The beam is constructed from two boards fastened together at the top and bottom with three rows of nails spaced every 4 in. 3 in. 3 in. Each nail can support a 360-lb shear force. • Part A Determine the maximum shear force V that can be applied to the beam. Express your answer to three significant figures and include appropriate units. HÁ ? V = Value Units

The beam is constructed from two boards fastened together at the top and bottom with three rows of nails spaced every 4 in. 3 in. 3 in. Each nail can support a 360-lb shear force. • Part A Determine the maximum shear force V that can be applied to the beam. Express your answer to three significant figures and include appropriate units. HÁ ? V = Value Units

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

See similar textbooks

Similar questions

For the simply supported beam subjected to the loading shown, sketch the shear force diagram. Determine the largest magnitude shear force. Let a=13.0 ft, b=4.0 ft, c= 8.0 ft, w = 17 kips/ft and M = 243 kip-ft. Give your answer in kips. Enter a positive number. M B C D a
Q1) A simply supported beam is 3 m long and carries a vertical load of 5 kN at point Im from the left-hand end. At a section 2 m from the left- hand end a clockwise couple of 3 kN.m is exerted, the axis the couple being horizontal and perpendicular to the longitudinal axis of the beam. The cross section of the beam shown in the figure. Determine the maximum bending stress set-up. All dimensions in mm 120 30 INEERIN 60 COLLE
1. For the simply supported beam with a T-shape cross-section as shown below, a- Draw the shear and moments diagram of the beam. b- Determine the maximum normal bending stress and specify its location. C- If the beam made from two boards determines the maximum shear stress in the glue necessary to hold the boards together along the seam where they are joined. d- Determine the shear stress at point B. 4 m 6.5 kN/m 6m- Glue 150 mm 30 mm 150 mm 30 mm
w1 B w2 Determine the shear force and bending moment at the one-third, middle, and two-thirds of the length of the beam (from point A), respectively. Use wl = 7 kN/m, w2 = 4 kN/m, and a =4 m. The shear force at the one-third of the length of the beam (from point A) in kN is (round to the nearest integer): kN The shear force at the middle of the length of the beam (from point A) in kN is (round to the nearest integer): KN The shear force at the two-thirds of the length of the beam (from point A) in kN is (round to the nearest integer): |kN The bending moment at the one-third of the length of the beam (from point A) in KN.m is (round to the nearest integer): kN.m The bending moment at the middle of the length of the beam (from point A) in kN.m is (round to the nearest integer): kN.m The bending moment at the two-thirds of the length of the beam (from point A) in kN.m is (round to the nearest integer): kN.m
Q1) A simply supported beam is 3 m long and carries a vertical load of 5 kN at point 1m from the left-hand end. At a section 2 m from the left- hand end a clockwise couple of 3 kN.m is exerted, the axis the couple being horizontal and perpendicular to the longitudinal axis of the beam. The cross section of the beam shown in the figure. Determine the maximum bending stress set-up. 100 60 All dimensions in mm 100 70 30 EERI
Q1) A simply supported beam is 3 m long and carries a vertical load of 5 kN at point 1m from the left-hand end. At a section 2 m from the left- hand end a clockwise couple of 3 kN.m is exerted, the axis the couple being horizontal and perpendicular to the longitudinal axis of the beam. The cross section of the beam shown in the figure. Determine the maximum bending stress set-up. 100 60 All dimensions in mm 100 70 30 EERING
QUESTION 3 If the allowable bending stresses for a beam in one application is 6 kip/in2 in tension. The cross-section of the beam is W8 x 40. If the beam is 10 foot long and simply supported and has a concentrated load applied at x = 3 ft as shown below. • Generate the shear force and bending moment diagram in terms of P; • Based on the allowable maximum bending moment you just obtained above, calculate/ input the mazimm allowable value of the load P: please, pay attention to units, and calculate your answer to 1 decimal place.. 3 ft 7 ft kip.
Which of the following is the shear force diagram for the beam below. 12 kN/ m C - 3 m 6m- Select one: Shear Force Shear Force
The beam in (Figure 1) is made from three boards nailed together as shown. If the moment acting on the cross section is M=650N.m determine the resultant force the bending stress produces on the top board. " 20 mm 200 mm M 25 mm 150 mm 20 mm
The beam is fabricated from two equivalent structural tees and two plates. Each plate has a height of 6 in. and a thickness of 0.5 in. The bolts are spaced at s = 8 in. Each bolt can resist a shear force of 17 kip. (Figure 1) Figure 6 in. 0.5 in. 3 in. V 1 in. 0.5 in. Part A Determine the maximum shear force V that can be applied to the cross section. Express your answer in kilopounds to three significant figures. V = IVE ΑΣΦ ↓↑ vec ? kip
At a given 7 locations/sections (0,1,2,3,4,5,6) on a beam of uniform I-section, the beam is subjected to a shear force of 100 kN. Plot a curve to show the variation of shear stress across the section and hence determine the ratio of the maximum shear stress to the mean shear stress given as;
Using a computer and step functions, calculate the shear and bending moment for the beam if P-16 kN. Use the specified increment AL. starting at point A and ending at the right-hand support. (Round the final answers to two decimal places) ها 1.2 m 16 kN/m AL-0.4m The maximum shear stress is The maximum bending moment is KN. kN m.