Answers:
Mmax = 170.67×106 Nmm
σb max = 248.42 N/mm2
F.O.S. = 1.24
Homework Answers
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Answers:
Mmax = 170.67×106 Nmm
σb max = 248.42 N/mm2
F.O.S. = 1.24
5. Calculate the...
Answers: Mmax = 170.67×106 Nmm σb max = 248.42 N/mm2 F.O.S. = 1.24 5. Calculate the maximum moment in the beam shown. I...
Answers:
Mmax = 170.67×106 Nmm
σb max = 248.42 N/mm2
F.O.S. = 1.24
5. Calculate the maximum moment in the beam shown. If the elastic section modulus of the beam is Z 687000 mm3, calculate the maximum bending stress in the beam. Calculate the factor of safety against failure if the design stress of the steel is ơd 309 N/mm2. 12 kN/m 8m 4m Fig. Q5
Answers: IXX = 54.47×106 mm4 Ztop = 722826 mm3 Z bottom = 242474 mm3 Mmax hog...
Answers:
IXX = 54.47×106 mm4
Ztop = 722826 mm3
Z bottom = 242474 mm3
Mmax hog = – 90.00×106 Nmm
Mmax sag = + 51.42×106 Nmm
9. Calculate Ixx for the T-section shown in Fig. Q9a. From this, calculate the elastic section modulus for the top and the bottom of the section. This section is loaded as shown in Fig. Q9b. Calculate the maximum hogging and sagging moment in the beam and plot the stress distribution through the depth of...
Answers: Z = 85017 mm3 Mallow = 26.27 kNm 4. Calculate the elastic section modulus for...
Answers:
Z = 85017 mm3
Mallow = 26.27 kNm
4. Calculate the elastic section modulus for the 12mm channel section shown. Note: Z-xx ymax If the design stress of the steel is ơd-309 N/mm2 calculate the moment capacity of the section (i.e the maximum bending moment the section can sustain) 96mm 12mm Fig. Q4
Answers: IXX = 92.11×106 mm4 wmax = 15.53 kN/m 1/R = 0.0085 m-1 6. Calculate lxx for the steel I-section shown in Fig....
Answers:
IXX = 92.11×106 mm4
wmax = 15.53 kN/m
1/R = 0.0085 m-1
6. Calculate lxx for the steel I-section shown in Fig. Q6a. This section is to span a distance of 9 m and is loaded as shown in Fig. Q6b. Calculate the magnitude of the maximum UDL that can be sustained by the beam if the design stress of the steel is 239 N/mm2. Calculate the curvature of the beam at midspan under that maximum UDL, taking Estel...
For the Wide-Flange I-beam with distributed load as in figure below calculate: 1) the shear force...
For the Wide-Flange I-beam with distributed load as in figure below calculate: 1) the shear force V(x) and the bending moment M(x) and plot the shear and bending moment diagrams 2) the maximum bending moment MMAX For the section of the beam with Mwax calculate for each of the points A and B shown in the figure: (a) the flexural stress og (b) the principal stresses 01, 02, 03 c) the principal stress angle Upi (d) the absolute maximum shear...
PLEASE SEE TEXT ANSWERS AT THE BOTTOM. I HAVE WORKED OUT PART A. PLEASE COMPLETE REST...
PLEASE SEE TEXT ANSWERS AT THE BOTTOM. I HAVE WORKED OUT PART A.
PLEASE COMPLETE REST OF Q.
ANSWERS: B) 2.59 kN, 0.473 MPa
C) 399
A simple wooden beam is constructed by bonding four 12.5 x 75 mm planks together with an adhesive as shown in Fig 1.1. load P Adhesive joint Fig. 01.1 - Cross-section through Constructed Beam The beam is Em long and must carry a load P as shown in Fig. 01.2. load P 2.5m 2.5m...
Hi, could you please provide a clear and easy to follow worked solution for the following questions. I will leave feedba...
Hi,
could you please provide a clear and easy to follow worked
solution for the following questions. I will leave feedback that
reflects the quality of your response.
The correct answers are
21.0kN.m
50.2MPa and 38.7MPa
22.6kN.m
A beam with the section illustrated in the figure below is subjected to pure bending with compressive stresses induced above the neutral axis. The beam is steel with a yield strength of 450 MPa, modulus of elasticity of 210 GPa and Poisson's ratio...
x Incorrect Two beams support a uniformly distributed load of w = 28 kN/m, as shown....
x Incorrect Two beams support a uniformly distributed load of w = 28 kN/m, as shown. Beam (1) is supported by a fixed support at A and by a simply supported beam (2) at D. In the unloaded condition, beam (1) touches, but exerts no force on, beam (2). Beam (1) has a depth of 300 mm, a moment of inertia of 11 = 125 x 106 mm, a length of L = 3.4 m, and an elastic modulus of...
Question 1 (Total 100/3 Marks) Figure 1 (all units are mm) shows a simply supported beam of span ...
Question 1 (Total 100/3 Marks) Figure 1 (all units are mm) shows a simply supported beam of span 2500 mm with a 5 kN/m load. The cross-section of the beam is a composite section made from two steel plates attached to the top and bottom of a timber section. The top steel plate is 5 mm wide and 20 mm deep. The bottom steel plate is also 5 mm wide but 10 mm deep. The timber section is 50 mm...
Question 3 (continued) Determine by suitable calculations: a) the torsion constant (K) of the cro...
Question 3 (continued) Determine by suitable calculations: a) the torsion constant (K) of the cross-section; b) the maximum value of torsional shear stress (in N/mm2) present at any point within c) (6 marks) (6 marks) the beam, and state clearly where this occurs; the vertical deflection (in mm) of the centroid of the cross-section at the free end of the beam; (6 marks) d) the total vertical deflection (in mm) of the point A located at the outside edge of...
Answers:
Mmax = 170.67×106 Nmm
σb max = 248.42 N/mm2
F.O.S. = 1.24
5. Calculate the maximum moment in the beam shown. If the elastic section modulus of the beam is Z 687000 mm3, calculate the maximum bending stress in the beam. Calculate the factor of safety against failure if the design stress of the steel is ơd 309 N/mm2. 12 kN/m 8m 4m Fig. Q5
Answers:
IXX = 54.47×106 mm4
Ztop = 722826 mm3
Z bottom = 242474 mm3
Mmax hog = – 90.00×106 Nmm
Mmax sag = + 51.42×106 Nmm
9. Calculate Ixx for the T-section shown in Fig. Q9a. From this, calculate the elastic section modulus for the top and the bottom of the section. This section is loaded as shown in Fig. Q9b. Calculate the maximum hogging and sagging moment in the beam and plot the stress distribution through the depth of...
Answers:
Z = 85017 mm3
Mallow = 26.27 kNm
4. Calculate the elastic section modulus for the 12mm channel section shown. Note: Z-xx ymax If the design stress of the steel is ơd-309 N/mm2 calculate the moment capacity of the section (i.e the maximum bending moment the section can sustain) 96mm 12mm Fig. Q4
Answers:
IXX = 92.11×106 mm4
wmax = 15.53 kN/m
1/R = 0.0085 m-1
6. Calculate lxx for the steel I-section shown in Fig. Q6a. This section is to span a distance of 9 m and is loaded as shown in Fig. Q6b. Calculate the magnitude of the maximum UDL that can be sustained by the beam if the design stress of the steel is 239 N/mm2. Calculate the curvature of the beam at midspan under that maximum UDL, taking Estel...
For the Wide-Flange I-beam with distributed load as in figure below calculate: 1) the shear force V(x) and the bending moment M(x) and plot the shear and bending moment diagrams 2) the maximum bending moment MMAX For the section of the beam with Mwax calculate for each of the points A and B shown in the figure: (a) the flexural stress og (b) the principal stresses 01, 02, 03 c) the principal stress angle Upi (d) the absolute maximum shear...
PLEASE SEE TEXT ANSWERS AT THE BOTTOM. I HAVE WORKED OUT PART A.
PLEASE COMPLETE REST OF Q.
ANSWERS: B) 2.59 kN, 0.473 MPa
C) 399
A simple wooden beam is constructed by bonding four 12.5 x 75 mm planks together with an adhesive as shown in Fig 1.1. load P Adhesive joint Fig. 01.1 - Cross-section through Constructed Beam The beam is Em long and must carry a load P as shown in Fig. 01.2. load P 2.5m 2.5m...
Hi,
could you please provide a clear and easy to follow worked
solution for the following questions. I will leave feedback that
reflects the quality of your response.
The correct answers are
21.0kN.m
50.2MPa and 38.7MPa
22.6kN.m
A beam with the section illustrated in the figure below is subjected to pure bending with compressive stresses induced above the neutral axis. The beam is steel with a yield strength of 450 MPa, modulus of elasticity of 210 GPa and Poisson's ratio...
x Incorrect Two beams support a uniformly distributed load of w = 28 kN/m, as shown. Beam (1) is supported by a fixed support at A and by a simply supported beam (2) at D. In the unloaded condition, beam (1) touches, but exerts no force on, beam (2). Beam (1) has a depth of 300 mm, a moment of inertia of 11 = 125 x 106 mm, a length of L = 3.4 m, and an elastic modulus of...
Question 1 (Total 100/3 Marks) Figure 1 (all units are mm) shows a simply supported beam of span 2500 mm with a 5 kN/m load. The cross-section of the beam is a composite section made from two steel plates attached to the top and bottom of a timber section. The top steel plate is 5 mm wide and 20 mm deep. The bottom steel plate is also 5 mm wide but 10 mm deep. The timber section is 50 mm...
Question 3 (continued) Determine by suitable calculations: a) the torsion constant (K) of the cross-section; b) the maximum value of torsional shear stress (in N/mm2) present at any point within c) (6 marks) (6 marks) the beam, and state clearly where this occurs; the vertical deflection (in mm) of the centroid of the cross-section at the free end of the beam; (6 marks) d) the total vertical deflection (in mm) of the point A located at the outside edge of...
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