geotherm user guide · 2010. 11. 3. · references m790
TRANSCRIPT
°Pen File
GEOTHERM User Guide
by James R. Swanson U.S. Geological Survey Reston, Virginia 22092
Contents
Abstract ..,,,,.,....,...,,....... 1
Introduction ,.,,,.....,....,....... 2
GIPSY ,,,...,,....,............,. 23
The Commands ..I.,.,.......,.....,.. 27
SELECT .,..,... t .,...,.,..,..... 27
ITERATE ........................ 31
BACK .....I.,...,,...,.,...,... 32
SORT .......................... 32
SUM ,. f ........................ 33
PRINT LIHESIZE = 120 . .................. 31*
LIST ....,..,..,...,...."....... 3U
COPY .......................... 35
ReferencevS cited ..................... 39
Examples, .......................... Uo
Firure
Figure
Figure
Fipure
Figure
Figure
Figure
Figure
Figure
Fitrure
Illustrations
I. Section A Input form , ,Page
2. Section B Input form ...,.,,.....,.... 11-18
3. Section C Input form ................. 19-22
4. Job control language ................. 2k
5. GIPSY commands .................... 26
6. Variable description formats and options ..... 29
7. Printout of Example 1 ................ Ul
8. Printout of Example 2 ................ 1*3-1*5
9. Printout of Example 3 ................ 1*8-51
10. Printout of Example 4 ................ 53
11
Abstract
GEOTHERM is a computerized geothermal resources file
developed by the U.S. Geological Survey. The file contains
data on geothermal fields, wells, and chemical analyses
from the United States and international sources.
The General Information Processing System (GIPSY) on the
IBM 370/155 computer is used to store and retrieve data. The
GIPSY retrieval program contains simple commands which can be
used to search the file, select a narrowly defined subset, sort
the records, and output the data in a variety of forms. Eight
commands are*listed and explained so that the GEOTHERM file
can be accessed directly by geologists. No programming
experience is necessary to retrieve data from the file.
1
Introduction
GEOTHERM is the operational computerized file, created
by the U.S. Geological Survey, of national and international
geothermal resource information. The data base covers
geothermal physical and chemical data and is stored and
retrieved by the General Information Processing System
(GIPSY).
GEO.THERM contains site-dependent geothermal information
The format is divided into three sections which contain
information on three subtopics: Geothermal field/area,
chemical analyses of geothermal fluids, and geothermal
well/drill hole.
Section A: Geothermal field/area - This topic contains
data on the locality, developments, subsurface
dimensions, geology, heat content, etc.
of a geothermal field or area.
Section B: Chemical analysis - This topic includes
- chemical analysis data of geotherrral
fluids. Space is .provided for three
types of analyses water, condensate, and
residual gas. Data items include sampling
conditions, solutes, and isotopes.
Section C: Geothermal well/drill hole - This topic
contains information on peothermal wells.
Data items include locality, temoerature, / *pressure, enthalpy, and well flow.
The GEOTHERM input forms are illustrated in figures 1-3.
The rest of this paper is devoted, to the use of the
GEOTHERM file. No previous computer knowledge is required
and the necessary job control language (JCL) is illustrated.
Further details on the GIPSY program can be found in the GIPSY
"Users Guide" and "Programmer Guide" (University of Oklahoma,
1975).
3
Geot
herm
al Resources
File
(GEOTHERM)
Revision
8 (February
1976
)
Sect
ion
A:
Geothermal Field-Area
Record Id
enti
fica
tion
A10
<
A20
< u
A25 <_
A30 < A
Record No.
Cross
Inde
x No.
Revision
Record Ty
pe
Reporter Name
Date
Organization
Geographic Locality
Name
of Field-Area
Users
of A
rea
Waring Fi
gure
(U
SGS)
B14 <
Waring Number (U
SGS)
B15
<
Coun
try
Code (L
ist
A) B4
0 <
A50
A60
A70
B'10
B13
Country
Name
State/Province
County
Latitude
Longitude
B50
<
B60
<
B65
<
B70
<
B80
<
Yr.
11
i ***
i i
Available
Maps of Ar
ea B81
Page
2
- Section
A
Township,
Range, Se
ctio
n, 1/
4, 1/4
B95s
i t
t>
3105
^ .
t i>
B1
15<,
.
. ,
, .
. .
i i
i i
i .
i .
I .
t .
TOK«sK;p
Rawjs
Sect
ion
*A
l/»
*Ba
se § Meridian
B125 *
Other
Loca
lity
In
form
atio
n B83
<
General
Description
Size of Surface
Expression
CIO
< .
i i
. .....
....
i
unit!
Ele
vati
on
B14
0 <
> <
i i
i i
i i
t i
j I
t i
i i
t
i >
units
Resource Ca
tago
ry
CIS
< _ >
Deve
lopm
ent
.Status
C20
< _ >
Pres
ent
Use
5 Developments
C30
< ________ ;
Potential
Use
C40
<
Inferred He
at Source
C50
< ____ \ _______ ;
Depths to
Production Zo
nes
Zone
1 C7
0 <
\ \
\ \
\ \
\ \
\ \
\ \
\. \
\ \
\ \
\ >
Unit
*
Zone
2 t
C80
* \_.
i_.j.,
_ i
i t
^ i
i t ^1
> t
i i
t t
i >
Thic
knes
s of Pr
oduc
tion
Zo
nes
Zone
1 C1
00 <
i i
i t
t i
i i
i t
i
Zone
2
C110 <
i i
i »
t t
i .
i
t i
i i
i i
i i
unit
s
Aver
age
Temperature
of Pr
oduc
tion
Zones
Zone
1
C114
<
i i
i t
t t
t t
t i
i |
i i
_.t
i i
« >
UA.<3
Zone
2 C1
15 <
i ^
i i
i i
t i
t »
j I
t if
t i
t >
un.'
t^
Surface
Ther
mal
Activity
C120
< _
-5-
Page 3
- Se
ctio
n A
Associated De
posi
ts
No.
of Hot
Spri
ngs
Electric Power
Capa
city
. -Y
ear
Prod
ucti
on Be
gan
Number of
Wells
Prod
ucin
g
Inje
ctio
n
Test
. .
Abandoned
Other
Total
No.
of Wells
Prin
cipa
l Exploration
Tech
niqu
es
C220
<
Comments (G
ener
al Description)
C230
<
Geothe
rmal Ch
arac
teri
stic
s
Main Re
serv
oir
Fluid
Natu
ral
Surface
Disc
harg
e
C130 <.
C135
<
C140
<
C150
<
C170
<
C180
<
C190
<
C200
<
C210 <
E10
<
E20
<
Unit
s
> >
Total
Calculated Di
scharge
of De
ep Water
Natural
Recharge
Inje
ctio
n Re
char
ge
Total
Natural
Heat
Fl
ux
Total
Withdrawal Flux
Excess Withdrawal/Natural
E16
Measured
E15- <
i i
i i
t i
\ i
j i
i i
i j >
m>i
tj
E17
E
stim
ated
(C
ircle
L
abel
)i
i i
i i _
i t
i >i
t it
i i
i i
i i
E3
0
E4
0
E5
0
E6
0
F.70
< |
i ti
i i
< \
i
. i
t i
i
<
iifii
1
. .
, ,
. 1
,,,,,!
i
i \
\
\ i
iU
rtit<
1 1
1U
nl^
1 ,
Iun
i£$"
I i
iu
nits
>
\ '
' ?
\ >
i i
i i
i **
1 1
f 1
. .1
S.
i i
| |
j >
-6-
Page
4
- Section
A
Heat
Flow of
Su
rrou
nding
Area
Rang
e of
Spring Temperatures
E75
<
E76
<_
! i
t i iiit
i i
i i
> to
E
77
<t
t i j
j i
i
^ i
r i
VA
j{S
Spring Description
(if
no temp,
meas
ured
) E78 <
Boil
ing
Hot
Warm
>
(Cir
cle
word)
Well in
form
atio
n
E95
<
E96
<
E97
<
E98
<
Maximum
Well Temperature
Depth
Datum
Bott
om-H
ole
Temperature
Depth
Datu
m
Ave. Thermal
-Gra
dien
t
Comm
ents
Rese
rvoir
Properties
Rese
rvoi
r Te
mper
atur
es
to Best Estimate
Base
d on
Subsurface Area
to Best
Estimate
Based
on
Depth
to Reservoir
Top
to
Best Estimate
RJ5
< 1
t i
i «
t i
i I.,
i 1
R20
< ,
f t
> i i
I i
i i
L
i >
I >
units
< II'
1'
R30
Assu
med
R50
R55
R60
R70
R40
Meas
ured
(Circled La
bel)
<.
<
>., ,1
I...,
l
R10
0 <
R11
0 <
R12
0 <
R13
0 <
R14
0 <
j i
i i
i un
its
t lit
I ii ill
i V
It
t .
I >
UA
itS
,1 ^
it
i .
\. II
J
t >
U
nits
- >
Page
5 - Section A
Depth
to Reservoir Bottom
to Best
Es
tima
te
Rese
rvoi
r Th
ickn
ess
to Best
Es
tima
te
Rese
rvoi
r Volume
to Best
Es
tima
te
Poro
sity
Best
Estimate
Ave.
We
ll Flow (M
ass)
to Well
Diameter
Comm
ents
Reserv
es
Tota
l Stored He
at
to Best Es
tima
te
Depth
Datum
Temperature
Datu
m
Recoverable
Heat
Depth
Datum
Temperature
Datu
m
R14
5 <
^
f i
t i
i i
n i
i i
< i
tiii i , i i i .
I I
>
» »
tun
its
R15
0 <
^ ,.......,.
1 ...
. ... >
un
its
R16
0 < ...........
R18
0 < {tiii it ii
t .i
.l
i t.
i
t i
r i
">
R19
0 <
. ...
i .
i ....
i ......
i >
R200
< 111,1.
R210 < _____.
R230
< ________
> to
R2
20 <
>
> >
R270
< 11.1
R280
< t
.
. .
R290
< .
,
. t
R300 <
un
its
t i ii
F13
<
i
i t
i it
I i
t t
i .
i t
F10
< t
F20
< L
i i
i i ti
i i
i t
I i
i i
i i
i i
un
its
iiiitliiiiliii.ii.
Unit
s i
F30
<i_
iiiiit'iiiili>
F40
<
L
F50
<
t
F60
<
,
iT!
unit'
s iif'iiiii
1.1
! t.i .it
t
. 1
1 I
! 1
1 t
1 1,1
j
1 >
-8-
Page
6 - Se
ctio
n A
Method Used
Recoverable By
-Pro
duct
Potential
By-Product
Com
ment
s (R
eser
ves)
:
Geology
Gene
ral
Rock
Ty
pes
Cap
Rock
Aquifer
Depth
Thickness
Cap
Rock
Aquifer
Depth
Thickness
Other Ho
rizo
ns
5 Units
Comm
ents
(H
oriz
ons)
:
Hydrothermal In
dex
Minerals
Impo
rtan
t Control
or Locus
Other
Structures or Tr
ends
Hydrology
F70
-c
F80
<
F100
G10
G30
G40
G 5
0 <
t
^ i
i itit
t ?
t 1 it
< II
i
G60
<
iii
. i
i t
. i
i i
I i
i t
i i
i
G70
<
______________________________
G80
<
_____
__
__
__
__
__
__
_
>'
G90
<
i i
. «
. .
Un
ltS
G1 0
0
<
L
t I
I t
III
I i
i I
I III
II
\ ">
G20
< _________________________________
G110
< ________________________________
G120
< _______________________________
G140
< _____
._______________________
G130
< _______________________________
G150
<
_________
Comm
ents
(Geology):
G160
Page
7 - Section A
Geop
hysi
cs
Grav
ity
Survey In
form
atio
n J2
0 < _______________________._______________ >
Magnetic Survey In
form
atio
n J30
<4____________
;______________________^___
v
Seis
mic
Survey Information
J40
< ,_____________________ ,
______________, >
Electrical Resist
ivit
y J50
<________I______________________________>
Other
Geop
hysi
cal
Resi
stiv
ity
J60
< ________________________________________, >
Comments (G
eoph
ysic
s):
J70
< ________________________________________ >
Envi
r9nm
enta
l Fa
ctors
. HI
S < ________________________________________ >
Prim
ary
Refe
renc
e (G
eoth
erma
l Field)
Author
K20
< _________________________________-_«___ >
Date
K30
< _________________ *
Title
K40
< ________________________________________ >
i "
, --
- '
.-
Reference
K50
<______________________________________ >
References
1)
. K7
0 <
_________________,____!____________ ..--.
>
2)
K80
< _________________________________________ >
3)
K90
< _________________________________________ >
4)
K100
<_________________________________________'>
-10-
Geothermal Resources File (GKOTHERM) Revision 8 (February 197G)
Section B - Chemical Analysis
Re c ofd Identification
Cross Index No. A20 < i r i... i r t _ t __j >
Record Type A30 < B >
Sample Type A34 < WELL ' SURFACE > (Circle word)
Repojrtejr
Name ABO <
Date A60
Organization A70
Geographic Locality
Geothermal field
Name of Sample Source
Country Code
Country Name
State/Province
County
Latitude
Longitude
YA MO,
<
BIO <
B20 <
B40 < , _ L _, >
B50 <
B60 <
B65 <
B70 < L r i- < i ! . i i i ! t V
B80 <,,,,-,,,.,,! I , >
>
>
>
>
>
>
p M e/wTov;nship, Range, Section/ 1/4, 1/4
i , .> B105<, . , .> B1I5<. , , , . , , . , , . . . , . , , , ,>Tow*»t«;{> Ran^c - Section 1./M i/1
USGS WRD Well-Spring Numbering System
mi 6 <
Other Grid System
System Used B100 <.
X Coorxi. B110 <,
Y Coord. B120 <,
UTM Zone No. B130 <
Nap Reference B82 <
Other Locality Information B83 <
Page 2
-Section B
Surface
Sample In
form
atio
n
Source Ty
pe
S10
<
Samp
le No
. M190 <
Collection Da
te
M200 <
Collector(s)
520
< ._________________________________________ >
Point
of Collection
N210
<____._________________________________
_ >
Volu
me Fl
ow Rate of Spring
M220 <
i i
i t
i ,
i ,
i t
t I
, ,
i ,
, ,
, >
Temperature
M210
< i
i .
t ,
t i
t i
t >
I . >
Qualitative
Stea
m/Wa
ter
Rati
o S4
0 < ____________________
________
t >
Depo
sits
or
Al
teration
S30
*______
_________________
Water
Treatment
Data
- M234
<
Other
Sample Information
S50
<
Refe
renc
es
M790
<
-12-
Page 3
- Se
ctio
n B
Well Sa
mple
Information
Samp
le \'
o.
Collection Date
Coll
ecto
r(s)
References
Wellhead St
atus
Wellhead Pressure
Wate
r Poin
t of Collection
Separation Pr
essu
res
First
Second
Third
Wate
r Sampling Temp.
Stea
m Point
of Collection
Separation pressure
Steam
Samp
ling
Temp.
Steam
Flow Ra
te (Mass)
Water
Flow
Rate (Mass)
Enthalpy of To
tal
Flow
Wate
r Treatment
Data
M19
0
M20
0
S20
M79
0
NIC
N30
P55
P60
<
t_ )
_ i
i i
i i
ii
i i
,P70
<
l_L
P80
<
L .
M21
0 <
L .
, .
. ,
, ,
, ,
,
un
.'tj
i i
1 \
i
A/G
I I
i i
I_
v_
ii ii
i i
j >
.>
P75
-: < till
1 I
I i
t l
{... Ill
< i
i
S60
<
t ,!!.,,
I I
, ,
} I
>
N50
<
i
t i
t lit
i i
i i)
i i
i it it >
M22
0 <|t
, t ,,,,
t t ,{,,,,.,.
>
.
N60
<
,,.,..
M23
4 <
_________
Othe
r sample information
S50
<
Page 4
- Section
B
Water Analysis
Analysis Da
te
Anal
yst(
s)
?H
1)
2)
Eh
Temperature
Specific -Gr
avit
y
Specific Conductance
Temperature
Alkalinity
Total Dissolved So
lids
Total
Suspended So
lids
Isotopic Da
ta
Del
O (18) of
Water
. .
Del
D of
Water
Del
C (13) of
Dissolved C0
Del
0 (1
8) of Dissolved SO
Del
S (34) of
Dissolved S0
Del
S (34) of
Dissolved H2
Tritium Content of
Water
C(14
) Content
of C0
2
Other
A31
M233
M236
M20
M202
M221
M222
M91
M21
M740
M22
< W >
AtTtmp.
.>
At .M202A
<i
i i i i L_J I L
j >
11
t t
i il tii
i i
i I >
....
.'. iT> >
t «
> I
II
i I
i I
I >
<t
ii .
\ _
<t
\i
ii
tun
its
M24
<t
i t
i
0270
<i
i i
i i
t. i
i i
t i
Q2
50
<
i i
i (
i t
i i
i i
i
Q1
50
<
t ,
, ,
, ,
, ,
, ,
,
Q2
00
<
i ,
, ,
, ,
i ,
i i
,
Q1
90
<
,,,,,,,,,' ,,
Q1
85
<
,,,,,,,,,,,
Q1
86
<
,,,,,,,,,,,
Q1
87
<
,,,,,,,,,,,
I 1
1 1
1units
i i ill
J 1
1 1
I
1 ,
, ,
,
I 1
1 1
1
1 1
1 1
1u*
;*5
l ,
, ,
,U
nt'ts
1 1
1 1
1
1 i
| > ^
t
J >
' f
1 >
I L
f >
i i
t > j^
1 1
1 >
um
is
0.1
10
<
Page
5 -
Section
B
Units
Used
M341 <
Li
M30
<
Na
M4 0
<
K ' M50
<
Rb
M480 <
Cs
M500 <
Na+K
M300
<
NH,
Ml 50
<4
'
NO.
M590 <
PO,
M600 <
4
SiO^
M130 <
SO.
MHO <
4
C03
M580 <
HC03
Ml 40
<
Rare Earths Analyzed
Actinides Analyzed
Rare
Gases Analyzed
Other Solutes & Gases
Commen
ts
>' Mg
M70 <
> Cu
M360 <
> Ca
M60
< >
Zn
M390 <
> Sr
M380<
> Hq
M440 <
> Ba
M330<
' >
B M120 <
> Ca+Ma
M180<
> HB02
M170 <
> Mn+3
M630<
> Al
M310 <
> Mn(TOT)
M520<
> Pb
M370 <
> Fe+3
M620<
> As
M320 <
> Fe(TOT)
M510<
> Sb
M470 <
> U
M450 <
> > > M750 <
M760 <
M770 <
M780 <
,
M800
<
> F
M90 <
>
> Cl
M80 <
>
> Br
M350<
>
> I
M490<
>
> O2
M610<
>
' >
N2
M530<
>
> C02
M570<
>
> SO
M540<
>
> H'2S
M160<
>
>
' 2
< >
CH,
M560<
' >
4 -..
., ..,
., ,.
,...,.
,..
> > '
. >
-15-
Page 6
- Se
ctio
n B
Condensate Analysis
Analysis Date
Anal
yst(
s)
pH
1)
2)
Eh
Temperature
Specific Gravity
Specific Conductance
Temperature
Alkalinity
Total Dissolved So
lids
Total
Susp
ende
d So
lids
Isotopic Data
. .
De
l 0
(18)
of
Water
Del
D of
Water
Del
C (13) of
Dissolved C0
2
Del
O (1
8) of Dissolved S0
4
Del
S (34) of
Dissolved S0
4
Del
S (3
4) of
Dissolved H2S
Tritium Content of
Water
C(14
) Content of
C02
Other
A32
<
C >
S7
0
<_
__
S80 <___
N191 <___
SlOO <___
S110 < _
> A
t N
191A
>Te
^p.
siO
OA
<
r «
i
< t
i '
i '
' i
i i
i i
) i
>
S140 .
< _____________________ >
S150 <t
, ,
( f
( t
t t
t ,
I ,
, ||
j ,
j
5160 **
'
' t
» t
i i
i. .«
i
.1 .
>
S170 <,
i
,
<
t I
I 1
J I
> I
I I
I I
i I
I .
I I
I >
Un.
tJ
S190
<
i )
) I
t I
I t
i.l
I !
J
I I
l_.._
i ^
Q260
<
t j
i i
i it
i i
i1
1
i Q2
4^
<i
^ i
i »
i i
> i
i i
I i
i t
i i
i i
S220
< j
i i
. t
i i
t i
j (
t I
i i
t <
i i
i
S 2 3 0
< j
t i
i i
i l
i i
i i
I i
i i
i i
i i
' . UAl't5
S240 <
i__._i
>
r j
t it
t i
iI
i
5250 <
l i
i t
i l
i. t.
i i
t I
^ i
i. i
i i j
t i
t i
j >
. >>
S260 <; .
t i
i i
t i
r t
t i
S270
<i
i
( |
t i
\ t
i t
{ {
t i
t i
i
S280
<
i >
Page
7 -
Section B
Units Used
T500 <
Li
T10
Na
T20
K
T30
Rb
T40
Cs
T50
Na+K
T60
NH4
T70
NO
T80
PO,
T90
4
Si02
T100
S04
T110
C03
T120
HC03
T130
Rare
Earth
Actinides
Rare Gases
Other So
lu
< < < < < < < < < < < < < s Analyzed
Analyzed
Analyzed
tes
& Gases
Comments
> > > > > > > > > > >. > > T440
T450
T460
T470
T490
Mq
T140
< >
Cu
T230
<
Ca
T150 <
> Zn
T240 <
Sr
T160 <
> Hg
T250 <
Ba
T170 <
> B
T260 <
Ca+Mg
T180 <
> HBOn
T270 <
Mn+3
T190 <
> Al
T286 <
Mh(TOT)
T200 <
> Pb
T290 <
Fe+3 .
T210 <
> As
T300 <
Fe(TOT)
T220 <
> Sb
T310 <
U T320 <
< < < < <
> F
T330
> Cl
T340
> Br
T350
> I
T360
> 00
T370
> N2
T380
> C02
T390
> SO^
T400
> H^S
T410
> Hn
T420
CH4
T430
> >
< < :
< :
< < :
<
.
< :
< :
< :
< <
>
-IT-
Page
8 -
Section B
Gas
Analysis
Analysis Da
te
Analyst(s)
A33
< G
>
U10
<___
U20
<
Gas/H20 Ratio
(mol
/mol
) U3
0 <
Units
Used
N230 <
CO.
H2S
0,
N80
<.
N90
<.
.N140
<.
N150 <
H2
CH C2H
6
He
N120
<
N130
<
N182
<
N170
<
Other Hydrocarbons
U40
<
Other
Isotopic Data
Del
C (1
3) of
CO.
C(1
4)
Con
tent
of
CO
,
Del
C
(13)
of
CH(
Del
D
of
CH4
Del
D
of
H0
U50
<
U60
t tii
t lit
t i
i
< I,
i i
i i
r t
t i
ii
i i
J 1
t >
<!*
I
I »
1 t
, I
I I
t i
Nl.lla.
.
f I
I I
» I
I
i ti
i i
i i
i 11
Urt
i'tS
Del
S
(34)
of
H2
S
Q220
<L
_L
_L
L_L
U1
10
<
|,),,
Rati
o A
r(4
0)/
Ar(
36
) Q
290
<_
__
__
__
Oth
er
U13
0 <
__
__
__
_
Com
men
ts
U14
0 <
______
i i
i i
\ i
Un
itj
f I
un
its
Ar
N183
<.
Rn
N110
<.
Hg
N160 <
-18-
GEOTHERMAL RESOURCES FILE (GEOTHERM)
C - Gcother-.nal Well/Drill Hole
ftecgjrd Identification
r Record No, ALO <......,.»
Cross Index No. A20 < ._______________
: Record Type A30 <_v
Reporter
Name A50 < .
Date. A60 <i_. ./.y«.
Organization - A70 <________
Location
; Geothermal Field BIO <_________________
KGRA Bll < _________
API No. B12 <_________________
Well name B30 <__ '__________
company B35 <___________________
Country Code BAG * t . ,^ .
. Country B30 < ___________________
State* B60 <________________
County B65 <__________________
B70 <t i \ - 1 i i « t i i
B80 <i i t i , . , , > . . , f \ > ^ fA»
township, Range, Section, %, %
6 Meridian B125<
Coordinate System
Northing B120<
Easting B110<
UTM Zone No. B130<
Reference B82 <
Locality Information B83 <.
-19-
SECTION C - PACK 2
grilling & Casing
Date Startedv
Date Completed
Date Abandoned
Well Status
Total Depth
Elevation
Casing
012
D10
JA-^-J/l-/_l_1 /
«o.
.x . .X
B150< t ,....,. . ._ .
D45 <
Producing Interval
Water Level
Drawdov/n
Porosity
Permeability
Well Log Information
D40 <
D25 < f i
D26 < L
D27 <
D28 < L
D29 <
11 r » r i i i ii I I r t i > L0*1175
Comments C230<
L61 < DRY STEAM
L62 < INITIAL TEST
SECTION C - PAGE 3
testing & Completion Data
Production Type'f
Measurements From
Date
Flow Rate
Orifice Plate Size
Steam Quality
Wellhead Temperature
j Bottom Hole Temperature 0130^ .....,.,.. I .:
HOT WATER >
SUBSEQUENT TEST >
L64 it itv/j i rs
D90 <
L65 <, . .
Wellhead Pressure
Enthalpy Of Steam
Enthalpy Of Brine
Enthalpy Of Total
Production Rate
Comments
1.67 <t -J L I L I I I
D230<, , , i " , , , , i ,
D240<, ,.,.,1,,..
L66 "^ i i , i i t i i i. . j
D140 <, , , , , , , . , , i
L68 «
U»»|T5 A/C,
I 1 , « 1 t l>
1 , . 1 1 i 1 1 *
L ,.,,,. ,>1 , i i i i. j
stem Test
Bate
Interval
Flow Rate
Fluid Recovery
Fluid Temperature
Final Flow Pressure
L20 <,
L25<1*0.
L26 < L
L27<
L40 <L_L_1_ -J ' ' I t i
L41 <
Final Shut-in Pressure L42 <
,_L__!>U»iiT5
'Final Hydrostatic Press. L43 <.........., |
-PI
JECTION C - PAGE 4Ijpr iroary Referencef
Author K20 <
Date - K30 <
= Title K40 <II Reference K50<
iCther References
1) K70 "<.
2) K8CK_
GIPSY
The General Information Processing System (GIPSY),
developed by the University of Oklahoma, is used for the
storage and retrieval of GEOTHEftM data. 'The GIPSY program
provides for easy access to the file by a set of simple
user commands. A retrieval setup consists of job control
language (JCL) and GIPSY retrieval cards. The JCL needed
to make a retrieval from GEOTHERM is listed in figure 4.
The retrieval cards, which follow the JCL cards, contain
the user commands and command parameters relating to a
specific retrieval.
GIPSY commands are user-oriented so that no prior
computer experience is necessary to make a retrieval. With
a set of eight commands, the user can select, sort, and
output information from the file. A successful retrieval
can best be accomplished by using the following questions
as a check list.
What kind of data is'desired (e.g., geochernical,
wells, or fields)?
Should the data be restricted by geographic locality,
temperature, chemical constituents, etc.?
Should the data be sorted?
What data items are desired for output (all or a
partial list of items)?
How should the output be organized (entire records,
tables, lists, etc.)?
// Job Card
//A EXEC CUESTRAN J)NAHE= % A93 i100.AZ231.WG9B200.GEOD* , DYOLrCCD915 ,
// DUrUT=3330,RNAME=*RIF.W0020.THERMl*,RVOL*CCD921,
// UNIT=3330,CLOCK=15,SPACE=800,RGN=110K
//QUE3TRAW.SYSRDR DD *
FORM
GEOTHERM
- GIPSY retrieval cards -/
/*
Figure 4.--Job control lanrua^e
The answers to these questions are important in formulating
a search strategy and assembling a set of GIPSY retrieval
cards.
The retrieval cards are a sequence of GIPSY commands
and conditions. A command always begins in the first column of
the computer card. Parameter statements that follow each
command begin in Column 2. For example, the. SELECT command
is followed by parameter statements which define and list
criteria for selection. The most common commands, and the
function they perform, are listed in figure 5.
-25-
SELECT
ITERATE
BACK '
FUNCTION
Search/Retrieval
SORT
SUMProcessing
PRINT LIMESIZE=120
LIST
COPY
Outout
Figure 5.--GIPSY commands
-26-
The -Commands
SELECT. --The SELECT command is used to initiate a
search on the GEOTKERM file. It will always be the first
command used for each retrieval but it can be used many
times in one job run. The result of this
command will be a subfile which, in turn, can be searched
using the ITERATE command. An example of the SELECT command
and parameter statements is listed below.
SELECT
A. B40 USvariable descriptions
B. A30 A
LOGIC A AliD B lofic statement
Two types of condition statements are reouired: the variable
description( s ) and the lo^ic statement. Examples in the use
of the SELECT command are shown in examples 1-4 (figures 7-10)
Variable description - This statement provides the
factors for selection of a record. For example,
the user may wish to see seo thermal field records
from the United States. The subset r«ust reflect
two characteristics.
A. United States
B. Geothermal Field Records
The variable descriptions would be:
A. B40<US>
B. A30<A>
-27-
The designators (A, B) are uniaue single alphabetic
characters used to identify one characteristic in
one search. Up to 26 designators can be listed
for each use of the SELECT command. Following the
designators are the data labels (B^O, A30). These
unique labels identify the data iteins of the file
(see input forms for subtopics in figures 1-3).
"BUG" is associated with country code and "A30" is
associated with record type. Following the labels
are restrictions which the user can impose. The
first conditions (<US>) indicates that the country
code, "US," is a factor in the search. The brackets
(< ">) enclose character strings. A list of variable
description forr.-ats and options are illustrated in
figure 6.»
Logic_Statement - The lo^ic statement is the key to
the search procedure. It links the variable descriptions
using the boolean operators, "AMD," "OR," and "NOT"
(the synbols * (AND), + (OR), - (HOT) can be used also).
In the example, both characteristics (i.e., peotherrnal
field records from the United States) are required.
The logic statement is:
LOGIC A AND B
-28-
A. A30
B. A30<KA
C. A30<A>
D.
E.
F. A30<£A£> THRU
G.
H. A30.EQ 20
I. A30 GT 20
J. A30 LT 20
K. A30 10 THRU 20
L. A30 EQ 'A20
M. A30 LT A20
N. A30 GT A20
A. Use only the label by itself v/hen.it is desired to select
on existence (presence) of a data item. For example,
the user may want to select analysis records only if they
contain temperature data.
B. This setup means the user wants any data with the word
"/il# M (a word is defined as a string of one or more
characters or numbers bounded by blanks).
C. This setup requires only the existence of the letter "A."
All words that contain the letter "A" will be selected.
Figure 6.--Variable description formats and options.
D. Use this setup for the prefix, "/) A." Records with
"around" or "about" will be selected but not "Canada."
E. Use to find the suffix, "ftf." Records with "Canada"
or "Nevada" would be selected but not "average."
F. The user can retrieve on a range of letters. In this
example, the words "A," "B," and "C" will be retrieved.
G. In this example, the character value of "20" would
be selected. The string, "20.0," would not be selected
H. The numeric value, 20, would be selected whether it
v/as 20.0, 020, or 20.
I. Records with a numeric value greater than (GT) 20
will be selected.
J. Records with a numeric value less than (LT) 20 will
be selected.
K. The user can select a range of numbers. In. this case,
all records with value of 10 through 20.
L-N. Numbers under two lables can be compared. In these
cases, the numeric values in labels A20 and A30
are compared. (EQ = equal, LT = less than, GT =
greather than.)
Figure 6. (cont'd)
-30-
Another lo,?ic statement could have been used with the
same variable descriptions to select a different subset.
For example:
LOGIC A Ai\T D NOT B
This example would retrieve records from the United
States but net if they were reothermal field records.
Parentheses may be used as in mathematical equations
to eliminate ambiguities,
LOGIC A OR B AMD C
LOGIC A OR (B AMD C)
ITERATE. The ITERATE command performs a function
similar to the SELECT command. When the SELECT command is
invoked the entire file is searched and all previous subsets are
deleted. The ITERATE command is used to search a previously
selected subset. The SELECT command produces a subset 1.
The ITERATE command will often follow the SELECT command
and it is used to search subset 1. The resultant subset
is subset 2 which in turn can be searched using the ITERATE
command a second time. These subsets are deleted when
(1) the job is finished (2) the SFLFCT command is used
again (3) the BACK command is used. The ITERATE command
is used like the SELECT command and contains the same
variable description and logic statements. For use of the
ITERATE command see examples 2 and 3.
* l'ne BACK command is used to return to a
previously selected subset. That subset can be either searched
with the ITERATE command or it can be sorted, printed, etc,
BACK
2
ITERATE
In this example, the user returns to subset 2 and then
searches it. Subsets 3 and greater are deleted but subset 1
is still retained. The resultant subset in this case v/ould
be a new subset 3. See example 3 for use of the BACK command.
SORT. The SORT or SORTD (descending sort) command
is optional. Records can be sorted by any information item
and the sorts can be nested.
SORT
B60 10
M130 5.2
The parameter-statenents consist of a list of the sort
fields and the number of characters involved in the sort.
In the example, B60 and M130 refer to state and silica
content respectively. The subset is first- sorted on the
first ten characters of state. The secondary sort is on
silica content and is ordered numerically for five dibits
with two decimal places. See example 2 for use of the SORT
command.
-32-
SUJi- --The SUM conir.and producer r.ho following information.
1. The number of occurrences of the item in the
selected subset
2. The arithmetic mean
3. The algebraic sum
4. Maximum value
5. Minimum value
This operation ignores text. The parameter statements consist
of a list of the items to be Drocessed.
SUM
MI 30
M40
This example would perform the SUM orocedure for silica content
(MI30) and sodium content (M-iO) for the selected subset. See
exanpie 4 for u?e of the SLir! command.
-33-
£RMI_LIll£S_TZE=120.--The PRINT command instructs the
system to print the records from the selected subset.
No parameter statements are required. Each record begins
at the top of a computer page. The NOPAGE option which
prevents beginning a new page for each record can be added.
PRINT LINESIZE=120 NOPAGE
See example 2 for use of the PRINT command.
LIST.--Sometimes the user only wishes to see a few
data items. The LIST command is used to print designated
portions of the selected records. The items are printed in
their entirety and are continued on subseouent lines if
there is an overflow. The parameters are a list of the data
items to be printed.
LIST
M130
MHO
M30
See example 3 for use of the LIST command.
COP_Y.--The COPY command is probably the most useful
output command. Fixed-length records can be produced
from CEOTHERM with this command. The system, therefore,
has a report generating capability which can produce
tables or formatted records for user-written processing
programs. The COPY command is used in example 3.
Copy to Printer - The user may wish to produce
tables from a subset of GEOTHERM records. The parameter
statements that follow the command consist of a list
of data items and character strings to be included in
the table. A line is printed for each record ofr
the subset. The parameter statements consist of the
following types.
AID x In this case the first "x" number of
characters from AID will be printed.
Blanks are inserted if there is no
data.
A10 x.y This format causes the first number
in A10 to be printed with "x" number
of dibits and "y"-decimal places.
The decimal point is assumed.
"STRING" Literal character strings can be inserted
by putting the string between single
quotes. This character string would be
printed for every record. Maximum
length is 60 characters.
The first statement after the COPY command is a literal
used for carriage control on the printer. The user has three
choices of spacing.
a blank provides single spacing
*1 % double space
H - N triple space
If one of these three cards is not entered, then the first
character of each line will be truncated. If output is
going to disk then this card is unnecessary.
Copy for Extended Applications - The COPY command is
very useful in producing formatted subfiles for further
processing. For example, silica, sodium, potassium,
and calcium concentrations from chemical analysis
records can be extracted, formatted, and output to cards,
tape or disk. Data that is extracted can be formatted
to fit the needs of the user program.
Suppose the user had a program desipned to process the
following data input format.
Column Field " Data type Length
1 Geothermal field Character 15
16 State . Character 15
31 County Character 15
^6 Silica Decimal 5.2
51 Sodium Decimal 5.2
56 Potassium Decimal 5.2
61 Calcium Decimal 5.2
-36-
The COPY output would be the followinr:
COPY
BIO 15
B60 15
B65 15
M130 5.2
M30 5.2
M60 5.2
With the addition of one job control statement this
data could go to cards, tape or temporary disk space.
The extra statement would, be inserted just before
//QUESTRAN.SYSRDR DD*. This extra JCL card for each
output is listed below:
Card Output
//QU[s3THAr:.SYSlvRKO DD SYS OUT = R , DCB= (RECFM=F A , LRFCL-80 , ELKS IZ Fir 60 )
Temporary disk output
//QUESTRAN.SYSURKO DD DSN=&&TEMP,UNIT=SYSDK,DISP=(MOD,PASS),
// DCB=(RECFM=FB,LRECL=XX,BLKSIZE=XX),
// SPACE^(CYL,(6,1),RLSE)
This example would create a data set (&&TEMP) on
a system disk pack. The LRECL (record length) and
BLKSIZE (block size) will vary with the total length
issued from the COPY command. This GIPSY procedure could
be followed by a program written in PL/1, FORTRAN, etc.
-37-
lane Out out
//QUESTR/UM.SYSURKO DD DSN=nyset, UMIT = TA PE9 ,
// DISP=(,KEEP),DCB=(RECFM=FB,LRECL=XX,BLKSIZE=XX),
// LABEL=(I,SL)
In this examole a data set called "mysct" would be created
on a standard label 9-tract taoe. The LRFCL (record length)
and BLKSIZE (block size) will vary with the total ierurth
issued from the COPY command.
-38-
References cited
University of Oklahoma, 1975, General Information Processing
System Users Guide, GIPSY documentation series, vol. 2:
University of Oklahoma, Office of Information Systems
Programs.
University of Oklahoma, 1975, General Information Processing
System Programmers Guide, GIPSY documentation series,
vol. 3: University of Oklahoma, Office of Information
Systems Programs.
-39-
Examples
Example 1
Objective - The user wishes to pet a counh of chemical
analysis (Analysis (A30=B) records from the states
(B60) of California and Nevada with temperature
(M210) greater than 35°C. In this case none of the
output options will be selected.
Input setup
// JCL
FORM
GEOTHERM
SELECT'
A. A30<B>
B. B60<CALIFORNIA>
C. B60<NEVADA>
D. M210 GT 35
LOGIC A*(B+C)*D
/*
-no-
Fig
ure
7
- E
xam
ple
1
SE
LE
CT
A.
A30<
8>
RE
CO
RD
T
YP
E.....
B.
ST
AT
E/P
fHV
INC
E.
R40<
CA
LtF
QR
NlA
>ST
ATE/
PRQ
VIN
:E.
D.
MZ
10
GT
35
WA
TER
S
AM
PLIN
G
TE
MP
....
LO
GIC
A
*(B
+C
)*D
SE
AR
CH
?0
:?3
:4l.2
S
EA
RC
H
BE
GIN
NIN
G
D:?
3:^
9.7
S
EA
RC
H
SU
9S
ET
SE
AR
CH
ED
SE
LE
CT
ED
VA
RIA
BLE
S
A 8 C 0
18S
O
41
6
SA
TIS
FIE
D
1309
38
6
732
65
2
Objective - The user wishes to select all records from
the United States and then search that subset for
Arizona records. The selected records are to be
sorted by county (B65) and geothermal field (BIO)
and then are to be printed.
Input setup
// JCL
FORM
GEOTHERM
SELECT
A. BilO<US>
LOGIC A
ITERATE
A. B60<ARIZONA>
LOGIC A
PRINT LINESIZE=120
/*
Mote: It v/ould actually be easier in this particular
example to ask for the Arizona records directly.
However, by selecting the U.S. records, the user
has a smaller subset to deal with. Thus, another
ITERATE command on the U.S. records could have
followed the first. Search time and cost would
be lower because the U.S. subset is searched instead
of the entire file.
:rr
3. E
xam
ple
2
A.
CO
UN
TRY
C
OD
E.
tonic
A
2>
:23
:<r9
.C
SE
AR
CH
B
EG
INN
ING
2
0:2
4:0
6.0
S
EtA
lH
CO
MP
LET
ED
SE
AR
CH
ED
I8
60
SE
LEC
TE
D
1*9
5
SU
BS
ET
1
V4
RU
8L
ES
S
AT
! S
PIE
D
A 14
,95
ITE
RA
TF
A.
R6G
<4fU
ZO
NA
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TA
TE
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OV
INC
E,
LOT,
1C
4
23:2
^:0
6.2
S
EA
RC
H
BE
GIN
NIN
G
2Q
:?V
.l7
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SE
AR
CH
C
QH
PLE
TC
O
H95
SE
LEC
TE
D
U
SU
BS
ET
2
VA
RfA
BU
ES
S
AT
ISF
IED
A 11
SO
RT
a&s
15
ftlQ
15
E
N3
CP
SO
RT
PR
INT
L
lNE
StZ
E-1
20
. -1*
3-
Fig
ure
8
. E
xam
ple
2
(cont'd)
PA
CE
0
00
1
REC
OR
D
0000
1
GfftT
HtR
MA
L
RE
SO
UR
CE
S
FIL
E
{GE
OT
H6
RN
) R
EV
ISIO
N
8
Se
cTIO
S
A.-
C
EO
TH
ER
MA
L F
IELD
-AR
EA
R
EC
OR
D
IDF
S'T
IF
lCiU
ON
REC
OR
D
NO
. ..
....
0
00
02
56
CR
OS
S
IMD
EX
\3
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CF
C0281
RE
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RD
T
YP
E.....
A
NA
ME
....
....
..
J.
RE
NN
ER
OA
TE
....
....
..
75/0
5O
RG
AN
IZA
TIO
N..
U.S
.G.S
.
GE
OG
RA
PH
IC
LO
CA
LIT
YG
-Cni
HE
rtH
AL
FIE
LD
-AR
EA
..
PO
WE
R
RA
NC
HE
S
INC
. W
ELL
S
COUN
TRY
CO
DE
....
....
...
us
COUN
TRY
NA
ME
....
....
...
UNIT
ED S
TATE
SS
TA
TE
/PR
OV
INC
E.........
AR
IZO
NA
Lin
ruO
E...............
33
-17
-06
N
, L
ON
GIT
UD
E..
....
....
....
U
1-4
1.-
12
U
TO
WN
SH
IP
RA
NG
E
SE
CT
ION
1
/4
1/4
C
2S
06E
I
SW
BA
SE
C
ME
RID
IAN
........
GIL
A
C S
ALT
R
IVE
RA
VA
ILA
BL
E
HA
PS
D
F A
RE
A:
HIG
LeY
1:2
4,0
00
GE
NE
RA
L D
ES
CR
IPT
ION
EL
EV
AT
ION
....
....
....
....
....
. 408.^
3
H 1
34
0.
FT
RfS
OU
ftC
c C
AT
cT.O
RY
.. ...........
6PR
ESEN
T US
E C
DEVE
LOPM
ENTS
: 2
WEL
LS
OF
ABOU
T 3K
H DE
PTH
SURF
ACE
THER
MAL
AC
TIV
ITY
....
..
FOUN
O BY
D
RIL
LIN
Gw
n.
OF
HOT
SP
RIN
GS
............
GE
OT
HE
RM
AL
CH
AR
AC
TE
RIS
TIC
SN
AT
UR
AL
SU
RFA
CE
D
ISC
HA
RG
E..
....
....
316.6
5
L/S
U
9000E
+04
L/M
IN
ES
TIM
AT
ED
WE
LL
INF
QR
HA
TIO
NH
AX
INU
H
WE
LL
TE
MP
ER
AT
UR
E...........
18
'».
C TO
3
20
0.
HB
OT
TO
M-M
OLE
T
EH
PE
PA
TU
RE
....
....
....
1
84
.0
C TO
3
20
0.0
0
H
RE
SE
RV
OIR
P
RO
PE
RT
IES
RE
SE
RV
OIR
T
EM
PE
RA
TU
RE
S..
....
.to
. 1
63
. C
TO
18
4.
C M
EA
SU
RE
DP
ES
T E
ST
IMA
TE
....
....
....
. 1
60
.0
CS
UB
SU
RFA
CE
A
RF
4..
....
....
....
. 1
.0
KM
**2
TO
5
.0
KH
**2
6ES
T
ES
TIM
AT
E..
...........
2.5
K
K**
2S
AS
EO
O
N:
9R
I LLIN
G
DE
PT
H
TO
TOP
O
F R
ES
ER
VO
IR.....
6ES
T
ES
TIM
AT
E.............
2000.0
0
M 2.0
00
KMD
EP
TH
TO
B
OTT
OM
O
F R
ES
ER
VO
IR..
3000,0
0
M 3
.00
0
Krt
TO
3000.0
0
M.
3.0
00
ftFS
T
ES
TIM
AT
E.............
30
00
.00
H
3.0
00
KMT
HIC
KU
ES
S
OF
RE
SE
RV
OIR
....
....
BE
ST
ES
TIM
AT
E.............
1000.0
0
M 1
.00
0
KMV
OU
HE
O
F R
ES
ER
VO
IR..
... ......
BE
ST
E S
TIM
AT
E.............
2.'3
00
K
M**
3C
OM
ME
NT
S:
DE
PTH
TO
B
OTT
OM
O
F R
ES
ER
VO
IR
IS
AS
SU
ME
O.
Rfs
eftv
esT
OT
Al
ST
OR
ED
H
e4
T..
....
....
cES
T E
ST
IMA
TE
....
....
..
a.3
71
6E
*17
J
l.9
99
9E
*l7
C
AL
AB
OV
E
15
. C
Figure
8. Example 2
(con
t'd)
OC
3G Y
&E
W£R
AL
RC
C<
TY
PE
S:
VO
LC
AN
ICS
(A
GE
?>
PAG
E 00
02
RE
FER
EN
CE
:.
O.E
. W
HIT
c 4
O.L
. W
ILL
UK
S,
ED
ITO
RS
.
1975
T
ITL
E..
....
. A
SS
ES
SH
EN
T O
F G
EO
THE
RM
AL
RES
OU
RC
ES
OF
THE
U
NIT
ED
S
TATE
S -
1975
...
u.s.
c.s. C
IRCULAR
726
RE
FER
EN
CE
S:
^E-I
S.
:OH
M.
MR
HIK
S
0 O
ON
NE
LL t
MR
. W
ARD
A
US
TIM
O
F G
EO
TH
cftH
AL
KIN
ET
ICS
Objectives: i) Seiect U.S. records.
2) Use the LIST command to print sample source
(B20), temperature (M210), sodium (M*IO),
potassium (M50), calcium (M60), and silica
(M.I 30).
3) Search the U.S. subset and seloct chenical
analyses records from Nevada.
*O Produce a tabular format of the Nevada
records including the same data elements
from the LIST command.
In order to illustrate the BACK command in this example,
the Nevada records will be selected from the U.S. subset
and output in tabular form. The U.S..subset is then called
back to be listed.
Input setup
// JCL
FORM
GEOTHERM
SELECT
A. B40<US>
LOGIC A
ITERATE
A. B60<NEVADA>
B. A30<B>
LOGIC A*B . '
-1*6-
Ci'i i
V \
B20 20
% x
M210 I
MHO 7
x »
M50 7
x %
M60 7
x x
Mi30 7
BACK
I
LIST
B20
M?iO
MMO
M50
M60
MI 30
9. E
xam
ple
3
SH
EC
T
A.
B40<
US
>C
OU
NTR
Y
CO
DE
,
ScA
RC
H?
?:2
4:5
l.l
SE
AR
CH
B
EG
INN
ING
?
0:2
*:5
6.5
S
EA
RC
H
CO
MP
LET
ED
SE
AR
CH
ED
1860
SE
LEC
TE
D
1*9
5
SU
BS
ET
VA
RIA
BLE
S
SA
TIS
FIE
D
A 1
VJ5
ITE
RA
TE
A.
860<
NE
VA
DA
>S
TA
TE
/PR
OV
INC
E.........
A30<
R>
RE
CO
RD
T
YP
E.
Lfr
.IC
A
*B
S=A
RC
H2
3:2
^:5
6.7
S
EA
RC
H
BE
GIN
NIN
G
23:2
5:2
2.9
S
EA
RC
H
CO
MP
LET
ED
SE
AR
CH
ED
1495
SE
LEC
TE
D
3^0
S
UB
SE
T
VA
RIA
BLE
S
SA
TIS
FIE
D
A B
CT
PY
« t
R23
2
0
t i
*210
1*
H40
7
i
H50
7
i i
38
6
1233
"Fig
ure
9, E
xam
ple
3
Ico
rrt'd
j
UC
K1 L
IST
M21
0
M^3
H50
M60
-1*9
-
Figu
re 9. Example 3
(cont'd)
90.0
90
.09
5.0
CA
RS
ON
(S
HA
W)
HO
T S
P
44
.M
MN
r.E
YSFR
B
OIL
ING
SPR
ING
21
-N9
5 .
6
SP
RIN
G
8
85
.*t
W?
R'S
M
AN
SIO
N,
NE
V
43
. S
1UT
H
ST
FA
MS
OA
T
WE
LL
WAR
M
^-S
5
2.
",S
-n
97
. 2
4?
97
.H
OT
SP
RIN
G
N N
EV
AO
HIT
S
PR
ING
. (
S H
IT
SP
RIN
G
ISS
UE
D
HIT
S
PR
ING
N
<iH
Al
I nw
R
ES
EA
RC
H
HE
L U
MN
iKC
Q
HO
T S
PR
ING
N
CF
YS
ER
S
PR
ING
S
SP
RIN
GS
L G
EY
SE
R
LftS
VF
C-S
.S
SP
RIN
GS
".
"Pit
VH
L6
W\R
M
SP
RIN
^?IV
!N
HTT
SPRI
NGS
( W
FLL
NFAR
HO
T SP
RIN
G
.= Y
SER
PANC
H SP
RIN
GS
HIO
SP
RING
PA
NACA
W
ARM
SPR
ING
S-t
ALL
OW
R
ES
EA
RC
H
WcL
S
IVN
AM
EO
H
IT
SP
RIN
G
I "S
TE
AM
" W
ELL
IKN
AH
EO
H
OT
SP
RIN
G
= LO
W IN
S
WE
LL
IN
ST
tL
UN
NA
ME
D
HO
T
SP
RIN
G
FLOW
ING
WELL
NEAR
'GE
UN
NA
ME
D
HO
T S
PR
ING
C C C C C C C C C
160.00
1000.00
110.00
35.9
744
682
806
866
37.3
66 ( 753
16.0
048.00
2.60
77 103
77 108
5.7
8.2
78
12.0
332. 00
1.30
10.9
TRAC
E6 6.8
13 7 6.7
15 5.9
11
165.00
160.
0090
.00
242.
0044 418
343
311
205
325
44 335
49-60.
60.
77.
BOILING
41.
79.
98.
1&-21.
29-31.
.
61.
77.
92.
29.
72.
97.
88.
66.
54.
80.
86.
56.
79 .
90.
54.
72.
.72.
5S.
49.
74.
7?.
C C C C C C C C C C C C C C C C C C C,
C C C C C C C C C C
774.3
741
282
282
130.95
239
295
300
250
540
160
180
I4fi
0277
450
170
81 340
463
120
45390
230
44200
238
250
150
165
66.9
91 53*38
33 17 31 38
80 13 20 42 1526
8.4
1.0
17 9.3
39 16
41 58 14
3633 34
22 26
30
6 46 46 100.
32 56 44 67 37
44
52 40
75 1.3
95 s. a
36
103
38 44
4.3
.2 31 25 6060
49 53 56
43 29 45
33 110
278.8
271
42 42 133.4
449
n 43
54 11
35 46
105
500
150
135
110
170
115
100
110
57 82 85 65 70
84
67 68
77 BO eo
66
65-5
0-
Figu
re 9« Example 3
(cont'd)
PAC
E 01
S4M
OLI
NG
T
EM
P....
100.0
<
a 4<
rl.O
O
K 1
3. O
Q .r.
i 0.1
0
S1D
2 3
03
.00
WAT
ER
SAM
PLIN
G
TE
MP
....
69.0
V
\ 6
03
.00
< 33. 0
3 CA
163.0
0
88.0
0
SAM
PLIN
G
TE
MP
....
52.0
U
87.0
3
K 9.Z
3r;
i3
.oo
SI3
2 108.0
.0
SAM
PLIN
G
TE
MP
....
83.0
ti
2B
8.0
0
K 21.0
0
CA
9.9
0
SI0
2
128.0
0
WA
TER
SAM
PLIN
G
TE
MP
....
22.0
NA
5
3.0
0
C 5.6
0
CA
18.0
35
9.0
0
WA
TER
SAM
PLIN
G
TE
MP
....
55.0
C
N4
14
50
.00
>C
61
.00
CA
5
33
.00
SI
02
'10
0.0
0
WA
TER
SAM
PLIN
G
TE
MP
....
77.0
C
NA
80
0.0
0
K 41
.03
CA
75.0
0
SIC
2 90.0
0
rfATE
R SA
HPL
INS
TE
HP
....
49.0
C
NA
51
.00
K
1.3
0
C4
2.0
0
SI
02
75.0
0
N4
83
.00
K 2.1
0CA
5.9
0-5
1-
i?. y n IP r> 1 e.
Objective - For Nevada analysis records use the SUM
command for temperature (M210), sodium (M^O),
potassiun (M50), caiciurn (f'60), and silica (fII30)
Input setup
// JCL
FORM
GSOTHERM
SELECT
A. B60<NEVADA>
B. A3rO<B>
LOGIC A*B
SUM
M210
M40
M50
M60
Mi 30 ' .
-52-
7i.r
u.r
e 10. E
xam
ple
SP
LcC
T
\.S
TA
TE
/PR
OV
INC
E.
RE
CO
RD
T
YP
E.....
LO
'tC
A
*B
SE
AR
CH
3:3
5:?
-). 9
S
EA
RC
H
BE
GIN
NIN
G
0:3
S:4
1.6
S
EA
RC
H
CO
MP
LET
ED
SE
AR
CH
ED
SE
LEC
TE
D
1860
3*0
SU
BS
ET
VA
RIA
BL
ES
S
AT
ISF
IED
A B
SUM
LAB
EL
M?1
D
"60
336
1339
<*)
234
29
0
275
Z73
260
SUM
15,7
60.5
1
03
,94
1.7
2
9,5
75.6
7
10,2
26.
I 3
0,7
63
.65
AV
E 67
.30
67
5358.
4L97
23
<t.
82
06
1
113.3
4096
MAX
186
lt51D
1
60
4
12
5"i
't
MIN 3 1
.73
O.I
B
0
GIP
SY
-
LW
msiT
Y
OF
.OK
LAH
OM
A
8:3
5
P.M
. T
UE
SD
AY
M
AR
CH
8,1
977
-53-