normal stress: ON= Beam's cross-section M₂y Bending stress: Τρ Torsional shear stress: T= V, Q Transverse shear stress: T = It Q=YA' or Q= Draw the bending moment diagram for the beam. Show all your work. P₁ A L 42 D L (m) Neutral Axis P₂ M x (m) BEAM SIGN CONVENTION V V Positive internal shear M M Positive internal moment Beam sign convention CROSS-SECTIONAL MOMENTS OF INERTIA ABOUT THE CENTROID y bh³ Quadratic (second) 1,= ly = moment of inertia 12 hb³ 12 πρ 1₂ = ly=4 bh3+hb3 Polar moment of inertia 1x = 12 1x =…
PROBLEM 2: Use the area method. The beam shown is supported by a pin at A and a roller at D. The end of the beam hanger at point B carries a load equal to 10 kN. 10 kN 8 kN/m 6 kN/m 1m 5 kN/m 13 kN/m 3 m 4 3 'В 1 m 3m 33 kN m
Question 1) F=20 kN single load, M=23 kN.m moment and w=19 kN/m distributed load are acting on the beam whose loading condition is given in the figure . The length L is also given as L=5 m . The cross-sectional properties of the beam are; body height y g =248 mm , body thickness x g =12 mm , flange width x f = 196 mm , flange height y f = 20 mm . Point E on the section is located just below the flange-body junction. It is desired to determine the stress state in the section taken from the C level of the beam. According to this; Question1-A ) Find the normal force (N C ) at point C. ( Write your result in kN .) Question1-B ) Find the shear force (V C ) at point C. ( Write your result in kN .) Question1-C ) Find the bending moment ( MC) at point C. ( Write your result in kN.m. )
100 N/m, A simply supported beam ABCD is subjected to a linearly distributed load, with wo two concentrated loads, one at C and the other at D, and a point moment at B as shown in Figure 4.1. The angles of the point loads are: 0₁ = 40° and 0₂ = 30° and the dimensions are a = = 5 m, b = 3 m and c = 2 m. b) Use the method of sections to derive expressions for the internal resultant loadings, i.e., normal (N) and shear (V) forces as well as bending moment (M) at the cross-section of the beam as functions of x. The expressions must be valid for 0≤x≤a and a ≤x≤ b and b≤x≤c. Check that your equations provide values at the midpoint of AB that are consistent with your results in part a. Wo A X a B 1 500 N 의 200 N·m b Figure 4.1. - Simply supported beam 0₂ 2 300 N
As shown in the figure below, a cantilever beam has a span of 6m long. And it is subjected to a concentrated load 6kN acting 4m from the support and a clockwise moment of 30kN.m at the free end. E = 200 GPa and I = 100,000,000 ??^4 . (Use area moment method) a) Determine the deflection at the free end due to concentrated load only. b) Determine the maximum deflection at the free end.
Question 1) F=22 kN single load, M=26 kN.m moment and w=17 kN/m distributed load are acting on the beam whose loading condition is given in the figure. The length L is also given as L=5 m. The cross-sectional properties of the beam are; body height yg=239 mm, body thickness xg=17 mm, flange width xf=185 mm, flange height yf=15 mm. Point E on the section is located just below the flange-body junction. It is desired to determine the stress state in the section taken from the C level of the beam. According to this; Question 1-D) Find the moment of inertia of the beam section. (Do your operations by converting the lengths to meters. Take at least 4 digits for the decimal part of your result and use the expression E for the decimal part. Write it as 5E-3 instead of 0.005.)
A simply supported beam of span 7 m carries loads as shown in Fig. D and E. Point E is the mid point of DB. Take E = 200 GPa and I = 150 x 106 mm². A 2 m 24 KN C 2m X Compute deflection at 6 kN/m E ||— 1.5 m² 1.5 m- B
1. A horizontal simply-supported beam is loaded as shown in Figure 1. It has a rectangular cross section, 70 mm by b mm. (a) Determine the vertical reaction forces at A and E. (b) If the allowable deflection at mid-span is 2 mm downwards, determine the dimension, b, of the beam needed. Use E= 150 GPa. 10kN 6kN/m 4kNm [36.26mm] Section A-A of Beam AF 0.2m 0.3m 0.8m E olo 水水 0.2m 0.3m 3kN Figure 1
Q/ An overhanging beam is subjected to the combined loading shown in Figure below. Determine the slope at support 4 and the deflection at C. 50 KN 25 kN/m 50 kN C D m www 5m 5m 4 m
The compound beam is subjected to the loadings as shown in the figure below. Use E-200x106 kPa and I=125x106 m². Determine the following: a. The deflection at A; b. The slope at point B; c. The displacement at D; and d. The illustation of the elastic curve of the compound beam. A 1.0m 1.5m B 18 kN 3m 35 kN-m 1.5m D 3m 14 kN/m Jooh
An 8-m span simple beam carries a uniform load of 2 kN/m and a concentrated load of 4 kN, two meters from the left support. Calculate the deflection one meter on the right of the maximum deflection. Use E = 170 %3D x 10^6 KPa and I = 80 x 10^6 mm^4. 10 mm 17 mm 14 mm 20 mm
Consider the beam shown in (Figure 1). Suppose that P = 6 kip, w = 1.2 kip/ft. Point E is just to the right of the 6-kip load. Follow the sign convention. Figure -6 ft + D 6 ft W B 4 ft- E -4 ft T 1 of 1 Part A Determine the normal force at section passing through point D. Express your answer to three significant figures and include the appropriate units. ND = Submit Part B VD = Submit Determine the shear force at section passing through point D. Express your answer to three significant figures and include the appropriate units. Part C Value MD Request Answer = Value Request Answer Determine the moment at section passing through point D. Express your answer to three significant figures and include the appropriate units. ULA Units Value Submit Request Answer Units ? Units ?

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