Part A: Determine the stress-concentration factor K due to the 20 mm diameter circular cutout in the member.Answer: K=2.27Part B: Determine the stress-concentration factor K due to the 10 mm radius shoulder fillets in the member.Answer: K=1.6Part C: Sing the information obtained about the stress-concentration factors in the member, determine the maximum applicable axial force PP that can be applied to the member.Answer : 2.19*10^5 NI couldn't find the solution of part C. Can you solve the part C, please?Thanks!!(Other informations are in the attachment) 12 of 13Learning Goal:To determine the effects of certain geometric shapes, namely fillets and circular cutouts, on the stress distributions inside a rigid body and to determine the maximum applicable axialforce in the same rigid body while considering these stress concentrations.The member shown below is made of steel (ol - 150 MPa) that is 83.0 mm thick. The member is subjected to an axial force Pthat is applied at both ends. Let r= 10.0 mm.w- 60.0 mm, h - 40.0 mm, and d- 20.0 mm.Part A- Stress-concentration factor due to a circular cutout

GIVEN :-σmax=150 MPastress concentration factor due to circular cutout: k=2.27stress concentration…

Part A: Determine the stress-concentration factor K due to the 20 mm diameter circular cutout in the member. Answer: K=2.27 Part B: Determine the stress-concentration factor K due to the 10 mm radius shoulder fillets in the member. Answer: K=1.6 Part C: Sing the information obtained about the stress-concentration factors in the member, determine the maximum applicable axial force PP that can be applied to the member. Answer : 2.19*10^5 N I couldn't find the solution of part C. Can you solve the part C, please? Thanks!! (Other informations are in the attachment

Part A: Determine the stress-concentration factor K due to the 20 mm diameter circular cutout in the member. Answer: K=2.27 Part B: Determine the stress-concentration factor K due to the 10 mm radius shoulder fillets in the member. Answer: K=1.6 Part C: Sing the information obtained about the stress-concentration factors in the member, determine the maximum applicable axial force PP that can be applied to the member. Answer : 2.19*10^5 N I couldn't find the solution of part C. Can you solve the part C, please? Thanks!! (Other informations are in the attachment

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter8: Applications Of Plane Stress (pressure Vessels, Beams, And Combined Loadings)

Section: Chapter Questions

Problem 8.5.11P: The hollow drill pipe for an oil well (sec figure) is 6,2 in. in outer diameter and 0.75 in. in...

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