Post on 11-Mar-2020
transcript
Dr. Ir. Harinaldi, M.EngMechanical Engineering Department
Faculty of Engineering University of Indonesia
Centrifugal PuMP
Pumping System in an IndustryPumping System in an Industry
Centrifugal Pump
Construction and ComponentConstruction and Component
CasingCasing
Volute- area enlarge along flow direction- create uniform velocity distributionDiffuser- large size centrifugal pump- guide vanes surround the impeller- fluid flow decelerated while
directed to enter the volute
Working PrinciplesWorking Principles
Fluid
Kineti
c ene
rgy
pressure
InstallationInstallation
iii Zg
Vg
p
2
2
Inlet head :
ooo Zg
Vg
p
2
2
Outlet head : Total head developed by the pump:
ioioio ZZ
gVV
gppH
2
22
outinfofis
s
hhhhHlossesHH
H = manometric headhfi = friction loss at inlethfi = friction loss at outlethin= inlet losshout = outlet loss
ImpellerImpellerTheoretical Assumptions: No tangential flow in
the blade passage Impeller blades are
infinitely thin No Velocity variation
across impeller width Analysis only at inlet
and outlet Radial inlet flow
21
22
21
22
21
22
1122
21 WWUUCCg
gCUCUEh xx
Flow Capacity/Flow Rate
Head and Flow Capacity H Head and Flow Capacity H -- QQTheoretical Head Rise / Euler Head
222111 22 bCrbCrQ rr
slip
2
'2
:
x
xs C
Cfactorslip
STODOLA PROPOSALeCx
STODOLA PROPOSALIf the number of blades is Z, and impeller circumference is 2r2 then the distance between blades is 2r2/Z = 2e/sin Then :
Other Slip FactorStodola 20o < < 30o
222
2
cot1sin1
UCZ rs
Buseman 30o < < 80o
122
222
222
and , offunction are and cot1
cot
rrZBAUC
UCBAr
rs
Stanitz 80o < < 90o
222 cot163.01
UCZ rs
ExampleExampleThe impeller of a centrifugal pump has backward-facing blades inclined at 30o to the tangent at impeller outlet. The blades are 20 mm in depth at the outlet, the impeller is 250 mm in diameter and it rotates at 1450 rpm. The flow rate through the pump is 0.028 m3/s and a slip factor of 0.77 may be assumed. Assume also the blades of infinitesimal thickness. Determine the theoretical and actual head developed by the impeller, and the number of impeller blades
Solution:Flow Capacity/Flow Rate
m/s 78.1
02.025.0028.0
2
2
222
222
r
r
r
r
CC
bDQCbCDQ
For ideal outlet velocity triangle = 30o
m/s 08.330tan/78.130tan22 oorx CW
m/s 92.1508.319
m/s 1960/145025.060
222
22
xx WUCNDU
Theoretical (Euler) head
(ans.) m 83.3081.9
92.1519
) (0 11122
E
inletatradiallyentersflowCg
CUCUE xxx
Actual head with slip
(ans.) m 74.2383.3077.0.. 2
'2
EECC
sN
xsx
Number of blade
(ans.) 815.830cot1978.1130sin177.0
cot1sin1 2222
ZZ
UCZoo
rs
Pump LossesPump Losses1. Mechanical friction power
loss, Pm
2. Impeller (Disc) friction power loss, Pi
3. Leakage and recirculation power loss, Pl
4. Casing power loss, Pc
Pump LossesPump Losses1. Mechanical friction power loss, Pm
Pump LossesPump Losses2. Impeller (Disc) friction power loss, Pi
Head loss : hiFlow rate : Qi
Pi = g Qi hi
Pump LossesPump Losses3. Leakage and recirculation power loss, Pl
Head across impeller : HiLeakage flow rate : q = Qi - Q Pl = g qi Hi
Pump LossesPump Losses4. Casing power loss, Pc
Head loss : hcFlow rate : Q Pc = g Qhc
Pump Losses Pump Losses HH--Q DiagramQ Diagram
EfficiencyEfficiency
so P
gQH inputpower shaft
pumpby developedpower FluidEfficiency Overall
iic H
HgQHgQH
loss Leakage-impellerby developedpower Fluidoutlet casingat power Fluid
inlet casingat power Fluidoutlet casingat power FluidEfficiency Casing
iv Q
QqQ
Q
impeller through rate Flowpump through rate FlowEfficiency Volumetric
EfficiencyEfficiency
ii
i
iii
iii hH
HhHgQ
HgQ
lossimpeller impellerby developedpower Fluidexitimpeller at power Fluid
impeller tosuppliedpower Fluidexitimpeller at power FluidEfficiencyImpeller
s
iiim P
HhgQ
shaft theinput toPower impeller tosuppliedpower FluidEfficiency Mechanical
EH
hHH
iiH
impellerby developed head lTheoreticapumpby developed head ActualEfficiency Hydraulic
Efficiency RelationEfficiency Relation
icH
mvHmvico
Pump Shaft Power, Pump Shaft Power, PPss
QHqHQhQhgPP iciims
Driven Motor Shaft Power, Driven Motor Shaft Power, PPMM
Transmission Efficiency, Transmission Efficiency, TT
MTs PP T
SM
PP
PumpPump’’s Characteristic Curves Characteristic Curve
QKKEgAQUUE
21
222
cot
sN QKKE 21
flowratedesignisQwhere
QQKh
D
Dshock
:
23
24QKhf
Effect of Flow Rate VariationEffect of Flow Rate VariationInlet velocity
Outlet velocityQ ; H Q ; H
Effect of Blade Outlet AngleEffect of Blade Outlet Angle2222 cot rx CUC
bQaHgAQUgUE
gCUUE r
2222
2222
cot
cot
ofor 90 2
ofor 90 2 aH
ofor 90 2 bQaH
Effect of Blade Outlet AngleEffect of Blade Outlet AngleTheoretical characteristic curves
Actual characteristic curves
Flow in the Discharge CasingFlow in the Discharge CasingVolute Casing
Function:1. Collector2. Diffuser
Deviation in capacity from the design condition will result in a radial thrust (P):
222
136.0:
495
DQQKwhere
BKHDP
Function:P = radial force (N)H = Head (m)D2 = peripheral diameter (m)B2 = impeller width (m)Circular section to
reduce losses due to friction and impact
Flow in the Discharge CasingFlow in the Discharge CasingVaneless Diffuser
Flow in the Discharge CasingFlow in the Discharge CasingVaneless Diffuser Continuity:
222222 rrr CbrCrbACm rbCbrC rr 2222
Conservation of angular momentum:
rxxx CCusuallyrrCC 22
Then: xCC
rrCC x 22 Radius, r Outlet kinetic energi
'tan'tan 222 consCC rx
drrd
'tan
22 ln'tan rr Then:
diffuserofangle
Flow in the Discharge CasingFlow in the Discharge CasingVaned Diffuser
Number of vanes on the diffuser ring:
Greater number better diffusion but more friction loss
Square cross section of diffuser channel max rh
Number of diffuser vanes have no common factor with the number of impeller
Higher rate Shorter length Higher efficiency
Able to diffuse the outlet kinetic energy at:
Flow in the Discharge CasingFlow in the Discharge CasingContribution of each section of the pump to total head
Cavitation in PumpsCavitation in PumpsVapour bubbles formation of the liquid as the local absolute static pressure of a liquid falls below the vapour pressure occurs mainly at the suction side (at the eye of impeller as the
velocity increases and pressure decreases) Local pitting of impeller cavitation erosion Noise Decrease pump efficiency
Net Positive Suction Head (NPSH)Net Positive Suction Head (NPSH)The difference of total suction head in the impeller inlet side (impeller eye) above the vapour pressure
absolutearepressuresallg
pg
Vg
pNPSH vapii 2
2
A measure of the energy available on the suction side of the pump
A measure to indicate the occurrence of cavitation
Cavitation Parameter (Toma Cavitation Number)
Hg
pg
Vg
p
pumpbyDevelopedHeadNPSH
vapii
2
2
NPSH Required (NPSHR) Net Suction Head as required by the pump
in order to prevent cavitation for safe and reliable operation of the pump.
The required NPSHR for a particular pump is in general determined experimentally by the pump manufacturer (will vary depending on the size and speed of the pump) and a part of the documentation of the pump.
Net Positive Suction Head (NPSH)Net Positive Suction Head (NPSH)
Measurement of NPSHR by 3% head reduction
Example of pump documentation
NPSH Available (NPSHA) The Net Positive Suction Head
made available the suction system for the pump.
The NPSHA can be determined during design and construction, or determined experimentally from the actual physical system and calculated with the Energy Equation
Net Positive Suction Head (NPSH)Net Positive Suction Head (NPSH)
Energy at 1 = Energy at 2 + Energy lost between 1 and 2
inletinlet losseszg
pg
Vg
plosessg
Vg
pzg
p1
12
222
221
1
22
At inlet p2 = pi ; V2 = Vi and lossesinlet = hin + hfi, then:NPSH available at impeller inlet :
fiivap
A hhzg
pg
pNPSH 11
To avoid cavitation in a pump operationCavitation ~ NPSHCavitation ~ NPSH
RA NPSHNPSH RA or
Suction Specific SpeedSuction Specific SpeedA function due to cavitation that influences the efficiency
4/3
2/1
NPSHgNQN suc
Dimensionless suction specific speed
sucNf ,
4/34/3
4/3
H
NPSHNN
suc
s
Cavitation parameter
212
212
212
1 DDNNNPSHNPSH
Similarity Laws
ExampleExampleWhen a laboratory test was carried out on a pump, it was found that, for a pump total head of 36 m at discharde of 0.05 m3/s, cavitation began when the sum of the static pressure plus the velocity head at inlet was reduced to 3.5 m. The atmospheric pressure was 750 mmHg and the vapour pressure of water 1.8 kPa. If the pump is to operate at a location where atmospheric pressure is reduced to 620 mmHg and the vapour pressure of water is 830 Pa, what is the value of the cavitation parameter when the pump develops the same total head and discharge? Is it necessary to reduce the height of the pump above the supply, and if so by how much?