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Technical Terms Fluid Mechanics

Reference data and engineering information about technical terms fluid mechanics for fluid mechanics applications.

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Overview

Engineering reference data for Technical Terms Fluid Mechanics in fluid mechanics.

Key Formulas

Reynolds Number

Re=ρvDμRe = \frac{\rho v D}{\mu}

Ratio of inertial to viscous forces — determines flow regime.

Bernoulli's Equation

P+12ρv2+ρgh=constP + \frac{1}{2}\rho v^2 + \rho g h = \text{const}

Conservation of energy for steady, inviscid, incompressible flow.

Continuity Equation

A1v1=A2v2A_1 v_1 = A_2 v_2

Conservation of mass for incompressible flow.

Darcy-Weisbach

ΔP=fLDρv22\Delta P = f \frac{L}{D} \frac{\rho v^2}{2}

Pressure drop due to friction in a pipe.

Variables

SymbolDescriptionUnit
ReReReynolds number
ρ\rhoFluid densitykg/m³
vvFlow velocitym/s
DDCharacteristic dimensionm
μ\muDynamic viscosityPa·s
PPPressurePa
ffDarcy friction factor

Glossary of Key Terms

Acoustic Theory

The mathematical description of sound waves, fundamental to acoustical engineering and noise control in HVAC systems.

Aerodynamics

The study of the flow of gases, particularly as it relates to the design of vehicles and structures moving through air.

Boundary Layer

The thin layer of fluid in the immediate vicinity of a bounding surface where viscous effects are significant. The boundary layer can be laminar, transitional, or turbulent.

Cavitation

The formation and collapse of vapor bubbles in a liquid when local pressure drops below the vapor pressure. Characterized by Net Positive Suction Head (NPSH) requirements in pump systems.

Coanda Effect

The tendency of a fluid stream to stay attached to a convex surface rather than follow its original straight-line trajectory.

Conservation Laws

Fundamental principles stating that measurable properties of an isolated physical system (mass, energy, momentum) remain constant as the system evolves.

Froude Number

A dimensionless number defined as the ratio of flow inertia to gravitational forces:

Fr=vgLFr = \frac{v}{\sqrt{gL}}

where vv is flow velocity, gg is gravitational acceleration, and LL is characteristic length.

Euler Number

A dimensionless number representing the relationship between pressure forces and inertial forces:

Eu=Δpρv2Eu = \frac{\Delta p}{\rho v^2}

Hydraulics

The branch of science and engineering concerned with the mechanical properties and use of liquids, particularly water.

Hydrodynamics

Fluid dynamics applied specifically to liquids such as water, alcohol, and oil.


Dimensionless Numbers Reference

NumberFormulaRatioApplication
FroudeFr=v/gLFr = v/\sqrt{gL}Inertia to gravityFree-surface flows
EulerEu=Δp/(ρv2)Eu = \Delta p/(\rho v^2)Pressure to inertiaPressure drop analysis
ReynoldsRe=ρvL/μRe = \rho vL/\muInertia to viscosityFlow regime determination

Flow Regime Classification

Fluid flow can be classified based on the Reynolds number:

Flow TypeReynolds Number RangeCharacteristics
LaminarRe<2300Re < 2300Smooth, orderly layers
Transitional2300<Re<40002300 < Re < 4000Intermittent turbulence
TurbulentRe>4000Re > 4000Chaotic, mixing occurs

Conservation of Mass

The law of conservation of mass states that mass can neither be created nor destroyed. For fluid mechanics, this is expressed through the continuity equation:

ρt+(ρv)=0\frac{\partial \rho}{\partial t} + \nabla \cdot (\rho \mathbf{v}) = 0

For incompressible flow (ρ=constant\rho = \text{constant}), this simplifies to:

v=0\nabla \cdot \mathbf{v} = 0


Viscosity Types

TypeSymbolSI UnitDescription
Dynamic (Absolute)μ\muPa·sResistance to shear stress
Kinematicν\num²/sDynamic viscosity divided by density

The relationship between viscosity types:

ν=μρ\nu = \frac{\mu}{\rho}

Common unit conversions:

  • 1 cP (centipoise) = 0.001 Pa·s
  • 1 cSt (centistoke) = 10⁻⁶ m²/s

Flow Coefficient Standards

StandardSymbolDefinitionRegion
USCvC_vFlow rate (gpm) at 1 psi differentialNorth America
InternationalKvK_vFlow rate (m³/h) at 1 bar differentialEurope/Asia

Conversion between standards:

Kv=0.857×CvK_v = 0.857 \times C_v

References