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COLLEGE OF ENGINEERING
DEPARTMENT OF NUCLEAR ENGINEERING LABORATORY FOR FLUID FLOW AND HEAT TRANSPORT PHENOMENA
Technical Report No. 18
CHOKED FLOW ANALOGY FOR VERY L O W
QUALITY TWO-PHASE FLOWS
by :
Frederick G . Hamitt M . John Robinson
Under contract with:
National Aeronautics and Space Administration Grant No. NsG-39-60 Washington 25 , D . C .
Office of Research Administration Ann Arbor
March, 1966
k
https://ntrs.nasa.gov/search.jsp?R=19660017369 2018-05-24T09:13:32+00:00Z
ABSTRACT
Two t h e o r e t i c a l models t o pred ic t a x i a l pressure d i s t r ibu t ion ,
void fract ion, iliid velocity iil a cav i t a t ing ven tu r i are applied. The
theo re t i ca l p red ic t ions a r e compared wi th experimental da ta from cold
water and mercury tests, and good agreement f o r the pressure p r o f i l e s is
found. The predicted void f rac t ions a r e found t o be too high, probably
because the models assume zero s l i p o r negative s l i p between the vapor
and l iqu id phases.
The analogy between the cav i t a t ing ven tu r i and o the r choked flow
regimes i s explored. One of the t h e o r e t i c a l models used is based on the
assumption t h a t the cavi ta t ing v e n t u r i is e s s e n t i a l l y e n t i r e l y analogous
t o a deLaval nozzle operating i n a choked flow regime with a compres-
s i b l e gas .
The cav i t a t ing ventur i i s an example of an extremely low qua l i ty
choked two-phase flow device. The present study i s thus somewhat appl i -
cable t o the study of liquid-cooled nuclear reac tor pressure ves se l o r
piping ruptures , which have received considerable a t t e n t i o n i n recent
years . However, the qua l i t i e s encountered i n the present cav i t a t ion
case are an order of magnitude lower than those usual ly considered f o r
the reac tor s a fe ty analyses, so t h a t t he present study is a l imi t ing
case f o r these .
ii
ACKNOWLEDGMENTS
The authors would l i ke t o acknowledge the work of D r . Willy
Smith and M r , I an E . 3. Lauchlan, former s tudents at the 'u'niversity of
Michigan, whose void f r ac t ion da ta w a s used f o r t h e comparisons wi th
the t h e o r e t i c a l l y derived numbers i n t h i s i nves t iga t ion , and Captain
David M. Ericson Jr., USAF, doctora l candidate a t t he University of
Michigan, whose experimental p ressure p r o f i l e da ta w a s used f o r t h i s
comparison wi th ca l cu la t ed pressure p r o f i l e data.
.
iii
TABLE O F CONTENTS
Page
ABSTRACT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii
ACKNOWLEDGMENTS . . . . . . . . . . . . . . . . . . . . . . . . . iii
NOMENCLATURE . . . . . . . . . . . . . . . . . . . . . . . . . . . V
L I S T OF TABLES v i . . . . . . . . . . . . . . . . . . . . . . . . . . L I S T OF FIGURES . . . . . . . . . . . . . . . . . . . . . . . . . v i i
I . INTRODUCTION. . . . . . . . . . . . . . . . . . . . . . . . 1
. . . . . . . . . . . . . . . . 11. BACKGROUND FOR PRESENT STUDY 5
111. CALCULATING PROCEDURES . . . . . . . . . . . . . . . . . . . 10
A. H o m o g e n o u s F l o w M o d e l B . H y d r a u l i c Jump M o d e l
I V . RESULTS . . . . . . . . . . . . . . . . . . . . . . . . . . A. Theoret ical Models B . C o m p a r i s o n w i t h E x p e r i m e n t a l D a t a
V. CONCLUSIONS . . . . . . . . . . . . . . . . . . . . . . . . V I . A P P E N D I X . . . . . . . . . . . . . . . . . . . . . . . . . .
A . Sonic V e l o c i t y i n Low Q u a l i t y T w o - P h a s e M i x t u r e s . . . . . . . . . . . . . . . . . . . . . . .
B. C o n d e n s a t i o n ShockWave Analysis . . . . . . . . . . . C . H y d r a u l i c J u m p M o d e l . . . . . . . . . . . . . . . . .
BIBLIOGRAPHY . . . . . . . . . . . . . . . . . . . . . . . . . . .
24
35
36
36
37
38
39
Y
i v
.
~
i 1 I
Symbol
g,,g
h
J
k
L
M,&
P
R
t ,T
V
v
X
P z
NOMENCLATURE
Meaning
sonic ve loc i ty - area
r a t i o of vapor t o l i qu id volume
f l u i d (subscript) - force
g rav i t a t iona l accelerat ion constant , g - vapor (subscr ipt)
enthalpy
conversion constant - mechanical t o heat energy un i t s
t herma 1 conductivity
l i qu id (subscript)
Mach number, mass flow r a t e
pressure
universal gas constant
ven tu r i th roa t (subscr ipt) - t o t a l (subscr ipt)
spec i f i c volume
ve loc i ty
qua l i t y
parameter defined eq. (3) of Appendix
densi ty
a x i a l dis tance from throa t discharge i n ven tu r i s
V
LIST OF TABLES
Table
I. Calculated Parameters from Shock Wave and Hydraulic J m p Y ! d e ? s . . . . . . . . . . . . . . . . . . . . . . .
Page
18
v i
LIST OF FIGURES
i Figure Page
1. Basic ven tu r i flow path dimensions . . . . . . . . . . . . 6
2. Sketch of cav i t a t ing ventur i hydraul ic jump flow analogy . . . . . . . . . . . . . . . . . . . . . . . . 9
3 . Calculated sonic ve loc i ty v s . void f r a c t i o n f o r homogenous mixtures . . . . . . . . . . . . . . . . . . 11
4 . Calculated qua l i t y v s . void f r a c t i o n . . . . . . . . . . . 12
5. T-S diagram of the cavi ta t ing ven tu r i process . . . . . . 14
6 . Mach number r a t i o f o r both models vs . void f r a c t i o n f o r both shock wave and hydraulic jump models . . . . . . . 19
7 . Calculated pressure jump vs . void f r a c t i o n f o r shock wave model . . . . . . . . . . . . . . . . . . . . . . . 20
8. Normalized pressure and void f r a c t i o n v s . a x i a l pos i t i on f o r water, experimental v s . ca lcu la ted comparison f o r standard cav i t a t ion . . . . . . . . . . . . . . . . . . 2 1
9. Normalized pressure and void f r a c t i o n v s . a x i a l pos i t i on f o r water, experimental vs . ca lcu la ted comparison f o r f i r s t mark cavi ta t ion . . . . . . . . . . . . . . . . . 22
10. Normalizsd pressure and void f r a c t i o n vs . a x i a l pos i t i on €or mercury, experimental vs . ca lcu la ted comparison f o r standard cav i t a t ion . . . . . . . . . . . . . . . . 27
11. Void f r x t i o i l vs. radius f o r w a t e r a t severa l a x i a l locat ions f o r standard cav i t a t ion . . . . . . . . . . . 29
12 . Void f r a c t i o a v s . radius f o r water a t severa l a x i a l locat ions f o r f i r s t mark cav i t a t ion . . . . . . . . . . 30
13. Vold f r a c t i o n p ro f i l e s f o r standard and f i r s t mark cav i t a t ion conditions i n mercury . . . . . . . . . . . . 31
v i i
Figure Page
14. Average venturi void fraction vs . axial distance for mercury . . . . . . . . . . . . . . . . . . . . . . . . 32
. 15. Velocity prof i les as function of radial position and
cavitation condition, observer at tap position G , cold weter, 1/2 inch t e s t section . . . . . . . . . . . 34
v i i i
I. INTRODUCTION
Very low qua l i ty two-phase "choked" flows are important today i n
many appl ica t ions . That which has received the greatesc ac ten t ion i n
recent years i s the postulated nuclear reac tor accident wherein a rup-
t u r e of a high-temperature high-pressure l iquid-carrying pipe i s
assumed. Another r eac to r sa fe ty problem a l s o involving somewhat s i m i l a r
flow considerat ions i s the occurrence of a rapid f u e l temperature t ran-
s i e n t i n a liquid-cooled core. I n t h i s case the evaluat ion of the maxi-
mum ve loc i ty of t ranspor t of t h e liquid-vapor mixture from the region
becomes important.
Other appl ica t ions of such low q u a l i t y choked flows which have
been of importance f o r many years are cav i t a t ing flow regimes such as
e x i s t i n pumps, valves , marine propel lors , hydraulic tu rb ines , ventur i s
and o r i f i c e s , e t c . The present da t a and analyses a re motivated by these
l a t t e r appl icat ions and hence involve extremely low q u a l i t i e s as com-
pared t o the usual reac tor problem, s ince they deal with f l u i d s such as
low temperature water with i t s very low vapor t o l iqu id dens i ty r a t i o .
However, the void f r ac t ions are of a magnitude s i m i l a r t o those con-
s idered f o r the reac tor cases . Hence the present study examines i n
d e t a i l the extremely low qual i ty end of the spectrum from the viewpoint
1
2
of the reac tor s a fe ty problems, which i s , nevertheless , the primary area
of concern i n the usual cav i t a t ion s i t u a t i o n .
The e a r l i e s t s tud ies which, t o our knowledge, have considered
the analogy between low-quality two-phase flows and the conventional
compressible choked flows dea l with cav i t a t ion (L,2). I n both cases
cav i t a t ing ventur i s were considered, as i n the present study. I n the
paper by Hunsaker (1) it i s noted t h a t the maximum pressure rise occurs
a t the v i s u a l downstream termination point of the cav i t a t ion cloud. The
Randall (2) paper discusses the use of the choked flow fea ture of a cav-
i t a t i n g ven tu r i f o r flow-rate regulation and notes t h a t the flow region
downstream of the throa t e x i t cons is t s of a high speed j e t surrounded by
vapor, a f a c t a l s o noted by Nowotny (2). However, none of these pre-
s en t s a quan t i t a t ive ana lys i s of t he flow such a s the analogy t o the
con-rentional choked flow s i tua t ions presented here .
The exis tence of a close analogy between cav i t a t ing flow phenom-
ena i n cen t r i fuga l o r a x i a l pumps and compressible flow phenomena i n
s imi l a r compressors has been real ized f o r some t i m e , including the f a c t s
t h a t the occurrence of cavi ta t ion i n a pump i n l e t w a s somehow very s i m i -
l a r t o the occurrence of Mach 1 condi t ions i n a compressor i n l e t , and
t h a t both r e su l t ed i n a choked flow condi t ion. More quant i ta t ive
approaches have been made i n recent papers on cav i t a t ing flow i n cen t r i -
fugal or a x i a l flow pumps i n order t o explain some of the p e c u l i a r i t i e s
i n the e f f e c t s of the cavi ta t ion on the pump performance (A,>).
A recent: excel lent quant i ta t ive study of the flow of l o w qua l i t y
a i r -water mixtures through a converging-diverging nozzle, ( i . e . , a
3
ventur i" from the viewpoint of cav i t a t ing (flows), has been made by 11
Muir and Eichhorn ( 6 ) . This reports on the exis tence of a compression
shock when the flow i s underexpanded, but presents no ana lys i s of t h i s
shock,
is reported by Starkman, e t a1 (1). I n t h i s p a r t i c u l a r case the minimum
q u a l i t i e s considered are i n the 1 t o 2 percent range, which i s consider-
ably above the range considered i n the present paper. The exis tence of
compression shocks under su i tab le conditions i s mentioned, but no quan-
t i t a t i v e data thereon i s presented o ther than the observation t h a t the
condensation shock i s much less abrupt than the conventional normal
shock i n a compressible gas flow. F ina l ly , a very recent experimental
and theo re t i ca l study of water-nitrogen mixtures a t about 50 percent
void f r ac t ion by Eddington (E) deals with shock phenomena i n t h i s type
of mixture.
A study of low-quality flow of water through a s i m i l a r geometry
The above s tud ie s , which have only been se lec ted as t y p i c a l ,
s ince many more e x i s t i n the l i t e r a t u r e (see bibliography of reference
5, e .g . ) a r e motivated by conventional flow appl ica t ions r a the r than
nuclear reac tor s a f e t y problems, However, var ious s tud ie s motivated by
reac tor s a fe ty a l s o e x i s t i n the l i t e r a t u r e .
Xoody (10) and Min, Fauske, and P e t r i c k (11) are t y p i c a l . Generally
these dea l with s i m p l e converging ( r a the r than converging-diverging)
passages, s ince a converging opening b e t t e r models a poss ib le rupture of
a pipe o r pressure v e s s e l .
i n the throa t of the converging sec t ion , but do not concern themselves
with shock waves which a r e only involved i n the diverging
Studies by Levy (21,
Hence they consider the choked flow analogy
4
("supersonic") por t ion . Generally the q u a l i t i e s considered a r e g rea t ly
i n excess of those of the present paper.
I n addi t ion t o a l l the above, there has a l s o been some recent
interest (12) i n the q u i t e analogous s i t u a t i o n of high-quality choked
flows such as are encountered with sa tura ted vapor expanded through a
nozzle. I n t h i s case it has long been known t h a t condensation shocks
sometimes occur a f t e r the flow has a t t a ined a non-equilibrium sub-cooled
condition due t o the r ap id i ty of the expansion. This type of flow s i t u -
a t ion is primari ly appl icable to tu rb ines operating with sa tura ted o r
w e t steam i n l e t condi t ions.
11. BACKGROUND FOR PRESENT STUDY
Considerable experimental da ta has been gathered i n the authors '
laboratory on cav i t a t ing flow regimes i n ven tu r i s both with water and
mercury a s test f l u i d . This data includes measurements of a x i a l pres-
sure p r o f i l e s , ve loc i ty p ro f i l e s using a micro-pitot tube, and void
f r ac t ion d i s t r i b u t i o n by gama-ray densitometer, a s wel l a s high speed
motion p i c tu re s tud ies of the flow. A port ion of the da ta r e l a t i n g t o
the void f r ac t ion and p i t o t tube measurements a l ready appears i n the
open l i t e r a t u r e (13,14), while addi t iona l void f r ac t ion (15) and pres-
sure p r o f i l e da ta (16) has not y e t been published. A f u l l descr ip t ion
of the closed loop ven tu r i tunnel f a c i l i t i e s both f o r water and mercury
has a l ready been given (17).
ven tu r i s used i s shown f o r convenience i n Fig. 1. A 1/2" diameter
c y l i n d r i c a l th roa t of 2.35" length i s located between nozzle and d i f -
fuser sec t ions , esch with 6" included angle f o r the port ion adjacent t o
the t h r o a t . The d i f fuse r continues a t t h i s cone angle out t o almost the
f u l l pipe diameter.
However, the basic flow path design of the
With a wealth of experimental data i n hand f o r t h i s cav i t a t ing
flow geometry i t i s des i rab le to develop an ana ly t i ca l model capable of
pred ic t ing a p r i o r i the pressure p r o f i l e s , v e l o c i t i e s , temperatures, and
void f r ac t ions which would be encountered once the required independent
5
5
- 0 0 3-25 v)(D
t
. m C 0 -d m E
-4 a E" c 4J a a 0
VI
= 3 u 2 rl
I -4
4J
cu k 1 3 U C
0 8
6
m
a 4
7
var i ab le s had been set .
cav i t a t ing ventur i case, it also has some appl ica t ion t o o ther c a v i t a t -
While such a model appl ies pr imari ly t o the
ing flows such a s a r e encountered i n turbomachinery, e t c . , and a l s o t o
reac tor s a fe ty problems, even though these nay normally involve somewhat
higher q u a l i t i e s than those considered f o r the present case (maximum of
about
As already mentioned, e a r l i e r i nves t iga to r s (&3J have noted
t h a t a cav i t a t ing v e n t u r i flow can o f t en be considered approximately a s
a high speed c e n t r a l j e t issuing from the th roa t and with a diameter and
ve loc i ty approximately equal t o those a t the t h r o a t . Our own invest iga-
t i o n s with a p i t o t tube i n water (s), by v i s u a l observation i n mercury
where the gap between the transparent w a l l and the c e n t r a l mercury col-
umn could e a s i l y be seen (l3), and by gamma-ray densitometer void f rac-
t i o n measurement i n mercury (13,14), tended t o confirm the s u i t a b i l i t y
of t h i s model. However, l a t e r void f r a c t i o n measurements i n water (IS),
disagreed i n showing a predominance of void f r ac t ion near the ax i s . The
reason f o r the disagreement between the p i t o t tube and gamma-ray densi-
tometer data in water i s not known. However, the average void f r ac t ions
presented a s a function of ax ia l pos i t ion i n F igs . 8 and 9 a r e taken
from the garnayray densitometer da t a .
Two possible theo re t i ca l models f o r the flow were inves t iga ted .
Neither matches the observations on the flow regime completely, but
hopefully should give r e s u l t s of reasonable engineering accuracy.
i> HDmogeneous flow mode1 wherein it i s assumed tha t the vapor i s
dispersed 9rzifcrrr.ly thmughe-t t he f l u i d fer el!. p lanes normal tc t h e
8
a x i s , t h a t the two phases always have the same ve loc i ty , and t h a t
thermal equilibrium e x i s t s . The flow i s assumed adiaba t ic everywhere,
and i sen t ropic except f o r t he condensation shock wave which i s assumed
t o e x i s t a t the termination of the cav i t a t ing region.
stream of the shock i s assumed to be zero. Conservation of momentum
m a s s , and energy are s a t i s f i e d f o r a l l cross-sect ions.
The qua l i t y down-
i i ) Assuming the c e n t r a l j e t model with diameter and ve loc i ty equal
t o those a t the th roa t , i t is assumed t h a t the c a v i t a t i o n termination
region is analogous t o a hydraulic jump. The region around the c e n t r a l
j e t i s assumed f i l l e d with stagnant vapor a t a pressure equal t o the
sa tu ra t ion pressure ex i s t ing a t t h e th roa t discharge. While the "height"
of the jump i s terminated by the sidewalls of the ven tu r i a t t h e i r loca-
t i o n , the pressure a t the w a l l i s assumed equal t o t h a t a t t h e appropri-
a te submergence i f a n ac tua l hydraulic jump exis ted (see sketch of
F ig . 2 ) .
g rav i ty is neglected so t h a t the wal l pressure a t t he jump i s assumed t o
apply over the e n t i r e cross-sect ion. A s i n the conventional hydraulic
jump analysis, momentum and mass a re considered t o be conserved across
the jump. Af te r the jump t h e l i qu id f i l l s the e n t i r e cross-sect ion, so
t h a t the qua l i t y here i s zero as i n the previous model. Note t h a t the
void f r a c t i o n upstream of t h e jump i s simply the r a t i o of a rea around
the j e t t o t o t a l a rea f o r any cross-sect ion.
I n t h i s model as applied t o the conical ven tu r i d i f fuse r ,
+
f
I
9
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t I
3 0
U E
$ M E 4 U cd U 4
c)
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%
c r)
t I
N
bo 4 h .
h 2
111. CALCULATING PROCEDURES
The ca lcu la t ing procedures followed f o r the two models a r e sum-
mari ze d be low :
A . Homogeneous Flow Model
1. Throat Discharge t o Cavi ta t ion Terminat ion Point
From the throa t discharge t o the cav i t a t ion termination point
t he flow is assumed t o be isentropic-adiabat ic . The throa t ve loc i ty and
w a t e r temperature a t the throat can be considered independent var iab les ,
and hence known f o r a given case. Assuming t h a t the flow i s analogous
t o a compressible gas choked flow i n a deLaval nozzle, Mach 1 must exist
a t the th roa t discharge where it i s assumed t h a t the cav i t a t ion w i l l
begin.
e x i s t f o r a cy l ind r i ca l th roa t due t o the e f f e c t s of f r i c t i o n . 111 the
present i dea l flow ana lys is of course the pressure would remain constant
along the throa t . A s shown i n F i g . 3, sonic v e l o c i t i e s i n l o w qua l i t y
water-steam mixtures can be extremely low (see Appendix f o r appropriate
r e l a t i o n s ) , and hence of the order of reasonable throa t v e l o c i t i e s f o r
cav i t a t ing ventur i s , f o r void f r ac t ions i n excess of Then, as
shown i n Fig. 4, the qua l i t y is of the order of 10 t o 10 , and i t s
ne t e f f e c t upon the thermodynamic mixture proper t ies except f o r sonic
Here, i n a real case, the minimum pressure would be expected t o
-6 -8
10
*.
11
0 -
LL Ir. 0 L L O oolc! O O n N W Y ) II n n
w w w l - l - k -
4 0 0 0
I l l I I I I I I I I I I I I I I 1 1 1 1 1 I I I Y)
I
k 0 w c 0 4 +, 0 cd k w U 4 0 > Im rn k Q) > A +, .r( 0 0 r( Q) > 0 4 a 0
U 0, +J
cd r( 1 0 r( td u m
M
R
rn
4
12
. I- /
/
I- /
O TEMP=ZOO*F
0 TEMP=60*F
V TEMP =53.5*F
/
I- // 1860
I I I I 1 l l l l I I I I I l l l l I I I 1 l l l l l I I 1 1 1 1
10'2 to4 I
VOID FRACTION
Fig. 4 Calculated quality versus void fraction
13
ve loc i ty is negl ig ib le .
considered pure l iqu id .
Hence the flow issuing from the th roa t can be
The computation of conditions f o r any point downstream of the
th roa t discharge and within the cav i t a t ion region is e n t i r e l y s imi l a r t o
t h a t normally employed for the computation of condi t ions i n a nozzle
handling w e t steam. Conventional steam tab le s (19) can be employed.
The assumed process an a T-S diagram is sketched i n Fig. 5, the region
between
shock but i n the cav i t a t ing region), being the por t ion under present
discussion.
( th roa t discharge), and 1 (a point immediately upstream of the
Using the steam tab le s (19), it i s necessary t o f ind by t r i a l
and e r r o r t he temperature a t point 1 such t h a t the flow w i l l remain
i s en t rop ic , and the conditions of energy and mass conservation w i l l be
maintained (see Appendix f o r appropriate r e l a t i o n s ) . For the cold water
example computed ( throa t ve loc i ty of 6 4 . 6 f t . / s e c . ) , the temperature
drop t o the point of cav i ta t ion termination i s only a very s m a l l f rac-
t i o n of a degree. This i s typ ica l of the cav i t a t ion case. Even so,
t h i s temperature decrease must be considered s ince the s p e c i f i c volume
and entropy of the vapor a r e extremely sens i t i ve t o temperature i n t h i s
region. Also, the ve loc i ty of the mixture i s qu i t e constant from the
th roa t discharge t o the cav i t a t ion termination poin t , with the void
f r a c t i o n increasing appropriately t o counter the increase i n cross-
s ec t iona l area of the d i f fuse r . The t h e o r e t i c a l model f o r homogenized
flow i s thus cons is ten t with the hypothesized c e n t r a l j e t flow regime i n
t h a t both pred ic t r e l a t i v e l y constant ve loc i ty through the cav i t a t ion
region.
I-
w 2 I- Q L1L w n 2 w I-
C
a
14
) SATURATION LINE
DIFFUSION AFTER SHOCK
d EXPANSION FROM INLET TO THROAT IN CONVERGING ( SUBSONIC 1, PORTION 4
SHOCK /v \EXPANSION FROM THROAT
TO SHOCK IN DIVERGING, (SUPERSON IC)rPORTION.
1861 ENTROPY, s
Fig. 5.--T-S diagram of the cavitating venturi process.
15
2. Cavi ta t ion Termination Region (Shock Wave)
The conditions immediately upstream of the pos tu la ted shock wave
are as given from t h e ca l cu la t ion previously discussed. I f t h e v e l o c i t y
of sound is computed f o r t h e mixture a t t h i s po in t , i t i s found t h a t t h e
flow i s highly supersonic as would be expected from t h e analogy with
compressible gas flow. It i s required t h a t immediately a f t e r t he shock,
which is assumed t o requi re zero a x i a l ex ten t , a l l t he vapor has con-
densed (Fig. 5), so t h a t t he qua l i t y and void f r a c t i o n are zero. Thus
it is clear t h a t a f t e r t he shock the flow i s highly subsonic s ince t h e
v e l o c i t y of sound i n a l i q u i d i s t y p i c a l l y of t h e order of 10 t o 10
f e e t per second.
3 4
Afte r the shock the f l u i d may have a pressure i n excess of vapor
pressure f o r the new temperature, which i s presumably s l i g h t l y above the
temperature upstream of the shock by v i r t u e of t h e l a t e n t heat re leased
by the condensing vapor. I n fac t i t is clear that t h e enthalpy a f t e r
the shock must be g r e a t e r than t h a t a t th roa t discharge, s ince the
k i n e t i c head has decreased. In general , then, the temperature must also
be higher since, while t he re was a s l i g h t q u a l i t y a t t h roa t discharge,
t h e f l u i d i s assumed vapor f r ee a f t e r t h e shock.
The ca lcua t ion of conditions a f t e r t he shock from the upstream
conditions requi res an appl ica t ion of conservation of momentum and mass.
The only quant i ty of i n t e r e s t t o be found from conservation of energy i s
t h e temperature a f t e r t h e shock. However, sample ca l cu la t ions show t h a t
t h i s quant i ty does not change appreciably over the shock. The conserva-
t i o n of mass and momentum equations can easily be arranged t o the form
16
of eq. (6) and (7) i n Appendix B y with the assumption t h a t 6-4. Hence
t h e v a l i d i t y of the theo re t i ca l r e s u l t s is l imited t o xC0.01. Using
these equations i t i s possible t o make the ca l cu la t ion . However, i n
order t o explore the analogy with compressible gas flow it w a s des i red
t o express the r e l a t i o n s i n terms of Mach number. This can be accom-
p l i shed as shown i n Appendix A following t o some exten t t h e procedure of
Jakobsen (9 . The opera t ive equations are now eq. (12) , (13) , and (14),
and from these the conditions a f t e r the shock can be computed.
3 . Cavi ta t ion Termination t o Venturi Discharge
Since the flow i n t h i s region is vapor f r e e , the computation i s
e n t i r e l y straightforward and assumes f r i c t i o n l e s s flow. I n terms of t h e
T-S diagram (Fig. 5), t h i s portion is an i s en t rop ic compression from 2
t o cl, where t h e l i q u i d i s subcooled.
B. Hydraulic Jump Model
1. Throat Discharge to Cavitation Termination
I n t h i s region a cen t r a l l i qu id j e t (zero qua l i ty ) is assumed
surrounded by stagnant vapor at t h e vapor pressure corresponding t o
th roa t discharge temperature.
out.
t he j e t ve loc i ty remains equal t o the th roa t ve loc i ty .
t he void f r a c t i o n a t any a x i a l pos i t i on wi th in t h e c a v i t a t i o n region is
simply t h e r a t i o of t h e c ross -sec t iona l a r ea around t h e j e t t o the t o t a l
c ross -sec t iona l a rea . This i s a l s o approximately t r u e f o r t he shock
wave model s ince , a t l e a s t f o r t he examples computed, the ve loc i ty
upstream of the shock is about equal t o t h e th roa t ve loc i ty .
Temperature i s assumed constant through-
Since t h e j e t diameter i s assumed equal t o the th roa t diameter,
For t h i s model
17
2. Cavi ta t ion Termination Region (Hydraulic Jump)
Conservation of mass and momentum i s appl ied across the cavi ta -
t i o n termination region as i n the conventional hydraulic jump ana lys i s
(20) except t h a t t he pressure i s assumed uniform across a plane normal
t o axis immediately upstream of t h e jump, i.e., g rav i ty is neglected.
The j u q , as the shock wave, is = s a m e 3 t o reqrrire zerc a x i a l ex ten t .
The analogy t o a hydraulic jump s t e m s from considerat ion of a two-
dimensional case wherein the ventur i w a l l would be f i c t i t i o u s l y removed,
and the l i q u i d allowed t o assume the height downstream of the jump which
it would a t t a i n i f the flow were hor izonta l , and under the influence of
g rav i ty (Fig. 2) .
The appl icable equations a r e shown i n Appendix C , the operat ive
equations now being eq. (15) and (17). It i s noted t h a t t he momentum
equation, (16), is i d e n t i c a l t o t he comparable momentum equation from
the shock wave ana lys i s , ( 7 ) . Thus the models w i l l give s imilar r e s u l t s
i f V i s the same i n the two cases. I n the cases f o r water flow which
have been invest igated, t h i s is e s s e n t i a l l y t r u e , even f o r the 200°F
1
water (Table I and Figs . 6 and 7 ) . Since the pressure rise predict ions
from the two models are almost i d e n t i c a l f o r the cases examined, only
one t h e o r e t i c a l curve is shown i n Figs . 8 and 9, where the experimental
r e s u l t s and theory a r e compared. This equa l i ty of r e s u l t s between the
models is a l s o the case f o r void f r ac t ion , so t h a t again only one
t h e o r e t i c a l curve is shown.
0000000
. t m c o o h m \ D m o O o o
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0 0 0 0 0 0
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23
3 . Cavitation Termination t o Venturi Discharge
The calculation f o r t h i s region i s identical t o that already
discussed for the shock wave model.
I V . ReSULTS
A. Theoret ical Models
As previously discussed, ca lcu la t ions have been made f o r the
ventur i shown i n Fig. 1 f o r water a t 53.5”F, 60.0°F, and 200°F. The
lower temperature matches experimental water data with 64.6 f t . / s e c .
t h roa t ve loc i ty f o r void f r ac t ion and pressure p r o f i l e s (15,16) taken
f o r two d i f f e r e n t ex ten ts of the cav i t a t ing region:
(standard cav i t a t ion ) , and 1.75 inches ( f i r s t mark cav i t a t ion ) , down-
stream from the throa t e x i t .
0.786 inches
The ca lcu la t ing procedures have already been described, and the
equations involved a re shown i n the Appendix. An examination of these
w i l l show t h a t t he calculat ions a r e independent of th roa t ve loc i ty
unless ac tua l magnitudes of pressure r i s e and Mach number a re required.
The f l u i d propert ies , however, a r e required immediately, so tha t i t is
necessary t o specify the f lu id and i t s temperature. Assuming, then, t h a t
water is the f l u i d a t the three spec i f ied temperatures and assuming var-
ious values f o r t he r a t i o of cross-sect ional a reas between cav i t a t ion
termination and th roa t , i t is possible t o compute qua l i ty , void f rac-
t i o n , and sonic ve loc i ty immediately upstream of the shock. For a given
water temperature, there i s of course a unique r e l a t i o n between void
fraction and sonic T!elncity> end alsn v n i d f r l c t i n n lrzd flj121-ii-V rant4 1””’J ¶ ----
24
25
these a re shown i n Figs . 3 and 4 , respect ively, and l i s t e d i n Table I.
It i s a l so possible , without specifying ve loc i ty , t o compute t h e
r a t i o of Mach numbers (M1/M2) across the shock and the r a t i o of shock
pressure rise t o throa t k ine t ic pressure u t i l i z i n g e i t h e r of the calcu-
l a t i o n a l models.
t o conventional compressible gas cases, increasing from the order of 10
t o the order of 10 as the void f r a c t i o n increases from the order of
A s noted, the Mach number r a t i o is very large compared
3
t o 10". Even la rger r a t i o s occur as void f r ac t ion approaches
uni ty . However, these may not be meaningful s ince, as previously men-
t ioned, the assumptions made r e s t r i c t the v a l i d i t y of the ca lcu la t ion t o
the r e l a t i v e l y low qual i ty range.
decrease markedly a s void f r ac t ion i s decreased, and become uni ty f o r
zero void f r ac t ion , s ince a condensation shock i s not possible i n t h a t
case.
2 A l s o both M1/M2 and (p2/pv)/,oVt
To obtain e i t h e r actual Mach numbers o r pressure rise, it i s
necessary t o specify the ac tua l th roa t ve loc i ty .
B. Comparison with Experimental Data
1. Axial Pressure P ro f i l e s
Experimental a x i a l pressure p r o f i l e s have been measured (16) f o r
t h e ven tu r i of Fig. 1 f o r water a t 53.5OF, th roa t ve loc i ty of 64.6 f t . /
sec., and f o r the cav i t a t ion terminating a t 0.786" and 1.75", respec-
t i v e l y , from the throa t e x i t . For comparison with the theo re t i ca l
models, a normalized suppression pressure i s formed by subtract ing vapor
pressure and dividing the r e s u l t by the throa t k ine t i c pressure.
26
According t o classical conceptions of c a v i t a t i o n , t h i s number should
always be zero a t t h r o a t discharge.
now w e l l recognized (21, e.g.).
i c a l models are such t h a t t h e normalized suppression pressure must be
zero a t t h i s po in t . For e i t h e r t h e o r e t i c a l model the pressure is then
e s s e n t i a l l y constant t o the end of t h e c a v i t a t i o n region, while i n the
r e a l case it f a l l s t o a minimum downstream of the th roa t e x i t (Figs. 8
and 9 ) .
The f a c t t h a t it normally is not i s
However, t he assumptions of t h e theore t -
Similar pressure p r o f i l e da ta is ava i l ab le f o r mercury (22) a t a
v e l o c i t y of 33.1 f t . / s e c . and 115"F, and f o r t he c a v i t a t i o n terminating
a t 0.786'' from the t h r o a t e x i t . This da ta w a s normalized as previously
described.
shown i n Fig. 10.
The r e s u l t i n g comparison t o the t h e o r e t i c a l p r o f i l e s i s
A t t h e end of the c a v i t a t i o n zone t h e t h e o r e t i c a l models each
p red ic t a s t e p rise i n pressure, which goes through a maximum f o r
increas ing ex ten t of the cav i t a t ion region. It can be shown from
eq. (17) of Appendix C , which app l i e s t o the hydraulic jump model, t h a t
t h i s maximurn occurs f o r a value of v e n t u r i rad ius , r , equal t o (2) 1/2 rt,
where rt i s the v e n t u r i throat rad ius .
show a s t e p r i s e i n pressure a t t he end of t h e c a v i t a t i o n region (which
i s marked i n Figs. 8, 9, and 10 by t h e s t e p r i s e of predicted pressure) ,
but they do show a s u b s t a n t i a l g rad ien t of about t he co r rec t magnitude
t o match the pred ic t ion from the models.
The experimental p r o f i l e s do not
Af t e r the c a v i t a t i o n termination region t h e pressure continues
t o r i s e more gradually f o r both experimental and t h e o r e t i c a l p r o f i l e s as
27
I
i
0 E El -1
a
I 0
3 P 3 a W
8
kf 3 4
0
a a 0 W
-1 3
I
W -1
5 1 E l
a 5
B
I-
E w - W
I
0
+-
I 06z'zch)b 1 - 3tJnSS3tld 03ZIlW'lrVtlON ( 'd-d
I
v) W I 0 z I t- w J z - 5i 0 E I t-
3 t- z W > r 0 E LL w 0 z v)
A
X
E
F a 5 a
o a l ? 0
o u a m
28
expected f o r a s ing le phase d i f fuse r .
mental a x i a l pressure p r o f i l e s match reasonably we l l .
Thus the theo re t i ca l and experi-
2 . Void Frac t ion P r o f i l e s
Local void f r ac t ions for the flow regimes coiisidered here w a s
measured as a funct ion of radius and a x i a l pos i t i on with a gamma-ray
densitometer (13,15).
w a t e r and Fig. 13 f o r mercury. For the water tests the void f r ac t ion i s
g rea t e s t i n regions along the ven tu r i ax i s , contrary t o previous expec-
t a t i o n s from s imi l a r measurements and v i s u a l observations i n mercury as
w e l l a s e a r l i e r p i t o t tube measurements i n w a t e r ( t o be discussed
l a t e r ) .
very high along the ven tu r i wall and small along the ax i s , ind ica t ing
the s u i t a b i l i t y of the hydraulic jump analogy f o r t h i s case .
From p r o f i l e s of t h i s type it i s possible t o compute average
F igs . 11 and 12 show the r e su l t i ng p r o f i l e s f o r
For the mercury t e s t s it w a s found t h a t the void f r a c t i o n w a s
void f r ac t ion as a funct ion of axial dis tance.
f o r water and mercury f o r standard cav i t a t ion in. Fig. 14. This , plus
add i t iona l data f o r f i r s t m a r k cav i t a t ion , i s rep lo t ted i n F igs . 8, 9,
and 10 t o show the comparison with ca lcu la ted values f o r the two flow
models. While the loca l void f r a c t i o n d i s t r i b u t i o n s between water and
mercury d i f f e r widely, it i s noted t h a t the averaged d i s t r i b u t i o n s i n
both cases are considerably l o w e r than the ca lcu la ted models would ind i -
c a t e near the end of the cavi ta t ion termination region. It is noted
t h a t the void f r ac t ion d i s t r ibu t ion i n mercury follows t h a t ca lcu la ted
qu i t e c lose ly almost t o the point of the jump, ind ica t ing t h a t the
Such p r o f i l e s a r e shown
hydrsulic J--r ; r r m n *---*- nnslnui i O J in chis case mnrr -J be quite g c d . 9c'n'cv2r, the
29
30
25
20 s z 0
0 15
a a
5
t 0 5 .IO .20 -25 .30 DISTANCE FROM INCHES
Fig. 11.--Void fraction versus radius for water at several axial locations for standard cavitation.
30
30
25
$ * 20 Q
2 I-
15 D 0 > -
10
5
DISTANCE FROM c-INCHES
Fig. 12.--Void fraction versus radius for water at several ax ia l locations for f i r s t mark cavitation.
31
z
r .3 .2 . I
It- END OF
CAVITATION
1.25
1.00 I I
I I
I .75
I 30
STANDARD FIRST MARK
Fig. 13.--Voia traction profiles for standard and first mark cavitation conditions in mercury.
32
z 0
P)
m U m d a d m d X m
2
: rn k W > C 0 4 U c) m k v(
a d 0 ? d k 3 U C s
: P 2
W bo m k
I
. . b o h 4 k k 3
c) k
8 k 0 w
33
averaged void f r ac t ion near the jump i s qui te a b i t higher i n both
models than the experimental values. This is p a r t i a l l y due t o the f a c t
t h a t these models assume i n one case t h a t the ve loc i ty of the vapor i s
zero and i n the o ther t h a t it is equal t o l iqu id ve loc i ty , whereas i n
a c t u a l i t y there may be s igni f icant "slip" so t h a t the vapor ve loc i ty i s
considerably g rea t e r than tha t of the l iqu id .
the void f r a c t i o n f o r a given qua l i ty would be less, and thus somewhat
nearer t he experimental values.
If t h i s were the case,
3. P i t o t Tube Measurements
Fig. 15 shows micropitot tube ve loc i ty p r o f i l e s f o r water
(21,13) across a ven tu r i s imilar t o tha t used i n these t e s t s .
tube is located upstream of the cav i t a t ion termination point f o r two of
t h e c a v i t a t i o n condi t ions shown (except "no cavi ta t ion" and f i r s t mark),
a t a point about 2 3/8" downstream from the th roa t e x i t .
t h a t i n t h i s case a well-defined c e n t r a l l iqu id j e t ex is ted with a
ve loc i ty of 90 t o 95% of throat ve loc i ty .
t h e order of 90% t h a t corresponding t o throa t ve loc i ty ind ica tes t h a t
t he f l u i d densi ty must have been close t o t h a t of pure l iqu id .
The p i t o t
It i s c l e a r
That the impact pressure was
34
r s a s " aaaa0 00602 o a x o
0 0 0 0 0 0 0 0 rc)
0 0 0 u2 Ir! * n
1 0 - 0
AI
'NI '33NWlS10 l V l 0 W t l
V . CONCLUS IONS
Major conclusions from t h i s work follow:
1) E i the r the homogeneous flow, thermal equilibrium model o r
the hydraulic jump model are capable of pred ic t ing axial pressure d is -
t r i b u t i o n i n a cav i t a t ing ventur i qu i t e c lose ly , even including the
behavior of the condensation shock marking the downstream termination of
the cav i t a t ion zone. This has been v e r i f i e d i n water and mercury.
2) Both models predict void f r ac t ions i n both f l u i d s , averaged
over the cross-sect ion a t f ixed a x i a l pos i t ions , t h a t are considerably
higher than those measured by gamma-ray densitometry. This may be due
t o the f a c t t h a t ne i ther model allows a vapor ve loc i ty g rea t e r than the
l i qu id ve loc i ty , whereas i n a c t u a l i t y such a pos i t ive " s l i p " probably
does e x i s t .
35
VI. APPENDIX
A . Sonic Velocity in Low Quality Two Phase Mixtures
The sonic velocities were computed following the methods of
Jakobsen (3. The operative equations are as follows:
where, v u v B = Y = 2 Void Fraction (= V.F.)
V;otal vL 2 P L ~ L = (Vg/Vf) 2 R a’ r - ‘ v v
a V = (gokRT)1/2 = 59.9(T)ll2 for water ( 4 )
Equation (1) is derived in reference 4 starting with the basic
relation :
and assuming constant temperature with no evaporation or condensation
during the sonic disturbance. The first assumption tends to give higher
sonic velocities than the alternative assumption of thermal equilibrium:
36
37
while the second assumption tends i n the opposite d i r ec t ion , but prob-
ab ly t o a lesser ex ten t .
B. Condensation Shock Wave Analysis (Assuming x = 0 a f t e r shock and p = pv before shock)
1. Basic Conservation Relations - - - 1-1 = v /v v1 I Vf (1-x)+v x 2 f
A g Mass :
b
2 ho = h x + hl (1-X) + V1/2goJ
Ig f Energy :
n L -
- h2f + v2/2goJ
2. Assumptions and Rearrangement t o Working Form
m
x = m v / 5 = m v / y , for low qua l i ty (x <.01)
z For the cav i t a t ion problem, fi<1, so 1-x = 1
then (6) becomes :
V,/(v +v B) = V2/vf = V 1 f /v (Bt-1) f f
o r
Vl/V2 = B + 1
38
Introduce Mach number:
M1 = Vl /a l , V1 = M a , e t c . 1 1
then (10) becomes :
Subs t it u t ing
And momentum
o r
And from (1)
equation (7) becomes :
2 2 P f P 1 = P2’Pv = (MIMplaL - M2aL)/goVf
a = aL(l+B) / (l+Bvf/vg) (1+Br) = aL (l+B)/
(MI /M2) ( 14) 1
C . Hydraulic Jump Model (Assuming space around j e t t o be f i l l e d with stagnant vapor and j e t s t a t i c pressure = pv)
Momentum:
BIBLIOGRAPHY
I -
b
1. Hunsaker, J . C . , "Cavitation Research, A Progress Report on Work a t t he Massachusetts I n s t i t u t e of Technology," Mechanical Engineering, Apr i l , 1935, pp. 211-216.
2. Randall, L. N., "Rocket Applications of the Cavi ta t ing Venturi," ARS Journal , January-February, 1952, pp. 28-31.
3. Nowotny, H., "Destruction of Mater ia ls by Cavitation," VDI-Verlag, Berl in , Germany, 84, 1942. Reprinted by Edwards Brothers, Inc. , Ann Arbor, Michigan, 1946. English language t r a n s l a t i o n a s ORA I n t e r n a l Report No. 03424-15-1, Department of Nuclear Engineering, The University of Michigan, 1962.
4 . Jakobsen, J . K. , "On the Mechanism of Head Breakdown i n Cavi ta t ing Inducers," Trans. ASME, J. Basic Eng., June 1964, pp. 291-305.
5. Spraker, W . A . , "Two-Phase Compressibil i ty E f fec t s on Pump Cavita- t ion," Cavi ta t ion i n Fluid Machinery, ASME, 1965, pp. 162-171.
6 . Muir, J . F., and Eichorn, R. , "Compressible Flow of an Air-Water Mixture Through a Ver t ica l Two-Dirnensional Converging-Diverging Nozzle," Proc. 1963 Heat Transfer and Flu id Mechanics I n s t i t u t e , pp. 183-204.
7 . Starkman, E . S., Schrock, V . E . , Meusen, K. F. , Maneely, D . J . , "Expansion of a Very Low-Quality Txo-Phcse Fluid Through a Con- vergent-Divergent Nozzle," J. Basic Eng., Trans. ASME, June, 1964, pp. 247-264.
8. Eddington, R. B . , " Invest igat ions of Shock Phenomena i n a Super- sonic Two-Phase Tunnel," AIAA Peper No. 66-87, 3rd Aerospace Sciences Meeting, New York, Jsnuary, 1966.
9. Levy, S., "Prediction of Two-Phase C r i t i c a l Flow Rate," ASME Paper 64-HT-8, J . Heat Transfer , Trans. ASME, May, 1960, p. 113.
10. Moody, F. J . , "Paximum Flow Rate of a Single Component, Two-Phase Mixture," ASME Paper 64-€E-35, ASHE Trans., J . Heat Transfer.
39
40
11. Min, T. C . , Fauske, H. K., Pe t r i ck , M., "Effect of Flow Passages on Two-Phase Cr i t ica l Flow," I&EC Fundamentals, Vol. 5, No. 1, Febru- a ry , 1966, pp. 50-55.
12 . Deich, M. E . , Stepanchuk, V. F., Saltanov, G. A., "Calculating Com- pression Shocks i n the Wet Steam Region," Teploenergetika, 1965, 12 (4) : pp. 81-84.
13. Smith, W., Atkinson, G. L., H a m m i t t , F. G., "Void Frac t ion Measure- ments i n a Cavi ta t ing Venturi," Trans. ASME, J. Basic Eng., June, 1964, pp. 265-274.
14. H a m m i t t , F. G . , Smith, W., Lauchlan, I., Ivany, R., and Robinson, M. J . , "Void Fract ion Measurements i n Cavi ta t ing Mercury," E Trans., Vol. 7 , No. 1, pp. 189-190; a l s o Nuclear Applications, February, 1965, pp. 62-68.
15. Lauchlan, I. E. B., "Void Frac t ion Measurements i n Water," Term Paper, NE-690, Nuclear Engineering Department, The University of Michigan, Ann Arbor, Michigan, August , 1963.
16. Ericson, D. M. , Jr. , Capt. USAF, unpublished data, Thesis underway, Nuclear Engineering Department, The University of Michigan, 1964.
17. H a m m i t t , F. G., "Cavitation Damage and Performance Research F a c i l i t i e s ,I1 Symposium on Cavitat ion Research F a c i l i t i e s and Techniques, pp. 175-184, ASME Flu ids Engineering Division, May, 1964.
18. H a m m i t t , F. G., Wakamo, C . L., Chu, P. T . , Cramer, V. L . , "Fluid- Dynamic Performance of a Cavi ta t ing Venturi," ORA Technical Report No. 03424-2-T, Nuclear Engineering Department, The University of Michigan, October, 1960.
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