It is a problem of expansion and shrinkage of steel material so that the slightly smaller hole of a steel bushing of 1.999 diameter with the following process/materials/data to apply: Coefficient of expansion of carbon steel = 0.0000068 in/in-°F. Temperature raised by gas heating = 24.5 °F Cooling media to use dry ice with boiling point of -109.3 °F (-78.5 °C). Shrinkage rate below boiling point is 0.00073 in/in. Determine the final clearance between the expanded steel bushing hole against the shrinkage of the steel shaft. A. 0.000793 in B. 0.000693 in C. 0.000750 in D. 0.0008 in. Please solve elaborately and include the Units. Thank you dear, your solution will be appreciated much.

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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It is a problem of expansion and shrinkage of steel material so that the slightly smaller hole of a steel bushing of 1.999 diameter with the following process/materials/data to apply: Coefficient of expansion of carbon steel = 0.0000068 in/in-°F. Temperature raised by gas heating = 24.5 °F Cooling media to use dry ice with boiling point of -109.3 °F (-78.5 °C). Shrinkage rate below boiling point is 0.00073 in/in. Determine the final clearance between the expanded steel bushing hole against the shrinkage of the steel shaft. A. 0.000793 in B. 0.000693 in C. 0.000750 in D. 0.0008 in. Please solve elaborately and include the Units. Thank you dear, your solution will be appreciated much.
where: J = polar moment of inertia = T Dª /32 (for solid shaft)
c = distance from neutral axis to the farthest fiber
T = torque
c = r (for circular cross section)
7. Bending Stress(S:) Si =
d = diameter
For rectangular beam S = 6 M
b h?
Mc
where: M = moment
F
c = distance of farthest fiber from neutral axis
| = moment of inertia about the neutral axis
| = bh/12 (for rectangular cross section)
I M
c Sf
L
Z = section modulus
Y
8. Strain and Elongation Strain =
Stress
FL
Stress =
A
E
Strain
FL
Y =
AE
AY
where: y = elongation due to applied load
L = original length
F = force
A = area
S = stress
9. Thermal Elongation; Stresses
y = kL (t2 - t1) S = E! = kE (t2 - t1)
where: k = coeficient of thermal expansion, m/m-°C
For steel k = 6.5 x 10-6 in/in-F = 11.7 x 106 m/m-C
E = 30 x 10° psi
Relation between shearing and tensile stress based on theory of failure:
Samax = Sty /2
Smax = Sty
10. Variable Stress
1 Sm Sa
FS Sy S,
Sy = yield point
where: FS = factor of safety
Sn = endurance limit
Smax + Smin
S. = variable component stress =
Smax - Smin
Sm = mean stress =
2
2
Smax = maximum stress
11. Poisson's Ratio(u) = is the ratio of lateral unit deformation to axial unit deformation.
Smin = minimum stress
E
F
E = strain =-
AE
where: G = shear modulus of elasticity
2G
W2 – W1
Ey
t2 - ty
Lateral Strain
Ey Ez
Ex
L2 -L,
Ex
L1
Ez
Longitudin al Strain
Ex
t,
Transcribed Image Text:where: J = polar moment of inertia = T Dª /32 (for solid shaft) c = distance from neutral axis to the farthest fiber T = torque c = r (for circular cross section) 7. Bending Stress(S:) Si = d = diameter For rectangular beam S = 6 M b h? Mc where: M = moment F c = distance of farthest fiber from neutral axis | = moment of inertia about the neutral axis | = bh/12 (for rectangular cross section) I M c Sf L Z = section modulus Y 8. Strain and Elongation Strain = Stress FL Stress = A E Strain FL Y = AE AY where: y = elongation due to applied load L = original length F = force A = area S = stress 9. Thermal Elongation; Stresses y = kL (t2 - t1) S = E! = kE (t2 - t1) where: k = coeficient of thermal expansion, m/m-°C For steel k = 6.5 x 10-6 in/in-F = 11.7 x 106 m/m-C E = 30 x 10° psi Relation between shearing and tensile stress based on theory of failure: Samax = Sty /2 Smax = Sty 10. Variable Stress 1 Sm Sa FS Sy S, Sy = yield point where: FS = factor of safety Sn = endurance limit Smax + Smin S. = variable component stress = Smax - Smin Sm = mean stress = 2 2 Smax = maximum stress 11. Poisson's Ratio(u) = is the ratio of lateral unit deformation to axial unit deformation. Smin = minimum stress E F E = strain =- AE where: G = shear modulus of elasticity 2G W2 – W1 Ey t2 - ty Lateral Strain Ey Ez Ex L2 -L, Ex L1 Ez Longitudin al Strain Ex t,
V1
Machine Elements
1. Cylinders Rolling in opposite direction:
Á. Tangential speed
B. Relation of diameter and speed
V, = V2 = T D, N, = r D2 N2
DI N1 = D2 N2
Speed of Driver
C. Speed Ratio =
Speed of the Driven
D. Center Distance = R, + R2 =
D, + D2
2. Cylinders Rolling in the same direction
Vi = V2 = n D, N; = n D2 N2
D, N1 = D2 N2
A. Tangential speed
B. Relation of diameter and speed
Speed of Driver
Speed of the Driven
D2 - D1
C. Speed Ratio =
D. Center Distance = R2 -R, =
Stresses
1. Stress (S) = a total resistance that a material offers to an applied load, Ib/in? , kg/cm² , KN/m?
2. Ultimate stress (Su ) - is the stress that would cause failure
3. Yield stress(Sy) - maximum stress without causing deformation
4. Allowable stress(Sal) = Ultimate stress/Factor of Safety
Sy
5. Design stress(Sa) - stress used in determining the size of a member. Sa =
or Sa =
FS
FS
where: FS = factor of safety
1. Tensile Stress (S.)
S =
For solid circular cross-section: A =
A
D2
#0,² -D²)
For hollow circular cross-section: A =
For rectangular cross-section: A = base x height = b x h
Fa
2. Compressive Stress(Sc)S. =
A
3. Shearing Stress(S.)
F
A. For single bolt of rivet needed to join to plates together. S, =
For single rivet: A = t/4 D²
For double riveted joint: A = 2(TT/4 D²)
where:
D
B. Shearing due to punching of hole.
S =
where A = 1 Dt (for punching a hole) A = 4 St (for square hole)
Where: S = length of side of square
C. Pressure needed to punch a hole, F: F = d x t x 80, tons
t = plate thickness
t = thickness, in
where: A = DL
Where: d = hole diameter, in
-Shear area
4. Bearing Stress(Sb)
Sp = Fb IA
a. Based on yield strength FS = Sy / Sall
5. Factor of safety(FS)
b. Based on ultimate strength FS = S,/ Sall
D
6. Torsional Shear Stress(Ss)
Projected Area
D
Transcribed Image Text:V1 Machine Elements 1. Cylinders Rolling in opposite direction: Á. Tangential speed B. Relation of diameter and speed V, = V2 = T D, N, = r D2 N2 DI N1 = D2 N2 Speed of Driver C. Speed Ratio = Speed of the Driven D. Center Distance = R, + R2 = D, + D2 2. Cylinders Rolling in the same direction Vi = V2 = n D, N; = n D2 N2 D, N1 = D2 N2 A. Tangential speed B. Relation of diameter and speed Speed of Driver Speed of the Driven D2 - D1 C. Speed Ratio = D. Center Distance = R2 -R, = Stresses 1. Stress (S) = a total resistance that a material offers to an applied load, Ib/in? , kg/cm² , KN/m? 2. Ultimate stress (Su ) - is the stress that would cause failure 3. Yield stress(Sy) - maximum stress without causing deformation 4. Allowable stress(Sal) = Ultimate stress/Factor of Safety Sy 5. Design stress(Sa) - stress used in determining the size of a member. Sa = or Sa = FS FS where: FS = factor of safety 1. Tensile Stress (S.) S = For solid circular cross-section: A = A D2 #0,² -D²) For hollow circular cross-section: A = For rectangular cross-section: A = base x height = b x h Fa 2. Compressive Stress(Sc)S. = A 3. Shearing Stress(S.) F A. For single bolt of rivet needed to join to plates together. S, = For single rivet: A = t/4 D² For double riveted joint: A = 2(TT/4 D²) where: D B. Shearing due to punching of hole. S = where A = 1 Dt (for punching a hole) A = 4 St (for square hole) Where: S = length of side of square C. Pressure needed to punch a hole, F: F = d x t x 80, tons t = plate thickness t = thickness, in where: A = DL Where: d = hole diameter, in -Shear area 4. Bearing Stress(Sb) Sp = Fb IA a. Based on yield strength FS = Sy / Sall 5. Factor of safety(FS) b. Based on ultimate strength FS = S,/ Sall D 6. Torsional Shear Stress(Ss) Projected Area D
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