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Contents of the Fundamentals of Fluid Flow PDF

List of 72 Fundamentals of Fluid Flow Formulas

Angular Momentum at Inlet

Angular Momentum at Outlet

Angular Velocity for Work Done on Wheel per Second

Area of Curve using Vorticity

Circulation using Vorticity

Component of Velocity in X Direction given Slope of Equipotential Line

Component of Velocity in X Direction using Slope of Streamline

Component of Velocity in Y Direction given Slope of Equipotential Line

Component of Velocity in Y Direction given Slope of Streamline

Cross Sectional Area at Section 1 for Steady Flow

Cross Sectional Area at Section 2 given Flow at Section 1 for Steady Flow

Cross Sectional Area at Section given Discharge for Steady Incompressible Fluid

Discharge through Section for Steady Incompressible Fluid

Efficiency of System

Initial Velocity for Work Done if Jet leaves in Motion of Wheel

Initial Velocity given Power Delivered to Wheel

Initial Velocity when Work Done at Vane Angle is 90 and Velocity is Zero

Mass Density at Section 1 for Steady Flow

Mass Density at Section 2 given Flow at Section 1 for Steady Flow

Mass Flow Rate in Steady Flow

Mass of Fluid Striking Vane per Second

Power Delivered to Wheel

Radius at Inlet for Work Done on Wheel per Second

Radius at Inlet with Known Torque by Fluid

Radius at Outlet for Torque Exerted by Fluid

Radius at Outlet for Work Done on Wheel per Second

Radius of Wheel for Tangential Velocity at Inlet Tip of Vane

Radius of Wheel for Tangential Velocity at Outlet Tip of Vane

Radius of Wheel given Angular Momentum at Inlet

Slope of Equipotential Line

Slope of Streamline

Speed of Wheel given Tangential Velocity at Inlet Tip of Vane

Speed of Wheel given Tangential Velocity at Outlet Tip of Vane

Tangential Momentum of Fluid Striking Vanes at Inlet

Tangential Momentum of Fluid Striking Vanes at Outlet

Tangential Velocity at Inlet Tip of Vane

Tangential Velocity at Outlet Tip of Vane

Torque Exerted by Fluid

Velocity at Inlet given Torque by Fluid

Velocity at Inlet given Work Done on Wheel

Velocity at Inlet when Work Done at Vane Angle is 90 and Velocity is Zero

Velocity at Outlet given Power Delivered to Wheel

Velocity at Outlet given Torque by Fluid

Velocity at Outlet given Work Done if Jet leaves in Motion of Wheel

Velocity at Outlet given Work Done on Wheel

Velocity at Point given Efficiency of System

Velocity at Section 1 for Steady Flow

Velocity at Section 2 given Flow at Section 1 for Steady Flow

Velocity at Section for Discharge through Section for Steady Incompressible Fluid

Velocity for Work Done if there is no Loss of Energy

Velocity given Angular Momentum at Inlet

Velocity given Angular Momentum at Outlet

Velocity given Efficiency of System

Velocity given Tangential Momentum of Fluid Striking Vanes at Inlet

Velocity given Tangential Momentum of Fluid Striking Vanes at Outlet

Vorticity of Fluid Flows

Weight of Fluid for Work Done if there is no loss of Energy

Weight of Fluid for Work Done on Wheel per Second

Weight of Fluid given Angular Momentum at Inlet

Weight of Fluid given Angular Momentum at Outlet

Weight of Fluid given Mass of Fluid Striking Vane per Second

Weight of Fluid given Power Delivered to Wheel

Weight of Fluid given Tangential Momentum of Fluid Striking Vanes at Inlet

Weight of Fluid given Work Done if Jet leaves in Motion of Wheel

Weight of Fluid when Work Done at Vane Angle is 90 and Velocity is Zero

Work Done for Radial Discharge at Vane Angle is 90 and Velocity is Zero

Work Done if Jet leaves in Direction as that of Motion of Wheel

Work Done if there is no Loss of Energy

Work Done on Wheel per Second

Variables used in Fundamentals of Fluid Flow PDF

A Area (Square Meter)
A Cross Sectional Area (Square Meter)
A_cs Cross-Sectional Area (Square Meter)
G Specific Gravity of Fluid
L Angular Momentum (Kilogram Square Meter per Second)
m Mass Flow Rate (Kilogram per Second)
m_f Fluid Mass (Kilogram)
P_dc Power Delivered (Watt)
Q Discharge of Fluid (Cubic Meter per Second)
r Radius of wheel (Meter)
r_O Radius of Outlet (Meter)
T_m Tangential Momentum (Kilogram Meter per Second)
u Component of Velocity in X Direction (Meter per Second)
u Initial Velocity (Meter per Second)
u₀₁ Initial Velocity at Point 1 (Meter per Second)
u₀₂ Initial Velocity at Point 2 (Meter per Second)
u_Fluid Fluid Velocity (Meter per Second)
u_Fluid Fluid Velocity (Meter per Second)
v Velocity of Jet (Meter per Second)
v Component of Velocity in Y Direction (Meter per Second)
v Specific Volume (Cubic Meter per Kilogram)
V₂ Velocity of Fluid at 2 (Meter per Second)
v_f Final Velocity (Meter per Second)
V_{Negativesurges} Velocity of Fluid at Negative Surges (Meter per Second)
v_tangential Tangential Velocity (Meter per Second)
w Work Done (Kilojoule)
w_f Weight of Fluid (Newton)
Γ Circulation (Square Meter per Second)
η Efficiency of Jet
θ Slope of Streamline
ρ₁ Density of Liquid 1 (Kilogram per Cubic Meter)
ρ₂ Density of Liquid 2 (Kilogram per Cubic Meter)
τ Torque Exerted on Wheel (Newton Meter)
Φ Slope of Equipotential Line
ω Angular Velocity (Radian per Second)
Ω Vorticity (1 per Second)
Ω Angular Speed (Revolution per Second)

Constants, Functions and Measurements used in Fundamentals of Fluid Flow PDF

Constant: pi, 3.14159265358979323846264338327950288
Archimedes' constant
Function: arctan, arctan(Number)
Inverse trigonometric functions are usually accompanied by the prefix - arc. Mathematically, we represent arctan or the inverse tangent function as tan-1 x or arctan(x).
Function: ctan, ctan(Angle)
Cotangent is a trigonometric function that is defined as the ratio of the adjacent side to the opposite side in a right triangle.
Function: sqrt, sqrt(Number)
A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number.
Function: tan, tan(Angle)
The tangent of an angle is a trigonometric ratio of the length of the side opposite an angle to the length of the side adjacent to an angle in a right triangle.
Measurement: Length in Meter (m)
Length Unit Conversion
Measurement: Weight in Kilogram (kg)
Weight Unit Conversion
Measurement: Area in Square Meter (m²)
Area Unit Conversion
Measurement: Speed in Meter per Second (m/s)
Speed Unit Conversion
Measurement: Energy in Kilojoule (KJ)
Energy Unit Conversion
Measurement: Power in Watt (W)
Power Unit Conversion
Measurement: Force in Newton (N)
Force Unit Conversion
Measurement: Volumetric Flow Rate in Cubic Meter per Second (m³/s)
Volumetric Flow Rate Unit Conversion
Measurement: Mass Flow Rate in Kilogram per Second (kg/s)
Mass Flow Rate Unit Conversion
Measurement: Angular Velocity in Radian per Second (rad/s), Revolution per Second (rev/s)
Angular Velocity Unit Conversion
Measurement: Density in Kilogram per Cubic Meter (kg/m³)
Density Unit Conversion
Measurement: Torque in Newton Meter (N*m)
Torque Unit Conversion
Measurement: Specific Volume in Cubic Meter per Kilogram (m³/kg)
Specific Volume Unit Conversion
Measurement: Angular Momentum in Kilogram Square Meter per Second (kg*m²/s)
Angular Momentum Unit Conversion
Measurement: Momentum in Kilogram Meter per Second (kg*m/s)
Momentum Unit Conversion
Measurement: Momentum Diffusivity in Square Meter per Second (m²/s)
Momentum Diffusivity Unit Conversion
Measurement: Vorticity in 1 per Second (1/s)
Vorticity Unit Conversion

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