Nomenclature - Hydrodynamics of Pumps - Christopher E. Brennen

HYDRODYNAMICS OF PUMPS
by Christopher Earls Brennen © Concepts NREC 1994

Nomenclature

ROMAN LETTERS

a Pipe radius
A Cross-sectional area
A_ijk Coefficients of pump dynamic characteristics
[A] Rotordynamic force matrix
Ar Cross-sectional area ratio
B Breadth of passage or flow
[B] Rotordynamic moment matrix
c Chord of the blade or foil
c Speed of sound
c Rotordynamic coefficient: cross-coupled damping
c_b Interblade spacing
c_PL Specific heat of liquid
C Compliance
C Rotordynamic coefficient: direct damping
C_D Drag coefficient
C_L Lift coefficient
C_p Coefficient of pressure
C_pmin Minimum coefficient of pressure
d Ratio of blade thickness to blade spacing
D Impeller diameter or typical flow dimension
Df Diffusion factor
D_T Determinant of transfer matrix [T]
e Specific internal energy
E Energy flux
E Young's modulus
f Friction coefficient
F Force
g Acceleration due to gravity
g_s Component of g in the s direction
h Specific enthalpy
h Blade tip spacing
h_p Pitch of a helix
h^T Total specific enthalpy
h* Piezometric head
H Total head rise
H(s,θ,t) Clearance geometry
I Acoustic impulse
I,J Integers such that ω/Ω=I/J
I_P Pump impedance
j Square root of -1
k Rotordynamic coefficient: cross-coupled stiffness
k_L Thermal conductivity of the liquid
K Rotordynamic coefficient: direct stiffness
K_G Gas constant
ℓ Pipe length or distance to measuring point
L Lift
L Inertance
L Axial length
Latent heat
m Mass flow rate
m Rotordynamic coefficient: cross-coupled added mass
m_G Mass of gas in bubble
m_D Constant related to the drag coefficient
m_L Constant related to the lift coefficient
M Moment
M Mach number, u/c
M Rotordynamic coefficient: direct added mass
n Coordinate measured normal to a surface
N Specific speed
N(R_N) Cavitation nuclei number density distribution function
NPSP Net positive suction pressure
NPSE Net positive suction energy
NPSH Net positive suction head
p Pressure
p_A Radiated acoustic pressure
p^T Total pressure
p_G Partial pressure of gas
p_S Sound pressure level
p_V Vapor pressure
P Power
Vector of fluctuating quantities
Q Volume flow rate (or heat)
Rate of heat addition
r Radial coordinate in turbomachine
R Radial dimension in turbomachine
R Bubble radius
R Resistance
R_N Cavitation nucleus radius
Re Reynolds number
s Coordinate measured in the direction of flow
s Solidity
Surface tension of the saturated vapor/liquid interface
S Suction specific speed
S_i Inception suction specific speed
S_a Fractional head loss suction specific speed
S_b Breakdown suction specific speed
Sf Slip factor
t Time
T Temperature or torque
T_ij Transfer matrix elements
[T] Transfer matrix based on ,
[T*] Transfer matrix based on ,
[TP] Pump transfer matrix
[TS] System transfer matrix
u Velocity in the s or x directions
u_i Velocity vector
U Fluid velocity
U_∞ Velocity of upstream uniform flow
v Fluid velocity in non-rotating frame
V Volume or fluid velocity
w Fluid velocity in rotating frame
Rate of work done on the fluid
z Elevation
Z_CF Common factor of Z_R and Z_S
Z_R Number of rotor blades
Z_S Number of stator blades

GREEK LETTERS

α Angle of incidence
α_L Thermal diffusivity of liquid
β Angle of relative velocity vector
β_b Blade angle relative to cross-plane
γ_n Wave propagation speed
Γ Geometric constant
δ Deviation angle at flow discharge
δ Clearance
ε Eccentricity
ε Angle of turn
η Efficiency
θ Angular coordinate
θ_c Camber angle
θ^* Momentum thickness of a blade wake
Θ Thermal term in the Rayleigh-Plesset equation
Inclination of discharge flow to the axis of rotation
κ Bulk modulus of the liquid
μ Dynamic viscosity
ν Kinematic viscosity
ρ Density of fluid
σ Cavitation number
σ_i Cavitation inception number
σ_a Fractional head loss cavitation number
σ_b Breakdown cavitation number
σ_c Choked cavitation number
σ_TH Thoma cavitation factor
Σ Thermal parameter for bubble growth
Σ_{1,2,3} Geometric constants
τ Blade thickness
φ Flow coefficient
ψ Head coefficient
ψ₀ Head Coefficient at zero flow
ω Radian frequency of whirl motion or other excitation
ω_P Bubble natural frequency
Ω Radian frequency of shaft rotation

SUBSCRIPTS

On any variable, Q:

Q_o Initial value, upstream value or reservoir value
Q₁ Value at inlet
Q₂ Value at discharge
Q_a Component in the axial direction
Q_b Pertaining to the blade
Q_∞ Value far from the bubble or in the upstream flow
Q_B Value in the bubble
Q_C Critical value
Q_D Design value
Q_E Equilibrium value
Q_G Value for the gas
Q_H1 Value at the inlet hub
Q_H2 Value at the discharge hub
Q_i Components of vector Q
Q_i Pertaining to a section, i, of the hydraulic system
Q_L Saturated liquid value
Q_m Meridional component
Q_M Mean or maximum value
Q_N Nominal conditions or pertaining to nuclei
Q_n,Q_t Components normal and tangential to whirl orbit
Q_P Pertaining to the pump
Q_r Component in the radial direction
Q_s Component in the s direction
Q_T1 Value at the inlet tip
Q_T2 Value at the discharge tip
Q_V Saturated vapor value
Q_x Component in the x direction
Q_y Component in the y direction
Q_θ Component in the circumferential (or θ) direction

SUPERSCRIPTS AND OTHER QUALIFIERS

On any variable, Q:

Mean value of Q or complex conjugate of Q
Complex amplitude of oscillating Q
Time derivative of Q
Second time derivative of Q
Q* Rotordynamics: denotes dimensional Q
Re{Q} Real part of Q
Im{Q} Imaginary part of Q

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Last updated 12/1/00.

Christopher E. Brennen

ROMAN LETTERS

a	Pipe radius
A	Cross-sectional area
A_ijk	Coefficients of pump dynamic characteristics
[A]	Rotordynamic force matrix
Ar	Cross-sectional area ratio
B	Breadth of passage or flow
[B]	Rotordynamic moment matrix
c	Chord of the blade or foil
c	Speed of sound
c	Rotordynamic coefficient: cross-coupled damping
c_b	Interblade spacing
c_PL	Specific heat of liquid
C	Compliance
C	Rotordynamic coefficient: direct damping
C_D	Drag coefficient
C_L	Lift coefficient
C_p	Coefficient of pressure
C_pmin	Minimum coefficient of pressure
d	Ratio of blade thickness to blade spacing
D	Impeller diameter or typical flow dimension
Df	Diffusion factor
D_T	Determinant of transfer matrix [T]
e	Specific internal energy
E	Energy flux
E	Young's modulus
f	Friction coefficient
F	Force
g	Acceleration due to gravity
g_s	Component of g in the s direction
h	Specific enthalpy
h	Blade tip spacing
h_p	Pitch of a helix
h^T	Total specific enthalpy
h*	Piezometric head
H	Total head rise
H(s,θ,t)	Clearance geometry
I	Acoustic impulse
I,J	Integers such that ω/Ω=I/J
I_P	Pump impedance
j	Square root of -1
k	Rotordynamic coefficient: cross-coupled stiffness
k_L	Thermal conductivity of the liquid
K	Rotordynamic coefficient: direct stiffness
K_G	Gas constant
ℓ	Pipe length or distance to measuring point
L	Lift
L	Inertance
L	Axial length
	Latent heat
m	Mass flow rate
m	Rotordynamic coefficient: cross-coupled added mass
m_G	Mass of gas in bubble
m_D	Constant related to the drag coefficient
m_L	Constant related to the lift coefficient
M	Moment
M	Mach number, u/c
M	Rotordynamic coefficient: direct added mass
n	Coordinate measured normal to a surface
N	Specific speed
N(R_N)	Cavitation nuclei number density distribution function
NPSP	Net positive suction pressure
NPSE	Net positive suction energy
NPSH	Net positive suction head
p	Pressure
p_A	Radiated acoustic pressure
p^T	Total pressure
p_G	Partial pressure of gas
p_S	Sound pressure level
p_V	Vapor pressure
P	Power
	Vector of fluctuating quantities
Q	Volume flow rate (or heat)
	Rate of heat addition
r	Radial coordinate in turbomachine
R	Radial dimension in turbomachine
R	Bubble radius
R	Resistance
R_N	Cavitation nucleus radius
Re	Reynolds number
s	Coordinate measured in the direction of flow
s	Solidity
	Surface tension of the saturated vapor/liquid interface
S	Suction specific speed
S_i	Inception suction specific speed
S_a	Fractional head loss suction specific speed
S_b	Breakdown suction specific speed
Sf	Slip factor
t	Time
T	Temperature or torque
T_ij	Transfer matrix elements
[T]	Transfer matrix based on ,
[T]*	Transfer matrix based on ,
[TP]	Pump transfer matrix
[TS]	System transfer matrix
u	Velocity in the s or x directions
u_i	Velocity vector
U	Fluid velocity
U_∞	Velocity of upstream uniform flow
v	Fluid velocity in non-rotating frame
V	Volume or fluid velocity
w	Fluid velocity in rotating frame
	Rate of work done on the fluid
z	Elevation
Z_CF	Common factor of Z_R and Z_S
Z_R	Number of rotor blades
Z_S	Number of stator blades


GREEK LETTERS

α	Angle of incidence
α_L	Thermal diffusivity of liquid
β	Angle of relative velocity vector
β_b	Blade angle relative to cross-plane
γ_n	Wave propagation speed
Γ	Geometric constant
δ	Deviation angle at flow discharge
δ	Clearance
ε	Eccentricity
ε	Angle of turn
η	Efficiency
θ	Angular coordinate
θ_c	Camber angle
θ^*	Momentum thickness of a blade wake
Θ	Thermal term in the Rayleigh-Plesset equation
	Inclination of discharge flow to the axis of rotation
κ	Bulk modulus of the liquid
μ	Dynamic viscosity
ν	Kinematic viscosity
ρ	Density of fluid
σ	Cavitation number
σ_i	Cavitation inception number
σ_a	Fractional head loss cavitation number
σ_b	Breakdown cavitation number
σ_c	Choked cavitation number
σ_TH	Thoma cavitation factor
Σ	Thermal parameter for bubble growth
Σ_{1,2,3}	Geometric constants
τ	Blade thickness
φ	Flow coefficient
ψ	Head coefficient
ψ₀	Head Coefficient at zero flow
ω	Radian frequency of whirl motion or other excitation
ω_P	Bubble natural frequency
Ω	Radian frequency of shaft rotation


SUBSCRIPTS

On any variable, Q:

Q_o	Initial value, upstream value or reservoir value
Q₁	Value at inlet
Q₂	Value at discharge
Q_a	Component in the axial direction
Q_b	Pertaining to the blade
Q_∞	Value far from the bubble or in the upstream flow
Q_B	Value in the bubble
Q_C	Critical value
Q_D	Design value
Q_E	Equilibrium value
Q_G	Value for the gas
Q_H1	Value at the inlet hub
Q_H2	Value at the discharge hub
Q_i	Components of vector Q
Q_i	Pertaining to a section, i, of the hydraulic system
Q_L	Saturated liquid value
Q_m	Meridional component
Q_M	Mean or maximum value
Q_N	Nominal conditions or pertaining to nuclei
Q_n,Q_t	Components normal and tangential to whirl orbit
Q_P	Pertaining to the pump
Q_r	Component in the radial direction
Q_s	Component in the s direction
Q_T1	Value at the inlet tip
Q_T2	Value at the discharge tip
Q_V	Saturated vapor value
Q_x	Component in the x direction
Q_y	Component in the y direction
Q_θ	Component in the circumferential (or θ) direction


SUPERSCRIPTS AND OTHER QUALIFIERS

On any variable, Q:

	Mean value of Q or complex conjugate of Q
	Complex amplitude of oscillating Q
	Time derivative of Q
	Second time derivative of Q
Q*	Rotordynamics: denotes dimensional Q
Re{Q}	Real part of Q
Im{Q}	Imaginary part of Q