A concentrated load of P = 19 KN is applied to the upper end of a pipe with length L = 5 m. The outside diameter of the pipe is D = 330 mm and the inside diameter is d = 300 mm. Determine the magnitude of the maximum tension bending stress in the pipe. B O 84.9 MPa O 100.4 MPa O 79.2 MPa O 116.8 MPa O 63.5 MPa O

A concentrated load of P = 19 KN is applied to the upper end of a pipe with length L = 5 m. The outside diameter of the pipe is D = 330 mm and the inside diameter is d = 300 mm. Determine the magnitude of the maximum tension bending stress in the pipe. B O 84.9 MPa O 100.4 MPa O 79.2 MPa O 116.8 MPa O 63.5 MPa O

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter7: Analysis Of Stress And Strain

Section: Chapter Questions

Problem 7.2.4P: .4 The stresses on an clement arc known to be sx= 120 MPa, sy= 100 MPa, and txy= 75 MPa. Find the...

See similar textbooks

Similar questions

A concentrated load of P = 20 kN is applied to the upper end of a pipe with length L = 5 m. The outside diameter of the pipe is D = 330 mm and the inside diameter is d = 300 mm. Determine the magnitude of the maximum tension bending stress in the pipe. B A 105.9 MPa O 120.7 MPa O 113.9 MPa O 94.0 MPa 89.4 MPa L D
A concentrated load of P = 19 kN is applied to the upper end of a pipe with length L = 5 m. The outside diameter of the pipe is D = 330 mm and the inside diameter is d = 300 mm. Determine the magnitude of the maximum tension bending stress in the pipe. P B L D A 89.9 MPa O 114.9 MPa 106.2 MPa 84.9 MPa O 100.2 MPa
A round Steel rod of 50 mm diameter is bent into an arc of radius 10m. What is the maximum stress in the rod? Take E = 2×105 N/mm2
1 99 The cross-sectional area of the conduit is A = 0.004 m, and its wall thickness is t= 3 mm. It will safely support an average shear stress in the walls of 100 MPa. Based on this criterion, what is the largest axial torque T that can safely be applied to a section of the conduit? hwith P 2 in and in
Find stress Force=2 N Area of cross section=D1 m2
Find the value of maximum principal stress Maximum shear stress=80 MPa Minimum principal stress-30 MPa
A cylinder consists of an outer tube of internal and external diameters of 16 cm and 18 cm respectively shrunk on to an inner tube of internal and external diameters 8 cm and 16.01 cm respectively. The internal pressure developed in the cylinder is 300 MPa. If E= 200 GPa, find the maximum hoop stress developed in each tube.
Evaluate stresses and strains in the cross section of the dam shown in figure for the loads indicated. Take E= 30 GPa and Possion's ratio of 0.25. Choose CST element and apply appropriate constitutive relation. 10KN 4m 1m 20kN 3m 77
800 lb 600 lb 500 lb E A В O00 -4 ft- 6 ft- 3 ft- 2 ft Given: A W10 x 15 carrying the load shown. Neglect self-weight. Find: The maximum bending stress. Summarize the results on a stress diagram.
The drive shaft for a truck (outer diameter 60 mm and inner diameter 40 mm) is running at 43 Hz. If the shaft transmits 156 kW, what is the maximum shear stress in the shaft in MPa?
Consisting of chrome-nickel and bronze,the largest horizontal P force it can carry, and chromium-nickelCalculate the length change that will occur in the cable.Cross Section Areas: A chrome-nickel = 3 cm2A bronze = 6 cm2Elasticity modules: E chrome-nickel = 215 Gpa, E bronze = 90 GpaSafety Stresses: (σem) bronze = 100 Mpa, (σem) chromium-nickel = 600 Mpa
An aluminum rod is hanging from one end. The rod is 1 m long and has a square cross section 20 mm by 20 mm. Find the extension of the rod resulting from its own weight. Take E = 70 GPa and the unit weight = 27 kN/m3.