8.35 Steady-state creep data taken for a stainless steel at a stress level of 70 MPa(10,000 psi) are given as follows:T(K)10x 102.5 x 109771089If it is known that the value of the stress exponent n for this alloy is 7.0, compute the steady-statecreep rate at 1250 K and a stress level of 50 MPa (7250 pst).

Answered: Image /qna-images/answer/ed0d25a3-a3cd-4185-b6cf-a0cbacae33e6.jpg

8.35 Steady-state creep data taken for a stainless steel at a stress level of 70 MPa (10,000 psi) are given as follows: T(K) 1.0 x 10 977 2.5 x 10 1089 If it is known that the value of the stress exponent n for this alloy is 7i0, compute the steady-state creep rate at 1250 K and a stress level of 50 MPa (7250 psi).

8.35 Steady-state creep data taken for a stainless steel at a stress level of 70 MPa (10,000 psi) are given as follows: T(K) 1.0 x 10 977 2.5 x 10 1089 If it is known that the value of the stress exponent n for this alloy is 7i0, compute the steady-state creep rate at 1250 K and a stress level of 50 MPa (7250 psi).

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

See similar textbooks

Related questions

Q: 8.22 Consider the brass alloy for which the stress-strain behavior is shown in Figure 8.12. A…

Q: Determine the endurance limit of the material with a force 30 lbs led to a facture after 105…

Q: Iculate the activation energy (in J/mol) for creep for an alloy having the steady state creep havior…

Q: 10.3 A mild steel, known to have a proportional limit of 34,000 psi, was subjected to a tension…

A: The modulus of elasticity, also known as Young's modulus, is a measure of the stiffness of a…

Q: Given: A ground steel rod with known diameter d is operating at temperature T. You are designing…

Q: Steady-state creep rate data are given here for some alloy taken at 200°C (473 K): i Es (h-¹) 2.2 x…

Q: A structural component is fabricated from an alloy that has a plane strain fracture toughness of 45…

Q: 2) A 1 in Dia x 3 in long mild steel hammer head is to be heat treated for surface hardening. If the…

Q: Calculate the activation energy in j/mol for the creep of an alloy having the steady state creep…

Q: Steady-state creep rate data are given here for some alloy taken at 200°C (473 K): i, (h) a (MPa)…

A: Find the steady state creep rate .

Q: Compute the stress in the bar.

A: Here, is strain developed in the bar. is compressed length. is initial length of the bar.. is…

Q: Question-7. Steady-state creep data taken for an alloy at a stress level of 160 MPa are given below.…

A: Given, Data for stress level of 160 MPa The stress component , n =6.8 R = 8.3145 J/mol-K To find…

Q: Steady-state creep data taken for an iron at a stress level of 136 MPa are given here: If it is…

A: Given data: σ=136 MPan=8.3 Need to determine the creep rate at 1300 K.

Q: A plate contains an internal flaw that extends through the plate thickness. The plate is to be…

A: (A) Write the given data. b=1 mc=100 mmLf=1.25 mma=9.34×10-2 mmY=1.03

Q: Sintered silicon nitride parts are expected to experience tensile stresses 50% of the ultimate…

A: Given data:- tensile stresses (σ) =50% of the ultimate tensile strength Specific surface energy (γ)=…

Q: 8. A cylindrical bar of steel with a diameter of 10 mm is deformed elastically by applying a force…

Q: 25 30 35 40 45 50 |12. 10° (R-h) х103 х103 х103 х103 х103 х103 Larson-Miller 100,000 |2.2- 10° (K-Һ)

A: stress=80MPa(11600psi)Temperaure=700°C(973k) To-Find:- Time to rupture =.................hours

Q: The turbine blade root is found to contain a surface fatigue crack of 3.3 mm during a routine…

A: To determine how many more stop-start cycles should be used before addressing the crack in the…

Q: A cylindrical specimen of a cold-worked brass has a ductility (%EL) of 33%. If its cold-worked…

Q: For the stress-strain curve shown below, please estimate the properties indicated. Please do your…

A: Given:Stress-Strain curve.To find:Various mechanical properties enlisted.

Q: You need to design a metallic glass for use in industry. The glass transition temperature of the…

A: Given that, Temperature of metallic glass, T=250 °C,Time for permanent tensile stress, tuse=6…

Concept explainers

Design Against Fluctuating Loads

Machine elements are subjected to varieties of loads, some components are subjected to static loads, while some machine components are subjected to fluctuating loads, whose load magnitude tends to fluctuate. The components of a machine, when rotating at a high speed, are subjected to a high degree of load, which fluctuates from a high value to a low value. For the machine elements under the action of static loads, static failure theories are applied to know the safe and hazardous working conditions and regions. However, most of the machine elements are subjected to variable or fluctuating stresses, due to the nature of load that fluctuates from high magnitude to low magnitude. Also, the nature of the loads is repetitive. For instance, shafts, bearings, cams and followers, and so on.

Design Against Fluctuating Load

Stress is defined as force per unit area. When there is localization of huge stresses in mechanical components, due to irregularities present in components and sudden changes in cross-section is known as stress concentration. For example, groves, keyways, screw threads, oil holes, splines etc. are irregularities.

Question

100%

8.35 Steady-state creep data taken for a stainless steel at a stress level of 70 MPa
(10,000 psi) are given as follows:
T(K)
10x 10
2.5 x 10
977
1089
If it is known that the value of the stress exponent n for this alloy is 7.0, compute the steady-state
creep rate at 1250 K and a stress level of 50 MPa (7250 pst).

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

This is a popular solution!

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Trending now

This is a popular solution!

Step by step

Solved in 2 steps with 2 images

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.

Similar questions

6.27 Compute the dislocation density in tungsten if the flow stress is controlled by the stress necessary to operate a Frank--Read source. The shearstress in the slip plane is 50 MPa. Take G = 166 GPa.
1. Suppose that you have measured the strain aging kinetics of a high-strength low-alloy (HSLA) steel and obtained the following results: Aging Temperature (°C) Aging Time (min) ΔΥ (MPa) 150 240 40 130 1800 40 Determine (using a mathematical rather than graphical approach) the time necessary to obtain a strengthening increment, AY, of 40 MPa at an ageing temperature of 120°C. State any assumptions made in order to arrive at your approximation.
In a laboratory creep experiment at 1273K, a steady-state creep rate of 5 ××10-1 %, per hour is obtained in a metal alloy. The creep mechanism for this alloy is known to be dislocation climb with an activation energy of 200 kJ>mol. Predict the service temperature in (°C) for a creep rate of 8.68 ×10-5 %, per hour. (Assume that the laboratory experiment duplicated the service stress.)
Calculate the activation energy in J/mol for creep for an alloy having the steady state creep behavior shown in the figure. Use the data taken at stress level of 300MPa and temperature of 650C and 730C. Assume that the stress component n is independent of the temperature.
Suppose that an axle component of an automobile is fabricated from steel alloy with a plane strain fracture toughness of 45 MPa.m0.5 is exposed to a stress of 255 MPa and if the maximum internal half-length of the crack of the material is 3.2 mm, compute the dimensionless parameter (Y) of the material.
Calculate the ductility of this steel alloy in %EL.
Q3: Two material were tested in tension, the first is aluminum alloy has stress-strain curve define by 300 MPa was fracture after 35% reduction in area. The other a copper alloy has stress-strain curve define by=100+120 MPa was fracture after 98% elongation. Which alloy have more toughness? Support your answer with the sketch.?
Tensile and fully reversed loading fatigue tests were conducted for a certain steelalloy and revealed the tensile strength and endurance limit to be 1200 and 550 MPa,respectively. If a rod of this material supply were subjected to a static stress of 600MPa and fully-reversed oscillating stresses whose total range was 700 MPa. Assuming garber relationship will this rod fail by fatigue failure