GR-83-6
GRISWOLD FLOW CONTROL VALVE---HYDRAULIC TESTS
September 1983 Engineering and Research Center
U.S. Department of the Interior Bureau of Reclamation
Division of Research Hydraulics Branch
7-2090 (4-81) Bureau of R e e l a m a t i e n
,. REPORT NO ~ ~ , ; ~ * $ ~ ~ ~
G R - 8 3 - 6 . . . . , .... i ~ ~ ~ : ~ ~ • . . . . , ~ ~ ~ ~ l = ~ , , , . ~ = . ~ ~ , 4. T I T L E AND SUBTITLE
Griswold Flow Control Valve - - Hydraulic Tests
7. AUTHOR(S)
K. Warren Frizell
9. P E R F O R M I N G O R G A N , Z A T , O N NAME AND ADDRESS
Bureau of Reclamation Engineering and Research Center Denver, Colorado 80225
12. SPONSORING AGENCY NAME AND ADDRESS
Same
TECHNICAL REPORT STANDARD TITLE PAGE 3. RECIPIENT'S CATALOG NO.
5. REPORT DATE
September 1983 6. PERFORMING ORGANIZATION CODE
8. PERFORMING ORGANIZATION REPORT NO.
G R - 8 3 . 6
10. WORK UNIT NO.
t l . CONTRACT OR GRANT NO.
13. TYPE OF REPORT AND PERIOD COVERED
14. SPONSORING AGENCY CODE
15. SUPPLEMENTARY NOTES
Microfiche or hard copy available at the E&R Center, Denver, Colo. Ed:RNW
16. ABSTRACT
Four different Griswold flow control valves were tested and evaluated; they are anticipated for use on a pressurized sprinkler irrigation system. Tests were performed on each valve to observe discharge characteristics. Discharge accuracy was compared to the manufacturer's specifications. Debris conveyance was observed in two valves. Several kinds of debris were used and observed during the testing. Manufacturer's recommendat ions for screening debris were evaluated.
17. KEY WORDS AND DOCUMENT ANALYSIS
O. DESCRIPTORS"/flow control* / laboratory t e s t s / f l o w control va lves / spr ink ler irrigation/debris/hydraulics/pressure head/
b. IDENTIF IERS- - / f low control v a l v e / Y a k i m a Project, Washington/
c. COSATI F ie ld~Group 1 3 COWRR: 1 3 1 1 SRIM:
18. DISTRIBUTION STATEMENT 19 . SECURITY CLASS 121. NO. OF PAGE~ I (THIS REPORT)
! UNCLASSIF IED . 2 4 r20- SECURITY CLASS 2. PRICE
[ UNCLASSIF IED
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GR-83-6
GRISWOLD FLOW CONTROL VALVE -- HYDRAULIC TESTS
L .
by K. W a r r e n F r i z e l l
Hydraulics Branch Division of Research
Engineering and Research Center Denver, Colorado
S e p t e m b e r 1 9 8 3
UNITED STATES DEPARTMENT OF THE INTERIOR * BUREAU OF RECLAMATION
ACKNOWLEDGMENTS
This study was conducted with the cooperation of J im Warden, Head, Pipelines Section, Water Conveyance Branch, Division of Design (E&R Center), and the Pacific Northwest Regional Office in Boise, Idaho. Jerry Fitzwater, Civil Engineering Technician, assisted greatly in the test runs. The valves tested were on loan from Griswold Controls, 2803 Barranca Road, Irvine, California 92714.
The research covered by this report was funded mostly by the Bureau of Reclamation Pacific North- west Region office. Additional funds were furnished by the Bureau's Open and Closed Conduit Systems program.
Permission to reprint any of this material is granted provided appropriate credit is given to the Bureau of Reclamation, U.S. Department of the Interior.
The information contained in this report regarding commercial prod- ucts or firms may not be used for advertising or promotional purposes and is not to be construed as an endorsement of any product or f i rm by the Bureau of Reclamation.
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CONTENTS Page
Purpose ................................................... . . . . . . . . . . 1
I n t r o d u c t i o n ......................................................... 1
Sum m ary ........................................................... 2
Test facility ......................................................... 4
Test ing ............................................................. 5 Discharge accuracy ................................................. 5
Debris tests ........................................................ 6
TABLES
Table
1 Discharge test results, ll/z-inch t h r e a d e d minivalve, 24-gal/min design discharge . ..................................... 8
2 Discharge test results, 3-inch t h r e a d e d cluster valve, 100-gal/min design discharge . . ~ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
3 Discharge test results, 3-inch t h r e a d e d cluster valve, 245-gal/min design discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
4 Discharge test results, 3oinch t h r e a d e d cluster valve, 345-gal/min design discharge .................................... 9
5 Discharge test results, 3-inch t h r e a d e d inl ine valve, 100-gal/min design discharge .................................... 10
6 Discharge test results, 10-inch f langed cluster valve, 1,000-gal/min design discharge .................................. 10
7 Debris test results, 3-inch t h r eaded cluster valve, 100-gal/min design discharge .................................... 11
8 Debris test results, 3-inch t h r e a d e d inl ine valve, 100-gal/min design discharge .................................... 12
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C O N T E N T S - - C o n t i n u e d
F I G U R E S
F i g u r e Page
i G r i s w o l d t h r e a d e d i n l i n e f low c o n t r o l valve . . . . . . . . . . . . . . . . . . . . . . . . 12 2 O n e a n d o n e - h a l f - i n c h t h r e a d e d m i n i v a l v e ( f low c o n t r o l ) . . . . . . . . . . . . 13 3 T h r e e - i n c h t h r e a d e d c lu s t e r f low c o n t r o l valve . . . . . . . . . . . . . . . . . . . . . . 13 4 T h r e e - i n c h t h r e a d e d i n l i n e f low c o n t r o l valve . . . . . . . . . . . . . . . . . . . . . . 14 5 T e n - i n c h f l a n g e d c lu s t e r f low c o n t r o l valve . . . ~ . . . . . . . . . . . , . . . . . . . . . 15 6 F l o w c o n t r o l tes t fac i l i ty l a y o u t ................................... 16 7 D e b r i s i n j e c t i o n s t a t i o n .......................................... 17 8 D i s cha rge t es t r e su l t s of G r i s w o l d ll/2-inch t h r e a d e d m i n i v a l v e
- - des ign d i s c h a r g e 24 g a l / m i n .................................. 18 9 D i s cha rge tes t r e su l t s of G r i s w o l d 3- inch t h r e a d e d c lu s t e r valve
- - des ign d i s c h a r g e 100 g a l / m i n ................................. 18 10 D i s cha rge tes t r e su l t s of G r i s w o l d 3- inch t h r e a d e d c lu s t e r valve
- - des ign d i s c h a r g e 245 g a l / m i n . . . . . . . . . , . . . . . . . . . . . . . . . . . . . . . . . 19 11 D i s cha rge t es t r e su l t s of G r i s w o l d 3- inch t h r e a d e d c lu s t e r valve
- - de s ign d i s c h a r g e 345 g a l / m i n . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 12 D i s c h a r g e t e s t r e su l t s of G r i s w o l d 3- inch t h r e a d e d i n l i n e valve
- - des ign d i s c h a r g e 100 g a l / m i n ................................. 20 13 D i s c h a r g e t e s t r e su l t s of G r i s w o l d 10-inch f l a n g e d c lu s t e r valve
- - d e s i g n d i s c h a r g e 1,000 g a l / m i n ............................... 2 0 14 D e b r i s tes t r e su l t s o f G r i s w o l d 3- inch t h r e a d e d c lu s t e r valve
- - des ign d i s c h a r g e 100 g a l / m i n . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 15 F l o w Car t r idges , a f t e r U.S.A. s t a n d a r d Nos. 6 a n d 10 sieve
s c r e e n e d s a n d r u n s in 3- inch t h r e a d e d c lu s t e r valve - - d e s i g n d i s c h a r g e 100 g a l / m i n . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
16 F l o w c a r t r i d g e s a f t e r p i n e n e e d l e s a n d a q u a t i c w e e d r u n s in 3- inch t h r e a d e d c lu s t e r valve, de s ign d i s cha rge 100 g a l / m i n . . . . . . . . . . . . . . 23
17 D e b r i s tes t r e su l t s , 3- inch t h r e a d e d i n l i n e valve, de s ign d i s c h a r g e 100 g a l / m i n .................................................... 24
18 D e b r i s tes t r e su l t s , c o m p a r i s o n of 3- inch t h r e a d e d c lu s t e r valve a n d 3- inch t h r e a d e d i n l i n e valve - - s a m e d e b r i s t ypes . . . . . . . . . . . . . 24
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PURPOSE
At the request of the Bureau's Pacific Northwest Regional Office, tests were conducted
to evaluate the opera t ional characteristics and maintenance requi rements of several
Griswold flow control valves. The valves were proposed for the Yakima Project,
T ie ton Division in the Yakima-Tieton I r r igat ion District in Washington State. Tests
were performed to verify the manufacturer 's specifications of performance and
suitabili ty for a pressurized sprinkler irrigation application.
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INTRODUCTION
Flow control valves have been used on spr inkler i rr igat ion systems for many years.
However, their performance has not consistently satisfied the needs of both the user
a n d system operator. Griswold flow control valves - - Griswold Controls of Irvine,
California - - were tested to de termine the capabil i ty for delivering a constant flow
rate •within a +5 percent band over a design pressurecont ro l range.
The valves operate on the pr inciple of orifice control. They respond to pressure
different ial by using a calibrated spring that adjusts the orifice area exposed to the
flow which keeps the flow constant. Basic valve components are shown on figure 1.
These valves are available in four different ial pressure ranges (1.3 to 20, 2 to 32, 4 to 57,
and 8 to 128 l b / i n 2) and have flow rates ranging from 0.5 to 12,750 gal /min. Four valve
models were tested:
In the 8-* to 128-1b/in 2 range, two flow control valves were tested:
a 1 ½-inch threaded minivalve model (fig. 2) rated at 24 gal /min, and
a 3-inch threaded cluster model (fig. 3) with three flow cartridges:
m a 95 gal /min,
- - a 100 gal /min,
a 150 gal /min, and
having discharge ratings of: 100, 245, and 345 gal /min. i
In the 4- tO 57-1b/in z range, two flow control valves were tested:
a 3-inch threaded inl ine model (fig. 4) rated at 100 gal /min, and
a lO-inch flanged cluster model (fig. 5) with ten lO0-gal/min flow cartridges J
delivering a total flow of 1,000 gal/min.
In addi t ion to these discharge tests, the 3-inch threaded cluster valve and the 3-inch
threaded inl ine valve were tes t ed to obtain operat ional characteristics and to check
maintenance rqu i rements under different debris loads at a flow rate of 100 ga l /min at
50-1b/in z pressure d i f ferent ia l .
SUMMARY
1. Discharge tests on the 1]/2-inch threaded minivalve compared with the manu-
facturer 's specifications of a constant flow (+5 percent) over the 8- to 128-1b/in 2
dif ferent ia l pressure control range. The only major depar ture from acceptable values
were data below the +5.percent band by an addi t ional 28 percent at the low end of the
different ial pressure range (10 to 15 lb/in2).
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2. Discharge tests on the 3-inch threaded cluster valve showed varying degrees of
comparison with tha t of the manufac turer - - depending on the flow cartridges used.
Flow cartridge combinat ions of 100 and 245 ga l /min compared well at the lower back
pressures appl ied to the valve. However, at 50- and 75-1b/in z back, pressures, most data
points fell above the +5-pe rcen t band. The 345-gal/min combina t ion was mostly
above the manufacturer ' s -4-5 percent band at all back pressures tested. An addit ive
error effect in the discharge was noticed when each addi t ional flow cartridge was
inserted in the valve to obtain a higher flow rate.
3. Discharge tests on the 3-inch threaded inl ine valve compared fairly well with the
manufacturer 's specified flow accuracy. About one-half the data points fell above the
+5-percent band at all back pressures tested for the upper half of the pressure control
range. ,,
4. Discharge tests results on the 10-inch flanged cluster valve indicate excellent
comparison with the manufacturer ' s flow accuracy. All data points fell wi thin the
+5-percent band throughout the pressure control range.
5. Debris tests performed on the 3-inch threaded cluster valve and the 3-inch threaded
inl ine valve aff irm the manufacturer ' s debris recommendations. Using a U.S.A.
s tandard sieve No. 20 ups t ream of the valve appears adequate for most debris loads.
One should consider smaller sieve sizes for an irr igat ion project location subject to
heavy silt or sand loads. The study showed the No. 20 sieve screened sand indicated a
discharge reduct ion of 15 percent. Sand particles also fouled and h indered movement
of the spring-controlled piston; consequently, the piston requi red cleaning to obtain
design discharge. P ine needles and aquatic weeds plugged orifice areas and flow rates
reduced as much as 70 percent. Test data from comparing the two 3-inch valve models
subjected to similar debris loads showed no significant differences. Maintenance was
not a problem on the 3-inch threaded cluster valve assembly; fouled or damaged flow
cartridges could easily be removed and cleaned or replaced.
3
TEST FACILITY
Testing was done at the Bureau of Reclamation's Hydraulic Laboratory in Denver,
Colorado. A high-head pump was used. Each of the four valves was placed in series
with the pump (fig. 6). Pressure measurements upstream and downstream of the test
valve were made with pressure" transducers as indicated on figure 6. Transducer
o u t p u t s were recorded on a chart recorder. The me thod for recording discharge
through the flow control valves depended on the flow rate magnitude.
• Low flow rates (24 and 100 gal/min) were measured with a weighing tank.
• • Midrange flows (245 and 345 gal/min) were measured with a calibrated orifice
meter.
• The high flow rate (1,000 gal /min) was measured using a calibrated 8-inch ventur i
meter.
Upstream and downstream pressures could be adjusted by throt t l ing gate valves on
ei ther side of the test valve.
Debris testing was done on the same piping arrangements as the discharge tests. A
standard 6-inch tee was modif ied to hold a 200- to 400-mL debris sample which was
injected into the flow (fig. 7) after a steady-state condit ion was achieved.
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TESTING
Discharge Accuracy
1. T h e 1½-inch threaded minivalve was in the 8- to 128-1b/in 2 differential pressure
range and had a 24-gal/min flow cartridge. Tests were run at five back pressures
ranging from 0 to 75 lb / in 2 through the entire differential pressure range. Test results
are in'table 1 and on figure 8. Approximately two-thirds of the data points fell within
the band (-t-5 percent of design discharge) set by the manufacturer. The only major
discrepancy was in the lower end of the differential control range (10 to 15 lb/in2). In
this range, data were below the acceptable operating range where some points were
33 percent below design discharge.
2. The 3-inch threaded cluster valve was in the 8- to 128-1b/in 2 differential pressure
control range and had three flow cartridges that were tested at three design
:discharges; i.e., 100,245, and 345 gal/min. These test results are intables 2, 3, and 4 and
on figures 9, 10, and 11, respectively.
• One 100-gal/min flow cartridge and two blanks were used during the 100-gal/min
test. One-third of the data points fell above the +5-percent bancl. These points
occurred at back pressures of 50 and 75 lb / in 2 above 60-1b/in 2 pressure
differentials.
The 245-gal/min tests had two flow cartridges and one blank. Again, one-third of
the data points were above the +5-percent band. These points occurred at the
50-and 75-1b/in 2 back pressures but within the range of 25- to ll0-1b/in 2 pressure
differentials.
The 345-gal/min test had all three flow cartridges in place. About two-thirds of
the data points fell above the +5-percent band. These occurred in the 30- to
110-1b/in 2 pressure differential range at back pressures of 40, 50, and 75 lb / in 2.
5
3. The 3-inch threaded inl ine valve was in the 4- to 57-1b/in 2 differential pressure
control range and had a 100-gal/min design discharge. Test results are in table 5 and on
figure 12. One-half of the data points fell above the +5-percent band. Data indicate
flow th ro ugh the valve at a rate greater than design discharge at all back pressures
applied (12 to 60 lb / in 2) through differential pressures ranging from 20 to 57 lb / in 2.
4. The 10-inch flanged cluster valve was in the 4- to 57-1b/in 2 differential pressure
control range and was set at 1,000 gal/min. The valve contained ten 100-gal/min flow
cartridges and one blank. Test results are in table 6 and on figure 13. All data points
fell within the +5-percent band.
Debris Tests
Because of the operating concept of the Griswold f lo~ control valve (adjustable orifice
area), debris is a serious concern. The manufacture~ recommends screening water to i
the valve with at least a U.S.A. s tandard sieve No. 20. Debris tests were run to verify the
No. 20 sieve and to observe how the valve functions when larger debris enters it.
Debris tests were done on the 3-inch threaded cluster and the 3-inch threaded inl ine
valves at a steady state of 100-1b/in 2 pressure upstream of the valve and 50 lb / in 2
downstream of the valve. A 100-gal/min flow cartridge was in place in each valve. In
the cluster valve, the 100-gal/min flow cartridge Waspositioned below and slightly off
center of the incoming supply line. A debris sample of 250 to 400 mL was placed in the
injection chamber and, when steady-state operat ing condit ions were obta ined it was
injected into the flow. After injection, pressure and discharge were moni tored over a
durat ion of 20 to 30 minutes.
Several types of debris samples were used in the testing. Sand was tested for several
sieve sizes; i.e., U.S.A. standard sieve Nos. 6, 10, 14, and 20 (0.141-, 0.065-, 0.0331-, and
0.0168-inch openings), respectively. Dry pine needles in about 1-inch lengths were
tested and some debris collected from traveling water screens in the project area. The
latter debris consisted mostly of moss and Other aquatic weeds.
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All sand sizes were tested through the 3-inch threaded cluster valve; results are in
table 7 and on figure 14. Clogging of the orifice areas is evident as shown on figure 15.
However, clogging did not seem to be the major problem. When the flow cartridge was
cleaned and replaced in between test runs, about 15-percent decline in maximum
discharge was noted. This temporary loss in flow rate was due to fouling of the
spring-loaded piston. Apparently, small sand particles lodged between the movable
p i s t on and the valve body and restricted piston movement. After more thorough
cleaning, the valve operated at design discharge (before debris injection).
In addi t ion to the sand sizes tested, dry pine needles and field collected debris were
tested in the 3-inch threaded cluster valve. Results are in table 7 and on figure 14.
Major port ions of the orifice areas were plugged by those two debris (fig. 16). I t is
noted this material was unscreened and tested strictly to observe operation.
Several tests were run on the 3-inch threaded inl ine valve. Sand passing through a
No. 20 sieve, dry pine needles, and field-collected debris were each tested in this valve.
Results are in table 8 and on figure 17. Nearly identical results were found for the two
3-inch valves tested. Flow rate reduct ion was slightly less th rough the 3-inch threaded
cluster valve (versus the 3-inch threaded inl ine valve), probably due to the increased
turbulence near the flow cartridge caused by the larger chamber area (fig. 18).
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T a b l e 1 . - Discharge test results, l ~.inch threaded minivalve, 24.gal/min design discharge
P r e s s u r e Discharge Back
di f ferent ia l pressure l b / i n 2 ga l /min lb / in 2
4 10
25 50
73 98
123
150
6
10 16
50 75
100
123 141
5 13
24 51
73 100 125 151
4
9 28
75 100
123
6 11
28 49
73 99
4.2 0 to 2 18.9 2"3.5 23.1
21.9 "
21.5 22.1 "
25.7
16.5 21.8 24.4
24.1
23.4 23.6 25.5
26.0
4.1 21.8
24.5 23.8 22.3 21.3 24.8
26.6
3.6 16.0 24.7
22.1 23.5
24.8
13.6
19.7 25.2 23.4
22.8 25.3
9 to 12
22 to 27
47 to 52
72 to 76
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T a b l e 2. - - D i s c h a r g e test results, 3.inch threaded cluster valve, l O0.gal/min design discharge
Pressure Discharge Back
di f ferent ia l pressure l b / i n 2 ga l /min l b / i n 2
5 83.1 2 to 5 10 98.1 " 25 1 0 1 . 9 " 50 100.9 "
75 102.4 "
100 101.9 " 125 101.9 "
150 110.1 "
6 81.3 19 to 26 10 93.4 " 25 103.3 " 50 102.7 "
75 104.3 " 100 104.3 "
124 102.4 " 164 116.3 "
5 72.2 49 to 50 11 98.1 "
25 103.6 " 48 104.0 "
76 107.5 " 101 105.8 " 125 106.0 " 150 114.9 "
6 83.1 74 to 76
10 98.7 25 103.9 "
51 103.3 "
74 107.8 " 125 107.2 ~ "
150 116.2 "
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T a b l e 3. Discharge test results, 3-inch threaded cluster valve, 245ogal/min design discharge
P r e s s u r e D i s c h a r g e • B a c k
d i f f e r e n t i a l p r e s s u r e
l b / i n 2 g a l / m i n l b / i n 2
10 232.5 10 t o 12
25 249.9 "
52 243.7 "
66 236.5 "
75 237.8 "
95 2 3 4 . 4 "
127 236.5 "
10 230.2
24 241.8
50 248.5
72 243.4
101 239.8
126 239.8
24 t o 26
10 2 3 6 . 2 49 t o 51
24 256.2 "
53 261.7 "
74 259.9 "
105 255.1 "
130 252.3 "
237.1
258.8
259.9
263.3
261.1
253.8
10
24
50
77
101
125
74 t o 75
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T a b l e 4 . - Discharge test results, 3.inch threaded cluster valve, 345.gal/min design discharge
P r e s s u r e D i s c h a r g e B a c k
d i f f e r e n t i a l p r e s s u r e
l b / i n 2 g a l / m i n l b / i n ~
4 234.8 15 t o 17
5 275.2 "
8 298.2 "
10 309.1 "
12 332.8 "
25 349.8 "
27 364.7 "
28 361.1 "
20 357.1 35 t o 42
29 362.5 "
50 362.5 "
75 368.6 "
100 365.6 "
120 355.8 "
153 368.9 "
7 257.6 49 t o 51
9 305.1 "
25 360.7 " "
51 369.5 "
75 374.3 ~ "
101 270.4 "
1 2 4 360.3 "
150 379.8 "
5 263.7 75 t o 76
9 305.6 "
10 332.4 "
24 367.6 "
50 369.3 "
76 377.7 "
99 377.3 "
124 366.5 "
150 389.9 "
T a b l e 5. - - D i s c h a r g e test results, 3-inch threaded inline valve, l O0-gal/min design discharge
P r e s s u r e Discha rge B a c k
d i f f e r en t i a l p r e s s u r e
l b / i n 2 • g a l / m i n l b / i n 2
10 103.1 12 t o 16
20 104.6 "
3 0 105.9 ' "
41 102.5 "
52 108.9 "
60 115.5 "
70 120.4 "
1 97.0 18 t o 23
2 6 100.6 "
12 102.1 "
20 104.0 "
27 104.0 "
40 104.0 "
48 105.9 "
60 114.9 "
70 118.5 "
0 100.2 30 t o 32
6 104.6 "
10 105.9 "
21 107.4 "
31 107.1 "
38 106.8 "
50 110.0 "
60 116.9 "
70 124.6 "
0 96.0 60 t o 42
5 100.9 "
10 101.2 "
19 106.2 "
31 108.3 "
39 107.1 "
50 113.5 "
60 119.8 "
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T a b l e 6. - - D i s c h a r g e test results, lO.inch flanged cluster valve,
1,000-gal/min design discharge
P r e s s u r e Di scha rge B a c k
d i f f e r e n t i a l p r e s s u r e
l b / i n 2 g a l / m i n l b / i n 2
4 1 0 0 0 . 9 9 t o 12
10 1036.8 "
20 1036.8 "
30 1027.8 "
4 0 1018.9 "
51 978.5 "
60 1036.8 "
68 1104.1 "
5 996.4 18 t o 22
8 1023.3 "
20 1041.3 "
30 1032.3 "
40 1032.3 "
52 996.4 "
6 0 1059~2 "
69 1131.1 "
1 987.4 29 t o 32
5 1000.9 "
9 1023 .3 "
19 1036.8 "
30 1032.3 "
4O 1032.3 "
51 1005.4 "
58 1050.3 "
69 1144.5 "
0 942.6 38 t o 41
6 1018.9 "
10 1032.3 "
20 1041.3 "
30 1036.8 "
40 1036.8 "
52 1009.9 "
59 1068.2 "
70 1144.5 "
I I i I I I I i I I I I i I I I I I I
I I I I I I I I I I I I
Tab le 6 . , - -Discha rge test results, l O-inch flanged cluster: valve,
1,000.gal/min design discharge C o n t i n u e d
Pressure Discharge Back di f ferent ia l pressure
lb/ in 2 gal/min lb/ in 2
1 978.5 49 to 52 3 996.4 "
10 1027.8 " 20 1032.3 " 29 1032.3 " 39 1032.3 " 50 1005.4 " 60 1081.7 " 70 1166.9 "
0 978.5 60 t o 6 2 3 991.9 " 9 1018.9 "
19 1032.3 " 2 9 1032.3 " 40 1036.8 " 52 1018.9 "
Tab le 7. - - Debris test results, 3-inch threaded cluster valve, l O0-gal/min design discharge
U.S.A. s t anda rd sieve No.
Debr is type
6 sc reened sand
Discharge, g a l / m i n
P r e i n j e c t i o n In j ec t i on Pos t in j ec t ion
107.1 89.0
I I I
10 sc reened sand 1 90.5 i0 sc reened sand 2 104.3 14 sc reened sand 3 91.6 20 sc reened sand 102.0
1-inch d r i ed p ine need les ~ 108.9
F ie ld col lected aqua t ic weed and fish eggs 106.6
63.4 67.2 at 30 m i n 77.3 69.5 at 41 m i n 77.7 73.0 at 44 m i n 88.8 88.8 at 49 ra in
38.9 45.4 at 30 ra in
71.9 76.7 at 15 m i n
IReduced preinjection discharge because of piston fouling. 2Normal preinjection discharge- rigorous cleaning between runs. 3Reduced preinjection discharge because of piston fouling.
11
Table 8. - -Debris test results, 3-inch threaded inline valve, l O0.gal/min design dischat'ge
Debris type Discharge, gal/min
Preinjection Injection Postinjection
U.S.A. standard No. 20 sieve sand 99,6 1-inch dried pine needles 107.7 Field-collected aquatic weeds
and fish eggs 108.2 Field-collected aquatic weeds 105.8
96.7 91.5 at 20 min 25.38 31.1 at 20 min
71.6 72.7 at 25 min 70.2 68.2 at 20 min
FOrifice s fCon'l'rol s p r i n ~ S t " o n d o r d couplings
I-... ............. ~ ..L.......,.,.~,<.<.s,/,tJ~ ~,,,,//~.~_~o. ........ '<"t'2n°i'°i , . ' ( p i ) ~ l l , , ' i ~ ' 7 ~ ~ i J ' P ; l l l l l l l ) " . "-Movable p i s ' t O ~ ' N P T on valve body
GRISWOLD THREADED INLINE VALVE
Figure 1.--Griswold threaded inline flow control valvel
12
pipe,
I I I I I l I I I I I I I I. I I I I I
I I I I I I I I I I I I I I I I I I I
Figure 2.--One and one-half-inch threaded minivalve (flow control).
" r ~ ' a ~ i . 0 W"
. r
Figure 3.--Three-inch threaded cluster flow control valve.
13
Figure 4.--Three-inch threaded inline flow control valve.
14
i I i i I i i I I | |
I I l i I I I I
I I I I I I I I I I I I I I I I I I I
f !
/
/
/
r
Figure 5.--Ten-inch flanged cluster flow control valve.
]5
Downstream
6in go~e volve
15 Dio L ~ ~ I0 DJO
Griswold valve ~" "
~Upst reom " ~ pressure tron~
I 6 in pipe j~
PIPING ARRANGEMENT FOR IO IN FLANGED CUJSTER VALVE
Downstream /UpsiTeQm pressure ~-onsducer.~ 20Oio 2ODia ~ pressure tronsduce~
~ 3 in gate valve "J J- L
G swold valve ~]] Flow 3 in pipe / ~6 in- 3 in reducer Orifice met
w/flo~e t~ps j PIPING ARRANGEMENT FOR 3 IN INLINE AND 3 IN CLUSTER VALVES
O~ 0ownstreom I h 1 ¢ ~
I c~,//~-~lz in gate valve pressure t r a n s d u c e r . ~ , ~ _ ~ . ~ . 20D~ 20l~o - ~ - r e transducer
~ J - ~ i g h ~rank for Griswold valve ~' " ~ w 1½ in pipe "~- ~ - I - ~ in reducer flow measurement
PIPING ARRANGEMENT FOR I zJ- IN THREADED MINI-VALVE NOTE: Eoch of the three piping orrongements was placed in this
location for valve testing.
MAIN CItAN Nil.
' m~.-8in pipe with flow straightener
J~-2000 gallmin, 400 ~r heod, Flo-~" venturi motet 7 stoge pump
* See note [ ~ D C r i s injection statio~
~ 6 in gate valve
I I 6 in pipe - ~
PLAN
Steel t o i l b ~
fEnergy dissipator
I
Y~x']88 in motor operoted volve
Figure 6 . - -Flow control test facility layout.
1 i 1 i 1 1 1 i i 1 1 1 1 1 1 i l ~ 1
I I I I I I I , I I I I I I I I I I I I
\ i
To inject
hose w i t h clomp
Debr is f i l l e r
½-in. s teel r o d - - f _ _ _ 4- in pipe open ended
f
Debr is injection chomber
F" 2-~"
/ I
f Cover p l o t e w i t h
9osket m o f e r i o l seot
Stondord 6- in tee
. . . . . . . . . . . . i i i f r r
Figure 7.--Debris injection station.
17
FLOW
3~L~
25. E
~I. It
E \
15. | t W
<
U 0) 1¢L~ r,
PRESSURE CONTROL RANGE (O to 128' Ib/In*In) ,i
I
/ ! ' I
21-2 l b / t ~ * t n BACKPRESSURE 9-12 l b / t n * i n BACKPRESSURE 22-27 l b / t n o i n BACKPRESSURE
• ~ - . - - -~ - - -~ 47-52 l b / l n * l n BACKPRESSURE 72-76 l b / t n * l n B/~KPRESS~JRE
i J i i i i i i i i i i i i i
PRESSURE DIFFERENTIAL. ACROSS VALVE (It:~/i~*ie~)
Figure 8.--Discharge test results of Griswold i~-inch threaded minivalve-- design discharge 24 gal/min.
E \
O] v
12 0 tY < T U tN
S
125. ~ . !
_ . ~ . . . . . . ~ . . . . ~ ~ ~ - . . . . . . . . . . . . . . . . . . . . . . . . . . . _ _ . _ _ _1 L - -
~IS~RI ~ITROL RANGE | J
t
75. B. (8 t o 128 l b / i n * l n ) i
5 ~ g .
25. 0
B . B
2-5 Ib/in'In BACKPRESSURE Q ~ - - - - ~ . 19-28 Ib/in*in BACKPRESSURE
4g-5~ 1 6 / i n ' i n BACKPRESSURE 74-78 l b / l n * i ~ BACKPRESS1JRE
i i i i i 0 i i i i i t i i i
PRESSURE DIFFERENTIAL ACROSS;VALVE ( l~/ in*in)
Figure 9.--Discharge test results of Griswold 3-inch threaded cluster v a l v e - design discharge 100 gal/min.
18
I I I I I I I I I I I I I I I I I i
I
I I I I I I I I I I I I I I I I I I I
E \
g
v
b~ 0 < I U
0
31~1.8
I 15B. 0
10B. 8
5B. 8
2 L 0
I PRESSIJRE CONTROL RANGE, (8 t o 128 I 6 / i n * i n ) ~
÷5¢ BAND '~Lo__
Q ~ 10-12 )b / In* In BACKPRESSURE 24-25 I 6 / I n * I n BAI~(PRESSURE 4g-51 l b / t ~ * t n BACKPRESSURE 74-75 l b / l n ' l n BACKPRESSURE
i i i i i i i i i i i i i i i
P R E S S U R E D I F F E R E N T I A L ACROSS V A L V E ( I N / i n * i n )
Figure 10.--Discharg e test results of Griswold 3-inch threaded cluster valve - - design discharge 245 gal/min.
4 1 ~ 0
3 ~ 0
E \
01 v
2 5 ~ 0 llJ
< T U
CI
15~.s
IBB, 8
I - T - ~ ~ . . . . . . . . . . . . . . . . . . . . . . . . .
! , " i
15-27 I b / t n m i n BACXPRESSI~E 35-42 l b / t n l i n BACKPRESStlRE 4g-51 l b / l n * l n BACKPRESSURE 7 5 - 7 8 l b / i n e g n BACKPRESSLIRE
i ¢ i i i i i i i i i i ¢ i i i
PRESSURE DIFFERENTIAL ACROSS VALVE C1bli~i~)
Figure l l . - -Discharge test results of Griswold 3-inch threaded cluster v a l v e - design discharge 345 gal/min. . :,
19
I I '2 ~' _
"' ~!.._ I
I E 75. I - - P R E S S U R E CONTROL RANGE (4' t o 57 l b / t n * t n > - - - - - - ~
5~8 .
25. ¢
I L 8
0
v
(3 r~
U Cq
O ( 3 ~ - m O ' 1 2 - 1 8 ' b / i n * i n BACKPRESSURE
' 9 - 2 3 l b / i n * i n BACXPRESSURE ~ 1 - ~ l b / t n * l n BACKPRES~URE 4E-42 l b / t n e t n BACKPRESSURE 49-52 l b / t n * t n BACKPRES~JRE 59-82 l b / l n * * n BACXPRESSURE
I I I - i , i I I I
P R E S S U R E O I F F E R E N T I A L A C R O S S , V A L V E ( 1 N / i ~ * i ~ )
I I I I
. Figure ,12.~T--D~¢harge test.r~ults of Griswold 3-inch threaded inline v a l v e - design discharge 100 gal/min. , , I
I
,,4
E
0
bJ (.I I1:
T U tO "
Q ,
-. . . . . ; , . ,
I 9-12 l b / t n * l r , BACKPRESSURE 18-22 l b / t r ~ t M BAC~PRESSURE 29-32 l b / t r ~ l n BACKPRESS1JRE 38-41 l b / t n * t n 49-52 l b / t n - t n ~ S S U R E B~-B2 l b / i n * t n BAC~REb'SU~E
7 5 8 . m i i i i i i I i
m m m 'I w ~ ~ I
P R E S S U R E D I F F E R E N T I A L A C R O S S V A L V E ( l b / l ~ * i ~ )
Figure 13.--Discharge test results of Griswold 10-inch flanged cluster v a l v e - design discharge 1,000 gal/min.
i .
I I I I I I I
20 I
I !
I I I I I I I I I I I I I I I I I
12~. B.
\
v
ht
< I U
O
8 ~ 0
4 0 .
20. 0
__---------0
\
SAND, PASSING NO. 8 SIEVE SAND, PASSING NIX 18 SIEVE SAND. PASSING NO. 14 SIEVE SAND, PASSING NO. 1B SIEVE. REP SAND. PASSING NO. 2B SIEVE l - i ~ h DRIED PINE NEEDLES
. . . . 0 F I E L D S C R E E N E D DEBRIS
D l P l I I ; I I I I I I I I I
TIME (mi,",) -
Figure 1 4 . - - D e b r i s test results of Griswold 3-inch threaded cluster valve " design discharge 100 ga l /min .
21
a. Flow cartridge after No. 6 sieve screened sand run
b. Flow cartridge, after No. 10 sieve screened sand run
Figure 15.--Flow cartridges, after U.S.A. standard Nos. 6 and 10 sieve screened sand runs in 3-inch threaded cluster valve, design discharge 100 gal/min.
22
I I I I I I I I I I I I I I I I I I I
I I I I I I I I I I I I I I I I I I I
a. Flow cartridge after run with 1-inch pieces of dry pine needles.
b. Flow cartridge after run with field screened aquatic weeds.
Figure 16.--Flow cartridges after pine needles and aquatic weed runs in 3-inch threaded cluster valve, design discharge 100 gal/min.
23
1~ 0.
100.0
?
\
W
< I U
0
8~0
80. 0 .
20. 0
SAND, PASSING N0.20 SIEVE 1 - tnoh DRIED PINE NEEDLES FIELD SCREEDED ~EBRI~ EGGS FIELD SCREENED DEBRI~ MOSS
0 . 0
T I M E (m i Pn)
Figure 17.--Debris test results, 3-inch threaded inline valve, design discharge 100 gal/min.
120. 0 .
100. 0
80. 0 E
%
m v
6 0 . 0 tsl (3
< T U 01 40.
Cl
20. 0
•!/______ ~ Q---------H~ S-*.oh CLUSTER
0.0 i i i " i
N~ 20 SIEVED SAND G'-- . . . . Q S - i n o h INLINE
NO. 20 SIEVED SAND S - i n c h CLUSTER, pINE NEEDLES
. . . . 0 S - i t , oh INLINE, PINE NEEDLES (3-- - - - - - - - , -~ 3 - i n o h CLUSTER
FIELD SCREENED DEBRIS, EGGS G~ .... Q S-Inoh INLINE
FIELD SCREENED DEBRIS, EGGS
i i i I L L I I m ~ ~ m
T I M E ( m l n )
Figure 18. --Debris test results, comparison of 3.inch threaded cluster valve and 3-inch threaded inline valve - - same debris types.
2 4 GPO 841 -@49
I I I I I I I
I I I I I I I I i TM
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