The overhang beam is subjected to the uniform distributed load having an intensity of w = 46 kN/m (Figure 1)
Part A
Determine the maximum shear stress developed in the beam.
The overhang beam is subjected to the uniform distributed load having an intensity of w = 46 kN/m (Figure 1)
The overhang beam is subjected to the uniform distributed load having intensity of w = 55 kN/m. Determine shear stress developed in the beam.
The beam having a cross-section as shown is subjected to the distributed load w (1) Calculate the moment of inertia, I (2) If the allowable maximum normal stress ơmax-20 MPa, determine the largest distributed load 5. w. (3) If w 1.5 kN/m, determine the maximum bending stress in the beam. Sketch the stress distribution acting over the cross-section. 100 mm 50mm 120 mm 3 m50 mm 3 m
The simply supported beam is subjected to a uniform distributed load, w of 30 kN/m in the negative y-direction and a point load, P of 15 kN in the negative z-direction. The total length, L of the beam is 6 m. Answer the questions that follow: 'n Eenvoudige opgelegde balk word belas met 'n uniform verspreide belasting van w 30 kN/m in die negatiewe y-rigting en 'n puntlas P = 15 kN in die negatiewe z-rigting. Die totale lengte, L...
Question 3. A uniform load of intensity 12 kN/m and a concentrated load of magnitude 2.4 kN are supported by a beam ABC with overhang at one end (see Figure 3). Draw the shear-force and bending-moment diagrams for this beam. Also, determine the position of maximum moment with respect to point A. 12 kN/m 2.4 kN A С B -1.6 m -1.6 m -1.6 m
The intensity of the distributed load acting on the beam is w = 2.6 kN/m (Figure 1) Figure < 1 of 1 > A Am Part A Determine the magnitude of reaction at A. Express your answer to three significant figures and include the appropriate units. NA = Value Units Submit Request Answer Part B Determine the x and y components of reaction at B using scalar notation. Express your answers using three significant figures separated by a comma. Ivo...
Question 3. A uniform load of intensity 12 kN/m and a concentrated load of magnitude 2.4 kN are supported by a beam ABC with overhang at one end (see Figure 3). Draw the shear-force and bending-moment diagrams for this beam. Also, determine the position of maximum moment with respect to point A. (20 marks) 12 kN/m 2.4 kN A C B -1.6 m -1.6 m -1.6 m I Figure 3
Question 3. A uniform load of intensity 12 kN/m and a concentrated load of magnitude 2.4 kN are supported by a beam ABC with overhang at one end (see Figure 3). Draw the shear- force and bending-moment diagrams for this beam. Also, determine the position of maximum moment with respect to point A. (20 marks) 12 kN/m 2.4 kN А C B -1.6 m 1.6 m *1.6 m Figure 3
Question 3. A uniform load of intensity 12 kN/m and a concentrated load of magnitude 2.4 kN are supported by a beam ABC with overhang at one end (see Figure 3). Draw the shear- force and bending-moment diagrams for this beam. Also, determine the position of maximum moment with respect to point A. (20 marks) 12 kN/m 2.4 kN A С B ΟΙΟΙΟ -1.6 m 1.6 m - 1.6 m Figure 30
Strength of Material If the shaft is subjected to a uniform distributed torque of to = 12 kN-m/m. The shaft is made of 2014-T6 aluminum alloy and is fixed at A and C. Part A Determine the maximum shear stress developed in the shaft. The shaft in is used to transmit 29 hp while turning at 590 rpm. Part A Determine the maximum shear stress in the shaft. The segments are connected together using a fillet weld having a radius of 0.18 in.
Beam ABC with an overhang at one end supports a partial uniform load of intensity 12 kN/m and a concentrated moment of magnitude 4 kN·m at C (see figure). Draw the shear-force and bending-moment diagrams for this beam.