Submit Revised Field Manual, Groundwater Monitoring Program and Interceptor Ditch Operation

ML18227E200
Person / Time
Site:	Turkey Point
Issue date:	05/06/1976
From:	Gupton C, Knowles P Dames & Moore
To:	Sharon Tucker Florida Power & Light Co, US Atomic Energy Commission (AEC)
References
Download: ML18227E200 (74)
v • d • e

Text

FLORIDA POWER

& LIGHT COMPANY TURKEY POINT, FLORIDA GROUND-.WATER MONITORING AND

~ XNTERCEPTOR DITCH,OPERATION PROCEDURES i -,

~

4598-047-26

AHOHORAOC ATLANTA SCTHCSD*

CHICAOO C INC IN N ATI ORANTORD DCNVCR I'AIRSANKS HOUSTON LOS AHCCLCS NCW YORK PHOCNIX PORTLAND SALT LAKC CITY SAN YRAHCISCO SANTA SARSARA HONOLULU SCATTLC WASHINOTOH O C.

~~~/~gg ~

CONSULTANTS IN THC CNVIRONHCNTAI.AND APPLICD CARTH SCICNCCS CALO*RY PCRTH OUAH SCOUI JAKARTA SINOAPORC JOHANNCSSURO SYDNCT LAOOS TCHRAN LONDON TORONTO HADRID TOKYO VANCOUVCRqS,C 3OI WEST CAMINO GARDENS BOUI.EVARD

~ BOCA RATON, I. LORIDA 33+38 l305) 392-9070 TWX: BIO 9S3-7539 May 6, 1976 Florida Power

& Light Company P.O.

Box 013100 Miami, Florida 33101 Attention:

Mr. Samuel Tucker Field Manual Revised Groundwater Monitoring Program and Interceptor Ditch Operation Turkey'Point, Florida Florida Power

& Li ht Com an Gentlemen:

l We are pleased to submit this field manual for the revised Ground-water Monitoring Program, G-Well Series, and Interceptor Ditch Operation at Florida Power

& Light's Turkey Point Gener-ating Plant.

This manual. describes monitoring procedures for select G-wells, ID and L-wells and the operation of the Inter-ceptor Ditch.

This manual is for your review and approval prior to transmittal of copies to the Centraland Southern Florida Flood Control District (FCD),

Gee

& Jenson and Dade County agencies.

As was discussed at the April Quarterly Meeting with FCD, held on April 20, 1976 at the Turkey Point Generating Station, final written approval of the revised ground-water monitoring program w'll not be granted until FCD has approved this field manual.

It has been our pleasure to serve you in this manner.

Please contact us at your earliest convenience if you have any questions pertaining to the contents of this manual.

Yours very truly, CPG/PCK:sl DAMES

& MOORE Charles P. Gupton, P.E.

Porter-C.

Knowles, P.E.

Associate

.~

1.0 INTRODUCTION

This procedures manual applies to field work presently being conducted at Turkey Point for the Ground-water Monitoring Program west of the Cooling Canal System and Interceptor Ditch Operation.

l~

The procedures presented in this manual reflect agreements as of the April 20, 1976 Quarterly Meeting between Florida Power

& Light Company and Central

& Southern Florida Flood Control District.

Reference is also made to the original agreement between the abovementioned

parties, dated February 2, 1972.

2.0 KEY PARTICIPANTS The following tabulation gives the key parties involved in this project for Florida Power

& Light Company and their relative responsibilities:

~

~

C~om an Florida Power

& Light Co.

Environmental Department P.O.

Box 013100 Miami, Florida 33101 Res onsibilit Overall Program Direction and Contact Phone:

(305) 552-4064 Land Management Department P.O.

Box 013100 Miami, Florida 33101 Data Collection Phone:

(305). 552-3918 Dames

& Moore 301 W. Camino Gardens Blvd.

Suite A

Boca Raton, Florida 33432 Data Verification and Review Phone:

Q05). 392-9070 IDAMGS6 MOORS

3. 0 GROUND-WATER MONITORING PROGRAM 3.1 Monitorin L'ocations The'ollowing wells shall be monitored during this 4

program:

ID-A, ID-B, ID-C, ID-D and ID-E L-l, L-2, L-3, L-4, L-5 and L-6; G-6; G-7; G-21; G-27; G-28; G-35.

These wells are designated as to location on Plate 3.1.

3.2 Monitorin Fre uenc 4

The following tabulation presents the schedule of measurements for the respective wells listed in the preceeding section:

1st of every month - ID-A through ID-E L-1 through L-6 4

G 7i 21I 28'5 1st of January,

March, May and November G-6 and G-27 3.3 Parameters The following data shall be collected at e'ach well at the times specified in the preceeding section:

a.

Ground-water Elevation (ft.)

Measured inside the casing from top of casing.

Elevation of top of casing is known.

b.

Surface-Water Elevation (ft.) Measured outside the casing from top of casing.

c.

Conductivity (umhos)

Measured with depth to total well depth.

Readings shall be obtained at one Q) foot intervals.

d.. Temperature

( C)

Measured the same as conductivity.

e.

Water Sample Collection One water sample per well DAMSS 8 MOORS

should be obtained for laboratory titration of chloride ion content.

Depth of sample collection is not constant, but approximately half the water samples should be obtained from within the first twenty feet of the water column in the well.

Generally, this portion of the water column contains the transition from water of low chlorinity to water of higher chlorinity.

These

samples, in combination with

)

water samples from deeper

depths, should provide chloride data, which generally spans the entire spec-trum of chloride ion encountered.

3.4 Monitorin Procedure The following procedure shall be followed in collection of raw field data:

1.

Calibrate the Hydrolab TC-2 Conductivity-Temperature Meter prior to each day of the monitoring using two standard saline solutions of 15,000 umhos and 90,000 umhos.

The instrument shall be calibrated in ac-cordance with the procedures established in Section 3.7, Equipment Calibration.

2.

Measure both surface water elevation and ground-water surface elevation at each well by measuring from top of well casing.

3.

Insert Hydrolab probe to a depth of one (1). foot below water level in well; when meter needle stabilizes, read and record conductivity and temperature.

4.

Repeat procedure in Step 43 at intervals of one (1) foot to bottom of well.

DAMSS 8 MOORS

0

5.

Obtain water sample for chloride ion titration in accordance with recommendations in Section 3.3(e)..

Hater samples are obtained with a Masterflex Pump.

When taking a sample with the pump, a minimum of 800 ml of water from the desired sampling depth shall be pumped through the line to insure the sample is representative and not contaminated by water left in the line from a previous sampling station.

Sample water shall be pumped directly into clean, dry bottles which shall be tightly capped to prevent contamination of the sample.

6.

After monitoring every third well, the calibration of the Hydrolab probe shall be checked with the 90,000 umhos/cm standard saline'olution in accordance with procedures described in Section '3.7.

Note, however, that the instrument shall not be adjusted at this time.

7.

After each day of monitoring, the conductivity of the 90,000 umhos/cm standard solution and the calibration of the Hydrolab probe shall be checked in accordance with procedures in Section 3.7.

3.5 Data Verification Xn order to check the validity of the conductivity

data, the relationship of conductivity versus chloride is I

determined each month by regression analysis.

This analysis requires the use of an independent variable (true variable) and a dependent variable.

Chloride content determined by QAMSS S MOORS

0

laboratory titration is used as the true variable and the conductivity vaxiable is adjusted to the line of best fit by the method of least squares.

Therefore, for the conductivity-chloxide relationship to be valid for the determination of the position of isochlors, the chloride determination by laboratory titration must be correct.

In order to reduce the possibility of this source of errox, the raw titration data and raw conductivity data shall be immediately plotted on the historical conductivity-chloride relationship as shown on Plate 3.2.

The majority (75 percent} of the plotted raw data points should fall within the variance shown for the historical relationships.

The remaining 25 percent of the points. should be reasonably close to the historical relationship.

For conductivities less than 10,000

umhos, the historical relationships are less definitive.

For these conductivities, the ratio of the raw titration value (parts per thousand).

to the corresponding raw conductivity value (umhos/cm} should be reasonably close to the following historical ratios:

Conductivity umhos/cm Rat:io Less than 2000 2000 6000 6000 10000

0. 10.0

0. 237

0. 33.4 In addition to these two check methods, the raw points

should be inspected for direct proportionality.

In other words, the chloride content increases with increasing con-

ductivity.

Any two relative data points which reverse this relationship should be checked for probable error.

If, at any time, data is suspected to be in error, the following steps shall be taken:

l.

Retitrate the suspect water sample to determine chloride content.

Replot this titration data versus the corresponding conductivity data and reinspect for direct proportionality.

2. If data is still suspected to be in error after the retitration, then the well(s) in which the suspect data occurs shall be remonitored in accordance with the procedures set forth in Section 3.4.

The conductivity, temperature, water level and titration data shall be transmitted by phone to Dames 8 Moore in Boca Raton.

Dames 6 Moore will recheck the titration data for proportionality and variance from the historical relationship in accordance with methods presented in previous paragraphs.

The water level, temperature and conductivity data will be compared with the previous month's data and with historical data from periods of similar seasonal conditions.

(Water level fluctuation, precipitation and air temperature are among the factors to be considered when choosing times of similar seasonal conditions.)

If any water level, temperature and/or conductivity data exhibit abnormal

changes, the wells in which these changes occur will be remonitored in accordance with procedures set forth in.Section 3.4.

Suspect wells will be remonitored and checked until Dames a Moore is I

1 j

il PAMQS 8 MOORS

satisfied that the data represents actual ground-water conditions.

At this time, the data will be processed in accordance with Section 3.6.

The initiation of the monitoring each month shall allow sufficient time for checking suspect field data.

Therefore, the monitoring should be initiated at least five working days prior to the 1st of each month.

3e6 Data Processin The raw field data shall be entered on provided. standard forms.

This standard form is shown on Plate 3.3.

This form shall be filled out in triplicate.

Distribution of the data shall be in accordance with the following:

a.

Original To FPGL Environmental Department who will forward to FCD.

b.

One Copy Retain on file at Land Management offices at Turkey Point.

c.

One Copy Forward to Dames

& Moore in Boca Raton office.

Data shall be forwarded to FCD within-72 hours after the first day of each month.

Examples of completed forms are presented in the attached Appendix.

3.7 E ui ment Calibration The following calibration procedures apply to the Hydrolab TC-2 Conductivity-Temperature Meter'nd shall be followed '~striotl, during this program OAMSS 8 MOORS

0

Conductivit Calibration Prior to each day of monitor-ing, the instrument shall be calibrated in accordance with the procedures established hereinafter and the appropriate information entered on the Calibration Log (plate 3.4). in the space designated "Before Monitoring".

The calibration of the Hydrolab TC-2 conductivity meter is accomplished by the use of two potassium chloride,NC1}

solutions prepared in accordance with ASTM D1125-64, Standard Methods of Test for Electrical Conductivity of Water.

The procedure is as follows:

'a.

Prepare one solution of approximately 90,000 umhos conductivity.

1.

Dissolve approximately 60.0 g of KCl (weighed, in air) in tap or drinking water and dilute to 1 liter.

2.

Measure conductivity of solution with a Beckman RC-19 conductivity bridge using a certified cell to determine the "true" conductivity of the s'olution.

3.

Adjust Hydrolab unit to read the value obtained with the Beckman conductivity bridge.

b.

Prepare one solution of approximately 15,00Q umhos conductivity.

1.

Dissolve approximately 7.5Q g of KCl (weighed in air} in tap or drinking water and dilute to 1 liter.

2.

Measure conductivity of solution with Beckman RC-19 conductivity unit using certified cell.

3.

Read conductivity of solution with Hydrolab unit.

DAMQS8 MOOAQ

If the reading obtained with the Hydrolab unit differs from the reading for the low conductivity solution given by the Beckman unit by more than 1,000

umhos, the conductivity of the 90,000 umhos solution shall be rechecked with the Beckman unit and the procedure repeated.

Calibrating the meter with a solution of high conductivity reduces the percent error introduced when calibrating the instrument at the lower end of 'the conductivity range.

The 15,000 umhos solutions serve as a check on the accuracy of calibration at 90,000 umhos.

In order to insure that the instrument is maintained in calibration throughout each day of monitoring, the 90,000

'mhos/cm standard saline solution used in the initial calibration shall be carried to the field and the solution should be read after monitoring every third well.

The reading given by the instrument should be recorded on the standard calibration log (Plate 3.4} in spaces designated "During Monitoring".

However, the instrument shall not be adjusted in the field to the reading given by the standard solution.

Upon returning to the laboratory after each day of

. monitoring the conductivity of the 90,000 umhos/cm solution shall be checked with the Beckman RC-19 Bridge in order to assure that the conductivity of the standard solution has not changed throughout the day.

The standard solution shall

\\

then be read with the Hydrolab.

This calibration sequence shall be entered on the calibration sheet in the space labeled "After Monitoring".

easveas 8 svaoosaa

The calibration will be used to develop "drift curves" to be used in correcting the data.

If the "After Monitoring" Examples of "completed forms are presented in the attached a.

Turn the instrument to "temperature zero" and adjust calibration sequence yields a reading deviation exceeding five (5) percent of the total reading, the data shall be corrected using the drift curve.

In summary, the maximum "I

allowable reading deviation for a 90,000 umhos/cm solution 1

would be + 4,500 umhos/cm.

t I

le Appendix.

Tem erature Calibration The Hydrolab TC-2 temperature lI;,

meter standard for calibration is internal and the procedure used shall be as follows:

to read -5 C.

b.

Turn the instrument to "temperature calibrate" and adjust to read 45 C.

c.

Prepare two H20 solutions at temperatures of approxi-mately 20 C and 30 C.

d.

Compare the temperatures measured with the Hydrolab unit to those obtained with a highly accurate labora-tory thermometer.

e. If the Hydrolab and the thermometer agree within 0.5 C, the temperature meter is considered calibrated.

f. If the two do not agree, use the following procedure:

l.

Adjust the Hydrolab unit to read the measurement given by the thermometer in the 20 C solution. DAMSELS 8 IVEODRH

0

2.

Read the 30 C solution with the'Hydrolab unit and thermometer.

If the readings differ, adjust the Hydrolab unit to read the same as the thermometer.

3.

Again read the 20 C solution with both instruments.

If there is a difference, adjust the Hydrolab to equal the thermometer reading.

4.

Repeat, this alternating procedure until the Hydro-lab 'unit will read both solutions within 0.5 C.

'll-DAMSS 6 MOORS

G-3 G 2 8-I 000LI W (TCT t000 N00 0

000 G-l3 8-20A CONT AOL STAVCTISIt G-IO Sdl G l2 I. 3 G-9 IO 8 NORTH PUMP STATION

{PUMPS NO. I 8 N0.2I G-IT G-16 S-I 8 G I9 I.4 g

9-IS NOTEI PROPOSED MONITORING WELLS DESIGNATED BY RECTANGLE 0-27 G-24

~i-0 S25~

6 26

/

n G-23 IO 0 S 22 SOUTH PUMP STATION opUMps Na3 a Na4)

AAAAOX.

LOCATION 5 TO F

'INt A

T 8-32 I. 6 G-34~

r G-3I G-33 20 CONTSOL STISJCTLTIt G.30 LINt O

LTIt 5

I0.6 8 -29

~I~I

~W

~

~

PLOT PLAN OAMSO 0 MOO000 PlATK 5 ~ I

50

~ 20 O

U 10 IO 20 50 CONDUCTIVITY (pmhos/cm x IO~)

40 50 CONDUCTlVlTY-CHLORIDE RELATlONSHlP G-5'ELLS DAMES 0 MOORS ILATK 3,X

a~

WELL ID,

- HZZI (1-4)

I,.

TIME HIZI (20-23)

HARACTERISTI C (40-46)

GROUND WATER MONITORING PROGRAM FCD WELL SERIES TURKEY

POINT, FLORIDA GROUND WATER LEVELS (FT)

(DEPTH BELOW CASING)

(30-33)

MONTH-YY WATER ELEVATION (FT)

GROUND DATE (MN/DD/YY)

CHECKED BY r

CASING ELEVATION (FT.MSL)

(10-17)

RECORDER (25-27)

DATE IZZU (35-38)

SURFACE DEPTH BELOW CASING (FT)

COND.

lUMHOS/CM)

TEMP,

('C)

DEPTH BELOW CASING (FT)

COND..

{UMHOS/CM)

TEMP.

(

C)

DEPTH BELOW CASING (FT)

COND.

l UMHOS/CMI TEMP.

(

C)

(2)

(6)

(12)

(22)

(26)

(32)

(42)

(46)

(52)

PLATE 3.3

. INSTRU~'lENT CALIBRATION Instrument:

Date:

Time Calibration Data Parameter I

Before lionitoring (Laboratory)

Calibration Standard Heter Reading Heter Adjusted To Read:

Conductivit Temoera ture 2.

During Honitoring After Three hells After Six 5'.elis After Nine hells After Twelve Elells After Fifteen 7l lls 3.

After Honitoring (Laboratory)

Calibration Standard (Re-check standard solution w/Bechman RC-39)

Heter Reading Heter Deviation (from standard)

Correction Applied (explain)=

'4. 0 INTERCEPTOR DITCH OPERATION 4.1 Introduction The purpose of the Interceptor Ditch is to prevent inland movement of cooling canal water by maintaining a

seaward ground-water gr'adient during times when a natural seaward gradient does not exist.

During the wet season and the early part of the dry season, a natural seaward gradient usually does exist.

During the rest of the year,

however, it is necessary to artificially generate a seaward gradient east of Levee 31 Borrow Canal by pumping water out of the Interceptor Ditch.

The procedure for monitoring the ground-water gradient and operation of the Interceptor Ditch are presented in the following sections.

4.2 Monitorin Locations Surface water elevations shall be monitored at staff gages located in Cooling Canal 32, Levee 31 Borrow Canal and the Interceptor Ditch at five locations relative to Lines A,.

B, C, D and E, as shown on the inset, Plate 3.1.

Hhen pumping of the Interceptor Ditch commences, additional data shall be obtained at each of the two ID'pump stations.

Locations of the pump stations are also shown on Plate 3.1.

A generalized Interceptor Ditch pump station is shown on Plate 4.1.

Each station consists of two variable discharge pumps with the maximum capacity of each equaling 15,000 gpm. MMES 8 i%'TOO$ZD

0

charts, both of which are located in each discharge weir.

A pump rating curve relating water elevation (ft.) in the discharge weir versus pumping rate c ~

(gpm) is shown on Plate 4.2.

Stevens recorders Stevens continuous water level recorders shall be in operational mode at each pump discharge weir at commencement, of Xnterceptor Ditch pumping.

Procedure for operating the recorders are presented in the attached Appendix.

Shaded areas designate the applicable time and gage scales for these recorders.

4.5 Pum in Criteria As long as a natural seaward ground-water gradient

exists, pumping of the Xnterceptor Ditch is not required.

The following criteria defines when a natural seaward gradient exists and when the Xnterceptor Ditch must be pumped to create an artificial gradient east of Levee 31 Borrow Canal.

'Seaward Gradient A natural seaward gradient exists when the Levee 31 water surface elevation (ft.,

MSL) is greater than 0.2 feet higher than the water surface elevation (gt.,

MSL) in Cooling Canal 32.

Xf this criterion is not met, a natural seaward l'radient still exists if the water surface elevation (ft., MSL) in Levee. 31 is.greater than 0.3 feet 0

higher than the water surface elevation (ft., MSL) in the Interceptor Ditch.

I Landward Gradient If a seaward gradient condition is not met, then pumping of the Interceptor Ditch must'e initiated to artificially create such a seaward gradient.

Pumping rates shall be adjusted so that the water surface elevation (ft., MSL) in the Interceptor Ditch is on the order of 0.3 feet lower than the water surface elevation (ft., MSL) in Levee 31.

Pumping shall be terminated when the criteria for a natural seaward gradient is met. (see preceding subsection entitled Seaward Gradient).

The flow chart on Plate 4.3 depicts the requirements for pump operation.

This chart shall be referred to each time a set of water elevations is obtained to determine when II pumping is or is not required.

The above criteria apply to each section of,the Inter-ceptor Ditch, individually.

As can be seen on Plate 3.1, the pump stations divide the Interceptor Ditch into three segments.

Each segment is evaluated separately with respect to the operating criteria.

One section, therefore, might require pumping while another might not.

In those segments V

of the Interceptor Ditch where two lines of staff gages occur (the northern and the southern segments),

pumping shall be initiated when either one of the lines of staff gages fails to meet the specified criteria for a seaward VAWI~SQTv1OC'A~J

gradient.

Adjustable intake gates (stop-logs) in each pump intake basin allow for various pump combinations to diawdown specific Interceptor Ditch segments.

4.6 Data'rocessin Upon seasonal initiation of pumping of any section of the Interceptor Ditch, the Director of the Resources Planning Department, Central G Southern Florida Flood Control District.,

located in Nest Palm Beach, shall be immediately notified by telephone.

The data, as described in the preceding section, shall be submitted monthly to the Flood Control District.

The data shall be compiled on the provided forms.

These forms are shown on Plates 4.4, through 4.7.

Examples of completed forms are presented in the Appendix.

'I The forms shall be filled out in triplicate.

Distribu-tion shall be in accordance with the following:

a.

Original To FPGL Environmental Department who will forward to FCD.

b.

One Copy Retain on file at FPGL Land Management offices at Turkey Point.

c.

One Copy Forward to Dames 6 Moore in Boca Raton.

Data shall'e forwarded to FCD within 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> after the last day of the month. QAA4S 8 RVlCCÃt

4.7 E ui ment Maintenance Occassional cleaning of the staff gages is required when algae and other marine gxowths inhibit reading of the staff gages.

Care must be taken when cleaning to prevent, damage or movement to the staff gages.

When pumping of the Xnterceptor Ditch is required, Stevens continuous water level recorders must be operating in each pump discharge weir.

General operation and mainten-ance procedures for these recorders are given in the Appendix.

The specifications for the recorders located at the pump stations are highlighted on Appendix pages by shading of applicable information.

~

~

'NTERCEPTOR DITCH PUMP INTAKE STOP LOGS DISCHARGE WEIR VIATER t.EVE L RECORDERS DISCHARGE 15,0OO GPM PUMP INTAKE DISCHARGE WEIR DISCHARGE iS.OOO GIM IINITERCEPTOR DITCH

~ PERMANENT IO PUMP STA TloN GENERALIZED LAYOUT NOTE' BASING NOT TD SCALE

0

PERMANENT ID PUMPS R'ATING CURVE

4. I I

3.9 3.7 3.5 3.1 2.9 WEIR CREST O ELEVATIOM 6

8 IO OlSCHARGE OVER WEIR

( I,OOO G.P.M )

l2 I4 l6

>AMQS 43 AIOOCaca PLATE

4. 2

INTERCEPTOR DITCH PROGRAM OPERATIONAL FLOW DIAGRAM Re a L-,

an ana Water Level Elevations L-31 Elev.

Magnus C-32 Elev. Greater Than 0.20 'feet ev.

anus C-32 Elev. Less Than 0.20 feet Pumping o

ID Not Required or Terminated ompare an Elevations L-E ev.

Magnus ID Elev. Less Than 0.30 feet ev.

anus ID Elev. Greater Than 0.30 feet Pumping o

D Required to Increase Differential to 0.30 feet umping oz Not Required or Terminated NOTE:

This operating criteria applies to each line of staff gages.

In those sections of th'.'.Interceptor Ditch which contain two lines of staff gages, pumping shall be initiated for a segment when 'either one of the lines of staff gages indicates that pumping is required.

Pumping shall *be terminated in these sections wheno'th lines of staff gages indicate that pumping is not required.

PLATE 4.3

0

WATER LEVELS-LEVEE 3I, CANAL 3Z, INTERCEPTOR DITCH INTERCEPTOR DITCH PROGRAM MONTH/'YEAR LINE A LIIVE8 LIIYE C LINE D LIA'E E V L a g L.

o>

.)fL y

I Cf I

a" L

V L.

4)

I a

7 Ol I L 4.

Eu a

lo l2 l5 l6 t IF L-3I MINUS C-32 IS LESS THAN 0.2 FEET, THEN COMPLETE NEXT TllIO COLUMNS FLORIDA POWER 8 LIGHT CO.

1 OF tlATE 4A

WATER LEVELS-LEVEE 3I, CANAL 32, INTERCEPTOR DITCH INTERCEPTOR DITCH PROGRAM MONTH/YEAR LINE A LINE 8 LINE D LINE D LINE E 4

c c

cc.

k 6

cc a~c cc I

cl cc c

cc c

V

~ c cc

~) QL c

oR c

ccc 4 cc L

't 5 L W

cc.

ccc cc.

I cc.

ccc c

cc.

c ccc

'?

c~

o 4 c

ccc Vl cc c

cc.

g I

c c

~ cc L

~c a ccc ccl o

l7 IB l9 20 22 23 26 30 3l t IF L-3I MINUS C-32 IS LESS THAM 0.2 FEET, THEM COMPLETE NEXT TWO COLUMNS FLORIDA PAYER 8 LIGHT CO.

2 Ot tlATE 4.6

0

IrVTERCEPTOR DITCH PUAIP OPERATIOH AIOIITII/YEAR PVAP N2I PCS hXIf OAT OP IIORTII TIRE STATE CAGE REAOIVC CVV FROAI IO.

RATIRC SECTIOIV CORVE CEAVC ECPWl PC4PEO STATE CAGE AEAIVJVC IXCW PROV RATXVC CORVE

/GRAT EO.

SECTICV SEAVC PIANO STAFF CAGE REAO/RC IXOW FRCV RATIRG CCIAE EGPIII IC SECTIOW CECVC Pl/AOXP IX

/ROW RATIVC COAX'O.

SECIIOV SEGVC PICOT OCSDVVER 10 13 16 FLORIDA POWER 'B LIGHT CQ I OF 2 PLATE 6.6

INTERCEPTOR DITCH PIIIIIP OPERATION fEOIIFIT/'EAR PIFDP hC I OAT

'F TIVE STAIR GAGE READAIG W FROW ID.

RATING SEC TIOII CIIITE BEATS TGPIII TIVE STAfF GAGE REAODIG nOWTROV FATIDIC CVEtT (4PII'f ID.

SECTIOR GEIIIG 4TAIT CAGE REAOIIIG now IIKw RATIRC CV~

IGPIII IR SEC TIOII OEDIG PVAOYD TIVE STAFF CAGE AEADRC IZAYIIINI RDItHC TGPILI I.D.

SECTIOIl SllVC PCIWCP IB I9 2I 22 24 3I FLORIDA POJYER 8 LIGHT CQ 20F2 PLATE 4.7

APPENDIX

GROUND WATER MONITORING PROGRAM FCD WELL SERIES TURKEY

POINT, FLORIDA ELL ID

-A

{1-4)

{20-23)

CHARACTERISTI C

{40-46)

g. go MONTH-YY WATER ELEVATION {FT)

GROUND DATE {MN/DD/YY)

CHECKED BY 6 I /0 7 (

CASINO SLSVATION (FT.MSLI

{ 10-17)

RECORDER GROUND WATER LEVELS {FT)

{DEPTH BELOW CASING)

{25-27)

{30-33)

DATE SURFACE

{35-38)

SURFACE DEPTH BELOW CASING (FT)

~

COND.

) UMHOS/CM)

TEMP.

(

C)

DEPTH BELOW CASING (FT)

COND.

lUMHOS/CM)

TEMP.

(

C)

DEPTH BELOW CASING (FT)

COND.

l UhlHOS/CM)

TEMP.

(. c) o:z 3,

12 00 Ob g 4 o:'iZ<

~

do:-

oj 06 oO zr.

zf.

zr, zf.

(2)

(6)

(12)

(22)

(26)'32)

(42)

(46)

(52)

PLATE 3 3

XNSTRU;1ENT CALXBRATZON Instrument:

Date:

Calibration Data Pa ameter 3 fore Monitoring {Laboratory)

Calibration Standard Meter Reading Heter Adjusted To Read=

Conductivit Terna rature il~

~

~

2.

During Monitoring After Three Tlells After Si>: bells After Nine Hells After Twelve He After Fifteen t elis t/~oa

//OQO 9ioaa

/0 OOQ 3.

After Monitoring (Laboratory).

Calibration Standard

{Re-check standard solution w/Bechman RC-39)

Meter Reading Meter Deviation (from standard)

Correction Applied {explain)=

92 AC 8'Poaa Boo&

PLATE 3

4

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0 0

BULLETIN 12 24th Edition Leupold a Stevens, Inc.

600 N.W. Meadow DrIve, Beavestoa, oregon Phoae: Area Code $03/646-917 IsaaIIIav address)

?.C. B"z 66 Beav orion. Ore-oa. U.S.A. 9700 FIG. 1A FIG. 18

... an accurate, dependable instrument that provides continuous, long-term records, for:

H STREAM GAGING H WATER SUPPLY K3 GROUND WATER STUDIES H I R RIGATION 4

+

2-As <<h 'l+w4

~

1 Q~ 'vjy

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~... provides continuous, unattended recording with high accuracy regardless of range Q Unlimited Range in Stage E3 Easy Field Change of Chart Speed and Recording Ratio El Easy Chart Changing H Many Months Unattended Operation from Mechanical Power The earliest model of this instrument was the pioneer con-tinuous water stage recorder. Constant improvements since the year 1911 perfected through field use and the skill gained over a half century of manufacturing precision engi-neering instruments have made it the preferred recorder for river hydrography, and for any installation where long term operation is required or in which wide fluctuations in water levels occur.

Operation is Simple Reduced to its basic function, the recorder accomplishes the following:

A strip chart is moved at a predetermined rate controlled by a clock movement. A marking stylus moves laterally across the chart in direct prooortion to changes in water level.

Thus, the result is a graphic record of water levels against time.

A single strip chart will last from 25 hours2.893519e-4 days <br />0.00694 hours <br />4.133598e-5 weeks <br />9.5125e-6 months <br /> to 2 years, de-pending upon gearing and type of chart drive. Both English and nlefric models are offered.

FIG. 2 Unlimited Range Reversal of the marking stylus at each margin assures unlim-ited range without interruption, or reduction in scale. For easier interpretation, an optionci reversal indicator can be installed at the factory-or in the field. The stylus marks the chart so that reversals on rising stages can be distinguished from falling stages (See Optional Equipnterfrj.

0.01 Foot (3mm) Sensitivity The recorder mechanism is precision-made and ball-bearing equipped as necessary to respond to 0.01 ft. change at 1:6 scale, using a 10-in. float.

The Stevens Type A Water. level Recorder shown on the front cover has optional float tape, spined float pulley and index bracket for direct indication of levels. Illustrated here is the standard model, with beaded float line and standard pulley. Note one. piece, gasketed cover, with viewing port.

Choice ofDrives and Clocks A universal driving bar (outside the clock case) engages pins on the time scale gears of the recorder to move chart at constant speed.

Clocks are interchangeable in the field, without special tools.

0

Negator Spring Drive with Chelsea Clock-for time scales up to 4.8 inches/day. Negator spring drive will operate recorder for 4th months, regardless of time scale (from l.2 through 4.8 inches/day J selected. On special order drives for 6 months may be obtained. Chelsea clock contains an I I.jewel marine move.

ment, housed in sealed case, without dial. The escapement is always visible through a glass port.

Synchronous Motor Drive-for time scales up to 864 inches per day. For AZ operation only.

Where water flow is artificially controlled (such asin the fore-bays and tailraces of power plantsJ a faster time scale is de-sirable for making the record of the wide and rapid fiuctua-tions more legible. In all cases, the slowest time scale consis-tent with legibilityshould be used.

TAB LE 1

Time Scales with Chelsea Clock

{Negator Spring or Weight Drivenl Weight Drive with Chelsea Clock-for time scales 1.2 through 9.6 inches/day. A 12-pound weight drives the instrument. The weight drops from 4.7 to 5.7 feet per month, depending on time scale, and this can be reduced by increasing the weight and interposing movement reduction sheaves in the clock weight cable.

Scale Designation (incheslday) 1.2 2.4 Major (1Z inches)

Minor (0.1 inch) 24 hrs.

12 hrs.

2 hts.

1 hr.

Value of Chart Divisions 25-yard Strip Chart lasts 2 years 1 year 4.8 7.2 e 9.6 6 hrs.

4 hrs.

3 hrs.

30 min.

20 min.

15 min.

6 mos.

4 mos.

3 mos.

Choice of Float Line or Oirect-Reading Graduated Tape both of Stainless Steel 1.2 24 hrs.

2 hrs.

2 years

+Weight Driven Only Time Scales with Synchronous Motor Clock.

Beaded Float Line. Geometrically wound, non-twisting cable, 0.04 in. dia., is standard equipment.

Beads crimped on at uniform intervals of 6" (12.5 cm) match recesses in fioat pulley for non.slip operation. (see Fig. 3.)

2.4 4.8 7.2 9.6 12 hrs.

6 hts.

4 hts.

3 hrs.

1 hr.

30 tnin.

20 min.

15 min.

1 year 6 mos.

4 mos.

3 mos.

Optional Float Tape. Used when visual reading of gage heights

-in addition to recording-is desirable.

Graduated in feet,