Nickzom Blog |

How to Calculate and Solve for Relative Apparent Viscosity (for Concentrated suspension) | Rheology

The image above represents relative apparent viscosity (for concentrated suspension).

To compute for relative apparent viscosity (for concentrated suspension), three essential parameters are needed and these parameters are Intrinsic Viscosity (η_i), Solid Landing (φ) and Maximum Solid Landing (φ_m).

The formula for calculating relative apparent viscosity (for concentrated suspension):

η_ra = (1 – ^φ / _φm)^-(η_i)φ_m

Where:

η_ra = Relative Apparent Viscosity
η_i = Intrinsic Viscosity
φ = Solid Landing
φ_m = Maximum Solid Landing

Let’s solve an example;
Find the relative apparent viscosity when the intrinsic viscosity is 20, the solid landing is 32 and the maximum solid landing is 12.

This implies that;

η_i = Intrinsic Viscosity = 20
φ = Solid Landing = 32
φ_m = Maximum Solid Landing = 12

η_ra = (1 – ^φ / _φm)^-(η_i)φ_m
η_ra = (1 – ³² / ₁₂)^{-(20) x 12}
η_ra = (1 – 2.66)^-240
η_ra = (-1.66)^-240
η_ra = 5.705e-54

Therefore, the relative apparent viscosity (for concentrated suspension) is 5.705e-54.

Continue reading How to Calculate and Solve for Relative Apparent Viscosity (for Concentrated suspension) | Rheology

How to Calculate and Solve for Sedimentation of Concentrated Suspension | Rheology

The image above represents sedimentation of concentrated suspension.

To compute for sedimentation of concentrated suspension, five essential parameters are needed and these parameters are Change in Density between the Dispersed and Continuous Phase of the Suspension (ΔP), Acceleration due to Gravity (g), Particle Radius (a), Viscosity of Continuous Phase (η) and Solid Landing (φ).

The formula for calculating sedimentation of concentrated suspension:

v = ^2ΔPga2 / _9η(1 – φ)^{5 ± 0.25}

Where:

v = Sedimentation of Concentrated Suspension
ΔP = Change in Density between the Dispersed and Continuous Phase of the Suspension
g = Acceleration due to Gravity
a = Particle Radius
η = Viscosity of Continuous Phase
φ = Solid Landing

Let’s solve an example;
Find the sedimentation of concentrated suspension when the change in density between the dispersed and continuous phase of the suspension is 20, the acceleration due to gravity is 12, the particle radius is 32, the viscosity of continuous phase is 14 and the solid landing is 0.

This implies that;

ΔP = Change in Density between the Dispersed and Continuous Phase of the Suspension = 20
g = Acceleration due to Gravity = 12
a = Particle Radius = 32
η = Viscosity of Continuous Phase = 14
φ = Solid Landing = 0

v = ^2ΔPga2 / _9η(1 – φ)^{5 ± 0.25}
v = ^{2 x 20 x 12 x 322} / _{9 x 14} x (1 – 0)^{5 + 0.25}
v = ^{2 x 20 x 12 x 1024} / ₁₂₆ x (1)^5.25
v = ⁴⁹¹⁵²⁰ / ₁₂₆ x 1
v = 3900.95 x 1
v = 3900.95

Therefore, the sedimentation of concentrated suspension is 3900.95.

Continue reading How to Calculate and Solve for Sedimentation of Concentrated Suspension | Rheology

How to Calculate and Solve for Sedimentation of Dilute Suspension | Rheology

The image above represents sedimentation of dilute suspension.

To compute for sedimentation of dilute suspension, four essential parameters are needed and these parameters are Change in Density between the Dispersed and Continuous Phase of the Suspension (ΔP), Acceleration due to Gravity (g), Particle Radius (a) and Viscosity of Continuous Phase (η).

The formula for calculating sedimentation of dilute suspension:

v = ^2ΔPga2 / _9η

Where:

v = Sedimentation of Dilute Suspension
ΔP = Change in Density between the Dispersed and Continuous Phase of the Suspension
g = Acceleration due to Gravity
a = Particle Radius
η = Viscosity of Continuous Phase

Let’s solve an example;
Find the sedimentation of dilute suspension when the change in density between the dispersed and continuous phase of the suspension is 10, the acceleration due to gravity is 9.8, particle radius is 22 and the viscosity of continuous phase is 11.

This implies that;

ΔP = Change in Density between the Dispersed and Continuous Phase of the Suspension = 10
g = Acceleration due to Gravity = 9.8
a = Particle Radius = 22
η = Viscosity of Continuous Phase = 11

v = ^2ΔPga2 / _9η
v = ^{2 x 10 x 9.8 x 222} / _{9 x 11}
v = ^{2 x 10 x 9.8 x 484} / ₉₉
v = ⁹⁴⁸⁶⁴ / ₉₉
v = 958.2

Therefore, the sedimentation of dilute suspension is 958.2.

Continue reading How to Calculate and Solve for Sedimentation of Dilute Suspension | Rheology

How to Calculate and Solve for Einsten Relative Apparent Viscosity (for Dilute System or Suspension) | Rheology

The image above represents einstein relative apparent viscosity.

To compute for einstein relative apparent viscosity, one essential parameter is needed and these parameter is Solid Landing (φ).

The formula for calculating einstein relative apparent viscosity:

η_ra = 1 + 25φ

Where:

η_ra = Einstein Relative Apparent Viscosity
φ = Solid Landing

Let’s solve an example;
Find the einstein relative apparent viscosity when the solid landing is 24.

This implies that;

φ = Solid Landing = 24

η_ra = 1 + 25φ
η_ra = 1 + 25 x 24
η_ra = 1 + 600
η_ra = 601

Therefore, the einstein relative apparent viscosity is 601.

Continue reading How to Calculate and Solve for Einsten Relative Apparent Viscosity (for Dilute System or Suspension) | Rheology

How to Calculate and Solve for Relative Apparent Viscosity | Rheology

The image above represents relative apparent viscosity.

To compute for relative apparent viscosity, two essential parameters are needed and these parameters are Viscosity of Non-Newtonian Fluid (η_a) and Viscosity of Continuous Phase (η_c).

The formula for calculating relative apparent viscosity:

η_ra = ^η_a / _ηc

Where:

η_ra = Relative Apparent Viscosity
η_a = Viscosity of Non-Newtonian Fluid
η_c = Viscosity of Continuous Phase

Let’s solve an example;
Find the relative apparent viscosity when the viscosity of non-newtonian fluids is 44 and the viscosity of continuous phase is 11.

This implies that;

η_a = Viscosity of Non-Newtonian Fluid = 44
η_c = Viscosity of Continuous Phase = 11

η_ra = ^η_a / _ηc
η_ra = ⁴⁴ / ₁₁
η_ra = 4

Therefore, the relative apparent viscosity is 4.

Calculating for Viscosity of Non-Newtonian Fluids when the Relative Apparent Viscosity and the Viscosity of Continuous Phase is Given.

η_a = η_ra x η_c

Where;

η_a = Viscosity of Non-Newtonian Fluid
η_ra = Relative Apparent Viscosity
η_c = Viscosity of Continuous Phase

Let’s solve an example;
Find the viscosity of non-newtonian fluid when the relative apparent viscosity is 16 and the viscosity of continuous phase is 8.

This implies that;

η_ra = Relative Apparent Viscosity = 16
η_c = Viscosity of Continuous Phase = 8

η_a = η_ra x η_c
η_a = 16 x 8
η_a = 128

Therefore, the viscosity of non-newtonian fluid is 128.

Continue reading How to Calculate and Solve for Relative Apparent Viscosity | Rheology

How to Calculate and Solve for Viscosity of Bingham Fluids | Rheology

The image above represents viscosity of bingham fluids.

To compute for viscosity of bingham fluids, three essential parameters are needed and these parameters are Yield Stress (ζ_y), Shear Rate (γ) and Co-efficient of Rigidity (η_B).

The formula for calculating viscosity of bingham fluids:

η_a = η_B + ^ζ_y / _γ

Where:

η_a = Viscosity of Bingham Fluids
ζ_y = Yield Stress
γ = Shear Rate
η_B = Co-efficient of Rigidity

Let’s solve an example;
Find the viscosity of bingham fluids when the yield stress is 21, the shear rate is 18 and co-efficient of rigidity is 14.

This implies that;

ζ_y = Yield Stress = 21
γ = Shear Rate = 18
η_B = Co-efficient of Rigidity = 14

η_a = η_B + ^ζ_y / _γ
η_a = 14 + ²¹ / ₁₈
η_a = 14 + 1.166
η_a = 15.16

Therefore, the viscosity of bingham fluids is 15.16.

Calculating for Yield Stress when the Viscosity of Bingham Fluids, the Shear Rate and the Co-efficient of Rigidity is Given.

ζ_y = (η_a – η_B) γ

Where;

ζ_y = Yield Stress
η_a = Viscosity of Bingham Fluids
γ = Shear Rate
η_B = Co-efficient of Rigidity

Let’s solve an example;
Find the yield stress when the viscosity of bingham fluids is 12, the shear rate is 14 and the co-efficient of rigidity is 8.

This implies that;

η_a = Viscosity of Bingham Fluids = 12
γ = Shear Rate = 14
η_B = Co-efficient of Rigidity = 8

ζ_y = (η_a – η_B) γ
ζ_y = (12 – 8) 14
ζ_y = (4) 14
ζ_y = 56

Therefore, the yield stress is 56.

Continue reading How to Calculate and Solve for Viscosity of Bingham Fluids | Rheology

How to Calculate and Solve for Viscosity of Pseudoplastic Fluids | Rheology

The image above represents viscosity of pseudoplastic fluids.

To compute for viscosity of pseudoplastic fluids, three essential parameters are needed and these parameters are Flow Index (n), Shear Rate (γ) and Consistency (η_p).

The formula for calculating viscosity of pseudoplastic fluids:

η_o = η_p γ^{n – 1}

Where:

η_o = Viscosity of Pseudoplastics Fluids
n = Flow Index
γ = Shear Rate
η_p = Consistency

Let’s solve an example;
Find the viscosity of pseudoplastic fluids when the flow index is 20, the shear rate is 14 and the consistency is 10.

This implies that;

n = Flow Index = 20
γ = Shear Rate = 14
η_p = Consistency = 10

η_o = η_p γ^{n – 1}
η_o = 10 x 14^{20 – 1}
η_o = 10 x 14¹⁹
η_o = 10 x 5.97e+21
η_o = 5.97

Therefore, the viscosity of pseudoplastic fluids is 5.97e+22.

Continue reading How to Calculate and Solve for Viscosity of Pseudoplastic Fluids | Rheology

How to Calculate and Solve for Viscosity of Newtonian Fluids | Rheology

The image above represents viscosity of newtonian fluids.

To compute for viscosity of newtonian fluids, two essential parameters are needed and these parameters are Shear Stress (ζ) and Shear Rate (γ).

The formula for calculating viscosity of newtonian fluids:

η = ^ζ / _γ

Where:

η = Viscosity of Newtonian Fluids
ζ = Shear Stress
γ = Shear Rate

Let’s solve an example;
Find the viscosity of newtonian fluids when the shear stress is 15 and the shear rate is 5.

This implies that;

ζ = Shear Stress = 15
γ = Shear Rate = 5

η = ^ζ / _γ
η = ¹⁵ / ₅
η = 3

Therefore, the viscosity of newtonian fluids is 3.

Calculating for Shear Stress when the Newtonian Fluids and the Shear Rate is Given.

ζ = η x γ

Where;

ζ = Shear Stress
η = Viscosity of Newtonian Fluids
γ = Shear Rate

Let’s solve an example;
Find the shear stress when the newtonian fluids is 20 and the shear rate is 4.

This implies that;

η = Viscosity of Newtonian Fluids = 20
γ = Shear Rate = 4

ζ = η x γ
ζ = 20 x 4
ζ = 80

Therefore, the shear stress is 80.

Continue reading How to Calculate and Solve for Viscosity of Newtonian Fluids | Rheology

How to Calculate and Solve for Resistance of a Temperature Detector | Temperature Measuring Instruments

The image above represents resistance of a temperature detector.

To compute for resistance of a temperature detector, four essential parameters are needed and these parameters are Reference Resistance (R_o), Temperature Co-efficient of Resistivity (α), Temperature of Thermistor (T) and Ambient Temperature (T_o).

The formula for calculating resistance of a temperature detector:

R = R_o [1 + α(T – T_o)]

Where:

R = Resistance
R_o = Reference Resistance
α = Temperature Co-efficient of Resistivity
T = Temperature of Thermistor
T_o = Ambient Temperature

Let’s solve an example:
Find the resistance when the reference resistance is 11, the temperature co-efficient of resistivity is 13, the temperature of thermistor is 17 and the ambient temperature is 19.

This implies that;

R_o = Reference Resistance = 11
α = Temperature Co-efficient of Resistivity = 13
T = Temperature of Thermistor = 17
T_o = Ambient Temperature = 19

R = R_o [1 + α(T – T_o)]
R = 11 x [1 + 13 x (17 – 19)]
R = 11 x [1 + 13 x (-2)]
R = 11 x [1 + -26]
R = 11 x -25
R = – 275

Therefore, the resistance of temperature detector is – 275 Ω.

Continue reading How to Calculate and Solve for Resistance of a Temperature Detector | Temperature Measuring Instruments

How to Calculate and Solve for Relationship between Resistance and Thermistor Temperature | Temperature Measuring Instruments

The image above represents the relationship between resistance and thermistor temperature.

To compute for relationship between resistance and thermistor temperature, four essential parameters are needed and these parameters are Reference Resistance (R_o), Temperature Parameter (β), Temperature of Thermistor (T) and Ambient Temperature (T_o).

The formula for calculating relationship between resistance and thermistor temperature:

R = R_o e^{β(1 / _T – 1 / _To)}

Where:

R = Resistance
R_o = Reference Resistance
β = Temperature Parameter
T = Temperature of Thermistor
T_o = Ambient Temperature

Let’s solve an example;
Find the resistance when the reference resistance is 21, the temperature parameter is 10, the temperature of thermistor is 14 and the ambient temperature is 8.

This implies that’

R_o = Reference Resistance = 21
β = Temperature Parameter = 10
T = Temperature of Thermistor = 14
T_o = Ambient Temperature = 8

R = R_o e^{β(1 / _T – 1 / _To)}
R = 21 x e^{10 x (1 / ₁₄ – 1 / ₂₁)}
R = 21 x e^{10 x (0.071 – 0.125)}
R = 21 x e^{10 x -0.0535}
R = 21 x e^-0.535
R = 21 x 0.585
R = 12.29

Therefore, the relationship between resistance and thermistor temperature is 12.29 Ω.

Continue reading How to Calculate and Solve for Relationship between Resistance and Thermistor Temperature | Temperature Measuring Instruments