Please use ANSYS SOFTWARE Task 1My ID: 21080238"A 100 mm diameter stainless steel pipe is subjected to a downward force of n N (asshown in figure 1), where n corresponds to the last three digits of your UWE ID (e.g.,if your ID is 14020175, n = 175). Determine the displacement at the end of the pipe(the point of load application) and the maximum stress for the following twoscenarios":Pipe thickness = 8 mmPipe thickness12 mmUse ANSYS software to model and analyze the pipe. Write a concise report outliningthe findings and describing how the displacement and maximum stress are affectedby the pipe's thickness.Note: For precise modeling, use the dimensions exactly as they appear in the givenfigure.50 mmFixed end300 mmBnN1 m0.5 m 0.5 m100 mmFigure 1

Answered: Image /qna-images/answer/ccf8e65a-5499-4156-9d49-19d28122efe4.jpg

Answered: Task 1 My ID: 21080238 "A 100 mm…

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

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I need to find the forces in each tube but I keep getting stuck. I have been getting really long equations to do algibra onwhich I suspect might be where the error was comming from. The values I have tried are F2 = -0.97786, and -4.889 kips
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Needs Complete typed solution with 100 % accuracy. Don't use chat gpt or ai i definitely upvote you. Be careful Downvote for ai or chat gpt answer.
Posted this 2 times and a wrong answer was given twice ….. Pls do if u know it
A2.3 Please help. Written on paper not typed on computer or keyboard please. Need help both questions. Please include all units, steps to the problem and information such as its direction or if it is in compression or tension. Thx.
Learning Goal: To use Mohr's circle to determine the principal stresses, the maximum in-plane shear stress, and the average normal stress in an element. The state of plane stress on an element is shown below. Let oz= 30.0 MPa, O, = -100.0 MPa, and Try = 50.0 MPa 100 MPa 50.0 MPa 30.0 MPa Part A - Construction of Mohr's circle for the state of stress For the element shown, construct Mohr's circle for the state of stress shown associated with the x plane. First, select the center of Mohr's circle (point C) and select the point that represents the state of plane stress shown (point A). Given these two points, determine the length of the line connecting these two points, which represents the radius R of the Mohr's circle.
Need help with engineering Materials review problem
OP •C h W The man in the diagram is trying to move a large box by pushing on it with a force, P. The box weighs 300 N and its centre of gravity is located in the centre of the box (point C). Given: a = 1.8 m b = 0.8 m h= 0.9 m What is the minimum force that will cause the box to tip? Please include the unit ("N") within your answer and round to 3 significant figures (e.g. if the calculated answer was 55.562 Newtons please input: 55.6 N). Answer: What is the minimum coefficient of static friction that will permit tipping to occur? Please do not include the unit s (as there are none) within your answer and round to 3 significant figures (e.g. if the calculated answer was 55.562 please input: 55.6). Answer:
Please complete parts 1-3.
please solve with neat hand writing so I can understand
1. This question relates to stresses due to combined loading. A shaft subjected to combined torsion and axial thrust is designed to resist a shear stress and a compressive stress as shown in Figure Q1. Using the information provided in Table Q1: Figure Q1 Txy 90 mpa ox 130 mpa a) Determine the principal stresses and show them on a sketch of a properly oriented element. b) Determine the maximum shear stresses and associated normal stresses and show them on a sketch of a properly oriented element. c) Calculate the safety factors according to the three theories (Rankine, Tresca, and Von- Mises). Take the yield strength of the material as, Oyield = 250 MPa. d) Sketch the Mohr's circle for the stressed component location and indicate the stress states, principal stresses, and maximum shear stress.
What modulus of elasticity in tension is required to obtain a unit deformation of 0.00105 m/m from a load producing a unit tensile stress of 44,000 psi? A. 42,300 x 10⁶ psi B. 41,202 x 10⁶ psi C. 43,101 x 10⁶ psi D. 41,905 x 10⁶ psi Please solve the Problem elaborately and Refer Machine Elements and Stresses Equations from the figures or use other shortcut Methods you have or you may Solve both or in more different methods the better ?. Your solution will be use as reference for my Future Board Exam preparation/review/study. Thank you so much dear your work will be appreciated much and rated excellently.

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