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How to Calculate and Solve for Compressional or P Waves | Rock Mechanics

The image above represents compressional or P waves.

To compute for compressional or P waves, three essential parameters are needed and these parameters are Dynamic Bulk Modulus of Elasticity (k_d), Dynamic Modulus of Rigidity (G_d) and Elasticity of Rock Mass (p).

The formula for calculating compressional or P waves:

v_p = ^{√[k_d + 4/₃G_d]} / _p

Where:

v_p = Compressional or P Waves
k_d = Dynamic Bulk Modulus of Elasticity
G_d = Dynamic Modulus of Rigidity
p = Elasticity of the Rock Mass

Let’s solve an example;
Given that the dynamic bulk modulus of elasticity is 11, the dynamic modulus of rigidity is 30 and the elasticity of the rock mass is 23. Find the compressional or P waves?

This implies that;

k_d = Dynamic Bulk Modulus of Elasticity = 11
G_d = Dynamic Modulus of Rigidity = 30
p = Elasticity of the Rock Mass = 23

v_p = ^{√[k_d + 4/₃G_d]} / _p
v_p = ^{√[11 + 4/₃(30)]} / ₂₃
v_p = ^{√[11 + 40]} / ₂₃
v_p = ^√[51] / ₂₃
v_p = ^7.141 / ₂₃
v_p = 0.310

Therefore, the compressional or P waves is 0.310.

Continue reading How to Calculate and Solve for Compressional or P Waves | Rock Mechanics

How to Calculate and Solve for Shear Force or S Waves | Rock Mechanics

The image above represents shear force or S waves.

To compute for shear force or S waves, two essential parameters are needed and these parameters are Dynamic Modulus of Rigidity (G_d) and Elasticity of Rock Mass (p).

The formula for calculating shear force or S waves:

v_s = ^√(G_d) / _p

Where:

v_s = Shear Force or S Waves
G_d = Dynamic Modulus of Rigidity
p = Elasticity of Rock Mass

Let’s solve an example;
Find the shear force or s waves when the dynamic modulus of rigidity is 12 and the elasticity of rock mass is 28.

This implies that;

G_d = Dynamic Modulus of Rigidity = 12
p = Elasticity of Rock Mass = 28

v_s = ^√(G_d) / _p
v_s = ^√(12) / ₂₈
v_s = ^3.46 / ₂₈
v_s = 0.12

Therefore, the shear force or S waves is 0.12.

Calculating the Dynamic Modulus of Rigidity when the Shear Force or S Waves and the Elasticity of Rock Mass is Given.

G_d = (v_s x p)²

Where:

G_d = Dynamic Modulus of Rigidity
v_s = Shear Force or S Waves
p = Elasticity of Rock Mass

Let’s solve an example;
Find the dynamic modulus of rigidity when the shear force or s waves is 21 and the elasticity of rock mass is 14.

This implies that;

v_s = Shear Force or S Waves = 21
p = Elasticity of Rock Mass = 14

G_d = (v_s x p)²
G_d = (21 x 14)²
G_d = (294)²
G_d = 86436

Therefore, the dynamic modulus of rigidity is 86436.

Continue reading How to Calculate and Solve for Shear Force or S Waves | Rock Mechanics

How to Calculate and Solve for Rock Density Designation | Rock Mechanics

The image above represents rock quality designation.

To compute for rock quality designation, two essential parameters are needed and these parameters are Sum of the Length of Core Pieces > 10cm (S) and Total Length Drilled or Core Recovery (L).

The formula for calculating the rock quality designation:

RQD = 100(^S / _L)

Where:

RQD = Rock Quality Designation
S = Sum of the Length of Core Pieces > 10cm
L = Total Length Drilled or Core Recovery

Let’s solve an example;
Calculate the rock quality designation? Given that the sum of the length of core pieces > 10cm is 20 and the total length drilled or core recovery is 14.

This implies that;

S = Sum of the Length of Core Pieces > 10cm = 20
L = Total Length Drilled or Core Recovery = 14

RQD = 100(^S / _L)
RQD = 100(²⁰ / ₁₄)
RQD = 100(1.428)
RQD = 142.85

Therefore, the rock quality designation is 142.85.

Calculating the Sum of the Length of Core Pieces > 10cm when the Rock Quality Designation and the Total Length Drilled or Core Recovery is Given.

S = RQD x L

Where:

S = Sum of the Length of Core Pieces > 10cm
RQD = Rock Quality Designation
L = Total Length Drilled or Core Recovery

Let’s solve an example;
Calculate the sum of the length of core pieces > 10cm? Given that the rock quality designation is 32 and the total length drilled or core recovery is 11.

This implies that;

RQD = Rock Quality Designation = 32
L = Total Length Drilled or Core Recovery = 11

S = RQD x L
S = 32 x 11
S = 352

Therefore, the sum of the length of core pieces > 10cm is 352.

Continue reading How to Calculate and Solve for Rock Density Designation | Rock Mechanics

How to Calculate and Solve for Bulk Modulus of Elasticity (E) | Rock Mechanics

The image above represents bulk modulus of elasticity (E).

To compute for bulk modulus of elasticity (E), two essential parameters are needed and these parameters are young’s modulus (E) and Poisson’s ratio (v).

The formula for calculating the bulk modulus of elasticity (E):

k = ^E / _{3(1 – 2v)}

Where:

k = Bulk Modulus of Elasticity (E)
E = Young’s Modulus
v = Poisson’s Ratio

Let’s solve an example;
Find the bulk modulus of elasticity (E) when the young’s modulus is 66 and the Poisson’s ratio is 58.

This implies that;

E = Young’s Modulus = 66
v = Poisson’s Ratio = 58

k = ^E / _{3(1 – 2v)}
k = ⁶⁶ / _{3(1 – 2(58))}
k = ⁶⁶ / _{3(1 – 116)}
k = ⁶⁶ / _3(-115)
k = ⁶⁶ / _-345
k = -0.19

Therefore, the bulk modulus of elasticity (E) is -0.19.

Calculating the Young’s Modulus when the Bulk Modulus of Elasticity (E) and the Poisson’s Ratio is Given.

E = k (3 – 6v)

Where:

E = Young’s Modulus
k = Bulk Modulus of Elasticity (E)
v = Poisson’s Ratio

Let’s solve an example;
Find the young’s modulus when the bulk modulus of elasticity (E) is 22 and the Poisson’s ratio is 18.

This implies that;

k = Bulk Modulus of Elasticity (E) = 22
v = Poisson’s Ratio = 18

E = k (3 – 6v)
E = 22 (3 – 6(18))
E = 22 (3 – 108)
E = 22 (-105)
E = -2376

Therefore, the young’s modulus is -2376.

Continue reading How to Calculate and Solve for Bulk Modulus of Elasticity (E) | Rock Mechanics

How to Calculate and Solve for Mohr – Coulomb Criterion | Rock Mechanics

The image above represents mohr – coulomb criterion.

To compute for mohr – coulomb criterion, three essential parameters are needed and these parameters are Cohesion (|τ_o), Co-efficient of Friction (μ) and Normal Stress (σ_n).

The formula for calculating the mohr – coulomb criterion:

|τ| = τ_o + μσ_n

Where;

|τ = Mohr – Coulomb Criterion
|τ_o = Cohesion
μ = Co-efficient of Friction
σ_n = Normal Stress

Let’s solve an example;
Find the mohr – coulomb criterion when the cohesion is 7, the co-efficient of friction is 30 and the normal stress is 28.

This implies that;

|τ_o = Cohesion = 7
μ = Co-efficient of Friction = 30
σ_n = Normal Stress = 28

|τ| = τ_o + μσ_n
|τ| = 7 + 30(28)
|τ| = 7 + 840
|τ| = 847

Therefore, the mohr – coulomb criterion is 847.

Calculating the Cohesion when the Mohr – Coulomb Criterion, the Co-efficient of Friction and the Normal Stress is Given.

|τ_o = |τ| – μσ_n

Where;

|τ_o = Cohesion
|τ = Mohr – Coulomb Criterion
μ = Co-efficient of Friction
σ_n = Normal Stress

Let’s solve an example;
Find the cohesion when the mohr – coulomb criterion is 44, the co-efficient of friction is 10 and the normal stress is 4.

This implies that;

|τ = Mohr – Coulomb Criterion = 44
μ = Co-efficient of Friction = 10
σ_n = Normal Stress = 4

|τ_o = |τ| – μσ_n
|τ_o = 44 – 10(4)
|τ_o = 44 – 40
|τ_o = 4

Therefore, the cohesion is 4.

Continue reading How to Calculate and Solve for Mohr – Coulomb Criterion | Rock Mechanics

How to Calculate and Solve for Friction Angle | Rock Mechanics

The image above represents friction angle.

To compute for friction angle, two essential parameters are needed and these parameters are Uniaxial Compressive Strength (σ_c) and cohesion (c).

The formula for calculating the friction angle:

φ = 2tan^-1(^{σ_c – 2c} / _{σc + 2c})

Where;

φ = Friction Angle
σ_c = Uniaxial Compressive Strength
c = Cohesion

Let’s solve an example;
Find the friction angle when the uniaxial compressive strength is 11 and the cohesion is 22.

This implies that;

σ_c = Uniaxial Compressive Strength = 11
c = Cohesion = 22

φ = 2tan^-1(^{σ_c – 2c} / _{σc + 2c})
φ = 2tan^-1(^{11 – 2(22)} / _{11 + 2(22)})
φ = 2tan^-1(^{11 – 44} / _{11 + 44})
φ = 2tan^-1(^-33 / ₅₅)
φ = 2tan^-1(-0.6)
φ = 2(-30.96°)
φ = -61.927

Therefore, the friction angle is -61.927.

Continue reading How to Calculate and Solve for Friction Angle | Rock Mechanics

How to Calculate and Solve for Shear Modulus | Rock Mechanics

The image above represents shear modulus.

To compute for shear modulus, two essential parameters are needed and these parameters are young’s modulus (E) and Poisson’s ratio (v).

The formula for calculating the shear modulus:

G = ^E / _{2(1 + v)}

Where:

G = Shear Modulus
E = Young’s Modulus
v = Poisson’s Ratio

Let’s solve an example;
Find the shear modulus when the young’s modulus is 32 and the Poisson’s ratio is 24.

This implies that;

E = Young’s Modulus = 32
v = Poisson’s Ratio = 24

G = ^E / _{2(1 + v)}
G = ³² / _{2(1 + 24)}
G = ³² / ₂₍₂₅₎
G = ³² / ₅₀
G = 0.64

Therefore, the shear modulus is 0.64.

Calculating the Young’s Modulus when the Shear Modulus and the Poisson’s Ratio is Given.

E = G (2 + 2v)

Where:

E = Young’s Modulus
G = Shear Modulus
v = Poisson’s Ratio

Let’s solve an example;
Find the young’s modulus when the shear modulus is 12 and the Poisson’s ratio is 10.

This implies that;

G = Shear Modulus = 12
v = Poisson’s Ratio = 10

E = G (2 +2v)
E = 12 (2 + 2(10))
E = 12 (2 + 20)
E = 12 (22)
E = 264

Therefore, the young’s modulus is 264.

Continue reading How to Calculate and Solve for Shear Modulus | Rock Mechanics

How to Calculate and Solve for Bulk Modulus of Elasticity (stress) | Rock Mechanics

The image above represents bulk modulus of elasticity (stress).

To compute for bulk modulus elasticity (stress), two essential parameters are needed and these parameters are Average Horizontal Stress (h_av) and Vertical Stress (σ_v).

The formula for calculating the bulk modulus elasticity (stress):

k = ^h_av / _σ_v

Where;

k = Bulk Modulus of Elasticity (Stress)
h_av = Average Horizontal Stress
σ_v = Vertical Stress

Let’s solve an example;
Given that the average horizontal stress is 15 and the vertical stress is 34. Find the bulk modulus of elasticity (stress)?

This implies that;

h_av = Average Horizontal Stress = 15
σ_v = Vertical Stress = 34

k = ^h_av / _σ_v
k = ¹⁵ / ₃₄
k = 0.44

Therefore, the bulk modulus of elasticity (stress) is 0.44.

Calculating the Average Horizontal Stress when the Bulk Modulus Elasticity (stress) and the Vertical Stress is Given.

h_av = k x σ_v

Where;

h_av = Average Horizontal Stress
k = Bulk Modulus of Elasticity (Stress)
σ_v = Vertical Stress

Let’s solve an example;
Given that the bulk modulus of elasticity (stress) is 25 and the vertical stress is 8. Find the average horizontal stress?

This implies that;

k = Bulk Modulus of Elasticity (Stress) = 25
σ_v = Vertical Stress = 8

h_av = k x σ_v
h_av = 25 x 8
h_av = 200

Therefore, the average horizontal stress is 200.

Continue reading How to Calculate and Solve for Bulk Modulus of Elasticity (stress) | Rock Mechanics

How to Calculate and Solve for Horizontal Strain | Rock Mechanics

The image above represents horizontal strain.

To compute for horizontal strain, five essential parameters are needed and these parameters are Principal Horizontal Stress Component 1 (σ_H1), Principal Horizontal Stress Component 2 (σ_H2), Poisson’s Ratio (v), Vertical Stress (σ_v) and Young’s Modulus (E).

The formula for calculating the horizontal strain:

ε_H = ^{(σ_H1 – vσ_H2 – vσ_v)} / _E

Where:

ε_H = Horizontal Strain
σ_H1 = Principal Horizontal Stress Component 1
σ_H2 = Principal Horizontal Stress Component 2
v = Poisson’s Ratio
σ_v = Vertical Stress
E = Young’s Modulus

Let’s solve an example;
Find the horizontal strain when the principal horizontal stress component 1 is 7, the principal horizontal component 2 is 9, the Poisson’s ratio is 11, the vertical stress is 21 and young’s modulus is 27.

This implies that;

σ_H1 = Principal Horizontal Stress Component 1 = 7
σ_H2 = Principal Horizontal Stress Component 2 = 9
v = Poisson’s Ratio = 11
σ_v = Vertical Stress = 21
E = Young’s Modulus = 27

ε_H = ^{(σ_H1 – vσ_H2 – vσ_v)} / _E
ε_H = ^{(7 – 11(9) – 11(21))} / ₂₇
ε_H = ^{(7 – 99 – 231)} / ₂₇
ε_H = ^-323 / ₂₇
ε_H = -11.96

Therefore, the horizontal strain is -11.96.

Calculating the Principal Horizontal Stress Component 1 when the Horizontal Stress, Principal Horizontal Stress Component 2, Poisson’s Ratio, Vertical Stress and Young’s Modulus is Given.

σ_H1 = (ε_H x E) + vσ_H2 + vσ_v

Where;

σ_H1 = Principal Horizontal Stress Component 1
ε_H = Horizontal Strain
σ_H2 = Principal Horizontal Stress Component 2
v = Poisson’s Ratio
σ_v = Vertical Stress
E = Young’s Modulus

Let’s solve an example;
Find the principal horizontal stress component 1 when the horizontal strain is 22, the principal horizontal component 2 is 10, the Poisson’s ratio is 7, the vertical stress is 12 and young’s modulus is 3.

This implies that;

ε_H = Horizontal Strain = 22
σ_H2 = Principal Horizontal Stress Component 2 = 10
v = Poisson’s Ratio = 7
σ_v = Vertical Stress = 12
E = Young’s Modulus = 3

σ_H1 = (ε_H x E) + vσ_H2 + vσ_v
σ_H1 = (22 x 3) + 7(10) + 7(12)
σ_H1 = 66 + 70 + 84
σ_H1 = 220

Therefore, the principal horizontal stress component 1 is 220.

Calculating the Principal Horizontal Stress Component 2 when the Horizontal Stress, Principal Horizontal Stress Component 1, Poisson’s Ratio, Vertical Stress and Young’s Modulus is Given.

σ_H2 = -(^{(ε_H x E) – σ_H1 + vσ_v} / _v)

Where;

σ_H2 = Principal Horizontal Stress Component 2
ε_H = Horizontal Strain
σ_H1 = Principal Horizontal Stress Component 1
v = Poisson’s Ratio
σ_v = Vertical Stress
E = Young’s Modulus

Let’s solve an example;
Find the principal horizontal stress component 2 when the horizontal strain is 28, the principal horizontal component 1 is 14, the Poisson’s ratio is 5, the vertical stress is 17 and young’s modulus is 7.

This implies that;

ε_H = Horizontal Strain =28
σ_H1 = Principal Horizontal Stress Component 1 = 14
v = Poisson’s Ratio = 5
σ_v = Vertical Stress = 17
E = Young’s Modulus = 7

σ_H2 = -(^{(ε_H x E) – σ_H1 + vσ_v} / _v)
σ_H2 = -(^{(28 x 7) – 14 + 5(17)} / ₅)
σ_H2 = -(^{196 – 14 + 85} / ₅)
σ_H2 = -(^{182 + 85} / ₅)
σ_H2 = -(²⁶⁷ / ₅)
σ_H2 = -(53.4)
σ_H2 = -53.4

Therefore, the principal horizontal stress component 2 is -53.4.

Continue reading How to Calculate and Solve for Horizontal Strain | Rock Mechanics

How to Calculate and Solve for Poisson’s Ratio | Rock Mechanics

The image above represents Poisson’s ratio.

To compute for Poisson’s ratio, two essential parameters are needed and these parameters are lateral strain (ε_l) and axial strain (ε_a).

The formula for calculating Poisson’s ratio:

v = ^ε_l / _ε_a

Where:

v = Poisson’s Ratio
ε_l = Lateral Strain
ε_a = Axial Strain

Let’s solve an example;
Find the Poisson’s ratio when the lateral strain is 80 and the axial strain is 4.

This implies that;

ε_l = Lateral Strain = 80
ε_a = Axial Strain = 4

v = ^ε_l / _ε_a
v = ⁸⁰ / ₄
v = 20

Therefore, the Poisson’s ratio is 20.

Calculating the Lateral Strain when the Poisson’s Ratio and Axial Strain is Given.

ε_l = v x ε_a

Where:

ε_l = Lateral Strain
v = Poisson’s Ratio
ε_a = Axial Strain

Let’s solve an example;
Find the lateral strain when the Poisson’s ratio is 40 and the axial strain is 9.

This implies that;

v = Poisson’s Ratio = 40
ε_a = Axial Strain = 9

ε_l = v x ε_a
ε_l = 40 x 9
ε_l = 360

Therefore, the lateral strain is 360.

Continue reading How to Calculate and Solve for Poisson’s Ratio | Rock Mechanics