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Semiannual Radioactive Effluent Release Rept for Browns Ferry Nuclear Plant,Radiological Impact Assessment Rept,For Jan-June 1990
	ML18033B611
Person / Time
Site:	Browns Ferry
Issue date:	06/30/1990
From:	; TENNESSEE VALLEY AUTHORITY
To:	;
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ML18033B610	List: ML18033B609; ML18033B611; ML18033B612;
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ENCLOSURE 1 TENNESSEE VALLEY AUTHORITY SEMI-ANNUAL RADIOACTIVE EFFLUENT RELEASE REPORT BROWNS FERRY NUCLEAR PLANT RADIOLOGICAL IMPACT ASSESSMENT REPORT JANUARY THROUGH JUNE 1990 9i02040309 900830 PDR

.ADOCK 05000259 R

PETER

Enclosure 1

Page 1 of 53 Radiological Impact Assessment Browns Ferry Nuclear Plant January June 1990 I

OUC 0

Potential doses to maximum individuals and the population around Browns Ferry are calculated for each quarter. as required in Section F.2 of the Radiological Effluent Manu'al.

Measured plank releases for the reporting period are used to estimate these doses.

Dispersion of radioactive effluents in the environment is estimated in accordance with the guidance provided by Regulatory Guides 1.109, l.illand 1.113 using meteorological data and riverflow data measured during the period.

Using dose calculation methodologies which are described in detail in the Browns Ferry Offsite Dose Calculation Manual, the doses are calculated and used to determine compliance with the dose limits contained in Browns Ferry's Operating License'.

In this report, the doses resulting from releases are described and compared to quarterly and annual limits established for Browns Ferry.

SUMMARY

OF LI UID A GASEOUS EFFLUE RELEASES F RST HAL 1

0 Although nuclear plants are designed to contain the radioactive material created by the fission process, small amounts of this material escape from the fuel rods.

Also, very small amounts of the structures and components of the systems become activated through the bombardment of neutrons and are worn away.

This radioactive material can be transported throughout plant systems and released to the environment.

rborne Re eases The noble gas fission products do not mix with water and are given off in a gaseous form.

A very small amount of solid radioactivity is given off along with these noble gases.

The most significant releases are processed so that the radioactive material is filtered and/or decayed prior to release through the plant vents.

Sampling and monitoring methods are used to determine the amount of radioactive material released.

If these methods indicate that.

radioactivity in airborne effluents is above preset limits, then releases are terminated.

Airborne releases* for each quarter in the period are given in Section 1 of this submittal.

u" Some small amounts of radioactive material migrate into the primary coolant water.

The primary coolant water is routed through a~urification system to remove most of these particles; however, not all are removed.

Some of the radioactive liquids may leak from pipes or valves in the system.

These liquids are collected in floor

0

Enclosure 1

Page 2 of 53 and equipment drains and sumps.

The collected liquids are then processed through a clean-up

system, composed of storage tanks, recycling systems, and demineralizers, to remove contaminants.

The purified water is then monitored to determine the amount of radioactive material remaining in the water prior to its release.

Steps are taken to ensure that the amount of radioactivity released to the environment is as low as reasonably achievable (ALARA). If the levels of radioactivity are above preset limits, the releases are circulated through the clean-up system again for additional processing.

All radioactivity released from the~plant into the Tennessee River is quantified prior to release.

Liquid releases for each quarter in the period are given in enclosure 1 of this submittal.

Effluent Monitor n Plant paths through which radioactivity is released are monitored.

These monitors record the radiation levels for each release.

Monitors which are used for liquid releases will automatically alarm and stop any release which is above regulatory limits.

Gaseous release monitors also provide alarming mechanisms to allow for the termination of any release above limits.

DOSE L S

The U.S. Nuclear Regulator Commission (NRC) requires nuclear power plants to be designed, built, and operated in such a way that the levels of radioactive material released into unrestricted, areas is as low.as reasonably achievable (ALARA).

To ensure that this is done, the plant's operating license includes Technical Specifications which govern the release of radioactivity.

These Technical Specifications specify limits for the release of radioactive effluents, as well as limits for doses to the general public from the release of these-effluents.

These limits are set well below the NRC 10CFR20 limits which govern the concentrations of radioactivity and exposures permissible in unrestricted areas.

This ensures that'radioactive effluent releases are ALARA.

The Technical Specification limits for doses at or beyond the site boundary from airborne noble gases releases are:

Less than or equal to 5 mrad per quarter and 10 mrad per year (per reactor unit) for gamma radiation, and-Less than or equal to 10 mrad per quarter and 20 mrad per year (per reactor unit) for beta radiation.

Enclosure 1

Page 3 of 53 The Technical Specification limit for the dose to a m'ember of the general public at or beyond the site boundary from iodines and particulates released in airborne effluents is:

Less than or equal to 7.5 mrem per quarter and 15 mrem per year (per reactor unit) to any organ.

The Technical Specificati'on limit for doses to a member of the general public from radioactive material in liquid effluents released to unrestricted areas, is:

Less than or equal to 1.5 mrem per quarter and 3 mrem per year (per reactor unit) to the total body, and Less than or equal to 5 mrem per quarter and 10 mrem per year (per reactor unit) to any organ The EPA limits for total dose to the public in the vicinity of a nuclear power plant, established in the Environmental Dose Standard of 40 OFR 190, are:

Less than or equal to 25 mrem per year to the total body, Less than or equal to 75 mrem per year to the thyroid, Less than or equal to 25 mrem per year to any other organ.

DOSE CALCULATIO S Estimated doses to the public are determined using computer models (the Gaseous Effluent Licensing Code, GELC, and the Quarterly Water Dose Assessment

Code, QWATA).

These models are based on guidance provided by the NRC (in Regulatory Guides 1.109, 1.111 and 1.113) for determining the potential dose to individuals and populations living in the vicinity of the plant.

The area around the plant is analyzed to determine the pathways through which the public may receive a dose.

The doses calculated are a representation of the dose to a "maximum exposed individual."

Some of the factors used in these calculations (such as ingestion rates) are maximum values.

Many of these factors are obtained from NUREG/CR-1004.

The values chosen will tend to overestimate the dose to this "maximum" person.

The expected dose to actual individuals is lower.

The calculation methods and results of the calculations are presented in the following sections.

i,

Enclosure 1

Page 4 of 53 DOSES 0

A BO NE E VENTS For airborne effluents, the public. can be exposed to radiation from several sources:

direct radiation from the radioactivity in the air, direct radiation from radioactivity deposited on the ground, i

inhalation of airborne radioactivity, ingestion of vegetation which contains radioactivity deposited from the atmosphere, and ingestion of milk and beef which contains radioactivity deposited from the atmosphere onto vegetation which is then eaten by milk and beef animals.

The concentrations of radioactivity in the air and the soil are estimated by the computer model GELC which uses the actual meteorological conditions to determine the distribution of the effluents in the atmosphere.

Again, as many of the parameters as possible are based on actual site specific data.

The model that is used to estimate

dose, as well as the paramete'rs input to the model, is described in detail in Section 1.0 of the Browns Ferry Nuclear Plant Offsite Dose Calculation Manual.

irbo e Re ease Poi ts a d Meteorolo cal Data Meteorological variables at Browns Ferry are measured continuously.

Measurements collected include wind speed, wind direction, and temperature at heights 'of 10, 46 and 91 meters above the ground.

Quarterly joint frequency distributions (JFDs) are calculated for each release point using the appropriate levels of meteorological data.

A joint frequency distribution gives the percentage of the time in a quarter that the wind is blowing out of a particular upwind compass sector in a particular range of wind speeds for a given stability class A through G.

The wind speeds are divided into nine wind speed ranges.

Calms are distributed by direction in proportion to the distribution of noncalm wind directions less than 0.7 m/s (1.5 mph).

Stability classes are determined from the vertical temperature difference between two measurement levels.

There are four routine release points from Browns Ferry Nuclear Plant:

the turbine building, the radwaste building, the reactor building, and the stack.

Enclosure 1

Page 5 of 53 Releases from the turbine building are considered ground-level releases to determine the dispersion of the airborne effluents.

The ground-level JFD is derived from windspeeds and directions measured 10 meters above ground and from the vertical temperature difference between 10 and 46 meters.

Releases from the radwaste and reactor buildings are considered split-level releases to determine the dispersion of the airborne effluents.

This means that portions of the release are treated as elevated while other portions are considered ground-level depending on the ratio of the vertical exit velocity to the horizontal wind speed.

The split-level dispersion approach is implemented using a model that requires two complete quarterly JFDs for each effluent vent, one for the elevated releases and one for the ground-level releases.

The ground-level portion of the split-level JFD is based on wind speeds and directions measured 10 meters above ground-level and from the vertical temperature difference between 10 and 46 meters.

The elevated portion of the split-level JFD is based on wind speeds and direction measurements at the 46-meter level and the vertical temperature difference between 46 and 91 meters.

Releases from the stack are considered elevated-level releases to determine the dispersion of the airborne effluents..

The JFDs for elevated releases are based on wind directions and wind speeds measured at 91 meters and the vertical temperature difference between 46 and 91 meters.

The generally open terrain around BFN is not believed to cause any significant effects on the transport and dispersion of gaseous effluents from the plant.

Within 30 kilometers of BFN, the terrain is mostly gently rolling hills (30 meters).

Between 30 and 80 kilometers the hills become larger to the north and south, and mountainous to the east and northeast.

The Tennessee River/Wheeler Lake may have a minor effect on transport and dispersion in the immediate vicinity of BFN during periods of winds with a southerly component, overcast skies, and r'elatively high wind speeds.

Then, the lower layer (10-46 meters) stability class tends to be more stable than would be expected.

However, during this infrequent condition, dose estimates will be conservative.

Enclosure 1

Page 6 of 53 xternal Ex osure Dose Ai bo e Ef lue ts Dose estimates for maximum external air exposures (gamma-air and beta-air doses) are made for points at and beyond the site boundary.

These doses are calculated for all receptor points shown on Table 3.

The reported dose is chosen for the offsite location with the highest calculated exposure during the quarter.

The doses calculated for Browns Ferry Nuclear Plant for each quarter are shown below.

Individual Doses from Airborne Effluents External Air Exposures (mrad)

Dose Location F

st ua e

y Air dose O.OE-OO mrad 8 Air dose O.OE-OO mrad All locations All locations t

'Second uarter y Air dose O.OE-OO mrad O'ir dose O.OE-OO mrad All l'ocations All locations

Enclosure 1

Page 7 of 53 Sub e s on Dose bo e Effluents External doses to the skin and total body, due to submersion in a cloud of noble gases, are estimated for the nearest residence in each sector.

These doses are calculated based on the reported releases for noble gases for all receptor points shown on Table 3.

The highest of these exposures is chosen and is assumed to be the maximum individual dose.

The submersion doses calculated for Browns Ferry Nucl'ear Plant for each quarter are shown below.

Individual Doses from Airborne Effluents Submersion Exposures (mrem) irst ua ter Dose Location Total Body Skin O.OE-OO mrem O.OE-OO mrem All locations All locations Second uarter l Total Body Skin O.OE-OO mrem O.OE-OO mrem All locations All locations

Enclosure 1

Page 8 of 53 t

Or a Dose Ai bo e E f ue ts Internal doses to organs due to releases of airborne effluents are estimated for the inhalation, ground contamination, and ingestion pathways.

The ingestion pathway is further divided into four possible contributing pathways:

ingestion of cow/goat milk, ingestion of beef, and ingestion of vegetables.

Doses from applicable pathways are calculated for each real receptor location defined in Table 3.

Doses are calculated based on the reported iodine and particulate releases.

To determine the maximum organ dose, the dose contribution from the three pathways are summed for each receptor.

For the ingestion dose, however, only those pathways that exist for each receptor are considered in the sum, i.e., milk ingestion doses are included only for locations where milk is consumed without commercial preparation and vegetable ingestion is included only for those locations where a garden is identified.

To conservatively account for beef ingestion, a beef ingestion dose equal to that for the highest site boundary location is added to each identified receptor.

For ground contaminati'on, the dose added to the organ dose being calculated is the total body dose calculated for that location, i.e., it is assumed that the dose to an individual organ is equal to the total body dose.

The organ doses calculated for Browns Ferry Nuclear Plant for each quarter are shown below.

Individual Doses from Airborne Effluents Maximum Organ (mrem)

Organ Age Group Dose Thyroid Child 1.2E-05 mrem Individual Pathway Contributions:

Vegetable Ingestionl 8.2E-06 Beef Ingestion 2

3.7E-07 Inhalationl 3.0E-06 Ground Contaminationl O.OE-00 Milk Ingestion N/A Seep d

ua te Bone Child 9.9E-04 mrem Individual Pathway Contributions:

Vegetable Ingestion3 8.6E-04 Beef Ingestion4 2.8E-05 Inhalation3 3.3E-06 Ground Contamination3 9.4E-OS Milk Ingestion N/A Maximum real receptor is located at Calculated for the site boundary at 3 Maximum real receptor is located at

" Calculated for the site boundary at 1829 meters in the NHW sector.

1650 meters in the NNM sector.

1672 meters in the NNW sector.

1525 meters in the N sector.

Enclosure 1

Page 9 of 53 Dose Summa Airborne Eff uents The table below gives a comparison. of the calculated quarterly doses to their respective limits.

Doses from Airborne Effluents First Half 1990 Browns Ferry Nuclear Plant Dose Pathway Airborne-Gamma air Dose Quarter Dose 1

O.OE-OO mrad 2

O.OE-OO mrad Quarterly Limit*

5 mrad Percent of Limit 0

0 Airborne-Beta air Dose 1

O.OE-OO mrad 2

O.OE-OO mrad 10 mrad 0

0 Airborne-Max Organ Dose 1

1.2E-05 mrem 2

9.9E-04 mrem 7.5 mrem

< 1 1

Since airborne releases are quantified on a per site basis, and the Technical Specification dose limits are given on a per unit basis, calculated airborne doses are initially compared to the per unit limit.

If this limit is exceeded, the release data is reanalyzed to determine which portion of the releases were attributable to each reactor unit.

Then these per unit releases can be used to calculate per unit doses which are compared to the per unit dose limits.

As is shown by the table, all calculated quarterly doses were well below the allowable limits established in Browns Ferry's Technical Specifications.

For a comparison to previous releases and doses, graphs are presented as Figures 1

and 2 which show corresponding airborne releases and doses for the period 1980 to the present.

Enclosure 1

Page 10 of 53 DOSES FROM LI U D EFFLUENTS For liquid effluents, the public can be exposed to radiation from three sources:

the ingestion of water from the Tennessee

River, the ingestion of fish caught in the Tennessee

River, and direct exposure from radioactive material deposited in the river sediment (recreation).

The concentrations of radioactivity in the Tennessee River are estimated by a computer model whi.ch uses measured hydraulic data downstream of Browns Ferry.

Parameters used to determine the doses are based on guidance given by the NRC, (in Regulatory Guides 1.109) for maximum ingestion rates, exposure

times, etc.

Wherever possible, parameters used in the dose calculation are site specific use factors determined by TVA.

The models that are used to estimate

doses, as well as the parameters input to the models, are described in the Browns Ferry Nuclear Plant Offsite Dose Calculation Manual.

L u d Re ease Points a d Rive Data Radioactivity concentrations in the Tennessee River are calculated assuming that releases in liquid effluents are continuous.

All routine liquid releases from Browns Ferry, located at Tennessee River Mile 294, are made through diffusers which extend into the Tennessee River. It is assumed that releases to the river through these diffusers will initially be entrained in one-fifth of the water which flows past the plant.

The QWATA code makes the assumption that this mixing condition holds true until the water is completely mixed. at the first downstream dam, at Tennessee River Mile 283.0.

The average river flows past the plant site were 122,875 ft3/s for the first quarter of 1990 and 34,054 ft3/s for the second quarter.

Dose Estimates Li uid E fluents Doses are calculated for recreation, consumption of fish, and drinking water for locations between the plant site and the mouth of the Tennessee River.

The maximum potential recreation dose is calculated for a location immediately downstream from the plant outfall.

The maximum individual dose from ingestion of fish is assumed to be that calculated for the consumption of fish caught anywhere between the plant and the first downstream dam (Wheeler Dam).

The maximum individual. dose from drinking water is assumed. to be that calculated at the nearest downstream public water supply

Enclosure 1

Page 11 of 53 (Champion Paper Company).

This could be interpreted as indicating that the maximum individual, as assumed for liquid releases from Browns Ferry, is an individual who obtains all of his drinking water at the Champion Paper

Company, consumes 21 kg (6.9 kg for a child) per year of fish caught from the Tennessee River between BFN and Wheeler

Dam, and spends 500 hours0.00579 days <br />0.139 hours <br />8.267196e-4 weeks <br />1.9025e-4 months <br /> per year standing on the shoreline gust below the outfall from Browns Ferry.

Dose estimates for the maximum individual due to liquid effluents for each quarter in the period are presented below.

Individual Doses from Liquid Effluents (mrem) rst ua e

Organ Total Body Age Group Adult Dose 2.3E-03 mrem Individual Pathway Contributions:

Water Ingestion 9.9E-06 Fish Ingestion 2.2E-03 Recreation 1.6E-04 Liver Teen 3.4E-03 mrem Individual Pathway Contributions:

Water Ingestion 1.4E-05 Fish Ingestion 3.3E-03 Recreation 1.6E-04 Second uarter Total Body Adult 2.3E-02 mrem Individual Pathway Contributions:

Water Ingestion 1.1E-04

~ Fish Ingestion 2.2E-02 Recreation 1.6E-03 Liver Teen 3.5E-02 mrem Individual Pathway Contributions:

Water Ingestion 1.5E-04 Fish Ingestion 3.3E-02 Recreation 1.6E-03

i

Enclosure 1

Page 12 of 53 t

Dose Summa i uid Ef lue ts The table below gives a comparison of the calculated liquid doses for the period to their respective quarterly limits.

Doses from Liquid Effluents First Half 1990 Browns" Ferry Nuclear Plant Dose Pathway Quarter Dose Quarterly Limit*

Percent of Quarterly Limit Liquid-Max Organ Dose 1

3.4E-03 mrem 2

3.5E-02 mrem Liquid-Total Body Dose 1

2.3E-03 mrem 2

2.3E-02 mrem 4.5 mrem 15 mrem

< 1

< 1 1

1%

The quarterly limit for liquid doses is the total site dose limit (the one-unit dose limit times 3).

This is because,all liquid radwaste systems are common to all 3 units and the releases cannot be attributed to one particular reactor unit.

As is shown by the table, all calculated quarterly doses were well below the allowable limits established in Browns Ferry's Technical Specifications.

For a comparison to previous releases'and

doses, graphs are presented as Figure 3

which shows corresponding liquid releases and doses for the period 1980 to the present.

Enclosure 1

Page 13 of 53 OP A

0 DOSES Population doses for highest exposed organ due to airborne effluents are calculated for an estimated 627,000 persons living within a 50-mile radius of the plant site.

Ingestion population doses are calculated assuming that each individual consumes milk, vegetables, and meat produced with the sector annulus in which he resides.

Doses from external pathways and inhalation are based on the 50-mile human population distribution.

Population doses for total body ~and the maximum exposed organ due to liquid effluents are calculated for the entire downstream Tenne'ssee River Population.

Mater ingestion population doses are calculated using actual population figures for downstream public water supplies.

Fish ingestion population doses are calculated assuming that all sport fish caught in the Tennessee River are consumed by the Tennessee River population.

Recreation population doses are calculated using actual recreational data on the number of shoreline visits at downstream locations.

Population dose estimates for airborne and liquid effluents are presented below.

owns e

uc ea Plant Po u at o

Dose

st a

1 First Quarter 1990 Total Body Dose Maximum Organ Dose (organ)

Liquid Airborne 1.4E-02 man-rem 1.9E-04 man-rem 2.4E-02 man-rem (liver) 1;9E-04 man-rem (thyroid)

Second Quarter 1990 Liquid Airborne 1.8E-01 man-rem 3.5E-04 man-rem 2.8E-Ol man-rem (liver) 5.7E-04 man-rem (thyroid)

Population doses can be compared'o the natural background dose for the entire 50-mile population of about 56,430 man-rem/yr (based on 90 mrem/year for natural background).

Enclosure 1

Page 14 of 53 DIREC D

0 External gamma radiation levels were measured by thermoluminescent dosimeters (TLDs) deployed around BFN.

The quarterly gamma radiation levels determined from these TLDs during this reporting period averaged approximately 17.1 mR/quarter at onsite stations and approximately 15.3 mR/quarter at offsite

stations, or approximately 1.8 mR/quarter higher onsite than at offsite stations.

This is consistent with levels reported at TVA's nonoperating nuclear power plant construction'ites where the average radiation levels onsite are generally 2-6 mR/quarter higher than the levels offsite.

This may be attributable to natural varidtions in en'.ronmental radiation levels, earth moving activities onsite.

the mass of concrete employed in the construction of the plants, or other undetermined influences.

Fluctuations in natural background dose rates and in TLD readings tend to mask any small increments which may be due to plant operations.

Thus, there was no identifiable increase in dose rate levels attributable to direct radiation from plant equipment and/or gaseous effluents.

DOSE TO E

S OF UB C

S SI BOUNDAR No routine activities within the site boundary by members of the public have been identified which would lead to their radiation exposure.

t

~TOTAL DOS To determine compliance with 40 CFR 190, annual total dose contributions to the maximum individual from BFN radioactive effluents and all other nearby uranium fuel cycle sources are considered.

The annual dose to any organ other than thyroid for the maximum individual is conservatively estimated by summing the following doses:

the total body air submersion dose for each quarter, the critical organ dose (for any organ other than the thyroid) from airborne effluents for each quarter from ground contamination, inhalation and ingestion, the total body dose from liquid effluents for each quarter, the maximum organ dose (for any organ other than the thyroid) from liquid effluents for each quarter, and any identifiable increase in direct radiation dose levels as measured by the environmental monitoring program.

This dose is compared to the 40 CFR 190 limit for total body or any organ dose (other than thyroid) to determine compliance.

Enclosure 1

Page 15 of 53 The annual thyroid dose to the maximum individual is conservatively estimated'y summing the following doses:

the total body air submersion dose for each quarter, the thyroid dose from airborne effluents for each quarter, the total body dose from liquid effluents for each quarter, the thyroid dose from liguid,effluents for each quarter, and any identifiable increase in direct radiation dose levels as measured by the environmental monitoring program.

This dose is compared to the 40 CFR 190 limit for thyroid dose to determine compliance.

Cumulative annual total doses are presented in the following section of this report.

Total Dose from Fuel Cycle Calendar Year 1990 Browns Ferry Nuclear Plant Dose

, Total Bod (ex t thy O.OE-OO 1.2E-05 2 'E-03 3.4E-03 O.OE-OO First Quarter or an 0

an Dose (mrem) cep roid)

Total body air submersion dose Maximum organ dose (airborne)

Total body dose (liquid)

Maximum organ dose (liquid)

Direct radiation dose Second Third Quarter Quarter O.OE-OO (1) 9.9E-04 2.3E-02 3.5E-02 O.OE-OO Fourth Quarter Total 5.71E-03 5.90E-02 Cumulative Total Dose (Total Body or other organ) mrem 6.47E-02 RTotal body air submersion dose Thyroid dose (airborne)

Total body dose (liquid)

Thyroid dose (liquid)

Direct radiation dose O.OE-OO 1.2E-05 2.3E-03 1.6E-04 O.OE-OO O.OE-OO 1.0E-04 2.3E-02 1.6E-03 O.OE-OO Total (Thyroid) 2.47E-03 2.47E-02 Cumulative Total Dose (Thyroid) mrem 2.72E-02

Enclosure 1

Page 16 of 53

~

CO CITS'~0 As a resul t of operation of Browns Ferry Nuclear Plant for the second half of 1989, radioactive effluents were released to the atmosphere-and the Tennessee River.

The released radioactivity resulted in estimated potential doses to the public which are well below the Technical Specification Limits and Regulatory Guidance.

Cumulative doses for the calendar year are given below along with a comparison to the respective annual limits for the doses.

Cumulative Doses from Effluents Calendar Year 1990 Browns Ferry Nuclear Plant Percent of Annual Limit Dose Dose Pathway Airborne-Gamma air Dose Airborne-Beta air Dose Airborne-Max Organ Dose Liquid-Total Body Dose Liquid-Max Organ Dose Total Dose Thyroid O.OE-OO mrad O.OE-OO mrad 1.0E-03 mrem 2.5E-02 mrem 3.8E-02 mrem 2.7E-02 mrem 10 mradl 20 mradl 15 mreml 9 mrem2 30 mrem2 75 mrem 0

%%d 0

1 1%

Total Dose Total Body or Organ other than Thyroid 6.5E-02 mrem 25 mrem 1%

Since airborne. releases are quantified on a per site basis, and the Technical Specification dose limits are given on a per unit basis, calculated airborne doses are initially compared to the per unit limit.

If this limit is exceeded, the release data is reanalyzed to determine which portion of the releases were attributable to each reactor unit.

Then these per unit releases can be used to calculate per unit doses which are compared to the per unit dose limits.

2 The quarterly Technical Specification limit for liquid doses is the total site dose limit (the one-unit dose limit times 3).

This is because all liquid radwaste systems are common to all 3 units and the releases cannot be attributed to one particular reactor unit.

e

Enclosure I Page 17 of 53 TABLE lA (page 1 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FORiGROUND-LEVEL RELEASES JOIRT tttctvrAOS rat Utsczts or vlsD stttD ~I SIRD DzatcTzos Fos STASZLZTT CIA55 A IDSLTA TI0 I~ 1 C/14 ~ X)

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0 ll5 I ~oil I ~I~I 0 ~ 0 O.oil 0 ~ Oil 0,0 0 ~I

~ 0

~,0 0 ~ 0 0,0 0,01 ~

0.014 0,0 0,0'

~ 1$ 2 I ~ OSC I,111 0,011 O.oil 0,0$ 1 0,0$ 1 O.oil 0,0 0,0 0>>oil I ~ ZIX 0 ~ 1$ 2 0 ~ 0 0,0 0,0 0,0 0 '

0 ~oil 0 Oil 0 ~ 011 0 '

0 ~ 0 0 ~ OSC 0 ~ 0 0 ~ 111 VZSD 51$ ID{X1R) 1$

~

5574 0,0$ 4 0,014 0 ~ Oil 0>>oil 0,0 I ~I 0 ~ 0 I'D 0 ~ Oil 0 ~ OSC 0,0 0,0 0,014 O.XIS I ~ 111 0 ~ 111 0>>0 I ~ 0 I ~ 0 0>>0 0.0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 '

0,0 0,0$ 4 0 '0,0 0,0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 I ~ 0 0 ~ 0 I ~ 0 0 '

0 '

0,0$ 4, 0 ~ 114 0,4 I.5 12. ~

12.$ I~.1 II.4 21. ~

)01' 0,0 0 ~ 0 0,0 0,0 0 ~I 0 ~ 0 I ~I 0 ~I 0.0 0 ~ 0 0,0 I'D 0,0 0 ~ 014 0 ~ 0 0 ~ 0 TOTAL I ~ 111 O.lls 0 ~ XIS 0.0$ 4 0,0 I ~ 014 0>>SIT 0 ~I~I 0

2 ~I 0 1$ 2 I ~ 111 F 111 0 ~ 111 0 ~ 421 0.42$

I ~ XIS IUSTOTAL 0.0 0,0

4. STI I ~ SCI 0,$ 42 O,OSC I ~ 211 0,0 ~I 211 TotAL toots or TALxD ITADILztT ossaaTATzoss 1011 ToTAL RQUR5 or stADILxTT cLASS

~

~I ToTAL sooa5 or vALxD vzsD DzatcTIQR vzsD 5ttto STADILITT clASI I I ~

TOTAL SOUS5 OF VAI>>ZD VISD DZRSCTZOS VZSD Sttto ITASZLZTT OISXRVATIORSXOIS TotAX>> RQUS5 cALS 0

Enclosure 1

Page 18 of 53 TABLE 1A (page 2 of 4)

BROGANS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR. GROUND-LEVEL RELEASES sozst raacastaoi rac ocsczas or szsn srccn st sxsn nzacctzos roa I'TAIZLZTT CLA55 C

{ iezi DCLTA-T(~I 5 C/100 Nt Iaosas tsaat NOCLCAR 1LANT JAN le

$ 0 NAR )I~

$ 0 WIND nzacctzos N

Nss NC SNC C

~SC SC

$ $5 5

Sslt SW sss sssw

~W Sall CAXN e

0 ~ 0 0 '

0 '0.0 Oel Oes 0,0

~

0 'I ~ 0 0 'I~I 0 '

Oeo 0 ~I 0'*

Oel I~ 0 I ~ 0 0 ~I 0.0 0.0 Oel 0'I ~I 4,0 4,0 0 ~ 0 0,0 0,0 0 '

0 0

0 '

~

0

~ e4

~

0, ~

~ ~ll

~ 0$ 4

~

1$ 2

~ ill

~,ill

~ Oil

~ lll

~ I 0,0 4,0 I~ 0 0,0 0.4 i. ~

1.5 ).l 0 ~I 0.4' I ~I~I I ~Oil l,lil 0.0$ 4 0 ~lil 0 Ill 0,0$ 4 I ~ 0 4,0 ~I 0.054 I ~ 0$ ~

0 ~ 1$ 2 0 ~I 0, ~

I ~ 0 ~I 0 ~ili I ~ 2IS I ~ Oil 0 ~Ill 0 ~ 0$ 4 0,0 0 ~ 0 0,0 Oel I ~ 0 I ~ 0 O,oil O.oil 0 ~ 1$ 2 I ~Oil szso stccotsts I

).5 5.4 5 '

7. ~

O.oil O. )lz 0 ~Ill 0 ~ 0 I~ 0 Oel 0,0 ~I I ~ Oll 0,0 0 ~ 0 0 ~Oil 0 ~ 0 0 ~ 0$ 4 I ~Iil alii I ~ OSC 0.0$ 4 0,0 I ~ 0 Oel 4

0 0

0 0.0 0 '0.0 0 ~I I ~ 0 0'I ~I Oelli 0 ~ OSC 0 ~ 0 4 ~I I ~I I ~I 0,0 0.0 0.0 0 '

0 0

0' 0,0 0

0 0,0 O.oil 0'I ~ Oil 0 ~ 0

~e. -Ie.e ee: ~

e ~. ~

ee.e-e

~. ~

>02 ~

5 0 ~I I~ 0 0 '

0.0 0.0 0,0 0.0 I ~ 0 0 '0,0 0.0 0.0 0 '0,0 0,0 0.0 0.1$ 1 0 ~ 525 I ~ 3 ~ 5 Oe0$ 4 Ie Ill 0

2 ~I 0 ~ )IS 0.317 0 ill I,Oil 0 ~IiI 0 '54 I ~ ZIS 0 ~ 525 0.577 I ill SNSTOtat.

Oel 0,0 I

I ~ 722 I ~ 104 I ~ 010 le l5i 0.337 0.0$ 4 I ~ 0 l25 To'ZAL COORS ot TALZD STASILITT OSSCRTATIONS 20$ 3 totat. Nooas or STASILITT CIASS c TDTAL Novas ot TALID sxND DtaccTzoN stan stean stASILXTT cLA5$ c

$ 2 TOTAL Nooas or TALzo szso ozacctzos-sxsn srcco-stasttxtt osscatatxoss 207$

TotAL cooa5 CAIN 0

Sozst rcaccstloc nc ocscxcs or wzsn stean st wtso nzaactzos roa 5tAIILZtT CXASS D

I ICOSI OCLTA T(< 0 ~ 5 C/100 NI Iaosss tcaRT NQCLCAR tLANT ZAN I ~

$ 0 NAR ll~

$ 0 szso nza'acTZON CAIN 0.4 l.i I.S ).I NIND 5tccDINtst 3.5 S.i 5 ~ 5 1. ~

7.5 Iz.i 12.5 ll.i ll.5 2 ~.I

)ezra.5 TOTAI N

NNC sc Csc C

CSC SC Ssc 5

5$s ss ass w

SNW NW NÃW 0,00$

I ~ Oll 0,004 0,001 I ~ 00 ~

I ~ 010 I ~ Oll O.OOI 0 ~ Oll 0 ~ 00l Oellz I ~ OOC I ~I 0 F 001 I F 003 0.007 I ~ 0 ~I O.lil Oelll 0 '

0 ~ Oil 0 ~ 0 I ~ 054 0 ~ 0 0 ~ Oil 0 '

0 '0,0 0,0 0,0 0 ~ 0 0.0 ~I 0.)IS 0.337

~ ill 0'$ 4

~ ill

~.52$

~ 517 0'IS

~

~II 0 ~ 1$ 2 I ~l)7 I ~ XIS I ~I I ~lll 0ell ~

I~ 2$ $

I ~ 337 I ~ 710 0.337 O,ill I~ ZIS I~ SIC

0. 51'1 I ~II~

0 ~ I~I 0 ~Oil 0

1$ 1 I ill I ~ 2$ $

I ~Ill 0elil 0.ill I,OSI I.OSI 0 ~ ZIS I ~ ZIS 0 ~ 14$

I ~ )IS 0 ~ $ 44 4 ~ill 0 ~ Oil 0 ~ Oil 0

0 I ~Ill 0 ~ill I ~ 14$

0 e)37 Oells Oesli 1.054 1elOC 0.0 Oel 0.1$ 2 0 ~lil I ~I I ~ 0$ 4 I ~Oil 0,0'

~ 0$ ~

0 ~ I~ 5 0 ~ ~ 2$

I ~ 104 0 ~III 0 )IS 0,0$ 4 I ~ 0 0 '

0 ~ 0 0.0 0 '

0' 0,0 I ~ 0 0,0 Oel 0 ~ OSC Oesll OeSC2 0 ~Oil 0'0.0 0,0 I ~ 0 0.0 4 '

0 ~ 0 I ~ 0 0.0 0 '

0 '

0 'I ~ 054 I ~ 0 I ~I 0.0 0 ~ 0 0 ~ 0 0.0 0,0 0,0 0 '

0'0,0 I ~I I ~ 0 0 ~ 0 0 ~I 0 ~ 4 0,0 0.0 l.Xl5 I ~ 375 2.024 I ~5)l I ~ 470 2.Ill 2.370 I ~ 354 I 145 0.)ii I N C)2 I ~ 014 I.203 2 ~ 011 2, ~ $ 4 I ~Sll SVSTOtAL 0'$ 4 0 ~ )IS I

I ~ l13 4.3$ 7 4.041 4, ~ IC 2 ~ 501 0,0$ C 0.0 24,4$ 5 TOTAL sooas ot TALID STAIZLZTT OISCRTAtXONS 2053 TOTAL COVR5 Ot StAIZLITT CLASS 0 554 ToTAL SOORS or TALID NIND Dzacctzos sxso lrccDITAIZLXTTcLASS 555 totat.

COORS ot TALID vxso oxacctxos-sxso srccDITARZLITT osscatatzoss 207$

TotAL cooas cAIN 1858%

Enclosure 1

Page 19 of 53 TABLE lA (page 3 of 4)

BROGANS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR GROUND-LEVEL RELEASES JOINT FIRCtttAOS FttOUINCZ55 OF VINO 5FSSD IT VIND DIRtCTZOV FOR STASILZTT CLA5$

~

L I ~5i DSLTA T(0 I ~ 5 C/100 NL IROVNS F!RRZ NUCLSAR SLANT JAN Lg

$ 0 KAR )I'0 VINO I 0 N

NNN NNttt tlt St

$$5 I

SSV SV VSV V

VNV NV

~NV 0'44 I ~ 004 I ~ 004 I 005 I ~ 011 0.011 0.02)

I ~ OII I ~ 011 0,004 I F 005 0 F 004 I ~ 004 I ~ 00)

I ~ 004 0,001 0.0 ~I 0 I 0 ~I~I 0 ~Ill 0.0 0.0 0.0 0.Rent 0 ~ 0 ~I I ~Lii I,lil 0 ~ 0$ 4 0 ~ 0$ 4 0,0 0'54 I ~ 0 I ~ 43)

I~ill 0'Is I ~ )37 I ~ ~ CC I ~ILI I ~ 7)2 I ~Tll I ~ ILI I ~ Rlt I 111 4.3 ~ 5 0')7 I

2 ~I I ~ )IS 4 ~ 2 ~I I ~ 4 I.i 1.5-).i 0 ~lit 0.)37

0. 41) 0.0 0 li~

0 '

~ 5 I ~ 0$ 4 I 1$ 2 0,170 0 Lii 0.0 ~I 0,4 ~I 0.1$ 2 I ~ Rlt 0 ~)ls 0.) ~ 5 VIND StttD(NFNL

).5 5. ~

5.5 7. ~

'0 ~ 52$

~ ei))

0'17

~,il) 0 ~ll5 0.473 I ~ $ 42 2.241 1,5IT I ~ 1)1 0 ~1ii 0.0$ 4 0 ~Iil I 1$ 1 l,lii 0 ~ ) ~ 5 Oe42$

Oe)IS 0.2' 0 '

0 ~ Oil 0.0 ~I 0.41)

I ~Lii I ~ )ls Oel ~I O,li~

0,0 ~I I.lii I 1 ~ 1 0 ~ 2ii I ~ 425 I ~ 0 I ~ 0 0.0 0 ~I 0 I 4 ~ 0 I ~ 0 I ~ 0 I ~I 0,0 I ~I I ~ 0 O,lil I ~ 054 I ~I 0

1$ 1 0 I 0 ~ 0 0,0 I ~ 0 0,0 0,0 0 ~I 0,0 0 ~I 0 ~ 0 0,0 0,0 0,0 0,0 O.lil 0 ~I 7.5 LR ~ ~

12.5 Ll.i 15.5 I~.i i%10 5

Oel I ~ 0 0,0 0 '

0 '

0.0 0 '

0 '

0,0 0

0 0 '0.0 0.0 0,0 0,0 0 '

TOTAL L.t)0 1.442 I ~ 40$

~

$ 21 1 ~i)5 L.t)5

~ ~ 4 I ~ ~I)

) ~ 41t I ate I ~ ~ )I O.CIO 1.04 ~

1 041 I ~ )05 I)1 SU'ITOtAL

0. LCI 0.$ 42 (

S.ICL

$.1)t 4.317 '+$ 44 0.)17 0,045-I ~ 0 I~.ILR TOTAL NOURS OF VALID 5TASZLZTT OIISRVAT1055 ROSS TOtAL NOURS OF 5TAIILITTCLA$5 5 400 TOTAL NOURS OF VALZD VIND DIRICTZON VIND SFSID I'IAIILZttCLASI 5 5$ $

TOTAL NOURI OF VALID VINO DlttCTION RIND 5$ 55D ItAIILITTOISIRVAtZONS 207$

TOTAL NOURI CALN JOINT FISCINTAOt Ftt UIVCIR5 OF V ND 5 ~ttD St VINO DIRtCTIOV FOR STAIILZTT CIA5$ F L

1 5( DILTA-TCQ ~ ~ 0 C/100 III JIOVNS FtRRT NUCLZAR FLANt JAN 1 ~ tl NAR )I~ tl VZND N

NNN Nt 555 5

555 55 555 5

SSV I'V VSV V

VNV NV NNV CALJI 0,00$

0,004 0,00$

0o011 0,022 0.01$

0,0)t O.lii O.OLR 0,00i 0 F 00'

~ 001 0.005 0.001 0 F 00) 0 F 001 0 ~ 4 L.i 0 ~I 0.0 I ~Oil 0 ~ Oil 0 ~I 0.) 11 0.1$ 3 0.3)7 I ~2il 0 ~ Lii 0 '54 0.44

'$4 0 ~ Oil 0 '

0 '

1.5 ).I

~. ~))

I ~ 152

~.) IS

~ 571 lsl I ~ 571 Cli 1.$ 74

~.))1 0 ~lil I ~ 0$ 4 I 0$ 4 I ~ Li~

0 '

0 ~ 1 ~I I.lil VZND'SFSIDLNFNL

1. ~

S.

$. ~ j.

I ~ 054 I ~I~ 4 Oolii 0.1 ~ 1 I~I 0 ~ Oil I,li~

I ~ 0$ 4 I ~ 517 I ~I 0.1$ 2 0,0 I ~ 425 0 ~ 1$ 2 I ICC 0.41)

I ~ 05 ~

0.770 O.li~

I ~ Oil I ~ Oil I ~ Oil O.lil Owl 0 '

0.0 0.0 I ~I 0 ~ Oi~

0 ~ I I Lii 0.0$ 4 T. S-1l.

Owl 0 ~ 0 0,0 0,0 0'

0 '

0.040

0. $17 O.jlt I ~Ii~

I ~ 0 Owl 0.0 0 ~ 0 0.0 0+0 0.$ \\. ~

I ~ 0 0 '

0 'I ~I Owl 0 ~ 0 0 '

0.0 0.0 0,0 Owl 0 '

0 '

Owl Iol Owl 1 ~.S

.I 0.0 0 ~I 0,0 0 ~I Oel 0 ~ 0 0.0 I ~I 0 ~I I ~I 0,0 0.0 I+I 000 0,0 0,0

}01~.5 0.0 0.0 0.0 I~I 0.0 0.4 0.4 0 '

0 ~I 0,0 0.0 0.0 0.0 0.0 I ~ 0 0 '

0.4)i 0 ~ SI1 0 itl O.TIR I 451 1.125 2 F 750 I ~ 11$

2 ~ 704 0 ) ~ 1 0

1$ )

0 ~ 1$ 5 0 ~ I~ 5 O.lit 0.1$ 5 I ~ 250 IUSTOTAL 0 ~ 1$ 2 I C)5 I 7 4$ 4

) ~sii 2 ~ 10$

0.$ 42 0 '

0,0 0,0 LC 7)t TOTAL NOURS OF VALID 5TAIILZTT OSSIRVATZONS ROAN )

tOtAL'NOUSS OF 5TASILZtt CLASS F TOTAL NOURS OF VALID VIND DIRICTZON VZND 5FSID ITASILZtt CLA$5

)il TOTAL NOURS OF VALID VINO DIRICTZON VINO IFISD StAIILITT 0555RVATZONS lOTS TOTAL NOURS CALII 18>Um

Enclosure 1

Page 20 of 53 TABLE lA (page 4 of 4)

BROMNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FORlGROUND-LEVEL RELEASES Joist Fcactstsos tlc otsczcs or vfso srcco ot WIRD olacctxos Foa STASILZTT CLASS 4 iDCLTA T 5 I ~ 0 C/ZOO Si

~Rowss FIRE socLCAR FLART JAS 1 ~

$ 0 KAR SX ~ I~

WZSD I~

I S

SSC Ss Css C

CSR SC SS ~

5

$ 5V SV VSV V

VWW SW SRV CALW 0 ~ 011 I ~ 011 0 ~ 045

~ eOXS I ~ 011 0 ~ 0 0 ~ 010 I ~ 14$

Oelll 0 ~ 001 0 ~I 0 ~ 0 I~ 0 I ~I 0 ~ 0 0 F 005 I ~Oil

~ I I ~I O. 1ii 0.0$ 4 Owl I ~ Oil 0.1 ~ 5 Iol I~I 0.0 0 'I ~ 0 0,0 0 '

Ie4

~ 1$ 1 4

2 ~ 1

~ o4$ 4

~ lii 0 ~ 1iI I ~ ~

0,22$

1 ~ Xzt 0,217 I ~lil 4 I I ~ 4 Ooo 0,0 4 'I ~ 454 4.4 1. ~

1.5 ).I 4 lii 0 ~ ~ SC Ool Oolil Oo4$ 4 Owl Oo0$ 4 1 ~ill I ~ Stz 0 '

Owl 0'

0.0 Owl 0,0 0.0 0 ~ 0 0 ~ 0 I ~ 0 0 ~ 0 I+oil 0.0 Oo0$ ~

I ~ 145 0 ~ OSC 0,0 0,0 0 'I ~ 0 0,0 I ~ 0 Oolil WXSO SFCCD(SSS) 5.8 S. ~

5.5 7. ~

I ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 ~ Oi ~

0,0 0 ~ 0 I ~I I ~ 0 0 ~ 0 0,0 I ~ 0 0.0 I ~ 0 I ~ 0 0 I 0

0

'l.l 0,0 0 I Ooo 0 ~I

'I~ 0 0 ~ 0 0.0 0.0 0 '0,0 0 '

0 ~ 0 0.0 0 ~ 0 0 ~ 0 0,0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 Oeo 0 ~ 0 0 ~ 0 0 ~I 0 ~I T.S 12. ~

11.5 1l.i 15.5 1 ~. ~

)az ~

S 0 'I ~ 0 0 ~ 0 0'I ~I I ~ 0 0

0 0 ~ 0 0 '0,0 0,0 0 '

0.0 0 'I ~ 0 0 ~ 0 TOTAI I ZST 0 14$

I ~ 101 J

0 ~ 152 I ~ 2$ $

0.0 I ~ 557 5.512 1 ~Oll 0.051 0,0 0.0 0,0 0.0 0,0 0 ~ 14$

5 OSTOTAII Oe2$ $

Ootzz i

~

~ ot42 1 ~ 501 0 ~ Ctx O.oil Owl I

0,0 0.0

~

$ $ 5 TotAL ROOtS OF TALID STASILITT olscaTATIOS5 2051 TOtAL ROURS OF STAOILITT CLASS 4 1$ 1 Totax. Rooas or Taxxo wxso ozacctzos-wxso srcco-stlsxLxn CLASS 0 lit total. Rooas or TAx,zo wzso oxacctxos-wxso srcco-STAOILxn osscaTAnoss 202$

TotAL Rooas cALR I

185 8rt

Enclosure 1

Page 21 'of 53 TABLE 1B (Page 1 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FO SPLIT-LEVEL RELEASES GROUND-LEVEL PORTION 5tnzT Polit ttscssfAOC tsf vfscIcs ot szsn 5tcfD IT szsn DzRccTIos FOR StASZLITT CLASS A (DCL'tA T(% X,t C/100 N(

SROSSS FCRRt CVCLCAR tLAST FAIt 1 Ot 1 OROVCD LCTCL RCLCA5C NODC JAC 1 ~ tO NAR ll~

$ 0 WIND sstc scCtt I

CSC SC 55C 5

55N SW S5N w.st 5((

ts((

CALN 0 ~ 0 0 ~I 0,4 0,0 0 ~ 0 0'

0.0 0,0 0,0 I ~ 0 0.0 I'D F 4 0 '

0 '

0 ~ 4 I ~ 0 I'D 0 ~ 0 0,0 I'D 0 'I'D 0,0 I'D I'D I'D I'D 0.0 0'

0' 0,0 0

0 4.0 0'

0 'I ~I 0.0 F 00)

I ~ 004'

~I I ~I

~ ~I 0,0 0 '

0 'I ~I O.C 1. ~

1,5 ). ~

SZID SFCCD(stt(

)

5 S.i 5.5 T.i I~I I F 004 0 '

I ~I I F 000 I ~ 011 0 '

I ~ 0 0 ~ 0 I ~ 0 0 ~ 000 I ~ 0 0.02I 0 ~ 0)5 O,OIC 0,010 O.OSX I ~ 1)l I ~ 01C I 5 0)S 0 ~ 00i 0 ~ 041 I ~ 001 0 ~ 0 0 F 00',0'

,I ~ 0 0.0 0.004 0

0

'05

1. ~ 11. ~

0 ~ Oil 0 ~ 1 ~ 0 I ~ 01) 0,0 0 ~I 0>>0 0 ~ OCi 0,0it

',01$

0.05 ~

0,0

0. 010 0 ~ Oii 0.01) 0.024 O.OSC 0 ~ 02) 0'25 I ~I 0,0 I ~I 0,0

~

0 '0,0 0,0 0.0 I~ 0 0,0 0.0 I ~ Olt 0>>OSO

0. Dlt 0 ~I 0.0 0 ~ 0 0,0 I ~ 0 0,0 0 '

0 ~ 0 0.0 I ~ 0 0,0 I 0 0 ~ 0 I ~ 0 it 0 5lli 0,0 11

~-I ~.I I ~.5-11. ~

)%24 ~ 5 I~ 0 0 '0.0 0,0 OeO 0 '0.0 0,0 0,0 0,0 0.0 0,0 0 '

0 '

0.0 0 '

TOTAI 0 ~ 0)2 0 ltt I ~ Oii I ~ 0 0 ~ 0 0 F 000 I ~ 124 0.151 0'2) 0 121 0.0 ~I 0 ~Oil 0 ~ 052 0 ~I)~

0.214 0,0 ~ 0 SVSTOTAI>>

0,0 0,0 0>>01)

I ~ 20) 0 ~ )IC 0 ASIA Oelii 0 ~ 142 0.0 I (22 IOTA(>> SOMS Of TALZD OISCRVAT1055 20)t ~ OOD TOTAX SOVIS Ot OIOVSD LCVCL ICLCASC

)IS,D)4 TOTAL SOMS OF STASZL(TZ CLASS A 2 ~ ~ 00 ~

TO'fAL IOVI5 Ot OIOVtD LCVCL STAIZLZ'fT CLASS I 2$ ~ 444 stz,zt Jo(st tfscfsfAOC rsf afsclcs ot vlsn stccn IT wlsn DIIIctzos Fox StASXLXTT CLA55 4

( let( DCLTA T(% Xe) C/100 N(

SIOSCS FIRST CVCLCAR FXAST tARt I Ot 2

OROUSD LCTCL ICLCASC NODS Jls I ~

tO NAR )1 ~

$ 0 Sltn DIRCCTZOS CAIJ(

0. ~ I ~i 1.5 ).I SXCD SFCCD(Ntt(

1.5 5. ~

~. ~ 1.

I ~ ~ II.I 11.5 I ~.I I

. ~ \\.I

)%1 ~.S TOTAL ttt CC CSC 5

CSC SC SSC 5

SSW SW WS(i

((

SSN IW ts((

0,0 0,0 0 '0.0 0.0 0.0 0.0 0.0 I'D 0.0 0 '0,0 0.0 0

0 0,0 I ~I 0,0 050 0,0 0,0 0>>0 0 '

050 0'I ~I I ~I I ~I I ~I I ~ 0 0.0 O.'0 I ~I 4 ~ 0 0.0 I ~ I I ~I I ~ 0 4,4 0 ~I

~

0 4,004 4,0 I 005

~

4 I ~I I ~ ~

0,0 0

~

0. ~

I ~ ~

4,DOI 0>>0 0.0 0 ~ 0 0.0 0.0 0.001

0. 011 0,01) 0.014 0.0 0,40) 0>>DOX 0.0'

>>0 054

0. ~

I ~ OCS I ~ 002 4.02) 4.0(i 0,0 0 '

0>>0 0 '

0 'I ~ 00 ~

0 ~ 014 0.017 D.O 0,0 I ~ ODC I ~ 0 0'

0'

~ 0$ 1 O.OX) 0 'OC 0 F 005 I ~ 407 I ~I 0,4 0,0 I ~I 0 ~ 0'

~ 03 ~

I ~I 0,0 0>>00 ~

0 ~ Oi) 0 F 042 I ~ Oli I ~ 2)0 0'0,0 0>>0 0.0 I'D 0.0 0.0 0.0 D,O 0.0 0,0 0.0 0.0 I ~ 01$

0,0 I AD 0>>01$

0.0 0 ~ 0 0.0 I ~ 0 0,0 0.0 0>>0 0.0 I ~ 4 0 I I ~I 0 ~I 0 ~I 0 ~OII I ~ 121 0>>0 I ~ 21$

0.0

. 0,0 0.0 0 '

0.0 0 '

0' 0 '

0.0 I ~ 0 0.0 I ~Oit 0,4 I ~I 0 Oit 0 ~ 01$

0 ~ 011 0 ~ Olt 0 F 00) 0.0 0 ~ 001 0.015 0 ~ 013 4 ~ OC ~

I ~0)I I ~4)i 0.001 0 ~ 012 I ~ 215 I ~ ZI)

I ~ 012 0 CI)

TOTAL COORS OF VALID OISCIVAtZOCS 10)$ >>000 TOTAL COV'RS OF OIOQSD LCVXL ICLCASC ZIS ~ 0)0 TOTAL tOOtS Ot STASILZTT CLASS

~

X) F 550 TOTAL tOMS Ot OIOVCD LXVCL STASZLZtt CLASS I ll.t20

Enclosure l Page 22 of 53 TABLE 1B (Page 2 of 4)

BROGANS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOB SPLIT-LEVEL RELEASES GROUND-LEVEL PORTION 5ILit JOZNT tsRCZNTAON tRI QINCI$5 ot UZND 5tstD st UZND DZRZCtlos toR 5TASZLzff cLASS c I

1 ~ 74 DSLTA T4i 1,$ c/100 N)

Ssotts tsRRT NUCLNAR tZANT taRT 1 Ot 2 OROUND LXVXL RXLRASS NODS JAÃ 1 ~

$ 0 NAR 11 ~

$ 0 WZND DIRSCTZON CALN I

~

1 4

1 I )

4 UZND StIIDINtt)

~.e-.I

~ ~ e-e.

e. ~-Ie.

Ie. ~-e ~ ~ ~

ZI ~ 5 2 ~.4

>ale

.5 TOTAL N

Nts NS SNS 5

$5$

$ 5$

5 SIN Sttst Wttt Nll

ÃNW 5USTO'TAL 0 ~ 0 I ~ 4 0 ~ 0 0 ~ 0 0,0 0 I 0.0 0 ~I 0 ~ 0 0 ~I I ~I 0,0 Oe0 0 ~ ~

OeO 0.0 0 ~ 0 0,0 I ~ 0 0'

0 'I ~ 0 0 ~ 0 0 '

0 ~ 0 0,0 I ~ 0 Oeo

' '0,0 I

0,0 0 ~ 0 0,0 0 ~ 0 I'D 0,0 I ~ 4 0,0 0'0 I ~ 4 I F 000 0 '

0'

~ ~I I F 000 0 ~ 0 0 '

0 ~ D 0 ~ 0 I ~ 0 I ~ 001 0,0 0 001 0 '0,0 0 'I ~ 004 Oeoll I ~ 020 0.014 0 ~ 0 0'I ~ 00 ~

I0,001 0,0 0,0 0,0 0 ~ 05I I ~ 005 0 ~ 01 ~

I ~ 021 0 ~ 001 0 ~ 004 Oeoll I ~I 0,0 0 '0,0 0 ~ 0 0 ~ 0 I~ 007 I F 001 0 ~ 014 0 ~ 001 0 ~ OII 0 F 007 Oe044 I ~ 005 0.0 0,0 0 ~I 0.047 0 ~ 0 ~ 1 0,0 Oeo 0,017 0'

0 ~ 017 I ~ 021 I ~ 027 I ~ 015 I ~ 242 0 ~ 011 0.0 0,0 I'D I'D 0.0 0 ~ 0 I'D I ~ 0 0.0 0 ~ 0 0 ~ 0 0,0 0,044 0 ~ DXI 0,0 0 ~ 107 0 ~ IL 0 ~ 0 0.0 0.0 I I 0,0 0.0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 012 0 ~ 0 0 ~ 041 0 ~I 0.075 0 ~I AD O.D 0.0 0 I 0.0 0.0 0.4 0.0 0,0 0.0 0 ~ 0 0 '

0,0 0'

0.0 0 '

0 ~I~I 0 ~ 051 0.021 0.001 0, F 04 0 014 0.0'.041

4. ~ 14 O.D 0 ~ 011 0 F 004 0.054 0.071 0 ~ 111 I ~ 01I 0.571 TQTAL Nooss ot vaz.zo ossssvatzots 101$ ~ 000 TOTAZe $0055 Ot OOOUND LZVIL RILIA5$

2 ~ 5 ~ 470 TOTAL SOQR5 Ot StASZLZTT CLA55 C

14 20 ~

TOTAL SOQR5 Ot OROUND LIVIL5TASZLXTT CLASS C

llesl ~

5' LZT JOZtt VSNCRNTAON ~

' I QINCZ$5 Ot UZND SVISD Sf WIND DZRICTZOt tOR STASZLiff CLASS D

I leS4 DSLTA T(i 0 ~ 5 C/100 Nl SROUNI tsssf NUCLRAR tLatt tARt 1 Ot 2 OROQND LXVXL RSLSASS NODR JAN 1 ~

$ 0 NAR 11 ~

$ 0 WZND DZRSCTZON catA 0.4 1.4 Z.S-S

~ ~

UZND stssDINttl 1.5-5. ~

5.5 7.4 e

e ie.e ee.e ee.e I.e e ~. ~

)0'5 t

NNR NN

$5$

5 5$

51st SW WSV wUtlf Nt

'NNil IUSTotaL 0 ~ 0 0 ~ 0 Oe0 Oe0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0,0 0,0 o

o 0 1 0 ~I 0 ~ 0 I ~I 0, ~

0 ~ 0 0 ~ 0 0 ~ 0 4 ~ 0 0.0 I'D 0 '

Oeo 0 ~ 0 0,0 Oeo 0,0 0 ~ 0 0 ~ 0 0 ~I I ~ 4 0 ~ 0 0'

0 0

~ e4 0,4 0,0 0,001 I F 004 0 ~ 024 4.01$

~ e001

~ 007

~ e 001 0,4 0.0 0 ~I 4 '

Oe072 0.007 I F 025 0.004 0,007 0 ~ 02$

O,OI7 0,070 0.114 0,074 I ~ 007 0,017 4,02$

I ~ 01$

0 ~ 001 0 ~ 000 0.014 I ~ 521 0 ~ 111 4,107 0,025 4.011

~

.ISED 0,040 0

X57 0 ~ 041 0,00

'.011 0,0 0.021 0.051 0,022

0. 01 ~

0 ~ 011 I ~ 7$ 1 0 145 0,17I 0.15$

0.0 0,0 0.017 0,0 ~I 0,.0 0.044 0 010 0 ~ 014 0,022 0.0' 0

0$ 2 0.17 ~

0.145 1elss 0 ~ 0$ 1 0.020 0,0 0'

0 ~I 0

0 0 ~ 0 0.0

0. 0.

0 ~I 0 ~ 0 0.0 0.041 0.251 0 ~ 115 0 ~ 010 0.711 Oeo 0'

Oeo 0 'I'D 0.0 0'0.0 0.0 0.%

'.0 0,0 0 ~ 0 0,07$

~ ~ 0 0

0 0.07$

0.0 0,0

.0. 0 0 '0,0 O,D 0,0 0 AD 0.0 0

0.0 0,0 0 '

0 ~ 0 DAN 0, ~

0. ~

0elSS 0,110 0.1$ 1 I ~ 014 0 ~ ~ 71 0 ~ ZII 0 ~ 151 0 ~ 105 0.1 ~ 4 O,D11

0. ~SI I ~ 0 ~I I ~ XIS 0 '41 0.52$

0 ~ 102 1

1 ~ 0 TOTAZe SOIIS Ot VALZD OSSIRVATZON5 201$ e000 TOTAL ROQRS Ot OROQSD LIVsfe RXLSAIS XISe070

'totAL NOUR5 Ot STASZLZTT CLASS D

1024e210

~

TOTAL ROURS Ot OROUND LIVILSTASZLZTT CLASS D

I~ e $ 10

Eaclosure 1

Page 23 of 53 TABLE 1B (Page 3 of 4)

BROWSES FERRY NUCLEAR PLAHT METEOROLOGICAL DATA FIRST UARTER 1990 JOIHT FRE UEHCY DISTRlBUTIOH IN PERCENT FOR) SPLIT-LEVEL RELEASES GROUHD-LEVEL PORTIOH stozt Jozat tcaccctaoc rac Ucaczcs ot wzao stcco lr wzan ozacctzoc Foa STAOILITT CLASS l I 0 Si DILTA TZ0 1 5 C/100 Il)

SRUWNS FSRRT NUCLEAL tLANT tART 1 Of 1 OROUND LCTSL RCLRASR NODR JAN 1 ~ to NAR 11 ~

$ 0 WZND CALN 0.4 5

3 WIND $ 1ICD(NIN)

>>. ~

~.I

~.e

>>.e

>> ~ ~ >>>>.I

>>e. ~

>>.e

>>e. ~

>> ~.

TntAZ Nal Nllall 4$ $

Sl 5$ $

3

, SSW SW WSW W

WNW NW NNW SUSTOTAL 0 ~ 0 0'

0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0 '

0 ~ 0 0 ~ 0 0 ~ 0 0,0 Ool 0 ~ 0 0 ~ 0 0 ~ 0 0 '

0 ~ 0 0,0 0,0

~

0 0 '0.0 0

0 0'0.0 0.0 0 F 003 0.0 0 ~ 0 e 0>>0 I

0,0 0,0 0

0 0.001 0 ~ 001 0,001 4 '

0 ~ 011 0 ~ 0 1I 0 ~ 014 0 ~Oti 0 ~ 174 0 ~ 071 0 ~ 014 0>>010 0 ~Oil 0 ~ 007 0 ~ 007

'0,001 0 ~ ~ 04 0 ~ 47$

0 ~Oli 0,037 0 ~ 01 ~

DE 0'

~ 03$

0 ~ 071 0>>ill 0 ~ 1IO 0 ~lit 0 ~ 054 0 ~ 017 0>>011 0>>031 0,010 0 oill 0 ~ 037 1.147

0. 0i1 0 ~ Oit 0,0$ 0 0'

0 ~ Dli 0 F 045 0 ~Oil 0 ~ 041 0 ~ 111 0 ~ 011 0 ~ 010 '

~ OOI 0.011 0,0 ~ 0 0>>OSI 0>>057 0>>7$ 0 0 ~ 111 0 ~ 074 0 ~ Oil 0,0 0>>004 0 ~ 005 0 olti 0 el 1 1 0>>154 0 ~ 011 0 ~ 030 0 ~ 010 0 ~lil 0 ~ Oil 0 ~ 044 0 ~ 115 1 ~ 014 0 ~ 0 0

0 0 ~ 0 0 ~ 0 0 ~ 0 0 0 0 ~ 0 0 ~ 0 0,0 0 '

0.0 0>>0 0>>01$

0 ~ Olt 0 ~ 0 0 ~Oli 0 ~ 15 ~

0 ~ 0 0 '

0>>0 0 ~ 0 0'

0'0,0 0,0 0 ~ 0 0 ~ 0

~ 0 ~ 0>>

0 ~ 0 0'

0 ~ 0 0.047 0 ~ 0 I ~ 047 0 ~ 0 0 '0,0 0,0 0.0 0 '

0' 0 '

0 ~ 0 0 ~ 0 0

0 0.0 0.0 0.0 0

0 0.0 0 '

0 lit 0 >>141 0 ~ 15$

0. ~ 44 0.100 0 ~ 171 0 ~ill 0 ~ 73$

0 ~ 735 0 130 0,0 ~ 7 0 ~ 0 ~ 0 0 ~lit 0 ~ 154 0 ~ 141 0 ~ltt 3 ~ TS$

tOtAL local OF TALID OISIRTAtloal I~ 1$ ~ ~ 00 TOTAL SOUS5 OF OROUND LSTRL RILIASS ZIS ~ ~ 74 TOTAL ROUR5 OF STAOZLITT CLASS I 71$.4$ ~

TOtAL lOURS OF OROUCD LITRL STASZLIT'I CLLSS l TC ~ 450 5 ~Izt JOINT 1'cacINTAOR Fac Ucaczc5 01 wzcn stccD at wzao ozacctzoa STASILItt CLASS 1 I

1 ~ Si DRLTA T(0

~ >>0 C/100 N)

SROWN5 FIRRI NUCLRAR 11ANt tART 1 OF 1 OROUND LCTCL llLRASR Nonl JAN 1 ~

$ 0 NAR 31 ~

$ 0 WIND e

e NSal Nllall SSR Sl Ssl 5

$ 5W SW WSW W

WNW NNW CAZJi 0 ~ 000 0.000 0.000 F 000 0 ~ 000 0 F 000 0 ~ 000 0 ~ 001 0 ~ 000 F 000 0 F 000 F 000 0,000 0'

0,004 0>>0 0,0 0 ~ 0 0

0 0.0 0 ~ 0 0 ~ 005 0,007 0,014 4 ~ 01D 0 ~ OOS 0 ~Dli 0,0 0 001 I 0 ~ 0 0 ~ 0

~

0 0 ~ 015 0 ~Dll 4 01 ~

0 ~ 014 0.01$

0.031 alii 0,11 ~

0 ~Oil 0 003 0 ~ 00$

0,004 0,011 0,4 0

ODC 0 ~ 0 0.4 1. ~

2.5 3 ~ I 0,010 0, 011 0,0 0,005 0,051 0,011 0,0$ 4 0 ~ 17 ~

0 ~ 101 0 00$

D.OPT 0,007 0 ~ 0 0.0 0 F 005 0 ~ 010 0 ~ 014 0 ~ 0 ~ 0 0 F 007 0 014 0 ~ 0 0 ~ 0 0 ~ 045 0 ~ 14$

0 ~ill 0 F 00'

~ 00$

0.0 0 ~ 0 0,0 0 '

0 ~ 013 0'

0,0 0,0 0,0 0,0 0,0 0 ~Oil 0 itl 0.113 0 ~ 011 D,O 0,0 0,0 4'

0 ~ 0 0 ~ 0 WZND SOCCDINta) 3.5 S. ~

S.S T.i 7.5 Il.i 0,0 4'

0,0 0,0 0 ~ 0 0 ~ 0 0>>0 0 ~ 0 0 ~ 0 0,0 0,0 0,0 0,0 0 ~ 0 0.0 0 ~ 0 0,0 0,0 0,0 0.0 0 ~ 0 0'

0 '

0 0

0 ~ 0 0,0 0>>0 0.4 0,0 0.0 0 ~ 4

~. ~

11 ~ 5 il.i 1I.S zi. ~

>01 ~ ~ 5 0 '0,0 0,0 0,0 0.0 0 '

0 '

0 ~ 0 0 ~ 0 0 '0,0 0'

0 ~ 0 0 ~ Oil 0 ~ 071 0 ~ 011 0 ~ 030 0.0 ~I 0 ~ 041 0 ~ 31D 1 17$

0 711 0 ~ 0 ~ 7 0 ~ ~ 1$

0 ~ 011 0 ~ ~ 15 0, ~

0.011 0 '13

~UOtOTAL 0.001 0 ~ 070 4 ~ 541 0 F 430 0,445 0 Tii 0 ~ 0 0, ~

0.0 470 TOTAL SOURS Ot TALIO OISIR'FATZONI 103$.000 TotAL local 01 ocoUND LRTIL RILSAIS SIST 070

'TOTAL SOURS Ot STAOILZtt CLASS 1 171 ~ $ 50 TOTAL ROURS OF OROUSD LSTSL STAIZLITT CIASS 1 5i >>i ~ 0

Enclosure 1

Page 24 of 53 TABLE 1B (Page 4 of 4)

BROGANS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR SPL1T-LEVEL RELEASES GROUND-LEVEL PORTION StLZT JOZIT t!SCtSTAOC ttt UtICZtS Ot VZID SSSCD ST VZID DZSCCTZOI tOS STASZLZTT CLA55 4

{DCLTA T )

~ ~ 0 C/200 Nl SCOVIS tCCIT IUCLCAC 1LAIT 1AIT 1 Ot 2 4IOVSD LCTCL SCLCASC IODt JAS LE 90 IAC SL ~

90 VZID DZICCTZOI 0.4 L.i 1.5 L.i VZID SSCCD(Ittl 2.5 5.i 5~$

i Z.S 12. ~

12.5 Lt.i 10.5 14. ~

TOTAL I

~IS IC CIC I

CSC SC 555 5

SSV 5V VSV VVIV IV

~IV 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0,0 0

0 0 ~ 0 0.4 0 ~ 0 0 ~ 0

,0.0 0,0 O.b 0 ~ 0 0 ~ 4 0 ~ 0 0 ~ 0 0,0 4 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 4,00 ~

0 ~ 0 ~ 2 0 ~ 0 0,0 4,0 0 '

.0 ~ 0 0 ~ 0 0,0 0 ~ 0 0,004 0 ~ 010 0,004 0,0 0 ~ 0 0 ~ 0 0.025 0,422 0.051 0 '

OoO 0 '0,0 0,0 0

0 0,0 0 ~ OLi 0 F 004 4'0,00i 0,004 0,0 0 ~Olt 0'44 0.112 0 ~ 4 0,0 0.0 0 ~ 0 0,0 0,0 0,0 0 ~ 0 0 '

0 '0,0 0 F 007 0.0 0 ~ Olt 0.12L 0 ~ 052 0 ~ 0 0,0 0.0 0.0 0 ~ 0 0,0 0 '09 0 ~ 0 0'

0,0 0 '

0 ~ 0 0 '

0 ~ 0 0 F 041 0,0 0,0 0,0 0.0 0.0 0,0 0 '0,0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0,0 0,0 0,4 0 ~ 0 0 ~ 0 0.0

',0 0.0 0.0 0.0 0 ~ 0 0,0 0,4 0,0 0.0 0.0 0,0 0,0 0,0 0.0 0.0 0 '

0 '

0' 0 '0.0 0.0

.0 ~ 0 OeO 0,0 0 '

4 ~ 0 0.0 0 '

0.0 0.020 0 ~ OLZ 0 ~ 044 0 ~ 004 0,01$

0,0 0.0$ 1 1 ~ 114 0

ZLT 0 ~ 0 0,0 0,0 0,0 0.0 0 '

0 ~ 009 SVSTOTAL 0.0 0 ~ 047 0 F 52'.510 0 ~ Slt 0.0 ~ 1 0,0 0,0 0 ~ 0 TOTAL LOUIS Ot TALZD OSSCSTATZOIS 1 ~ 19,000 TOTAL IOVIS Ot 4tOVID LCTSL SCLCASC 2 AS F 020 TOTAL SOVS5 Ot STASZLZTT CLA55 4 50 ~ 200 TOTAL IOUCS Ot OSOUID LCUCL 5TASZLZTT CLASS 4 10 ~ $ 40 1858m

Enclosure 1

Page 25 of 53 TABLE 1C (Page 1 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FO SPLIT-LEVEL RELEASES ELEVATED PORTION SFLZT JOINT FCRCCNTAOC Ftt UCNCIC5 OF WZND 5FCCD Dt WIND DZRCCTION FOR 5TASILITT CLA55 A

)DCLTAti~) 4 C/100 N)

CROWNS FCRRT NUCLCAR SLANT FARt 1 OF 1 CLCVATCD RCLCASS NODS JAN 1 ~

SO NAR ) 1 ~

SO WIND DIRtCTION CAZJ1 0

4 14 1 ~ 5 )4 WIND 51CtD)NSN)

i. ~ i.i

~. ~ i.

i. ~-ii. ii.i-ii.i i.i-\\~.

}QRI 5 N

NNC rc CNC

$55 5t 55$

5 SSV SV V5V W

WNV

~ NW NNV 0

0 0,4 0 ~ 0 0 ~ 0 0,0 0,0 OeO 0,0 0 ~ 0 0,0 0,0 0+0 0,4 0,0 0 '

0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0 '

0'0,0 0 ~ 0 0 '

~

0 '0,0 0,0 0,0 0.0 O,D 0 ~ 0 0,0 0

0 0.0 4.0 0 ~ 0 0,4 0.0 0,0 Oi4 0 '

0 ~ 0 0 ~ 4 0 ~ 0 0.0 0 ~ 0 0,0 0 '

Oo0 0,0 0 ~ 0 0.0 0,0 0 '0,0 0,0 0 ~ 0 0.0 0.0 0

0 0 ~ 0 0.0 0,0 0 '

0 ~ 0 0 ~ 0 0 ~ 0 0'

0' 0 '

0'

,Oi0.

0 ~ 0 0 ~ 0 0 ~ 0 0,0 0'

0.0 0 ~ 0 0 ~ 0 0 ~ 0 0.0

~

0 ~ 0 0,0 0,0 AD 0

0 0

0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0,0 0 ~ 0 0 '

0 '

0 ~ 0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 Oi0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0'

0 ~ 0 0.0 0.0 0 ~ 0 0.0 0.0 4.0 0 ~ 0

.0 ~ 0 0 ~ 0 0 ~ 0 0

0 0.0 0 ~ 0 0 '

0 ~ 0 0,0 0.0 OiO 0.0 0,0 0.0 0.0 0 ~ 0 0 ~ 0.

0.0 0.0 0.0 0 ~ 0

0. ~

0, ~

DAN 0,4 0, ~

0, ~

0,0 0 ~ 0 0, ~

0,0

0. ~

0,0 0,0

' '0,0 SUSTOTAL 0.0 OiO 0,0 0.0 0 '

0,0 0 '

0.0 0.0 0,0 TOTAL tOURS OF VALID OSSCRVATIONS TOTAL COUR5 OF CLCVATCD RCLCA555 TOTAL ROURS OF STASZLZtT CLASS A tOtAL COURS OF CLCVATtD STASILZTT CLASS A 101) ~ 000 1751 ~ S)S

)S, F 4' SFLIT JOINT FCRCSNTAOC Ftt UCNCItt OF WIND 5FttD tt VIND DZRCCTION FOR 5tASZLZtt CLASS 5

)

1 SC DCLTA T<i ).) C/100 N)

DROWNS FCRRT NUCLCAR SLANT TART I OF I CLCVATCD RCLtASC NODC JAN 1 ~

SO NAR )1 ~

SO WIND DZRtCTZON N

NNC rttrs C,

C5C 5$

55$

5

$ 5V 5W VSV W

VNW NW NNW CALN 0 ~ 0 0 '

0 ~ 4 0 '

Oi0 0,0 0 ~ 0 0,0 0 '

Oi0 0,0 0,0 0,0',0 0,0 0 ~ 0 0.5 1.4 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0.0 0,0 0,0 0.0 0.0 0.0 I

0,0

0. ~

1 ~ 5 ).4 0.0 0.0 0.0 0,0 OiO 0 ~ 0 0 ~ 045 0'

0 ~ 0 0 ~ 0 0,0 0,0 0,0 0,0 0 ~ 0 0 ~ 4 0 ~ 0 Di0 0,0 0 '

0 '0,0 0 '

0.0 0 ~ 0 0 ~ 0 0,0 0~0 0 '

0 '

0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0.0 0.0 0 ~ 0 0,0 0,0 0 ~ 0 0 '

0.0 0,0 0 ~ 0 0 ~ 0 0,0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0,0 0 ~ ODS 0 '

0 ~ 0 0 '

0 '

0 ~ 0 0 ~ 0 0,0 0 '

0.0 0 '

0 '

0.0 0.0 0 ~ 0 0 '

0 '

D.D 0 ~ 040 0 ~ 0 0 ~ 0 DiD VIND ssctD)NFN)

).5 5.4 5.55) ~ 4 7 ~ 5 11.4 11 '

14- ~

14.5 14 0 ~ 0 0,0 0.0 0 ~ 0 0,0 0,0 0,0 Di0 0 ~ 0 0'0 0,0 0,4 0.0 0.0 0,0 0 ~ 0

)0)4 ~ 5 0.0 0.0 0,0 0 ~ 0 0,0 0,0 0,0 0,0 0,0 0 ~

4',0 0 ~ 0 0.0 0.0 0,0 0.0 0'

0,0 0.0 0,0 0,0 0.0 0 ~ 0 ~ 4 Oi0 0,4 0 ~ 4 0,0' 0,0 0,0' 0,0 0 ~ 0 0 '

SUSTOTAL 0 '

0 '

0 ~ 0 ~ 5 0.0 OiO 0,044 0 ~ 040 0 '

0 ~ 4 0 ~ 17 ~

TOTAL NOUS ~

OF VALID ODSCRVATIONS tOTAL COUSS OF CLCVATCD RCLCASC5 TOTAL COUR5 OF STASZLZTI CLASS S

TOTAL COURS OF CLCVATCD STASILITT CLASS 4

10)S

~ 000 1)5).S)S 17 ~ 550

) ~ ~ )0

Enclosure 1

Page 26 of 53 TABLE 1C (Page 2 of 4)

BROWNS FERRX NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCX DISTRIBUTION IN PERCENT FOR SPLIT-LEVEL RELEASES

'LEVATED PORTION srr.xt Joxct rcaccataoc rac vcccxcs or wxcn stean at oxen nxacctxoa roa 5TASILITT CLA55 C L

1 1i DCLTA TXQ L,S C/100 NI SCOTNS react NVCLCAN SLANT tact 1 or 1 SLSTATSD CCLCAsc NODS JAN 1 ~

$ 0 NAN )1 ~

$ 0 NIND

\\

N NNC NC CNC

~Sc Sc SSC 5

SSW SN NSV N

VNV NW NNV SVSTOTAL CALN 0,0 0.0 0,0 0.0 0 '4,0 0,0 0.0 0.0 0,0 I ~ 0 I ~ 0 0,0 0 ~ 0 0,0 0 ~ 0 0.0 0 ~ 0

~

0 ~ 0 I ~I 0 ~I 0.0 0,0 I ~ 0 0.0 0,0 I ~ 0 0,0 0.0 0 ~ 0 0,0 0'

Owl 0.0 0.0 Oel 0 ~ 0 I ~I I'D 0,0 0 ~ 0 0 ~ 0 0 ~ 0 ~ 1 0 'I ~ 0 0 'I'D 0,0 I 0 OoO 0 ~Dit O.C L.i L.S ).I 0 ~ 0 0 ~ 0 0 I 0,0 0,0 0 ~I 0,0 I ~I 0,0 0.0tl 0 ~ Oit I ~I I ~ 0 I ~I 0 '

0 '

I ~ li1 0 ~ 4 0

0 0.0 0,0 0'

0,0 0.4 I~ Dit 0,0 0,0 I~ 0 0 lii 0 ~ Oil 0 ~ 0 Owl 0 ~ 0 0 ~lio NIND srccn{NFNL

).I S.i S,S 7.i 0,0 0 ~ 0 0 ~ 0 4'I ~I 0 ~ 0 0.0 0

0 I 0 0 ~ 0 0'0 ~ 2 0 ~ 0 0 Oil 0.0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0 '

0 ~ 0 0,0 0 'I'D 0 ~ 0 0.0 0,0 0,0 I ~ 0

~ 041 0 ~ 0 0 ~ 0 I'D 0,0 0,0 I ~I 0,0 0 ~ 0 0 I 0 ~ 0 Oo0 0 ~I 0 ~ 0 0 ~ 0 0 ~ 0 4 '0,0 Ool 0,0 I ~ OI) '.oll 0 ~ 0 7

S 11

~

12 1 ~ ~ I 14.5 IQ)i 5 0,0 0,0 0,0 0.0 0,0 0.0 0 '

DE 0 0.001 0,0 0.0 D.O 0 '

0.005 0,0 0 '

0 ~ 01$

0,4

0. ~

0 ~ 0 0

~

0 ~ ~

0

~

0.4 O.lit 0 ~ 054

'0. 0$ ~

0,0'11 0 ~lii

0. 110 0 005 0.0 0.0 0 ~ 415 TOTAL Cova5 or TALID oascavATIocs TOTAL sovas ot cLCTATCD SILcAscs To'TAL aovas ot STAOILITT cLA55 c TOTAL coo55 ot CLCVATCD STAOILITT CLA55 C 10)1,000 17 ~) 11$

li~ 200 11 550 srLIT Joxat rcaccctaoc rac ocacxcs ot vxro stean ox wxan oxacctxoc roa 5tASILItt CLASS D

I 1 ~ SX DCLTA t<Q 0 ~ 5 C/100 NI saowcs FcaaT NvcLCAC tLANT FAat 2 ot 2 ILCTATCD CCLSAsc Nooc JAN 1 ~

$ 0 NAN )1 ~

$ 0 WIND Q

N NNC Nc CNC 5

555 55 SSC 5

5all SN WSV W

NNN Nlt Scil CALN 0.0 0.0 0.0 0 ~ 0 0 'I ~ 0 0 '

0 '

0 ~I 4,4 0,0 0,0 0.0 0,0 0,0 I ~I 4 ~ 0 0 ~ 0 0 '

0 '

0 ~ 0 0,0 0,0 0 ~ 0 0 ~ 0 I ~ 0 I ~ 0 0 ~I 0.0 0.0 0 ~ 0 0,0 4,0 Delft D.ll1 0.0 D,oit 0,0$ ~

0.) ~)

0 ~ 2 ~ 5 0 ~ 0it 0,0 0 ~ 1 ~ 7 0 Li) 0.0 I ~ 0 ~ 1 0,0 I ~ 01 ~

0 '

L.i 1.5 ).i I ~ito

~Cll O,)lt O,Dit 0 ~ 1i7 I ~ )$ 2 I ~ )12 0 ~ 1i1 0 ~ 141 I ~ 2$ ~

D,li) 4.2$ 4 I LSC D.lti 0 ~lit 0.)12 0

CLS L.L'7) a 0 ~il~

0 ~ LIS 0 ~ 014 0.)21 0 ~ )CC I ~ LSL I+Ill 0.1$ 0 I )i)

I ~ 754 I i11 F 2)2 0.015 INC)L VINO 5 ~ CCD(NFNL

).5 S. ~

S.S 7. ~

1)1lll 1.11C 4 241 0 417 I ~ ~ Ci 1 lit L.itt 1 ~ 175 O,C11 I lit 0.1$ 1

0. ~It O.lii 1 447 I ~ SII 1.121 1 ~ )SI 0 ~ 1CL I'D 0,0 Oe)22 1 ~ 211

).7)i

)e)0) 0+ 41)

Oe))$

0 ~ OI0 0 ~iil 1 ~ 04i 0 ~ Sli 1,040 0 ~ 1 ~ 4 0'0,0 0 '

0' 0'I ~ OS1

0. i)1 O.j)L D.lii 0.254 0.1)C 0 ~ll)

O. 20)

O,ill 0 ~4)i 7 ~ 5 1).i 12 ~ 5 Ll.~

1I ~ 5 2 ~.I

)024 5

0,0 0 '

DE 0 0.0 0 '

0 '

0 ~Oll 0 ~ 015 0 ~ 0I1 0,0 0 '0,0 D.O 0 ~ DLI I')1 4 '

I ~Cll

~.1 ~ 0 1.141 0 ~ 4 1 5 0,'1CS L ~ 111 I ~ 411 I ill 152 2

~ 21 1 ~ IDS 1 ~ SIS 2 701

) ~ 0 ~ 1

) ~ 011 SVatOTAL I'D 0,0 L.i)2 4.$ 51

~ ~ C17 Ll~ 511 12 )51 2

$ 01 I ~ 101 il~ $ 50 TOTAL Socas OF TALID OISCAVATlocs TOTAL covas DF cLcvATID acLcA555 TOTAL cooa5 ot 5TASILLTT CLA55 D

To'TAL SOVCS ot CLCTATCD 5TASILITT CLA55 D 2011 F 000 17$ ) ~tlt 1024 F 210

$$7 ~ )20

Enclosure 1

Page 27 of 53 TABLE 1C (Page 3 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FO SPLIT-LEVEL RELEASES

. ELEVATED PORTION Itttf Jntct Fcaccctldt Fac vccctcc VF vtcn ctccn If wtan DIatcTzoc Fna STAIZLIT'I CLA55 C

)

4 ~ 5<

DCLTA TC< I ~ 5 C/100 N)

IIORRS FCCRT RVCLtAR FLIRT FAat 2 OF 3 cLcvAfCD RCLCASt NODS JAS L ~

$ 0 ~ NAR 11 ~

$ 0 NZRD DtatCTIOR CAIN I ~ ~ L. ~

1.5 t. I RIRD SFRRD{NFR) 3.5 S.i

~ 5 1 ~ 5 Il ~

12 5 Il.i I~.5 Ii.i

)eti.s TO'tAI R

RRC Rt CRC t

ISC IC

$ 5C 5

$5)t SW RSW W

lAW Rll RSW

IVSTOTAI, I ~ 0 0 '

0 '

o.o 0,0 0.0 0,0 o

o 0,0.

0 0

0.0 I ~ 0 0,0 0,0 0,0 0,0 0 ~I 0,0 0.4 0,0 O,O 0,0 0,0 0,0 0.00'it 0,0 0 ~ 0 0,0 0 ~I O,oit O,lit

~ ~ Otl 0,0 I ~oit 4,0$ 0

.I ~I 0 Oi'I

0. III O.LSC 0 ~lit 0 colt

~ lit I ~Otl 0 141 0 ~Oit I ~ 0 ~I 1,01$

0. 154 O,ill 0 ~ 2$i O,SKI I ~I~ 1 0.1IS 0 e145 0.245 0elil 0 ~ 1$ 4 Oeltl I ill 0e141 o,oit O.otl 0 ~ Oil 5 F 002 0 Iil O.ill 0.233 0 ~ 0$ 4 0.1$ 5 0 ~ CI ~

I ~ 214 0 ~ sli

0. 32I 0 ~ 0$ 4 0 eIll 0 ill 2 ~ill

) ~ II2 v Ito

))'.Ill 5

0 C

0 11$

I ~4il

0. 41i O,ill 0 341 1.1is 401 1 ~ 512 I

~Li 0,2$ $

oelol.

0.130 O.ill 0.5L5

0. 3il 0.020 13 ~ 0$ ~

I 142 Oeoll Oe120 0.0 0.041 0.143 I ~ $ 13 I ~ 4 ~ 4 I 121 I ~ 4 ~I 0 ~ 11$

I ~ 11$

0 ~ 1 I0 0,0 0 0 I ~ 122 C ~olt Oeo I ~ 0 0 ~ 0 0,0 0,0 0,0 0 221 0 ~ ~ 14 I ~ 103

0. 120 0 ~ 0 0 ~ 0 I ~ 0 0.023 0 0 0 '

I ~ 0$ 0 I I 0,0 0 '

0 '

0 ~ Ool I F 050 0 ~ 013 0.0 0.0 0,0 0.0 0,0 0 ~ 001 4 ~ 0 0 ~ 01i 0.14$

i,i51 I ~ 121 I ~ 014 0 ~Ill I,311 i,1$ $

C.CIZ i,lit I ~iol L.lii

',$ 1$

I 115 0 ~ l1C 0,401 I ~ Lll 31 531 TOTAL ROVIS OF VALID 005RCVATIORS TOTAL IOVII OF CLRVATCD CCLCAIC5 ToTAL sova5 OF 5TAstIITZ cLASS t TOTAte COVC5 OF CLCVAT'CD 5TAIZLZTT CLASS C

203$ F 000 1151

$ 2$

11$ Ctl Cil.lil 51LIT Jottf Fcacctflot Fac vttcttl OF vttn Itctn if Ntrn ntaccftnt Foa STASILITT CLAIR 1

) I si DCLTA t<~ I ~ 0 C/100 N)

ICORRS Fcatf RVCLRAR 1IART

~Aat 2 01 2 CLXfATCD RCLCA5t NODS JAR I ~

$ 0 NAR lie to

'WZRD RNtt RCttt C

CSR 5CSlt 5

SIR SR WIN R

WRR RR CAIN 0,0 Oeo 0,0 0,0 0,0 0.0 0,0 0.0 o.o 0,0 O,IOI 0,033 I ~I I ~ OOI 0 ~ 0 I ~I Oeo 0,0 0 'I ~I 4 '

0 '

0 ~I 0,0 0 ~ 4 0 ~ 0 I ~ I 0 'I ~I 0,0 Oeo I ~ 0 0 ~ 0 I ~ 0 0 '0,0 0,0 0.0 0,0 0 '0,0 o,o O.oit 0.1$ C I ~I O,oit 0 'I ~ 0 O.C I ~i 1.5 ). ~

RZRD 5 ~ CCD)NFR) 3.5 S. ~

5.5 1.i 0.0 0 ~Oil 0

0 I ~ 0 I ~ 0$ 0 0 ~I I ~Oit 0 ~ 0$ 3 0 4i$

4 114 0 ~I

0. alt 0 alta 0 i25 O,lit I ~I~I 0.05 ~

I ~Lii 0 liS I ~ 0 I ~I

0. III leo 0.0$ 4 ISO)I 0 ~ OIC 0 '

0.0 0 ~I I ~ 0$ 2 Oel 0,0 Oello 0 ~Oil oeo I ~ 110 I ~ 101 0elol 0 ~ 2CL oelC5 0elCL 0 e111 0eill 0 ~I~ 5 I ~ Oii I ~ 0 0 ~ 0 I ~I Oeo Oe001 Oeo 0 ~I I OIL 0 ~ 0 0,0 ~ 0 O,oio 0,0 0 ~I 0.0 Oeo 0.0 0.0 0,0 I ~ 0 0.0 0,0 0 ~ 0 I I 0 ~ 0 0 ~ 0 0.0 0 '

0 L

~ ~

0,0 o ~ o 0.0 0.0 0,0 0,0 I I

7. ~-ee.

ie.e-e ee.e-ee.e

)02i 5

0 ~ 0 0.0 0,0 0.0 I ~I 0 '

0 '

0 '0,0 lan 0 '

0 ~I 0 '0,0 led

~. ~

0 ~ I'1I 0

123 0 ~ 0 ~I I ~ 15$

I ~ 150 0 ~ 13 ~

I ~ 041 0 ~ill I 503 0 ~ ~ 22

0. 41$

0.34$

O,LII 0 ~ 051 0.0$ 2 4,0 SVSTOTAL 0 ~ Oit 0,0 I ~ 2$ ~

I ~ $ 01 I 1ts 2 F 344 I ~ 2 ~ 3 I ~I I ~ 0 5.143

'fOTAL ROVIS OF VAIID 055CRVA'fZ055 fotAL ROVI5 OF CLCVATCD RRLRAICI TOTAL ROVCS OF STAIILIT'f CLASS tOTAL ROVC5 OF CLCVATCD SfASZI ITT CLASS 1 103 '000 1151 ~ $ 2$

111 ~ $ 50

)11 510

Enclosure 1

Page 28 of 53 TABLE 1C (Page 4 of 4)

BROGANS FERRY NUCLEAR PLANT METEOROLOGICAL DATA F1RST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR SPLIT-LEVEL RELEASES

~ ELEVATED PORTION 5fLZT SOZCT tt\\CISTAOC ftt OCSCIt5 Of VZDD 5TSCD 'ST WISD DISCCTIOW fOS 5TASILITT CLA55 4

{DCLTA T 5 l 0 C/100 Nl SSOCCS fSCAT COCLCAC tLACT tAAT 1 Of 2 CLCTATtD CtLCASC COOS JAC I, 50 IQC 11, 50 WICD DZDCCTSOS 5

SCC CC CCC C

CSC SC 55C 5

SSW Slf WSW W

WÃN

ÃW CRT 0'

0' 0 '0.0 0 '

0 '

Oo0 0 '

0 ~ 0 0,0 0,0 0 '0,0 0,0 0,0 0.0 0 '0,0 0.0 0 '

0 '

0,0 0.0 0 '

0 '

0' 0,0 0,0 0,0 0.'0 0 '0,0 0 ~ 0 0 ~ 0 0,0 0 '0,0 0.0 0'

0 ~ 0 0 '

0 '0,0 0.0 0 ~ OlS 0,0 0 ~ 0 0 ~ 0 CALXO ~ I l

15) l 0 ~ 0 0 ~ 0 0,0 0,0lS 0,0 OoO Osl$ 5 0'

0 ~ 0 OA 0 '

0 '

0.0 0 ~ 0l5 0,0 0 ~ 0 0 ~ 0 0,0 0 '

0 '

0 ~ Olt 0 ~Ill 0 ~Oll 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0

0 0

0 0,0 0 ~ 0 WICD SSCCD(NSCI I 5 5. ~

$.5 7.l 0 ~ 0 0 ~ Oll 0,0 0,0 0.110 0 ~Oll 0 ill 0

0 0 ~ 0 0.0 0 ~ 0 0 '

0.0 0.0 0,0 0,0 0,0 0,0 0 ~ 0 0 ~Oll 0.0 0

0 0'

0.0 0 '

0,0 0 '

0 ~ 0 0 '

0 '0,0 0.0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0.0 0,0 0 ~ 0 0,0 0.0 0.0 0,0 0 ~ 0 0,0 0,0 0,0 0.0 7.5-11.l 12.5 1 ~. ~

10.$

>all

~

0.0 0.0 0.0 0 '

0.0 0'

0 '

0,0 0 '0.0

~

0 ~ 0 0 ~ 0 0,0 0 '0,0 0.0 TOTAL 0.0 O.oil 0 ~ 0 0,050 0.17$

0 ~ 1 ~ 5 0 ~ 177 0 '0.0 0,0 0,0 0,0 0 ~ 0 ~ 5 0 ~ Olt 0.0 0,0 5OSTOTAL 0 ~ 0 0 ~ 0 0 ~Olt 0.25' 0.215 0 ~ 151 0.0 ~ 1 0 ~ 0 0 '

0 '75 TOTAL 50055 Of TALID 005IATAT1055 TOTAL 50055 Of CLCTATCD SILCA555 TOTAL COOA5 Of 5TASILITI CLA5S 4 TOTAL SODAS Of CLCTATCD STASILI'ZI CLASS 4 101$

~ 000 1751. 52$

5 ~.10 ~

1$ ~ ~ OO 1858m

Enclosure 1

Page 29 of 53 TABLE 1D (Page 1 of 4)

BROMNS PERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT PRE UENCY DISTRIBUTION IN PERCENT FOR STACK RELEASES JOIN? FtRCtN?AOC FRC DCNCZC5 OF VZND 5?CCD

$ ? VIND DZRCCTZON FOR STAR)LITT CLA55 A

{DCLTA TI< Zot C/100 N)

~ROV$5 FtRRT NDCLCAR SLANT WZND DIRCCTZON CAIJI 0.$ 1. ~

1.$ ).i JAN l,

$ 0 IIAR )Iy $ 0 WZND SFCCD{IIFN)

).5 SAN 5 ~ 5-).i 7.$ 1).i 11 5 I~ i 10 5

1 ~ ~i lo)~

5 TOTAL N

NNC NC SNC C

CSC SC SSC 5$ W 5V V5V W

VNIF NW NNV 5DRTOTAL 0 ~ 0 0

~

0,0 0 ~ 0 0.0 0

0 0

0 0.0 0,0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 4 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 '

0 ~ 0 0,0 0,0 0'

0,0 0 ~ 0 0,0 0,0 0'

0 '

~ 0 0,0 0,0

, 0,0 0 ~ 0 0 ~ 0 0'

0

~

0,0 0,0 0 ~ 0 0 ~ 0 0 '

0 ~ 0 0.0 0 ~ 0 Oo ~

0 ~ 0 0

0 0

0 0'

0.0 0'

0 '

0

~

0 0

0 ~ 0 4.0 0,0 0 ~ 0 0,0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0'

0.0 0

0 0 '

0 ~ 0 0,0 0,0 0 '

0 '0,0 0.0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 OeO 0 ~ 0 0 ~ 0 0 ~ 0 0 '

0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 '

0 ~ 0 0,0 0 ~ 0 0 '

0 ~ 0 0

0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 '

0 ~ 0 0 ~ 0 0 ~ 0 0,0 0.0 0,0 0,0 0 '0,0 0.0 0

0 0 ~ 0 0.0 0,0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0 '0.0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0

0 0 ~ 0 0,0 0,0 0 ~ 0 0,0

0. ~

0.0 0.0 0,0 0,0 0,0 0.0 0.0 0.0 0.0 0 '0,0 0 ~ 0 OeO OeO 0.0 0 ~ 0 0.0 0,0 0.0 F 4 0 ~ 0 0 '

0,0 0,0 0 ~ 0 0,0 0 ~ 0 0,0 0oD TOTAL NOOR5 TOTAI COORS TOTAL NONR5 TOTAL ROOR5 TOTAL COORS OF VALID STASILITT ORSCRVATZONS Zot)

OF $TASILZT'I CLASS A 0

OF VALID VICD DZRCCTZON VIND 5FCCD O'TASILZTT CLASS A 0

OF VALID WIND DZRCCTZON WIND SFCCD STMZLITT OSSCRVATZON$

100$

CALII 0

JOIN? FtRCtt?AOR Ftt OCNCZC5 OF VZND SFC!D 0? VIND DIRtCTZON FOR 5TMILZTT CLASS ~

( l.ti DCLTA TIe 1.) C/100 N)

~ROVRS FCRRT NQCLCAR FLMT JM 1 ~

$ 0 NAR )1 ~

$ 0 WIND 0

N NNC NC CNC C

C5$

SC 5)C 55)V SW VSV W

VNW NW NNV CALN 0e0 0.0 4 '

0 '

0 ~ 0 0,0 0,0 0eO 0 ~ 0 0 ~ 0 0,0 0.0 0 '

0 ~ 0 0 '

Oe0 O.i 0,0 0 ~ 0 4 ~ 0 0 ~ 0 0 '

0,0 0 ~ 0 0'

0 '

0 '0.0.

0 '

OeO 0 '

0,0 I

5 ) ~ i 0.0 0 '

0 '

0.0 0,0 0 '

0.0 0.0 0 ~ 0 0.0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0,0 0 ~ 0 0.0 0 ~ 0 0 ~ 0 r 0 ~ 0 0 '0,0ii O,oii 0,0 0 ~ 0 0 ~ 0 OeO 0 '

0 '

0,0 0 '

0 ~ 0 0 '

0 ~ 0 0 ~ 0 0.0 0 '

0 '0.0 0'

0,0 0 '

0 '

0 ~ 0 0 ~ 0 WIND SFCCD(NFN)

) ~ 5 S,i 5.5 ).4 0,0 0,0 0,0 0,0 0

0 0,0 0.0 0.0 0 ~ 0 0,0 4 ~ 0 ~ 0 0,0ii 0,0 0.0 0,0 0,0 0 '0,4 0.0 0.0 0,0 0.0 0.0 OeO 0.0 0,0 0 ~ 0 0,0 0,0 0.0 0 '0.0 0

0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0,0 0 ~ 0 0,0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 040 0 '

0 '

0 ~ 0

).5 1).i 11.$ Ii.i I~.5 )i.i

)0)i'd) 0 ~ 0 0 ~ 0 0 ~ 0 0 '

0,0 0 ~ 0 0.0 0

0 0,0 0,0 0 '

0.0 0 '

0 0

0 ~ 0 0.0

0. ~

0.0 0.0 0 '

0,0 0, ~

0,0 ~ 4 O,0ii 0.0 0.0 O,oii 0,0 ~ 0 0.040 0,0 0.0 0,0 SDRTOTAL 0,0 0.0 0 '

0 ~Oti 0 ~ 0 0.0ti OsO 0 ~0ii 0,0

0. )io TOTAL COORS OF VALID 5?AS)LITT OSSCRVATIONS 10$ )

TO?A!

COORS OF 5?ASZI ZTT CLA55 0 5

TOTAL NODR5 OF VALID VIND DIRCCTION WIND SFCCD STASZLITZ CLA55 0 5

TOTAL ROOM OF VALID WIND DIRCCTION VINO SF!CD STASILIT'I OSSCRVATIONS

)00$

TOTAL COORS CAIJI

~

0 1858m

Enclosure 1

Page 30 of 53 TABLE 1D (Page 2 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT IFOR STACK RELEASES Joist tcsczstAoc tst ocsczc5 ot >>zsD 5tccD st >>ZND Dzs'CCTzor tos 5TASZLXTT CLASS C

I 1 74 DCLTArt(~L~ 5 C/100 ff)

SRO>>S5 tCRRT NDCLCAR tLANT JAN 1 ~

$ 0 ffAR )ly $ 0

>>IND nzscctzor CAZJf O.C 1. ~

1.5 ).i

>>zso Stccnfrts)

).5 5. ~

5.5 7.4 7,5 11 ~ ~

12 ~ 5 14 I 14 ~ 5 1 ~ ~ I TOTAZ r

NNC rc CNC C

CSC 55 SSC 5

55>>

5>>

>>I>>

>>N>>

N>>

Ns>>

SOSTOTAL 0 ~ 0 0

0 0 ~ 0 0 ~ 4 0 ~ 4 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 o.o 0

0 0

0 oao 0 ~ 0 0,0 0,0 0 ~ 0 0.0 I~ 0 I ~ 0

~ 0 0,0 0,0 0 ~ 0 0.0 0'

0'I~ 0 o.o

~ oo 0 ~ 0 4 I 0 ~ 0

~,0 4 ~ 0 0 ~ 0 0 ~ Oi ~

0 ~ 0 0 ~ 0 0

0 0

0 0,0 0,0',0 0 ~ 0 0 ~ Oi~

0 ~ 0 I~I 0.0 I~ 0 0,0 0,0 4.0 0 ~oil 0 ~ 0 0 ~I O.oil 0 ~ OII 0,0 0

0 0'

0 ~ 0 0 ~lii 0 ~I 0 ~I 0'

0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0'O,oil 0,0$ 4 O.oil I~ 0 0" 0 0 ~ 0 0 1$ 2 0 ~ 0 0

0 Oeo I ~ 0 0 ~I 0 ~ 0 0 ~ 0 0,0 0,0 0.0 0 ~ 0 0 ~Oil 0'

0 0

0 ~ 0 0 ~ 0 0 ~ 0 ~I Oeo I~ 0 0 ~ 0 0

0 Ooo Ooo 0,0 0 ~I 0,0 0 '

0 'O,oil 0 ~ 1ii 0.0 0 '

0 '

0.1$ 1 0'0 0

0 0 ~ 0 0 ~ 0 0

0 0

0 0.0 0

0 0,0 0.0 0

0 0,0 0,0 0 ~ 0 0 ~ 0 0

0 0,0 0 ~ 0 0 ~ 0 0,0 0.0 0.0 0.0 0 ~ 0 0 'O.lil 0 ~I 0 '

0 ~ 0 0 '

0 ~ 1ii 0.0 0.0 0.1$ 2 0 ~ 0 0.0 0

0 0 ~ 0 0 ~ 0 0

0 0 ~ 0 O.OIC 0 F 04'

~ 0 0,0$ 4 0

2 ~ 0 0 1$ 2 O.lii 0.0 0.0 4 ~ 415 TOTAL COORS Ot TALZD STASZLZTT OSSCRTAtlON5 20$ )

TntAL COORS Ot STASZLITT CLA5$ C 17 totAL COORS ot TALZO>>ZND DLRCCTION>>ZND 5tCCD STASZLITT CLASS C

17 TotAL COORS Ot TALXD>>ZND DZRCctzor>>ZND 55!CD ITASZLITI OSSCRTATIONS 20IS TOTAL COORS CALN 0

Jozst tllczstAoc t'll Qzsczcs ot >>zsn StccD ST >>IND DzsccTzos toR 5tAIILZTT CLA5$ D

{ 1.5f DCLTA Tfe<<o ~ 5 C/100 rf SRO>>NS tzsst NOCLCAR tLANT JAN I~

$ 0 NAR )1,

$ 0

>>IND c

DZRCCTZON CCAAIJf 0.4 'L.l 1.5 ) ~ I

>>IND stccnfrtr)

).5 I.i 5.5 7. ~

7 ~ 5 Li.i LX ~ 5 1 ~.I 1I.S Xi.~

feX ~.5 TOtAI r

SNC

~ 5 crc C

CSC 5'

SSC 5

$5>>

5>>

>>5>>

,>>>>r>>

N>>

Ns>>

SOSTOTAL oi005 0 F 010 0 ~ 010 0 ~ 021 0 010 O.OLS 0 ~ 015 0 ~ 010 0.0 0 F 005 0 ~ OLO 0 F 005 0 '

0 ~ 015 F 010 0 '

I ~lii 0 ~ 0 0,0 4,0 0,0 0 ~ 0 0.0 0 ~ 0 O,oil 0 '0.0 0,0 0,0 0,0 0.0 0.0 0.0 O.lil I

O.lil 0.0$ 4 4,0$ 4 0.1$ 1 0.0$ 4 O.LII O.ill 0'il 0,0 I ~Ii~

4.0$ 4 0,044 0,4 I ~Lii 0 ~ 454 0 ~ 0 1.2$ 5 I ~ 240 0.1$ 2 4 ~ill

.O.oil 0.0$ 4 Oo))C alii 0 ~ 1$ 1 0.0 0 ' '

0 ~ 1 ~I 0,)li 0,240 0.1$ 2 0 1$ 2 0.054 1.022 0,424 0 ~il~

0,574 0,0$ 4 O.oil 0 ~)Ii 0 ill 0.0$ 4 o,oi ~

0 ~lii 0,0$ 4 0 ~ XII 0 ~)li 4.1$ 2 0,0$ 4 0 ~ ))I I ~I7'I 2 ~oil

).145 1 ~ 727 0 Ltl 0 ~ 240 0.424 0,747 1

1$ 5 1 ~ 151 O.tll 0,71$

0.747 0 ~ IIO 0.424 1.10)

Lel51 1C at)0 2 F 042 1+775 0.$ LI 0.0$ 4 I. 1II O.IC1 1.247 2.0 ~ 1 2 ~ 2)i 1 ~ 055 0 ~)li 0.))C 0'47 1.2$ 5 1 ~ 007 1.)i) 17.402 0 ~ 471 0.1)4 0 ~ 0 0,0 0.0 Ice

)2 0.71$

0.747 1 ~ 5)5 I ~ Lo)

0. 514 0 Lii O. Ilo 1.007 0.$ 11 0 ~ 24 ~

I. $ 11 0.0 0,0 0 ~ 4 0,0 0 '

0,0$ 4 0.$ 11 0,1 ~ 2 I ~ill o,lil 0,0 ~I 0,0$ 4 0,)I ~

0 ~)li 0 )li 0 ~Lii 2.$ 24 5,445 4 ~ 05)

).70) 0 ~ Cii 0,41 ~

2 ~ltl I ill I ~ 711 5 22$

).45 ~

2 025 2 020 2 ~ 7)I 1 ~ ~ 52

)e7$ $

).157 5i.tli TOTAL COORS Ot TALID 5TASZLZTT OI5CRTAT10$5 20'I)

TOTAL NODR5 Ot STASZLZTT CLASS D

1147 totAr. Rooss ot TAz.zo >>zro nzscctzos->>Iso stcco-STASZLITT cLAss o ill~

TOtAL Nosss Ot TALID>>ZND Olslctzos>>ZND stCCD StASZLZTT OSSCRTATZONS 204$

TOTAL COORS CALII 18580

Enclosure 1

Page 31 of 53 TABLE lD (Page 3 of 4)

BROWMS PERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT PRE UENCY DISTRIBUTION IN PERCENT lFOR STACK RELEASES JOISt SZRCCRTAOC 1RC OCNCZCS Ot WIND 51CCD ST WZND DIRCOTION 1OR 5TASILZTT CLASS 5

( I 54 DCL'fA TC< LES C/LOO N)

SROVÃ$ 1CRRT SOCLCAR 1LAÃt JAN I,

$ 0 NAR 31 ~

$ 0 WIND I

CAIN O.C L. ~

1.5-3

~ ~

WZND SICCDLNIN) 3.5 5. ~

5.5 7. ~

7.5 Lj ~ ~

11.5 14.4 14.5 34.4 N

NSC NC CNC C

Css 5t 5$ C 5

SSW SW W5W W

WNW NW NNW SVSTOTAL 0 ~I 0 I 0,0 I'D 0,0 D,O 0,0 0,0 I ~I 0,0 0 'I ~I 4.0 0 '

0 '

Oel 0,4 0 ~ 0 0 ~ 0 0.0 Ooo I ~I I ~I 0,0 0,4 I ~I I ~ 044 0,0 I ~I 0,0 0.0 0 '

0 '

0 ~ Dil I ~I 0,0 I~I 0,04 ~

I ~ 04 ~

I'D 0 '44 0.0 I ~ 014 0 '

0 '0,04I I ~I 0,0 I ~I 0 '

I ~ 344 I~I~I I~Dil 0

OSC 0 ~ OSC 0 ~ 140 0 ~ 144 0,ISED F 04

',0$4 0O,oil O.oil 0 ~Dil I ~ DSC 0 ~ 0 0.0$ 4 43$

I ~ 0 ~I 0 ~I 0 ~ 111 0.0$ 4 0 ~ 1$ 1 0 F 334 0 ~ 134 0

1 ~ 4 I ~ 1 ~ 4 0.1$ 1 0.1'

~ZII 0 ~ 144 0 Llj 0'14 0 ~ Li~

1.4 ~I

0. ~ 11 0

4 ~I 0 Cli I 344 0 ilj 0.574 Loj$5 1 ~ 01 ~

I ~ 171 I ~ 471 0, ~ 40 I ~ 57C 0 ~ 431 I ~jll Ooj40 I ~jll LL 07$

0 ~ 144 0 ~5jl I ~ ZII

0. 140 ICOSA Des ~I I ~ 1$ 1 1 ~Cll 3 ~ 741 L ~ il7 0 ~ 440 0 ~ OSC

0. 431 I ~ 431 I ~ 140 0 ~ IC1 I~ 053 0 ~ 04 ~

0 0 ~I I ~ 140 0,0 0,0 I ~ 334'

~ SII 41$

0 'SS I 433 0 ~Lii O.LE 4 0 ~ 340 0,0 0,0 0.04 ~

404 I~I 0.0 0,0 0'I ~I 0'

0.574 I ~ $ 11 I 1$ 1 0 ~1ii 0,0 0,0 D.lil 0 ~ 0 ~I I ~Ill 0 '

L.SCC 0.747 1 101 I 43$

D,lil I F 007 1.350 4.345

'7 ~ 1$ ~

7 ~ 0$ ~

3 ~ LLI 1.1$ 5 I ~ 1$ $

Lo343 1 ~ 055 D.Cji I 43$

ICAL 351 TOtAL SOOR5 Ol TALZD STASZLZTT OSSCRTATZOSS 3053 TOTAL COORS 01 5TASZLITT CLASS I 757 TOtAL NOOR5 01 TALID VIND DIRCCTZOS VXSD 51CCD STASZLITT CLASS 754 TOTAX. COORS O1 TAX.XD VINO DZRCCTXOS-VXND SICCO-STASXIITT OSSCRTATXOSS 10 ~ 5 TOTAL COORS CADI

~

0 JOINT TCRCCRTAOC 1st VCNCICS OF WIND $1!CD ST WIND DZRCCTION 1OR ITASILZTt CLASS 1 I I 5(

DCLTA T(> 4,0 C/LOO NL IIOVRS 1CRRT CQCLCAR 1LANT JAN I ~

$ 0 NAR IL~

$ 0 WIND DZRCCTZON N

NNC NC CNC I

CSC SC SSC 5

$ 5W SW WSV V

WÃW NW NNW CADI 0 ~ 0 0 '0,0 0,0 0,0 0,0 0'

0 '

O,D 0 '

0 '

0.0 0.4 0 '0,0 0,0 0,0.

0,0 0 '

0,0 I ~ 0 0,0 0,0 0,0 0 '

0 '0,0 0,0 I ~I 0,0 0,0 I'D 0.0

~, ~

I 0

0. 044 0.0 0.0 0

0 0.0 ~I 0.0 0 '

0.0 0,0 0,0$ 4 0.0 0.0 I ~I 0.4 L.i L.S 1. ~

VISD $1CCD(N1SL 3.5 5

~

5 ~ 5 7.4 0 ~ 0 0.0 0.0 0,0 I ~ 0 0,0 0 ~ 0 0.0 0 ~I 0.0 ~I 0Ijii 0 ~Dil 0,0 0 F 04

',0 0,04I 0,0 ~I 0

0 0 ~ 0 0 ~ Dil 0,0 ~I 0'

0,0 0 '

0 ~ 0 0.0$ 4 0,0 0 ~ LSZ 0.0 0 ~ Dil 0.0 0 '

0.0 0 ~ Oil 0.04 ~

0 ~ 0$ ~

0.0 0 ~I I ~ 0 0 ~ 0 0.1$ I 0 ~ OSC 0.344 0 ~ 33C I ~ ~ 31 0 ~ 4IO 0.1$ I 0 ~ 140 D.ill 0 ~ 314 0.1$ 1 0.0$ 4 0 ~ 1$ 1 0 '14 0.0 I ~ 0 ~I 0.144 0,04 ~

0.0$ 4 0.0 0.0$ 4 0 '

O.oil I ~I 0.0 0.ISED 0.0 I ~ 0 0 '

0,1$ 1 0,1$ 1 0.0 0 ~ 0 ~I 0 '0,0 0 ~I 0 'I ~ 0 0

0 0 ~ 0 7.5 11 ~ ~

2j. ~ LI.4 Il 5 1 ~.4

)%14 ~ 5 I 0 0.0 0.0 0 '

0 I 0.0 0 '

0,0 I'D 0.0 0 '

0.0 0.0 0 '

0 '

TOTAL 0,444 0 ~ 3 ~I I ~I 0 F 04'

~ 314 1 ~ 103 I ~ LSL 0 ~5jl I ~ I15 0+334 I ~Ill 0 ~ 044 0 ~ill D ~ ZII 0.144 0 ~ 044 5VSTOTAL 0.0 ~

Oeo 0.1$ 1 F 140 0 F 574 I 3$ ~

I ~ 44C...

0 ~5jl 00 CD 371 TOTAL COORS 01 TALID STASILITZ Ols'IRTATIOSS 10'll TOTAL SOQR5 01 5TAIILIT'ICLASS 1

Lli TOTAL COORS 01 TALID 'WIND OIRCCTIOS VISD Sltto 5'ZASILZTT CLA5$ 1 133 TOTAL COORS 01 TALID VXND DXRCCTIOS VXSD 51CCD STAIILZT'I OISCRTATIOSS 10 ~ S TotAL COORS CAZII I

185 8GL

i

Enclosure 1

Page 32 of 53 TABLE 1D (Page 4 of 4)

BROMNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA FIRST UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT Jozrf rtsctrTAOt fst Utrczts of Uzro 5rttD ST vzro DzRtcTzor fos 5TASZLZTT CLASS 0 lOtLTA T

> I 0 C/100 Nl ssorrs ftRR'5 NUCLSAR rLANT JAN 1 ~

$ 0 NAR )1 ~ I~

16ND DZRRCTZON CALN 0.4 1 I 1.5 1.4 WZND Srtto{rfr) 1 ~I I ~I I ~ 5 T. ~

I 15.4 15,5 1 ~.I ZI.I Zi,i TOTAL Nrrt Nt SNS 55S 55 555 I

55N SN WSW VUrlt I~I I~I Owl

~,I I~ 0 0,0 I ~I I ~I 0,0 0 ~I 0 ~I 0 '

0 '

t NN 0 ~I Nrem 0 ~I SUSTOTAL 0.0 0 ~ 0 I ~I I~I 0 'I I 0,0 I ~I I ~I I ~I I ~I I ~I 0 ~I I ~I 0 'I ~ 0 0 '

0'I I

~

~. ~

~ I

~ ~ ~

~ I I~ ~

0,0 0 '

0 '~,I 0,0 0, ~

0, ~

0,0 I ~ ~

0, ~

I~I I~ 0 I ~I 0 '

0 'I ~ Oil I ~I I ~ 0 0,0 0 'I ~Oil 0 'I ~ 0 0 '

0 'I ~I 0,0 I~ 0 0 ~Oil I ~I I~sil 0 ~ 1II I ~I I ~ 0 0.0$ 4 0.0 0,0 0.0 0,0 0.0 I I 0.0 '

~I 0 ~Ill 0'

0 ~Oil

~ Ill I ~ 054 OeZII 0 ~ 14 4 I~I 0,0 I~I 0 '0,0 0,sing 0,0 0,0 I ~I 0.0$ 4

~

0.114 0.574 0,0 I~I I~ 0 I 0 I ~Oil I ~Oil I 0$ 4 0 0$ 4 0.0 0,0 I~I 0,0 0 ~ 0 0.0 I ~ 0 I+I 0.1ll I ~I I ~ 0 I ~ 0 I ~I I ~ 0

.0 ~Oil I ~I 0 ~I I ~I 0 ~I I ~ 0 I ~I Ooo 0,0 Oos Ooo 0 I I~ ~

0. ~

I ~

I, ~

0, ~

0.0

0. ~

0 '

0 ~I 0'

0 '

0 'I~ 0 I ~

0 '0.0 ~I 0.sing I ~Oil OeZII 0 sli 0 ~ 1II I ~ 1 ~I 0.0$ 4 0,0 0 F 04'

~ 0 0.0 I ~ Oil 0.0 0 '

O,oil 0,0 1.141 ToTAz, sovss or UALzo ITAszozTT osssRTATzoss 1051 TOTAL tOURS Of 5TASZLZTT CLASS 0 11 TOTAL SOURS Of TALZD VZND DZRSCT10N WZSD 5$ 5ID 5TASZLZTT CLA55 4'l TOTAL SOURS or TALZD larD DZRSCTION-NZrD sftto-ITAIZLZTTolstRTATZON5 105$

TOTAL SOUR5 CALN 0

1858m

Enclosure 1

Page 33 of 53 TABLE 2A (Page 1 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FORl GROUND-LEVEL RELEASES JOINT tCRCCNTA45 FRC UCNCIC5 OF WZND 5tCCD ST WIND DIRCCTION FOR CTASZLITT CLA55 A (DCLTA T4> I ~ 9 C/100 Nl SROWS5 FIRST SUCLCAR tLANT AtR 1 ~

$ 0 JUS )0 ~

$ 0 WIND DIRCCTION N

SSC NC CSC

$55 55

$ 55 5

55W 5W WSW

'V WNW SSV CAIN 0,0 0 ~ 0 0 ~ 0 0.0',0 0 ~ 0 0.0 0.0 0,0 0 ~ 0 0,0 0,0 0.0 0,0 0 ~ 0 0 ~ 0 0.6 1.4 0.0 0.0 0,0 0 ~ 0 0 ~ 0 0.0 0.0 0 '0.0 0,0 0.0 0 '

0.0 0.0 0,0 0 ~ 0 I.S 0,0 0,0 0 '0,0 0,0 0.0 0 ~ $ 1$

0 63$

0. ~ 41 O,ltl 0,0 0 ~ 0 0,0 0.0 0.0 0 ~ 0 0 ~ 0 F 0 0 '

0.0 0.0 0 ~ 0it 1.56$

1.030 0.$ )l 0 ~ 14) 0.141 0 ~ Oit 0 ~ 049 0,0 0 '

0 ~ 04$

0,049 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0.0

~

0 145 0 141 0.341 0 ~ 141 0,0 0.0 0,0 0,0 0,0 0,0 WIND SFCCD(NtN)

).S 9 '

9 5 7.4 0,441 0.) ~ 1 0 ~ 0$ 4 0,0 0,0 0,0 0 ~ Oit 0,0 0.0 0,0 0.0 0.0'.0 0 '

0 0, ~ )4 0 ~ Otl 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0.0 0 '

0 '

0.0 0,0 0.0 0.049 0,0 ~ 9 0,049 0,0 0.09$

0,0 0,0 0 ~ 0 0 ~ 0 0

0 0.0 0 ~ 0 0,0 0 '

0 ~ 0 0.0 0 ~ 0 0,0 0,0 0 '

0.0 7.5-11.4 11.5 I~.4 14.5 14.4

)QX4.5 0 ~ 0 0,0 0 ~ 0 0,0 0,0 0,0 0,0 0,0 0 '

0 '

0.0 0,0 0

0 0,0 TOTAI O.5 at 0 ~ 141 0 0$ ~

0,0 0 ~ 0 0 ~ 049

~0)

I ~ llS 1,711 0 ~ 5 ~ 9 0 ~ 147 0,196 0,09$

0 ~ 049 0 ~ )91 O,tll SUSTOTAL 0,0 0 ~ 0 I ~ 111 4.)ll O.t)1 I ~ 156 0 ~ 343 0

0 0,0 9 ~ 469 TOTAL SOU55 OF VALZD STASILXTT OSSCRVATIONS

)111 TOTAL 50455 Ot 5TASILZTT CLA55 A 194 TOTAL COURS OF VALZD WIND DIRCCTZOS VIND 5tCCD 5TASIIITT CLA5$ A 1$ )

TOTAL SOUS5 Of VALID WIND DZRCCTZOS VISD CtCCDSTASILZTT OSSCRVATZONS 10)$

TOTAL SOUR5 CALN

~

0 JOIST tCSCCSTAOC fll VISCICS Ot VZND 5 ~ CCD

$ 7 VINO DZRCCTZON FOR STASIZ,ZTY CLA55 0 I I ~ 9( DCITA T(i I ~ 1 C/100 N)

SROWS5 tCRRZ SUCLCAR tLAST Atl le

$ 0 JUS )0 ~

$ 0

'WIND DZRCCTION N

SNC, NC CSC 5

CSC SC 5$ 5 5

55V

~

5W VSW W

WNW NW SSW CAIJI 0.0 0.0 0,0 0.0 0,0 0,0 0 ~ 0 0.0 0 '

0 '

0,0 0.0 0 '0.0 0.0 0,4

0. ~ I ~ ~

0,0 0.0 0,0 0

0 0 '0.0 0,0 0.0 0.0 0 '

0 '0.0 0.0 0

0 0,0 0 '

I.S 3.4 0,0 0,0 0 ~ 0 0 '

0.0 0,049 0 ~ 196 0.141 0 ~ 490 0.145 0 ~ 049 0

0 0.049 0 '0.0 0 '

0.0 0

0 0.0 0 '

0.049 0.0 0,4$ 0 i 0.141 0.196 0.194 0 ~ 1$ 6 0.194 0,049

0. 04'9 0 ~ 0 0 ~ 0 0,0 0.0 0,0 0

0 0,04$

0.0 0.0 0.0 0,0 0 ~ 147 0.0 0.147 0,141 0 ~ 04$

0.196 0.141 WINO SFCCDINFS)

)

9 9

~

5 5

7 4

0 ~ 141 0.049 0.14) 0.049 0.0 0.0 0.0 0.0 0.0 0 ~ 049 0.0 0.0 ~ 9 0.04$

0.14$

O,ST 9 0.196 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0 '0.0 0,0 0 '

0 ~ 0 0.0 O. 141 0 ~ )41 alit 0,0 0,0 0,0 0,0 0 ~ 0 0

0 0.0 0,0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0

0 0,0 0 ~ 0 7.$ 11.4 11 ~ 5 1$ ~ ~

1$ ~ 5 34 ~ 4 Fe)4

~ S 0.0 0.0 0 ~ 0 0.0 0,0 0.0 0.0 0,0 0,0 0

0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0,0 TOTAL 0,141 0,049 0.145 0 ~ 049 0,09 ~

0 ~ 049 0,6 ~ 1 0.549 0,6 ~ 1 0 ~ 1)6 0 145 0 490 0 ~ ls ~

0,490 I ~ill 0 ~ 3$ 1 5USTOTAL 0,0 0.0 I ~ I~ 4 0.14) 1.667 0.51$

O..D 0 ~ 0 6.)76 TOTAL SOUR5 OF VALID STASII ITZ 4$ 5CRVATION$

1111 TOTAL SOUR5 OF 5TASZLIT'I CLA55 l)3 TOTAL SOUR5 OF VALID WIND DZRCCTZOS WIND SFCCD 5TASILXTT CLA55 l 1)0 TOTAL ROUR5 Ot VALID WIND DIRCCTZOS VIND SFCCD 5TASILZTZ OSSCRVATZOS5 10)t TOTAL SOUR5 CAIJI 0

18S8m

Enclosure 1

Page'4 of 53 TABLE 2A (Page 2 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR/GROUND-LEVEL RELEASES JOINT 1ERCENTAOE tRC UENCZC5 Ot WIND 51EED ST lfZND DZRECTZON tOR STASILZTT CZA$5 C

l I.'Tl DELTA Tfi-I 5 C/100 N)

~ROWN5 tCRRT NUCLEAR tLART AtR I ~ tl JQN 30 ~

$ 0 lflND DZRCCTZON N

NNC NE CNC C

C5$

SC

$ 55 5

$ 5W Ilf W5V W

WNlf NW NNlf 5USTOTAL CALX 0 ~I 0.0 0.0 0'I ~ 0 0,0 0 ~ 0 0,0 0,0 0 '

0 ~I 0.0 0 ~I 0 ~ 0 0 '0,0 0 '

0.4 I. ~

0 '

0 ~ 0

~ 0 0,0 0 '0,0 0,0 OeO 0,0 0 I I ~ 0 0 ~ 0 0 '

0 '

0,0 1.5 ) ~ ~

0,0 I ~ 01$

0,0 0,0 0,0 Ollit I ~5lt 0.4)I 0 ~ 311 I LSC 0.115 I ~ Olt 0 ~Otl 0,0 I ~ 0 0.0 R.RSC WIND SSECDINtNI

) as 5.1 5.5 T. ~

I ~I~ 9 0.0 0,0 0.019 0.0'.0 0 '

0,0 0 '

0 '

0 ~Oit 0.0 I 113 0.0 0 Lis 0.0 0,09I 0,01$

0 ~ Otl 0 '

I ISC 0 ~Oit I ~ Rti 0,01$

0.11T 0 ~ 0$ ~

0.0 0 ~ 1$ 4 0.09$

0 ~ Rti 0.0 0 ~ 01$

I ~ ~Ll

0. I31 lr)~.5 O.OSI 0 ~09l 0,11T I 11T 0,0 0 ~ 0 ~ 9 0,0 0 '0,0 0 ~ 0 0 ~ 0 0 ~ 019 0 ~ LCT 0.313

0. ~Il 0 ~ 1$ 4 I ~ 15I 0,01$

0,0 OoO 0,0 0.0 0,0 0,0 0,0 0.0 0,0 0,0 0.0 0,0 I ~ 095 0 ~ 1$ 4 0.0 0.313 0 ~ 0 0.0 ~ 9 0

0 0,0 I 0 0.0 0.0 0.0 0

0 0 I 0,0 0.0 0,0 0 ~ 0 0.0 0 ~ 0 0.0 0,0 0.0 0.0 0 '

0 ~I 0.0 0.0 0

0 0 '0.0 I ~ 0 0,0 0 '0.0 I 0 0 ~ 019 i,

0.0 T

5 IR 1

11 5 I~

~

I ~

5 TOTAL 0 ~ 1$ 4 0 ~ 115 O,RE 5 0 IIT 0 '

0 ~ 11T

0. $ 11 0 ~ TI5 0.1$ 0 0 ~ Rti 0 ~ 190 0 111 O.itO 0,4)I I.CTI 0 115 T ~ RSI TOTAL COURS Ot VALID 5TASILZTT 0$ 5CRVATIONS RIIT TOTAL NOU$5 Ot 5TASILZTT CLA5$ C 153 TOTAL ROUR5 Of VALID VIND DIRECTZON VISD 51ICD STASZLZTT CLA5$ C I~I TOTAL ROUR5 Ot VALZD WIND DIRCCTZOR WIND 5tCCD STASZLITT OSSCRVATION5 ROSS TOTAL NOQR5 CALN 0

JOINT tCRCCNTAOE 1$ $ UCNCIEI Of WIND 5tCCD 'IT WIND DIRECTZON fOR 5TASZLZTT CLASS D

{ I Sf DELTA Tfi I ~ 5 C/100 NI IROVNS tCRRZ NUCLEAR 1LAST ASR I ~

$ 0 JUN 30y 90 lfZND DIRECTION N

NNC NC CNC 5

55C SC 5$ C I

55W SW lfSW W

VNW NW NNV 5USTOTAL CAIJf 0 ~ 0 0,0 0 '

0 '

0 '0,0 0 '

0 '

0.0 0 ~ 0 0,0 0 I 0.0 I ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0.4 0.0 0 '

0.0 0 ~ 0 0,0 0 'I ~ IIT 0,0$ 4 0 ~ 019 0 ~ 0$ ~

0,0 0,0 0,0 0,0 0 '

0 ~I'

'91 1.5 ).1 O. 313 0 ~ 115 0 ~ LSC 0.115 0 ~ 115 0.1$ 1 I.RRC I.CCT 1.114 I ~ I~ )

0.4' I l)1 I 1$ 0 I ~ Rti 0.1$ 4 0.1$ 4 9.RCS 0.1$ 1 I ~ 5 ~ 9 0 ~ 3$ 1 0 ~ 313 0.11T O.LSC L.l)3 0 '39 O.I) ~

I ITT I ~ Rti L.l)3 1.1)5 0.3$ 1 0 ~ 1$ 1 0 ~ Li)

S.CCR 0,1$ 4 0.)tl O.LSC 0.)1T 0 ~ 0 0 ~ 1$ 4 O,CIT 0.0 ALIT 0.115 0,0 0 ~ 1$ 1 0.Sent 0.5' O. 115 0.1'.110 VIND I~ CCDIN1NI

)

5

~.I 5.5 T.i O.II)

'.t)1 0 ~ 111 0 ~ 01$

0 ~I 0 ~ 019 0 ~ I ~ T 0.0 0

11T I ~ 0 I ~ 0 0 ~ 1 ~ 5 0 ~ 3$ 1 O.TIS 0 ~lll I ~ CCT 0,019 0 ~ 11T 0,0 0,0 0,0 0

0 0

0 0.0 0.0 I ~ 0 0 ~ 0 0 ~ 01$

0.019 0.019 0.A )

0 ~ 1$ 1 0,0alit 0 '

0.0 0,0 0 '0,0 I 0 0 ~ 0 0 '0,0 0 ~ 0 I ~ 0 0.0 0.0 0.0

~.CRI 0.9 ~I 0.01$

T.S-I).1 11.5 Il.i II.S Ri.i

)Q)1.5 0.0 0.0 0.0 0.0 0,0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0,0 0,0 0,0 I ~ 0 TOTAL TCC 1,15'

~ RRC O.TIS 0 ~ 3$ 1 O.T)4 3,5I0 1 105 1.103 1.103 I tll R,T$ 5 R.T95 1.10$

1. t41 I ~ 501 31 ~ 0$ 1 I

TOTAL EOUR5 Ot VALID 5TASILZTT 0$ 5CRVATION5 RLIT TOTAL COURS Ot 5TASILITT CLA5$ 0 415 TOTAL COURS Ot VALID WIND DIRECTION VZND 5tCCD ITASILZTT CLA55 D

431 TOTAL ROURS Ot VALID VIED DIRECTION WIND 5tCED STASZLZTT 0$ 5CRVATION5 103$

TOTAL NOUR5 CALN 0

185816

Enclosure 1

Page 35 of 53 TABLE 2A (Page 3 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR IGROUND-LEVEL RELEASES Joxat ttactNTAOI tac vtaoxtc of Mxao stcco IT Mzao Dzatctzoa foa 5TARILITT CLASS C

I 0 ~ SC DCLTA TC> I 5 0/Loo Nl IROWNS 1 CRRT NUCLCAR 1LANT AtR 1 ~ 90 JUN 30 ~

90 WIND Dxatctzoa Rat NC CNC

'C C5C SC 55C 5

55W 5W W5W W

WNW RW NNW CALN 0'05 0,002 0.002 0 ~ Ooi 0 ~ 004 0 ~ 01L 0.015 Oeoll 0 ~ 011 0 ~ 00'9 0.00

',004 0.005 0 ~ 001 0 F 002 I ~ 00) 0 ~I 0,0 O,otl 0,049 ICOSI 0 ~ 0$ ~

0 ~ 1$ 4

~

0 194 0.1$ 4 0'9 ~

F 049 0 ~ Otl 0 ~ Otl 0 ~ 0 0 '

0 '

I l)i I 343 0 ~ LSC 0+4) ~

0 F 41'

~ ILS 2 ~ 254 1.717 1.$ 42 1 224 O,CIT 0 l)i O,TIS 0.094 0 '92 0 ~ 441 04 L.i I 5 )

4 I 441 I ~ LSC 0.441 0 ~ Lt~

I ~ 441 0

4$ 0 0, ~ IT I ~ 490 0 ~ SI1 I ~ 224 0 'I 490 0 ~ 441 0 ~ 143 0.2$ 4 0.)$ 2 0 ~ 2$ ~

0.145 0.04$

0,049 0 '

0,0$ 4 0 ~ 3$ 2 o,otl 0

1$ 4 I ~ 294 0,049 0 245 0.04$

0.049 0,147 I ~ 34)

WZND 51CCD(NtN) 3.5 5

4 5

5 T.i 0'47 0 ~Osl 0 341 0.0 0 ~ 049 0,0 0,0 ~ 9 0,0 0 ~ OSI 0.0 o,oit 0.0 0 ~oit 0 147 o,otl 0.441 0.0 0.0 0 ~ 0 0,0 0.0 0,0 0.0 0.0 0 ~ 0 0,0 0,0 0.0 0.0 O.osl 0,0 0 ~ 0$ ~

0.0 0.0 0.0 0.0 0,0 0 ~ 0 0.0 0.0 0 ~ 0 0,0 0 '0,0 0

0 0,0 0,0 0'

7.5 Lx.i 12 5 Ll.i II.S'24.4

)%2 ~

5 0.0 0.0 0.0 0 ~ 0 0.0 0,0 0.0 0,0 0 '

0.0 0.0 0 ~ 0 0.0 0 '0,0 0 '

TOTAL 1.722 O,IIS 1 ~ 130 0.$ )C

).SL)

).SSS

2. 51)

).4 ~ 4 3.050 0 ~ 434 1.473 1

42 ~

0'34 0 ~ t)4 1.7)S SURTOTAI 0 ~ Otl '

~ 47L 14.I CO 7.551 2.5$ 9 1 '

~ 9 0 ~ 1$ 4 0.0 0,0 ZI.)47 tOTAL COURS Of VALZD 5TAIILZTT 055CRVAtloc5 2117 TOTAL NOUR5 Ot'5TASILZTT CLASS 401 TOTAL SOUR ~ Ot VALID MIND DIRCCTION MIND StCCD STAIILITT CLASS t 574 TOTAL ROVR5 Ot VALID WIND DIRCCTZON 'MIND 51CCD I'TAIZLZTT OISCRVATION5 20)9 TOTAL COURS CALN JOINT ttactNTAOC tat UCNCICS ot MIND 5tttD Iz MIND 0 MIND Dxatctzoa toR StASIIZTT CLASS 1 I I ~ Si DCLTA T<m 4 ~ 0 C/LOO NF IROMNS fCRRT NUCLCAR tLANT Ata 1,

90 JVN )0 ~

90 WXNDI R

Nat NC CNC C

CSC 5C 555 I

55W 5W MSW W

MNW NNW CAIN 0.0 0

0 0 '

0 '

0,0 0 '0'0 0,0 0,0 0.0 0,0 0,0 0 '

0 ~ 0 0.4 L.i 0.049 0,0$ ~

0.0 ~ 9 0 ~ 4 ~I 0 ~ 147 0.24 ~

0 '47 0.341 O,L47 0.049 O.LSC 0.0 0,0 0.0 0 ~ Otl 0.04$

L.S ).4 0.715 O.TIS 0 ~ Lsi 0,490 0.7)4 O.CIT 1.124 0

$ )2

0. ~ IT O.oit 0 ~ 049 0.0 O.0 9I 0,094 0.194 0 ~ 245 0,245 0,343 0.)4) 0.)i) 0 ~ I ~ 7 0.049 0.1$ 4 0.0 0,049 0.0 0 '

0 '

0 'I ~ 0 0 A )$ 4 0 ~ 2$ ~

O.otl 0,0$ 4 o,osl b.o 0.0 0.0 0 '

0 ~ 0 0 '

0 '

0 '0.0 0 '0,0 0.1$ ~

WIND 5 ~ CZDIN1R) 5.5 7 ~ 4 0 ~ 04$

0 ~ 0 0 '0,0 0.0 0,0 0.0 0.0 0

0 0 I 0.0 0.0 0.0 0.0 0.0 0.0 0,0 Oeo 0 ~ 0 I ~ 0 I ~ 0 0 ~ 0 0,0 0

0 0 ~I 0 ~ 0 0 '0.0 0 '

0 ~ 0 0.0 0.0 0.0 0,0 0 I 0,0 0.0 0,0 0,0 0 '0,0 0.0 0,0 0,0 0.0 0 '0.0 0.0 7 ~ 5 12. ~

12 5 I ~ ~ ~

LI 5

2 ~ ~ 4 F024.5 0 '

0 ~ 0 0

0 0 '

0 '

0,0 0,0 0 '

0 ~ 0 0 'I ~I 0 '

0 '0,0 0 '

0,0 TOTAL I ~ 422 I ~ 324 O.CIT L.)73 1.030 0,san) 1,471 1.275 O,ll) 0 otl 0,2 ~ 5 0,0 0.0' 094 0'9 ~

0.745 SUITOTAL 0.0 2.040 7.140 2.0LL 0 ~ 7 ~ 5 0,049 0 '

0 ~ 0 0 '

045 TOTAL aovRs TOTAL ROVR5 TOTAL NOVR5 TOTAL NOVRS TOtAL NOUNS of VALID 5TAIILItT055CRVATION5 ot I'TAIILITTCLASS f 2117 I~ )

Of V Of VALID MIND DZRCCTZON MIND StttD StAIILITZ CLAS55 1

24C CALN ALID WIND DIRCCTZON WIND 51CCD STAIlLITT OISCRVA I ATI055 2039 0

1858m

Enclosure 1

Page 36 of 53 TABLE 2A (Page 4 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA'ECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOREGROUND-LEVEL RELEASES Jozsr rcacccTAOc rac ocaczcs or vzsn srccn Iz vzro ozaccTzos roa STAI1LITT CLA55 0 IDCLTA T I 4

0 C/300 III Iaovs5 rcMT socLSAA rLAsT Ara 1 ~ to JOS 30 ~ to VZOD DzacCT IOS CAIJI 0.4 1.5 I ~4'zcD srccnIIIINI 3.5 5 '

5 '

9.4 7.5 11 ~ ~

jz 5

1 ~ ~ 4 1 ~.5 14.4

)%zing 5

TOTA1.

Sssc Nc csc csc sc 555 5ssv 5v v5v vvs

~sv

,IOS TOTAL 0,0 0,0 0,4 0,0 0,0 I ~ 0 0.0 0 'I ~I 0,0 0,0 0.0 0 ~ 0 0.0 0 '0,0 0 ~ 0 0.09I 0.194 0,094 0,0 0 ~ 0 0.09 ~

0 ~ 347 0 ~ 194 4 ~ 0 ~ 9 0 ~ 049 0.0 0 ~ 0 0 '

0 ~ 049 0 ~ 049 0 ~ Oit 1 ~ 377 0 ~ZlC O.IIl 0.145 0 145 I ~ 343 I ~ 049 I ~ 19C 0.I'l 0 ~ 09I 0 ~Oit 0,0 0.0 0 '

0'

~ 0 ~ 0 0 ~ 347 0 ~ OII 0.191 0 ~ 094 0.145 0,0 0 ~ 0 0.0 I ~ 0 0.0 0 '0,0 I ~ 0 0.0 0.0 0.0 0 '

0 Ill 0 ~ 0 0,0 0.0 0 ~I 0.0 0.0 0 ~ 0 0.0 0,0 0,0 0,0 0,0 0 ~ 0 0.0 0.0 0 '

0,0 I ~ 0 0.0 0 ~I 0 ~ 0 0 '0.0 0

0 I ~I 0.0 0.0 0 '0,0 0.0 0 '

0 ~ 0 0

0 0.0 0 ~ 0 0

0 0.0 0,0 I ~ 0 0,0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0,0 0 ~ 0 0,0 0 ~I 0.0 0

0 0 '

0 '

0,0 0,0 I ~I 0 ~I 4 ~ 0 0 ~ 0 0

0 0 ~I 0 '

0.0 0,0 0,0 0 ~I 0.0 0 'I 0 0.0 0 ~ 0 0,0 0.0 0.0 0.0 0.0 0 '

0 '

0.0 0.0 0.0 0.0 0.0 0.0 0.931 1.47 3 II'90 0 ~ 141 0 ~ 1l 7 0 ~ 343 O,CIZ I ~jiz 0,0',0 0,0 0,0 0.049 0 ' '

I 194

5. 195 TOTAL lOOM Or TALjo STAS1LZTT OSSSSOATzocs zjj7 TOTAl Sooas Or STAS1LITT CLA55 0 jzs ToTAL sooas or TALzo vzso ozaccczoa-vzco srccn-ITAszLzTT cLAII 0 110 ToTA1. sooas or TALzn vzsn ozaccczos-vzsn srcco-STAIzLzTT osscaTATzocs jolt TOTAL SOOS5 CALN 0

1858m

Enclosure l Page 37 of 53 TABLE 2B (Page 1 of 4)

BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR SPLIT-LEVEL RELEASES GROUND-LEVEL PORTION 51LIT JOZIT FCRCCNTAOC fRC Vtsottt Or WIND SFCCD SY WIND DZRCCTZON FOR 5TASZLITY CLASS A (DCLTA T<0 I 5 C/)00 ll)

SROWI5 1CRRI NVCLCAR FLAst

~ 5 FART 1 Of I OROUID LCVCL RCLtA5C XODC Afa 1 ~

'$0 JVI )0 ~

$ 0 WIND IIst It CIC I

55C 5 ~

SSC 5

55W SW WSWI NIW IW INW CAL)t 0.0 0,0 0.0 0.0 0,0 0,0 0,0 0 ~ 0 0.0 0,0 0,0 0.0 0.0 0.0,

~ 0.4 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0.0 0 ~ 0' 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0,0 0,0 0,0 0,0 0 ~ 0 0,0 0.0 0,0 0,0 0 '

0 0

0 ~ 0 0 F 025 O.oii 0 ~

ORAL 0.0 0,0 0 '

0.0 0.0 0.0 0 '

0

~ I ~i 15). ~

0,0 0 ~ 0 0 ~ 0 0,0 0

0 0 ~ 0 0.070 0.100 0.121 0.05) 0.021 0.002 0,0 0 '

0 '0,0 0 ~ 00$

0.0 0,0 0 ~ 0 0 ~ 0 0 '

0 ~oij O.OSC 0 17i 0 ~ 03) 0 ~ 0 0,0 0,0 0.0 0.0 0.0

~

WIND SfCCDI)tfs)

) ~ 5 S.i 5.5 T.i 5.5 ll~

0 ~ OCC O.OCT 0 ~ 017 0,0 0,0 0,0 0,00$

0,0 0.0 0

0 0,0 0.02) 0.4 0 '

0 ~ OCR 0 ~ 110 Il.l-i.I 0 F 020 0 ~ 0 0.0 0,0 0,0 0 '

0.0 0 ~ 0 0 '0.0 0.0 0.020 0 010 0 F 010 0.0 0 01$

l. ~

5

. ~

0.0 0.0 0.0 0.0 0.4 0,0 0.0 0,0 0,0 0,0 0.0 0.0 0,0 0 ~ 0 0,0 0 '

)Qji.S 0 '

0 ~ 0 0,0 0 ~ 0

'0,0 0 ~ 0 0 ~ 0 0,0 0.0 0 0, 0,0 0.0 0.0 0.0 0 ~ 0 0 '

TOTAL 0 ~ 0$ 1 O.oi7 0.017 0

0 0 '

0 0

0 ~ 1$i 0.200 0 )1$

0.05$

0 ~ 021 O.oii 0 ~ 010 0 ~ 010 0.0 ~ 2 0 ~ 12$

SuatotAL 0.0 0,0 0 ~ 0$ 1 0

37$

0 ~ 110 0 ~ill 0,050 0.0 0.0

~

1.1$ 0 TOTAL NOURS Of VALID 055CRVATIOI5 2012.000 TOTAL ROVR5 Of 4ROVND LCVCL RCLtA5C 1'520 TOTAL NOURS OF 5TARZLITY CLA55

1).$ $ 0 To'TAL NOVR5 Of OROUND LCVCL STARILZTT CLASS A 2)

'ISO 51t,tt JOINT FSRCCNTAOC Fat Utsott5 Of WINO 51ttD SY WZND DIRCCTION FOR 5TARZLITT CIASS I

1 St DtLTA TlR 1 ~ 7 C/100 ill SRONIS 1taat NUCLCAR fLAIT

~Aat I of 2 oaousD t,tvct. RcLCASC IUDC A1R I ~

$ 0 JUI 10 ~

$ 0 WIND 5

I SNC sctst C

CSC St 55C 5

SSW 5N WSW W

WIW NW INW CAtjl 0,0 0,0 0'. 0 0,0 0.0 0.0 0 ~ 0 0 ~ 0 0,0 0,0 0,0 4 ~ 0 0,0 0,0 0 '

0 '

0 ~ C 1 ~i 0,0

~

0,0 0 ~ 0 0.0 0.0 0 '

0 '

0 ~ 0 0 '

0.0 0,0 0 '0,0 0,0 0 '

0 '

ITS-). ~

0.0 0.0

.0 '

4.0 0 '

0 '

0.00C 0 ~ 012 0 ~ Ooi 0 ~ 001 0 '0,0 0,0 0,0 0 '

0.0 0.0 0,0 0.0 0,0 0 '

0.02$

0,010 0.0)0 0 ~ 020 0.0)3 0,011 0 ~ 0 0,0 0 '

0 '

0 ~ 0 0.0 0,0 0,0 0 ~ OOR 0 '

0 '0,0 0.0 0 ~ 0)2 0 ~ 0 0.021 0 ~ 015 0 ~ 001 O.OIC 0 ~ 011 WIND 51!CD(IFI)

).S S.i S.S T.i 5

~ 5 ll.l 0.00$

0,007 0.0)7 0.00 ~

0 ~ 0 0,0 0.0 0 '

0.4 4.030 0 ~ 0 0 ~ 001 0.010 0 ~ 01$

4 '75 0')2 0.0 0.0 0 '

0 '0.0 0 ~ 0 0,0 0 ~ 0 050 0,0 0,0 0,0 0,0 0;0)0 0 F 071 0 ~ 010 0 ~ 0 0,0 0,0 0.0 0 ~ 0 0 ~ 0 0,0 0,0.

0.0 0.0 0 ~ 0 0 '

0 ~ 0 0.0 0.0 0.0 ll~ 5

~ 5 5

~ 5

)%jib 5 0 ~ 0 0,0 0.0 0.0 0 '

0 '

0 ~ 0 0,0 0.0 0,0 0,0 0.0 0 '

0.0 0.0 0 ~ 0 TOTAI 0,00$

0.007 0,037 0.00C 0 F 002 0.0 0.025 0.01C 0 ~ Oi 2 0.050 0'1i 0,0ij AORS 0 ~ OC$

0.151 0 ~ 05i SVRTOTAL 0,0 0". 0 0 ~ Oji 0 ~ 10$

0 ~ 102 0 ~ 1$ 0 0.111 0.0 0.0 0 ~ 514 TotAI, Novas or vALID osscavatzoss 2012,000 TOTAt. NOVNS Of OROVND LCVCL RCLCASC 1$i ~ SRO TOTAL NOVNS of STARZLttt CLASS

~

12.000 ToTAL Novas or OROVID LcvcL JTASILZTY CIAss

~

11.000

Enclosure 1

Page 38 of 53 TABLE 2B (Page 2 of')

BROGANS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FORt SPLIT-LEVEL RELEASES GROUND-LEVEL PORTION sfzzt Jozrt FCRczrtAOR FRcqocrczcl of wzrn sfcln lt wzrn nzrcctzor FOR STASZLITZ CLAI5 C I ~ 74 DCLTA T{0 1 ~ 5 C/100 NI IRONNS FCRRT RVCLCAR FIANT fART 1 OF I OROUND ICVCL RCZCA5C NODC AFR I,

$ 0 JUN lory to WIND DZRCCTZON r

NNC Nl Crc 5

CSC 5C CAIJI 0 ~I 0 ~I 0.0 0 ~ 0 0.0 0.0 0,0 55C 0,0 5

0.0 SSW 0,0 5N 0.0 r534

, 0.0 N

0.0 0.0.

0,0 0,0 0.4 I ~ 4 0,0 0,0 0 ~ 0 0,0 0.0 0 '0,0 0,0 0,0 0 ~ 0 0,0 0

0 0.0 0,0 0 ~ 0 0.0 L.S 3.4 Ooo I ~ 0 0 'I ~ 0 0,0 0.0 I ~ 022 0.017 0,014 0.003 0 F 00

',0 0,0 0 '

0,0 0,0 0 ~ 0 0 ~ 0 0.002 0,0 0.0 0,003 0.01$

0,0 0,040 0 F 007 0 ~ 014 0'13 0,002 0.0 0 ~ 001 0 '

0,0 0 ~ 001 0.0 0 ~ 0 0 '0,0 0,0 0.0 0 ~ 010 0.0 0.004 0.005 0.007 0 014 0.022 0,003 0 ~ 011 0 ~ 014 IDOLS 0,019 0.0 0.009 0.0 0,0 0,0 0.0 0,0 0,004 0 F 027 0 050 0.12I 0.03 ~

0 ~ 010 0 ~ 0 0,0 0,0 0 ~ 0 0.0 0 '

0 '

0,0 0 '

~ 0.0 0 '0,0 0,019 0.043 Oeo 0,0 0.043 0.0 0.0 0 'I I 0

0 0,0 I ~ 0 0.0 0 '

',0 0,0 0.0 0.0 0 ~ 0 WIND Sfccn(NFNI 3.5-5 '

5.5 7 ~ 4 7 ~ 5-12. ~

12.5 Il.i II.5<<24.4

>02 ~.5 0 ~I 0 '

0 '0,0 0

0 0 ~I 0.0 0 '0,0 0 ~I 0,0 0 '

0.0 0.0 0,0 0 '

TOTAI 0 011 0 ~I~ 1 0 ~ 021 I ~ 01$

0 '

0 ~ 012 0.04L 0 ~ 017 0.044 0 ~ 011 0')L 0,027 0 F 034 0 ~ OIS 0

194 0,017 SURTOTAL 0.0 0.0 0,04'

~ 101 0;074 0 '22 0 '73 0 ~ 0 ~ 3 0.0 0 CIL TOTAL COURS OF VALZD 055CRVATZON5 2012.000 TOTAL ROVR5 Of OROUND LCVCL RSLCA5C 1$ ~.Ilo TOTAL ROVR5 Of 5TASZLZTT CLA5S C

Li~ 500 TOTAL ROVR5 Of OROUND LCVCL 5TASILITZ CLASS C

13 710 5FLZT JOISt FIRCINtAOC FRC UCNCZC5 04 VZND 5 ~ CCD It 1fZND DZRCCTZON fOR 5TAIILITT CLASS I I 5< DCLtA T>2 ~

5 0 ~I 0 ~ 0 0.0 0.0 0,0 0.0 0.0 0 '

0.0 0,0 0.0 0 '

0.0 0.0 0,0 0 ~ 0 TOTAL 0 ll) 0 F 073 0 '91 0 ~ 032 0.055 0

114 0.402 0 ~ 350 0 '97 0.379 0 '54 0.130 O,OCO 0 F 072 0 '54 0 ~ 19l 5VSTOTAL 0.010 0.032 0,779 O.SCI 0.5CC 0.3)l 0.0 ~I 0.0 0.0 2,749 TOTAL coURS ot vAZ.ID osscavATI055 2012.000

'TOTAL COVR5 ot OROUND LCVCL RCLCA5C 114. ~ 20 TOTAL ROUR5 ot 5TASILITT CLA55 5 C09.420 TOTAL COURS Of OROUND LCVCXI 5TASZLITT CLL5S I 55 720 srx.zT )oxaT rcaccNTAOC rac vcaczcs or vzao srccn sz vzan nxaccTION roa STASILZTT CIA$5 1 I

1

$ 4 DCLTA T<>> 4.0 C/100 ffx SROVNS tCRRT NVCLCAR rLANT tART 1 Ot I OROUND LCVCL RCLtA5C ftoDC Ara 1 ~

90 JUN )0 ~

90 wzan N

SNC Nt CNC 5

55 ~

5C 555 5

SSN 5V Vs'N Vlfalf NW Ntlf CALN 0,0 0,0 0

0 0 ~I I ~ 0 0,0 0 I 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0 ~I 0,0 0,0 0,0 0 ~ 014 0,007 O.Ill 0.001 0.014

0. 011 0.0 0 '
0 '
0 '
0.0 0 '
~.0 0 ~ 0)2 0.022 0 F 002 I ~ OII 0,0',034 0.05
',109 0,05) 0.0 0.00' I
0 ~I 0.0 0,0 0.002 O.C 1.4 1.5 ).4 0 ~ 0)2 0 F 0'
~ 032 0,015 I F 007 0.00
'.04' 0.010 0,0 0 ~ 0 000 0,0 0,0 0,0 0,0'
~ 04$
0 ~ 015 0.015 I ~ 017 0 ~ 0 0.0 0.0 0 ~ 0 0,0 0,0 I ~ 0 0 ~ 0 0,0 0 ~ 0 0.0 0'30 VZND 59CCDINral
) ~ 5 SAN 5 '
1.4 I.I-II. II.I-I.I 0 009 0 ~I 0 ~ I 050 0,0 0,0 0 ~ 0 0 ~ 0 0
0 0.0 0.0 0.0 0.0 0.0 0.0 0 ~ 0 0.0 0.0
~.
0.0 0,0 0 ~ 0 0.0 0
0 0.0 0.0 0.0 0,0 0.0 0,0 0.0 0,0 0.0 I~
5 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0 ~ 0 0,0 0,0 0 ~ 0
0. ~ D 0 ~ 0 0,0 0,0 0 ~ 0 0 ~ 0 I ~ 0 0.0 f>>24 '
0.0 0.0 0.0 I ~ 0 0.0 0.0 0.0 0,0 0.0 0.0 0 '0,0 0,0 0,0 I ~I I ~ 0 TOTAL O.ill 0.071 0 F 050 I ~ I~I 0 ~ 0 ~ 2 0.054 0.105 I ~ 115 0 ~ 104 0.0 0 ~ 004 0,0 0,0 0,0 0,0 0 ~ ~ 57 SVSTOTAL 050 0.045 0.391 0.239 0 ~ 127 0.009 0,0 I ~ 0 0.0 0 ~ ~ 32 TQTAL RQURS ot vALzD osscavAT1055 2012,000 T0TAL soUR5 ot oaoosn lcvtx RCLcASc 194. I20 T0TAL NDURI of 5TAIILZTT cLL55 19I 920 TOTAL COURS Ot OROUND LCVCL STASILITT CLA55
~
1C ~ 730
Enclosure 1
Page 40 of 53 TABLE 2B (Page 4 of 4)
BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UEHCY DISTRIBUTION IH PERCEHT FOR SPLIT-LEVEL RELEASES GROUND-LEVEL PORTIOH srz,zt zozvt FSRCCCTAoc rRI Ucsczcs or wzsn srscn st wzsn DIRcctzos roR 5TASXLZTT CLA5$ 4 (DCLTA T
~
0 C/)00 K)
SROWRS FCRRZ RVCLCAR FLART FART I OF 2 4ROURD LcvcL RRLSA55 xone AFR 1 ~
90 JUR )0, 90
'WI5D DIRccTzoR 5
SRC SC CRC C
CSC 55 555 5
5$ W SW W5lf W
WÃW
ÃW RVlf CALW 4.0 4 ~ 0 0,0 0,0 4.0 0.0 4,0 4.0 0.0 4,0 4.0 4,0 4.0 o.o o.o 0.0 0 '0.0 0.0 0.0 0,0 4'05 F 005 0,0)9 0.0 0,0 0,0 0.0 0 ~ 0 0,0 0,0 0.0 0 019 0 ~ OSO 0 ~ 014 0 ~ 009 0
0 O. 001 0.0)S 0,070 0.415 0 F 00) 0 '0.4 0,0 0,0 0 '0.0 051 4
I 5 )
~
WICD SFCCD{NFR)
) ~ 9 SKI 5
5 I ~I 0.010 0 ~ 0 0 ~of) 0,0 0 ~ 011
0. 0 0 ~ 019 0
0 0 '
0 0
0 0 0.0 0 '
0,0 0.0 0 '
0 '
0.0 0.0 0.0 0 '
0 0
O.O 0.0 0 '
0.0 0.0 0.0 0 '
0.0 0
0 O.o 0 ~ 0 0
0 0.0 0 ~ 0 0
0 0.0 0,0 0 ~ 0 OaO 0 ~ 0 0.0 0,0 0
0 "0.0 0.0 0
0 0 ~ 0 0,0
~
0 ~ 0 0
0 0 '0,0 0,0 0 '
0 ~ 0 0,0 0.0 0,0 0,0 0 '
~
0.0 0 '
0 ~ 0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0 '
0 ~ 0 0 ~ 0 0<0 0
0 ~ 0 0 '
0 ~ 0 0 ~ 0 0.0 0.0 0 ~ 0 Z.S 12. ~
12 ~ S-I ~ ~ ~
I~.9 Ii.i
}02<.5 0.0 0.0 0,0 0.0 0
0 0.0 0,0 0,0 Oio 0.0 0 '0,0 0,0 0.4 0.0 4.0 TOTAL 0.019 0 F 097 0 022 0,0)9 0 '
0 005 0 ~ 011 0 ~ 10 ~
0 015 0.00) 0.0 0,0 0.0 0.0 0.0 0.0 5USTOTAL 4.0 4 450 0 ~ 192 F 09)
O.o 0 ~ 0 0 '
0,4 0.)fo TOTAL SOVR5 OF VALXD OSSCRVATZO55 TVTAL Rooks or 450URD LcvcL RcLSA55 TOTAI COVR5 OF 5TASZLITT CLA$5 0 TOTAL COURS Or OROVSD LCVCI STAOILXTT CLA5S 4 2012 ~ 000 I I)i.$20 14.9 ~ 0 S,oio
Enclosure 1
Page 41 of 53 TABLE 2C (Page 1 of 4)
BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FORlSPLIT-LEVEL RELEASES
'ELEVATED PORTION 5 ~Z,ZT JOINT
~ CRCCNTAOC FRC UCNCICS OF VIED 5tCCD RI VIND DIRECTION FOR 5TASZLZTT CLASS A (DELTA T{0 1 ~ 9 C/LOO NL SROVN5 FCRRT NUCLEAR FLARE
~ART 1 Ot I ELEVATED RELEASE LLODC ATR 1 ~
90 JUN )Oy 50 VIED DIRECTION N
RNC NC CNC 5
CSC SC 555 5
5$ 'N SV VSV V
VRV
~V NNV CAIll 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0.0 0,0 0.0 0,0 0,0 0.0 0 '
0 '0,0 0.0.
0.0 0 '
0 5
1 4
0,0 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0,0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0.0 0.0 0 ~ 0 1.5 ).4 0,0 0,0 0
0 0 ~ 0 0,0 0 ~ 0 0.0 0,0 0'
0.0 0.0, 0.0 0,0 0 '
0.0 0.0 NIND SOCCDLNFILL
).5>>5.4 5 ASSI ~ 4 0
0 0 '
0,0 0'
0 '
0,0 0 '
0,0 0.0 0,0 0 '
0,0 0.0 0 '
0,0 0 '
0 '
0 '
0 '
0 '
0.0 0,0 0 ~ 0 0,0 0 ~ 0 0,0 0,0 0,0 0,0 0.0 0.0 0,0 0,0 0,0 0 ~ 0 0 ~ 0 0,0 0,0 0 ~ 0 0,0 0 ~ 0 0,0 0 ~ 0 0,0 0,0 0.0 0 ~ '0 0 ~ 0 0,0 0,0 0.0 0.0 0,0 0,0 0 ~ 0 0,0 0 '
0' 0,0 0,0 0 '
0 '
0 '
0 '
0.0 0 ~ 0 0.0 0,0 0,0 0 '0,0 0,0 0,0 0 '
0,0 0.0 0
0 0,0 0 '
0.0 1.5-1 IL.~-\\.
iI.L-L 0,0 0.0 0
0 0,0 0 ~ 0 0,0 0,0 0,0 0.0 0
0 0
0 0.0 0,0 0.0 0 ~ 0 0.0 TOTAL 0.0 0
0 0.0 0.0 0 '0,0 0 '
0 '
0 '0,0 0,0 0 '0.0 0.0 0 '0,0 SURTOTAL 0,0 0
0 0,0 0,0 0.0 0,0 0,0 0 ~ 0 0,0 0,0 TOTAL NOUR5 OF VALID 005CRVATION5 TOTAL ROUR5 OF CLCVATCD RCLCA5C5 TOTAL ROURS OF 5TAOZLLTI CLASS A TOTAL COURS OI'LCVATCO 5TASZLITI CLASS A 1011. 000 1 ~ LI.LTS 1),SSO 0 '
5 ~I.ZT JOINT FIRCCNTAOC FRI UCNCICS OF VINO SFCCD OT VIED DIRECTION FOR STASZLITT CLASS O
1 1 5(
DELTA T(i L,I C/LOO Rl
~ROVN5 FCRRT NUCLEAR SLANT tART I OF I ELEVATED RCLCA55 NODE AFR 1 ~ tO JUN )0 ~
SO VIED N
NNC NC CNC 5
CSC SC
$ 55 5
55V SV V5V
'N VNV NV NNV CALN 0,0 0.0 0.0 0.0 0 ~ 0 0,0 0.0 0,0 0,0 0,0 0 '
0 '0.0 0.0.
0 ~ 0 0 ~ 0 0.4 1.4 0,0 0 '
0 '0,0 0 '
0 '0,0 0,0 0
0 0.0 0 '0.0 OeO 0.0 0,0 0,0 1.S ). ~
0 '
0.0 0 '
0.0 0,0 0 '
0.0 0,0 0.0 0,0 0.0 0.0 0 '
0 '
0 '0,0 VINO SFCCDLlltNL
) ~ 5 ST 4 5.5 7. ~
0.0 0 '
0.0 0,0 0.0 0 '
0.0 0 '
0 '
0,0 0 '
0.0 0 '
0 '
0 '
0 ~ 0 0.0 0.0 0.0 0 '
0,0 0.0 0.0 0.0 0.0',0 0.0 0.0 0 ~ 0 0,0 0.0 0 ~ 0 0,0 0,0 0.0 0 '0.0 0
0 0
0 0.0 0
0 0,0 0,0 0.0 0 '0.0 0
0 0.0 0.0 0.0 0.0 0
0 0,0 0 ~ 0 0,0 0.0 0,0 0 ~ 0 0.0 0.0 0.0 0.0 0,0 0,0 0'
0 '0,0 0 '
0 ~ 0 0.0 0,0 0,0 0,0 0 0'
~ 0 0.0 0.0 0.0 0 '
0.0 I ~ 5 11 ~ 4 11 ~ 5 L~. ~
10 S 14. ~
) ~ 14.5 0.0 0 '
0 '0,0 0 '
0 '0.0 0.0 0.0 0.0 0.0 0 ~ 0 0.0 0.0 0 '0,0 TOTAL 0.0 0.0 0.0 0.0 0,0 0 '0,0 0,0 0,0 0,0 0.0 0.0 0.0 0 '0,0 0,0 SURTOTAL 0 '
0,0 0,0 0,0 0.0 0,0 0 '
0 0
0.0 0.0 TOTAL NOUNS OF VALID OOSCRVATZONS TOTAL ROUR5 OF ELCVATCD RCLCA5CS TOTAL EOURS OF STAOZLLTI CLASS 0
TOTAL NOVAS OF ELCVATCD STASZLLTI CLASS
~
)OL).000 Ill)aLTO L) ~ 000 0.0
Enclosure 1
Page 42 of 53 TABLE 2C (Page 2 of 4)
BROGANS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR SPLIT-LEVEL RELEASES ELEVATED PORTION SPLIT JOINT PCRCCNTAOC f5t UCNCZC5 Of VIND 5PCCD ST VZND DZRtCTZON fOR STAR ILZTT CZASS C
I 1
TC DCLTA TC>> I 5 C/100 N)
SROVN5 ftRRZ NUCLCAR PLANT FART I Of 1 CLCVATtD RCLCASC XODC APR 1 ~
$ 0 JUN 10 ~
$ 0 VIND DZRCCTZON N
NNC Nt CNC C
555 55 555 I
SSV IV V5V V
VNV NV NNV CAIJI 0 'I ~ 0 0,0 0 ~I 0,0 0.0 0.0 0,0 0 ~ 0 0,0 I:0 0 ~ 0 0.0 0 ~ IL 0,0 0 ~I 0 ~ 4 0,0 0.0 I ~ 0 0.0 0 ~ 0 0.0'
~ 0 0.0 0.0 0
0 0,0 0,0 0.0 0 ~ 0
~
0.0 0 '
1.$ ) ~ I 0 ~I 0,0 0 '
0 'I ~ 0 0,0 0 ~ 0 0 '0,0 I I 0 ~I I ~ 0 I ~ 0 0 ~ 0 0.0 0 '
I ~ 0 0'
0 I 0,0
~ 0 Oio 0,0 0,0 0 ~ 0 0 '
0 0
0.0 0:0 0 ~ 0 0.0
, 0.0 0.0 0.0 0 ~ 0 0,0 o ~ o I ~ 0 0.0 0,0 0.0 0 ~I 0 ~ 0 0 ~ 0 0,0 0 ~ 0 I ~ 0 Ooo VI'ND 5PCCD(NPN) 5 S.l 0.0 0.0 0,0 0 '
0.0
'0 ~ 0 0.0 0.0 0.0 0.0 0 '0.0, 0.0 0.0 0.0 0.0 12.$
1 ~ ~ I 1I.S 0 ~ 0 0,0 0 ~ 0 0,0 0 '
0 '
0,0 0 '0,0 0 ~ 0 I ~ 0 0 ~ 0 0.01$
0 ~ 0 0,0 0.0 0.0 0.0 0.0 I I 0.0 0.0 0.0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0,0 0.0 0 '0.0 0.0
>>>RI.S 0.0 0.0 I ~ 0 0.0 0.0 0.0 0.0 0 '0,0 0,0 0,0 0.0 0 '0,0 0,0 0 '
TOTAL 0 ~ 0 0 '0,0 0 ~I 0,0 0.0 0.0 0.0 0,0 0 '
0.0 0 '
0 ~olt 0 ~ 0 0 ~ 0 0,0 5UStOTAL 0.0 0 ~ 0 0,0 0.0 0,0 0.0 0.01$
0.0 0,0 0.01$
tOTAL ROUR5 Of VALID 055CRVATION5 TOTAL ROUR5 Of CLCVATCD RCLCA5C5 TOTAL ROOR5 Of STASZLZTT CLA55 C
TOTAL COURS OF tLCVATCD 5TASZLITT CLA55 C 2012 000 1IIT~ 17$
14
$ 00 0 '50 SPZ,IT OINT ~ CRCZNTAOC FRC UCNCZC5 Of VIND 5PCCD IT VIND DIRCCTZON FOR STASZLITT CLASS D
I 1.$ (
DCLTA T<>>-I ~ 5 C/100 Nl IROVN5 FCRRZ NUCLCAR PLANT
~ART I of 2 CLCVATCD RCLCA5C NODC APR I ~
$ 0 JUN 10,
$ 0 VIND N
NNt Nt CNC C
CSC St 555 5
SSV 5V VSV V
VNV NV NNV CALN 0 '
0 '
0,0 0,0 0 '0,0 0.0 0 ~ 0 0,0 0'
0,0 0,0 0 '0,0 0,0 0,0 0.4
1. ~
0.0 0 ~ 0 0.0 Oeo 0 '
0 '
0.0 0 '50 0.0 0.0 0.0$ 0 I ~I 0,0 0,0 0 '0,0 I.t ).I 0.2$ ~
0.2$ 4 0 ~Itt 0 ~lit 0 ~ I ~I 0 ~ lt~
I.ltl I ~ III 0.1$ ~
0,5$ 4 0.lit 0 ~Itt 0 ~lit 0 ~ 1$ 'I I~ Ott I lit O.ltt I ~ill 0 ~ 24$
0 ~ltt I ~Itt 0.$ ~ 7 I.Ill 0 ~ II7 O.li7 I ~ 2$I I F 444 0.447 0.4$ 4 0 ilT 0 ~ 2$ I 0.1$ $
0 ~ 114 0,425 0 ~ltl 0 ~ Olt 0,1$ 0 0.47$
1,2$ 5 0 ~ 714 O,ill Oe470 0'$ 2 I ~ ~ 20 O,II~
0,474 0 47 ~
0 ~ 1$ 0 VIND 5 ~ CCDINPNI
) AS
%. ~
$ ~ $ T. ~
7.$ 12. ~
0 ~Ill I.lit 0.$ 4 ~
0 ~ 17$
I ~ 0 0 ~ Oil I. $ 4$
I.ill 1 ~ t51 I.OI7 1.101 1.0SI 1.022 1 ~ill 2 ~ 102 1 ~ 074 0 ~ It 1 I F 244 0.14$
0,0 0,0 I ~ Olo 1 ~ 21$
2,044 1 ~ 451 1 ~ 11$
0 F 244 O. II~
I ~ 141 0 ~ $ 15 1, ~ 17 1 ~ 441 0,0 0.021 0.0 0
0 0 ~ 0 0,0 0.111 0.144 I:ITI' F 205 0 ~ 017 0 ~ 11$
0 ~ 011 0.0) ~
0.1 ~ 4 0 ~ 154 P>>1 ~. $
0.007 0.0 I ~ 0 0.0 0.0 0,0 0,0" 0.022 0.
01',0 0 ~I 0 ~I 0,0 0 '0,0 0,0 TOTAL I ~ 7$ $
2. ~ 14 1.$ 77 0.$ 72 I
1 ~ 707 7 ~ 10$
5 ~ 415 I~ 244 1.$ $ 4 1 1I1 1.011 1.024 1 ~ $ 20 7$ 7 1 ~ll0 5OSTOTAL 0 ~ 0 0 ~ 0$ $
5 ~ 447 7 ~ 107 I.44$
17 llI 12 ~ 4 ~ 2 0.0 ~I
$2.7$ 1 tOTAI, COURS Or VALID OSSCRVATIONS To'TAL NOUR5 Of tLCVATCD RCLCA555 TOTAL ROUR5 OF 5TASZLITT CLA55 D
TOtAL ROU'R5 Or CLCVATCD StASZLZTT CLASS 0 2012.000 1 ~ 17.17$
112I.010 1042. 140
Enclosure l Page 43 of 53 TABLE 2C (Page 3 of 4)
BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR SPLIT-LEVEL RELEASES
.ELEVATED PORTION 5tLZT JOINT
~ ERCESTACC FRC UENCZtl OF UIND SFEED St UZSD DIRECTION tOR STAIZLITT CLA55 5 I
0 ~ Sf DELTA Tfr I 5 C/100 N)
~ROVSS tCRRT NUCLEAR tLANT tART I Of I CLCVATCD RCLCASt )IODC AFR I, tO JUN )0 ~
90 WIND DIRECTION Crt Nt CNC 5
$5C 5C 55C 5
55)f 5)f rs)f
)I)frr Nlf Nrr CAIJl 0.0 0,0 0,0 0 ~ 0 I ~I 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0.0 0 ~ 0 0,0 I ~ 0 I F 050 0,0 I ~ 050 0,0 0 'I ~I 0 '
0.0$ 0 0.0 0.0 0.0 0.0 0 '
0 '
0.0 0.0 0.34I I ~ 14$
I ~ 0$ $
0,14$
I lit 0.19'I I ~ )SI 0.1st 0'50 0 ~ 0$ 0 I ~ltl 0 ~ltl O,lit 0,0 0,0$ 9 0 1st I ~ 4 I 4
I 9 ).4 0,29l
~Oe249 I ~lit 0 I ~ '9 0.1st 0.0$ 0 1.093 0.547 0 ~lit 0.)t ~
0,744 I.lit 0.5' I Ott 0.1st 0 ~)ll
0. I)~
O.lll 0.)))
0 ~ Llt 0,0$ 5
0. 417 I ~ 494 1 ~ OLC 0.)IS 0,))9 0 lls 0 2II 0.3$ 2 0,14$
0,21 ~
0.0$ 7 UIND 5FEEDI)ltr)
).9 S.l
$.5-7.4 7.9 12.4 12 0.4))
0 ~ CSS 0 F 511 0'll 0,090 I ~ )I) ll7
l. 427
0. SOI 0 '72 0.444 I ~ )51 0 ~ OIS ~
0.1) 4 0'5) 0 ~ Ct) 0 ~ 041 0,0$ 3 0 ~ Ol) 0 ~ 0 0 ~ 041 0,0 0 '42 0 ~ Ctl 0 ~ 7)2 0 ~ 104 0 ~ OIO 0,0 0.203 0.07$
0 '41 0 '05 0.0 0.0 0.0 0 ~I I ~I 0.0 08050 O.OIT 0.0' 0
0 ~ 0 0.0 0.0 0.0 0.0,
'0,l 9 Ll.l LI.S 24.4
)814.5 I I 0,0 0,0 0.0 0 '
0 '
0.0 0.0 0 '0,0 0,0 0 '
0.0 0,0 0,0 I ~ 0 TOTAL I ~ CO ~
1 419 L,))4 O,I)5 0.574 0 ~tll 4 ~ 42$
4.017 I ~ 974 I SCI 271 I 1IC L.)70 0 ~ $ 00 0.92I 1.541 SURTOTAL 0 ~ 0 I ~ 149 I tll 4.242 4 '75 I.CST I 722 0,191, 0 ~ 0 27.5)0 TOTAL SOUR5 OF VALID 005CRVATIOS5 TOTAL SOUR5 Ot CLCVATCD RCLCA555 TOTAL SOV$ 5 Of 5TAIZIITI CLA5$
TOtAL $0$ $ 5 OF ELEVATED STASILZT't CLASS 1011 ~ 000 LILT~ 1st 40$.410 SS) F 900 5tLIT Jotrt FERccrtAVE FRI Ulrczc5 ot UIND stcED lt ltzrD DzRccTIos For StASZLZTT CLASS t I I ~ Sf DELTA tfr 4.0 C/100 N)
IRONS tCRRT NUCLCAR FLANT FART I Ot 1 tLCVATCD RCLCASC NODt Att Ly 90 JUN )0 ~
$ 0 NIND NNrt Nt CNC t
CIC St 555 5
55)f I'r rs)f N
WN)f
Ãr Srlf CAI)I 0 ~ 0 0.0 0.0 0.0 0.0 0,0 0 '
0,0 0.0 0
0 0.0 0.0 0 ~ 0 0 ~ 0, 0,0 0.0 0 ~I I ~ 4 0.0 0.0 0,0 0,0 0.0 0 '0.0 0,0 0,0 0 '0.0 0.0 0,0 0.0 0.0 0 '
1.5 ). ~
0,0 I ~ 0$ 0 I ~ 050 0,0 0 ~ 0$ 0 0 ~ 0$ 'I I ~ 19 ~
0 '99 0.1st 0.14$
0.14'I 0.0$ 0 0,0 0.050 0,14$
0,0 F 030 0 1st 0.050 0.14$
0.09$
I ~ Lit I 4$ 7 0 ~ 0$ 0 0.2$ $
0,547 I ~ 0$ 9 0.099 0.0$ 0 O.lit I ~ 0$ 0 O.ltt 0 ~ltl 0.0$ 5 0 ~ 047 0 IIC I ~ 191 I ~I~I 0
1$ 2 0 ~ 424 0 ~Ill 0 F 09'
'97 0 ~ 0 0 '
0.050 0'40 0,0 0 '97 0.217 0.1)0 I ~ 240 O S )$ 5 0,0 0 ~ 17$
I ~ )SS
0. ~ TI 0 ~ 174 I ~ I~ 0 0 ~ 04) 0,0 0.0 0 ~ 0 0 ~ 044 NIND StCCDINFN)
) ~ 5 S.l 5 ~ 9 7 '
7.5 Ll.l LL ~ S \\
0.0 0.0 0.0 0.123 0,0 0,0 0.0 0 ~ 040 0.041 0.0 0 ~I 0.0 0.0 0.0 0.0 0 '
I ~.
0,0 0,0 0.0 0.0 0,0 0 '0,0 0 '
0.0 0 ~ 0 0 ,0 0 '
0.0 0,0 0,0
)02 ~ as 0,0 0 ~ 0 0.0 0.0 0,0 0,0 0.0 0 '
0.0 0,0 0,0 0 '0.0 0.0 0.0 0 ~I TOTAL 0.4)7 0 ~ $ 41 0 F 277 0 ~Ilt 0 ~ CSS 0 ~ltl I ~ I~ 4 F 970 I'll'
~ 9 ~ 4 0 '25 0 ~ 1$ 2 I ~ 0$ 0 0.249 I ~ 247 I ~ 145 SUSTOTAL 0,0 0,0 I ~ 192 I ~4)l 2 ~ 010
1. ~ LS 0'05 0 ~ 0 0.0 9 '55 TOTAL $0$ $ 5 OF VALID OISCRVATIOSS tOTAL SOV$ 5 Ot CLCVATCO ICLCAStl TOTAL SOVRS Of 5TASZLZTT CLA55 TOTAL COURS Ot CLCVATCD 5TASZIZTT CLA55 t IOLIF 000 I~ L7 ~ 17$
Lt ~.920 1I2.1$ 0
Enclosure 1
Page 44 of 53 TABLE 2C (Page 4 of 4)
BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR SPLIT-LEVEL RELEASES
'ELEVATED PORTION SILxt soxst rcsetstAoc rsc otsexts or wxsn ssccn st wxsn nxscetxor ros 5TAsxtxTT eLA55 0 IDCLTA T I I I e/100 rl Isosss rccst sveLcAS ILADT BRACT 2 or 2 cLcvATcn ccLcAsc roDc AIC 1 ~
90 - IOC 30 ~
90 wxrn Zl r
SSC rc CSC C
CSC Sc SSC 5
SSW sr WSW r
rsvp rw SCW eALr 0 ~I 0,0 I ~ 0 0 ~ 0
.0 ~ 0 0 '0,0 I ~ 0 0.0 I ~ 0 I ~I 0.0 0 '
0 ~ 0.
I ~I 0.0 0 I 1.4 0,0 0 ~ 0 0 ~ 0 0 'I ~I 0.0 0,0 0.0 I ~I 0 'I ~ 0 "
0.0 0 '
0 '
0 '
0 ~I
l. 5 3.4 0.0 I 050 0 '0,0 0,0 0,0 0,0 I ~I 0.0 I ~I 0 '0,0 0,0 0 '
0.0 0
0 wxsn stccn(rrr) 3 ~ I 5 ~ ~
5 ~ 5 9.4 0 ~I 0 ~I 0 F 099 0.0 0'
0.095 0 F 050 0.0 0,0 0.04I 0,0 0,0 ~ 9 0.099 I ~ 049 0 '
0 '
0 ~ 0 0.050 0,0 0 '
0,0 0,0 0 '
0.0 0,0 I ~ 0 0.090 0.0 Oeo 0.0 0,0 0 ~ 0 0 ~ OIS 0 OIT 0.0 0 F 0'.0 0 ~ 0 0,0 0.0 0.sing 0 ~ 0 0,0 0 ~I 0.0 I ~I 0 ~ 0 0.0 0 '
0 '0,0 0,0 0
0 0.0 0,0 0.0 0 ~ 0 0,0 0.0 0,0 0 '
0,0 0,0 Oso 0 ~I 0 ~I 0,0 0
0 0 ~ 0 0,0 0,0 0,0 0,0 0.0 0,0 0,0 0,0 0.0 0
0 0,0 T.S 12. ~
12.5 lI.i 1$.5
)<2' 0 '0,0 0.0 0,0 0 '0,0 0 '
0.0 O.O 0.0 0.0 0,0 0,0 0.0 0 '
0.0 TOTAL
0. 0 IS 0'35 0.0'
~ 094 I 0 ~I 0 '49 0.149 0.0 0.095 0.0 0.0 0,0 0,0 0.050 0,0 0,0 5DSTOTAL 0 '
0 '
0.030 0,29 ~
0 ~ 291 0.252 0 '
I ~ 0 0 '02 TOTAL toots or vALID 0$ 5csvATloss TDTAL toots or cLcvATCD IcLCA5cs TOTAL sovss or stAslLxTT CLA55 0 TOTAL Costs or CLtVAtCD STAslLltt CLA55 0 2012.000 1511.239 24 ~'III 1I ~ 140 1858m
Enclosure 1
Page 45 of 53 TABLE 2D (Page 1 of 4)
BROWNS PERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT PRE UENCY DISTRIBUTION IN PERCENT FOR STACK RELEASES Jozct tccccNTAoc rtc Uctclct or Miso srtco Sr Mlco OIRcctzoN rox 5TASILZTT CLA55 A
)DCLTA t4< 1,1 C/100 Nl
~ ROW$ 5 FIRST NUCLCAR FLANT ASR I ~ 50 JUN )0 ~
50 WIND OIRCCTZON N
NNC NC CNC C
CSC 5$
Sst 5
55W 5W W5M W
WNW NW SÃW CALN 0,0 0,0 0 '
0 '0,0 0 '0,0 0,0
%,0 0 ~ 0 0.0 0 ~ 0 0,0 0.0 0,0 0 ~ 0 0.4 1.4 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 '0.0 0,0 0,0 0.0 0 ~ 0 0 '
0.0 0 '
0 '
0 '
0.0 1.$ 3.4 0 ~ 0 0,0 0 ~ 0 0'
0 '0,0 0 ~ 0 0.0 0,0 0.0 0.0 0
0 0.0 r
0.0 0.0 0
0 MIND 51CCD
).5-5.4 0.0 0
0 0 ~ 0 0
0 0.0 0,0 0.0 0.0 0 '
0 ~ 0 0.0 0,0 0 '0.0 0.0 0,0 (NFN )
$.5 2.4 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0
0 0
0 0 '0.0 0 ~ 0 0 '0,0 0 '
0 0
0,0 0,0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0.0 0,0 0 '0,0 0.0 0,0 0,0 0,0 0 ~ 0 0
0 0 ~ 0 0,0 0,0 0 ~ 0 0.0 0,0 0.0 0 ~ 0 0 ~ 0 0,0 0,0 0.0 0.0 0.0 0,0 0,0 0.0 0 '
0 ~ 0 0.0 0 ~ 0 0 '
0 '0,0 0,0 0.0 0 '
0 '0,0 0,0 0 '
2.$ 12.4 12.5-14.4 1$. ~
)01 ~
5 0
0 0,0 0,0 0
0 0,0 0,0 0,0 0 ~ 0 0 '
0 0
0,0 0,0 0,0 0 ~ 0 0 ~ 0 0,0 TOTAL 0,0 0,0 0 ~ 0 0,0 0'
0 '
0 '0,0 0 ~ 0 0,0 0.0 0.0 0.0 0 ~ 0 0,0 0,0 5USTOTAL 0,0 0.0 0.0 Ooo 0 ~ 0.
0,0 0 '
0 ~ 0 0,0 0,0 TOtAL NOU$5 OF VALID STASZLITT 0$ 5CRVATZO$5 2112 TOTAL NOVR5 OF 5TASZI ZTY CZA55 A 0
TotA). toots or vALID Mzto oztcctzot-Mzto Srcto-STASILZTT cLAss A
~
o TOTAL NOU$5 Ot VALZD WIND DZRCCTZON WIND StttD STASILZTT OSSCRVATIONS 2040 TOTAL NOUR5 CALN 0
JOINT
~ CRCCSTAOC ttt UCNCZC5 Ot WINO 51CtD ST WIND DlttCTION tOR STA41LITI CLASS
~
) 1,9(
D'CLTA TCe I ~ 7 C/100 N)
SROW$ 5 rtRRT NUCLCAR 1LAÃT A1$
1 ~
10 JUN )0 ~
50 WIND N
NNC Nt CNC Ctst SC 55$
5 SSW 5W W5W W
WNW NW NNW CALN 0.0 0.0 0 ~ 0 0,0 0 '0,0 0.0 0.0 0.0 0,0 0.0 0.0 0
0 0 '0.0 0.0
0. ~ 1. 4 0,0 0,0 0 ~ 0 0.0 0,0 0,0 0.0 0.0 0,0 0.0 0 ~ 0 0
0 0.0 0 '
0 '
0.0 1.$ ).4 0.0 0.0 0.0 0,0 0.0 0,0 0 ~ 0 0.0 0
0 0 ~ 0 0.0 0 '
0.0 0.0 0,0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0 '
0.0 0.0 0 '
0 '0,0 0.0 0.0 0,0 0.0 0.0 0.0 0.0 0 '0.0 0.0 0,0 0 '
0 '0.0 0.0 0.0 0.0 0.0 0 '0,0 WIND Srcco)NFN)
).5 5.4
$.5 3.4 0.0 0 '
0.0 0.0 0.0 0.0 0,0 0.0 0,0 0.0 0 ~ 0 0,0 0,0 0.0 0.0 0 ~ 0 0
0 0.0 0.0 0.0 0,0 0.0 0,0 0,0 0.0 0 ~ 0 0.0 0,0 0.0 0.0 0 '0,0 0.0 0 ~ 0 0,0 0;0 0.0 0,0 0 '
0.0 0.0 0 ~ 0 0,0 0,0 0,0 0 ~ 0 0,0 0,0 2 ~ 5 12 ~ 4 12.5
14. ~
14 ~ 5 24 ~ 4
)024,5 0,0 0,0 0,0 0.0 0.0 0.0 0,0 0.0 0.0 0,0 0.0 0,0 0.0 0,0 0.0 0,0 TOTAI 0.0 0,0 0.0 0,0 0,0 0
0 0,0 0,0 0,0 0.0 0,0 0,0 0,0 0.0 0.0 0.0 5$ 4TOTAL 0.0 0.0 0,0 0.0 0,0 0 '
0,0 0
0 0,0 0.0 TOTAL NOUR5 OF VALZD 5TASILZTT 0$ 5CtVATZO$5 2117 TOTAL ROVR5 Ot STASZI ITT CLA55 4 0
TOTAL COURS Or VALID 'MIND DZRCCTZON WISD 5tttD 5TASILZTT CLA55 4 0
TOTAL ROVRS OF VALZD WIND DIRCCTZON~ND 51CCD O'TASILZTT OSStRVATIONS 2050 TotAL COURS CALN 0
1858m
Enclosure 1
Page 46 of 53 TABLE 2D (Page 2 of 4)
BROWNS FERRY NUCLEAR PLANT METEOROLOGXCAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION XN PERCENT FOR STACK RELEASES Jozat ptactaTAOC rac Utscztt or NZSD Sttto sr Nzao Dzatctzoa roa STASZLITT CLASS C
( I 74 DCZTA Tli 1 5 C/100 II) saovas ttRR'I cocLtAR PLART Ata 1 ~
90 JUC )0~
90 WIRD Dzatctzor RÃat St cac 5
555 St 55C 5
55W 5N NSW W
VVN
ÃW saw CALII I ~ 0 0,0 0,0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0 '0,0 0 '0,0 0,0 0 ~ 0 0 ~ 0 0,0 0 '
0. ~ 1. ~
0,0 0 ~ 0 0,0 0.0 0,0 0,0 0 ~ 0 0.0 0 'I ~ 0 0,0 0 '
0 '0.0 0 ~ 0 0.0 1
5 ). ~
0 I 0
0 0.0 0 I 0.0 0,0, 0 '
0 '0,0 0 '
0 '
0 '
0 '
0,0 0.0 0 '
0,0 0.0 OIO 0,0 0.0 0,0 0 '
0.0 0,0 0 '
0 ~ 0 0,0 0.0 0.0 0,0 0
0 0,0 0.0 0 '
0 ~ 0 0 ~ 0 0 '
0 '
0 ~ 0 0,0 0.0 0.0 0 '
0.0 0.0 0 ~ 0 0.0 NZCD SttCD(llta)
).5
$.4 5.$
1 ~ ~
0' 0
0 0 ~ 0 0 ~ 0 0 ~ 0 0 ~ 0 0,0 0.0 0,0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0 '
0 ~ 0 0 ~ 0 0,0 0 ~ 0 0,0 0,0 0,0 0,0 0 ~ 0 0,0 0,0 0.0 0,0 0,0 0 '0,0 0 '0,0 0,0 0,0 0 ~ 0 0 ~ 0 0 '
0.0 0,0 0 '0.0 0,0 0.0 0.0 0,0 0 ~ 0 7.5 L)
~
12.$ 1l.i XI.5 2 ~ ~ ~
)a) ~.5 0,0 0.0 0,0 0 ~ 0 0 '0,0 0 '
0.0 0 0 0
0 0
0 0.0 0.049 0 '0.0 0.0 TOTAL 0.0 0.0 0,0 0,0 0,0 0'
0.0 0 ~ 0 0,0 0 ~ 0 0,0 0.0 0 '49 0,0 0 ~ 0 0 '
SUSTOTAL 0 '
0.0' 0 ~ 0 0.0 0.0 0 ~ 0 0,0 0,049 0 '49 TOTAL SOUR5 Of VALZD STAIZLZTI 055CRVATIOS5 TOTAL IIOUR5 Of 5TAWLITT CLAW C TOTAL II0UR5 of vALXD vzaD Dzacctloa vlso $pccD 5TAszLzTT cLA55 c TOTAL ROUR5 Of VALZD VICD DIRCCTIOC VZSD 5fttD STAIZLITT OSSCRVATIO55 TOTAL COURS CAtA 2111 1I 2040 0
JOXST rtactvTAOC FRC Utscltl ot WZRD 5ptcD sz wzaD DzatcTION toR 5TAIZLZTT CLA$5 D
(
1 54 DCLTA Tii 0 ~ S C/100 NI IIOVS5 fCRRI SUCLtAR PLART Ata 1 ~
90 JUC )0 ~
90 WIND DZRCCTZOS ast at cac t
CSC 5C 5$ 5 5
55N 5W W5N N
WSW RW aÃw CAIJI 0,0 0.0 0,0 0.0 0,0 0
0 0.0 0,0 OA 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0,0 0,0 0 '
0 '
0.0 0 '0,0 0 F 097 0,049 F 049 0 ~ 0 0'49 0'49 0,0 0,0 0.0 0 '0,0 0 ~ ) ~ 0 0.194 0.049 0,091 0 14) 0,24)
A ))4 0.) ~I 0 F 19
',)ll 0.24) 0 '
0 ~ 194 0 F 24) 0,049 0 ~ 091
0. ~ I
~
1.$ ).4 0.411 0.194 0.091 0.24) 0 ~ 091 0.4IO' 14$
0,091 0.291 0,144 0 ~ $ )4 0.$ )4 0 ~SI) 0.140 0.2 ~ 1 0 ~ 194 0,091 0.411 0.091 0.091 0.049 0 ~il5 0'45 0.55) 0 ~ill F 194 0 ~ 411 0 ~ 091 0 ~ 5 ~ )
0. F 11 I ~ 291 0'40 NISD Sttto()Ital
~ )
5 4
5 ~ 5 7
~
0. 921
1. 45 ~
0 ~ 5) ~
0,1 ~ 4 0.091 1.111 1.4$ 0 L.242 1.14l L.XL1 1 ~ ~ 02 1,499 L ~ )11 1 454 1 ~ 450 0 ~ 72I 0 ~ 922 0.5)4 0 ~il5 0,0 0 '
0.144 1 194 2.1ll 1 ~ IS) 1 990 0'2I 0.171 0.)40 LE $05 499 2 ~ 141 0 ~ 194 0 ~ 19 ~
0.0 0.0 0,0 0 ~ 0 1.145
0. 411 0 ~ 12I O.I14 0 ~ )I~
0,291 0 ~ 091 0 ~ IIO 0.1) I 0.4)1 1
5 Il 4 12 5 II~ ~
1I 5 24.4
)a)4.$
0 ~ 091 0.049 0.0 0.0 0 ~I 0 049 0 F 194 0,)ll 0.24) 0,194 0,049 0 ~ 194 0 F 049 0 ~ 0 0 ~ 0 0 ~ 0 TOTAL
) ~ 010
).05 ~
1.242 0 ~ 5 ~ 1 0 ~ ~I5 1.IX4 7.0)9 5, ~Io 5 ~ 4IS 4 ~ SSL 4 F 029 1 ~ $ 92 1 ~ 1$ $
4.440 4.440
$ 41 SUSTOTAL 0 '
0 '91
) ~ 49$
5 ~ I14
~ 091 LI ~ 49$
11 ~ ~ 44 4 iol 1.$ 0$
$ 9 F 029 TOTAL COURS ot VALID 5'TASZLITT OSICRVATIOS5 2111 TOTAL COURS Of STASZLZTT CLA$$ 0 12$ ~
TOTAL ROUR5 Of VALID WISD DZRCCTIOS VXSD 5 ~ CCD ITASZLXTT CLA5$
D 121 ~
TOTAL SOURS OF VALID WZSD DZRCCTXOR VISD SPWD STASILITT 0$ 5CRVATIOS$
2040 TOTAL COURS CALII 0
1858m
Enclosure 1
Page 47 of 53 TABLE 2D (Page 3 of 4)
BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT PRE UENCY DISTRIBUTION IN PERCENT OR STACK RELEASES JOZNT FERCERTAOE fRE UENCIES Of WIND 5 ~ IED RT WIND DIRECTION FOR 5TAIILITTCLA55 I l
0 ~ $ 4 DEITA-T<i 1 5 C/100 N)
IRONRS fERRT NUCLEAR tLANT WIND DIRECTION CALll O.C L. ~
1.5 3.4 AtR I ~ 90
.JVN 30 ~
$ 0 WIND StEED(NFRL 3.5 5.4 5.5 7.4 7.5 12.4 12 5 LI.4 LI ~ 5 34 ~ ~
)024.5 TOTAI N
NNE NE ENE 5
555 SE SSE 5
55W 5'W W5W W
WRW NW NNW 0.02L 0,007 0.007 0.007 0 ~ 021 0.035 O,OL4 0'14 0,0 0.007 I ~ 014 0.0 0.007 I ~ 021 0,007 0 014 Orbit 0,0 I ~ 0 0,0 0 ~ 0 0 '0,0 0.0 0,0 0,0 0 '0,0 0 '
0 ~ 049 0,0 0,0 0.097 I ~ 04$
0,0 ~ 9 I ~Oit O.LE I 0,241 0.0 ~ 7 0.0$ 7 0 '
0 F 049 0.0$ 7 0 '
0,049 0.0$ 7 0.04$
0,0$ 7 0.1$ 4 0,097 0.140
0. 1$ 4 0 '
0 ~ 194 O.LII 0,140 0.291
0. 145 0,243 I ~ 194 I 1$ 4 0 lti 0.145 0.0 0,04$
0,0$ 7 0 ~ 1$ 1 0,0$ 7 0 ~ 097 0 lti 0 F 340 O,CIO 0,4IS I ~ 3 ~ 0 0,340 0.241 0.1$ 4 0 ~ 145 0 ~ 04$
0,0$ 7 I ~ ~ 37 0,305 0 ~ 720 0.43T 0 ~ 1$ 4 0.3 ~I 1 111 1.4$ 9 1.40 ~
0 ~ 431 i.241 0.431 O.CIO 0,154 0 4IS 0,1$ 4 0,437 0 Cll 0 35 ~
0 340 0 ~ 0 0 ~ 145 0 ~ 574 Lolli L ~ 9to 0.437 0,514 0 4IS 0.0$ 7 0,049 0.194 0 ~ I25 0,097 0.049 I ~ 0$ 7 I 0 I ~ 04$
0 0
0,340 0.140 0.241 0 ~ 194 0,097 0'4t 0 0$ 7 0 0$ 7 0.0 ~ 9 0.04$
0 ~ 0 0,0 0 ~ 0 0 '0.0 0.0 0 ~ 049 0,097 0 Oit 0 ~ 0 0.0 0.0 0 ~ 0 0 '
0,0 0,0 1.1IO 1.310 1 ~ 705 1.123 0 F 500 1 ~ 200 412 4 ~ 2 ~I 4,4CC 1,401 2 ~ 435 a
1,COI
1. 315 0 ~I 0'7I 1 F 275 SUSTOTAL I ~ 1$ ~
0 ~ 09.7 1.242 2.747 1 ~ 7IC '
ll~ 252 I.C41 445 0 ~ 194 30 ~ 04I TOTAL ROVER Ot VALZD 5TASZLZTT 055ERVATION5 1117 TOTAL ROUR5 OF 5TARZLZTT CLASS 5 410 TOTAL ROUR5 Ot VALID WIND DIRECTZON WIND 5tEED 5TAIILZTT CLA55L'lt TOTAL ROVRS Ot VALID WIND DIRECTION WIND 59550 STARZLZTT OSIERVATZON5 20CO TOTAL EOVRS CALN JOINT ttbCENTAOE FRE UENCIE5 Of WIND I~ I'ED RT WIND DIRECTION FOR STAIILITT CLASS F
(
1 ~ 54 DELTA VCR 4
0 C/100 Nl SROWE5 FERRT NUCLEAR tLART AFR 1 ~
$ 0 JUN 30 ~
$ 0 WIND DIRECTZON N
NNE NE ENE 5
55E SE 555 I
55W SW WSW W
WRW NW NNW CAIJI 0.004 0 004 0,0 0,004 0,0 0,007 0,007 0,0 0 004 0.004 0,00' F 00
',00
'ao 0 ~ 0 0,004 0.4 1.4 0.0 0 '
0 ~ 0 0,0 0.0 0 '
0 ~ 0 0.0 0,0 0 '
0 '0,0 0,0 0 ~ 0 0,0 0.0 1.5 )
~
0 ~I~ 9 0,049 0 ~ 0 0.0 ~ 9 0.0 0.097 0'97 0,0 I ~ Oit 0 ~ 04$
o,oit 0 ~ 0 ~ 9 0,0 ~ 9 0,0 0.0 0 ~ 0 ~ 9 WIND SSEED(NFR) 3.5-5.4 5.5 T. ~
0.049 0.0 0,0 0,0 0.04$
0,0' 0.0 0,0, 0,0 0 ~ 1$ 4 0.0
0. 140 0,0 0,0$ 7 0,1$ 4 0 ~ Oit 0.0$ 7 0.0$ 7 0,0 0 ~ 144 0.0 0 '
0'97 0.0 0,0 0.0 0,049 I ~ 049 0.049 0.0 0.0 0,0 I ~ 04$
0 ~ 049 0.1$ 4 0.243 O.SIL 0.437 0.4 ~ 5 0.2'tl I ~ 431 0.243 0.1$ 4 0.0 ~ 7 I ~ 144 0.049 0 ~ 144 0.0 I ~ SII 0.2$ 1 0.049 0,097 0.144 0.04$
0.097 0 ~ 2$ 1 0 ~ SI1 0.5' 0 F 243 0 ~ 1$ 4 Oeo 0 I 0,0 0.04$
0,0 0,0 ~ ~
0 I 0.144 0,0 ~ 9 0,04$
0,0 0,04$
0 '97 0,04$
0,0 0,0 0,0 0 ~ 0 0.0 0,0 7.5
12. ~
12.5 1 ~. ~
lb.5 24.4
)024.5 0.0 0 '0,0 0.0 0.0 0 '
0,0 0.0 0,0 0 ~ 0 0.0 0,0 0,0 0.0 0 '0,0 TOTAL 0.732 0 441 0,3 ~I 0 ~ 53I 0,$ 71 0.$ 70 0 ~ TI4 0,574 1.557 L.072 0
409 0,441 0 ~ 19 I 0 144 0 ~ 194 0 ~ 101 5URTOTAL 0,049 0 '
0 ~ CLL O.SIL L.OLS L.I35 3.151
0. ~I5 0.0
9. F 5
'OTAL ROUR5 OF VALID 5TASILITT 055ERVATZON5 2117 TOTAL ROVRS OF 5TARZLZTT CLA55 t 207 TOTAL ROUR5 Ot VALID WIND DZRECTZON WIND 5tEED STASILITT CLA55 203 TOTAL ROURS OF VALID WIND DIRECTION WIND StEED ITARILITT 055ERVATZONS IOCO TO'TAL ROUR5 CAIJ4
Enclosure l Page 48 of 53 TABLE 2D (Page 4 of 4)
BROWNS FERRY NUCLEAR PLANT METEOROLOGICAL DATA SECOND UARTER 1990 JOINT FRE UENCY DISTRIBUTION IN PERCENT FOR STACK RELEASES JoINT tcaccsTAOC tacoocscI'$5 or wzao stcco Ot Uxso Dxacctzoa Fog STASILITT CLASS 0 (DCLTA T 9 I 0 C/ZOO 8)
~ ROUCS tcRRT CUCLCAR tLACT Ata I ~
90 JUC 30'0 NZCD DIRCCTZOS CAZJI 0.4 1.9 ).4 UZCD 5tCCD(lira) 3.5
$.4 5.$ 7. ~
I 5 11 ~ I 13
$ 1$.4 1 ~ ~ 5 ZI.I
)&14.5 TOTAL C
CSC ac CCC 5
CSC SC 555 5
SSU SU WSN U
WÃW Clt Csee 5 URTOTAI 0
0 0 ~ 0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0.0 0 ~ 0 0,0 0.0 0.0 0.0 0 '
0 ~ 0 0,0 0 ~ 0 0,0 0.0 0 ~ 0 0'
0 '0,0 0,0 0.0 0,0 0,0 0.0 0.0 0.0 0,0 0 '0.0 0,0 0 0 0,0 0
0 O,ox 0 ~ 0 0,0 0,0 0
0 0,0 0,0 0
0 0.0 0 '
0 0
0 ~ 0 0,0 0 ~ 0 0,0 0,0 0.0 0,049 0,049 0 ~ 0 0 '
0 '
0 0
0 ~ 0 0 ~ 0 0.0 0,0 0 '
0 '
scott 0,0 0,0 0,0 0,099 0 ~ 04'9 0 ~ 0 ~ 9 0 ~ 0 0 ~ 0 0,0 0 '0,0 0.0 0.0 0,0
.0,0 0.0 0.19 ~
0 ~ 0 0,0 0,0 ~ 9 0 '0.0 0 ~ 144 0.0 0 ~ 049 0,049 0 ~ 0 0 ~ 0 0.0 0.0 0,0
,0 ~ 049 0,0 0,340 0,049 0'I9 0.1 ~ 5 0 '
0 '
0 ~ 0 0,0, 0.0 0 F 097 0
0 0.0 0.0 0.0 0.0 0 '0.0 0.340 0.0 0 ~ 049 0 ~ 0 0
0 0.0 0
0 0.0 0,0 0.0 0,0 0.0 0 ~ 0 0,0 0 ~ 0 0 ~ 0 0,0 0 049 0,0 0 ~ 0 0,0 0,0 0
0 0,0 0,0 0 '
0,0 0,0 0,0 0,0 Oeo 0
0 0,0 0
0 0.0 0,049 0.099 0 ~ 194 0 F 097 0 '97 0 ~ 343 0,0 0,0 ~ 9 0 ~ 144 0 ~ 0 0.0 0 ~ 0 0 ~ 0 0 ~ 0 0 049
~ 0 1 ~ 019 TOTAL COURS Ot VALID STAOILZTT OSSCRVAT1055 ZZZT TotAL COURS Ot 5TARIIZTT CLA$5 0 11 Totax, cooas or TAI.ID Uxso Dzacctxow-UIRD Srcco-STASILITT cLAss 0 11 Totax. Rooas or vax.xo @Iso Dxacctxoc-UIRD Stcco-STARILITT osscav*txoas Zoio TDTAL Nooas cAIJI 0
Enclosure 1
Page 49 of 53 TABLE 3 0
S RRY CLEAR PLANT RECEPTO LOCA 0
S AND 0
S 0 I
EREST DISTANCE POI SEC OR Site Boundary locations POI DISTANCE S
C 0 m
Site Boundary Site Boundary Site Boundary Site Boundary Site Boundary Site Boundary Site Boundary Site Boundary N
1525 NE 1250 E
1375 SE 5600 S
2550 SW 2300 W
2550 NW 2275 Site Boundary Site Boundary Site Bdundary Site Boundary Site Boundary Site Boundary Site Boundary Site Boundary NNE ENE ESE SSE SSW WSW WNW NNW 1300 1450 1575 2875 2425 2500 3325 165.0 Real Receptors used for airborne doses (based on Fall 1989 Land Use Survey)
Resident Resident Resident, Garden Resident Resident, Garden Resident, Garden Resident Resident
,Garden Garden Garden Garden Milk Cov Teen Milk Cov Child N
NE E
SE
~ S SW W
NW N
NE W
NW N
WNW 1676 3772 3810 8100 4534 5066
'629 3048 1672 4420 3048
~ 3543 7924 5181 Resident Resident Resident Resident, Garden Resident, Garden Resident, Garden Resident Resid'ent Garden Garden Garden Garden Milk Cov Teen Milk Cow Teen NNE ENE ESE SSE SSW WSW WNW NNW NNE ENE WNW NNW ENE NNW 2705 1715 4343 7087 4191 4343 4534 1524 2895 2705 5410 1829 9448 10972
Enclosure 1
Page 50 of 53 TABLE 4 FIVE-YEAR
SUMMARY
OF UARTERLY DOSES*
Air Submersion Air-Y Air-8 Skin "
TB Year QTR mrad mrad mrem mrem Real Pathway Max. Or an Liquid Effluents TB Max. Or an mrem mrem 1985 3
<.001
<.001 0.0 0.0 4
<.001
<.001 0.0 0.0
.01 Bone
.Ol Bone
.05
.10
.07 Liver
.14 Liver 1986 1
2 3
4
<.001
<.001
<.001
<.001
<.001
<.001
<.001
<.001 0.0
<.001 0.0 0.0 0.0
.Ol
<.001 <.001 0.0
<.001 0.0
<.001 Bone Liver Liver Liver
.08
.23
.15
.03
.11 Liver
.31 Liver
.19 Liver
.04 Liver 1987 1
2 3
4
<.001
<.001
<.001
<.001
<.001
<.001
<.001
<.001
<.001
<.001 0.0
<.001
<.001
<.001 0.0
<.001
.0015 GI Tract
.0024 GI Tract
.0037 GI Tract
.0071 Liver
.02
.05
.06
.09
.02
.07
.07
.12 Liver Liver Liver Liver 1988 1
3 4
<.001
<.001 0.0
<.001
<.001 0.0
<.001
<.001 0.,0
<.001
<.001 0.0 0.0 0.0 0.0 0.0
.0001 GI Tract
.0051 GI Tract
.0022 GI Tract
.0026 Bone
.02
.13
.09
.03
.03
,17
.12
.03 Liver Liver Liver Liver 1989 1
0.0 0.0 2
0.0 0.0 3
0.0 0.0 4
0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
<.001 Thyroid
<.001 GI Tract
<.001 Bone
<.001 Thyroid
.007
.Ol
.008
.01
.008
.01
.004
.006 Liver Liver Liver Liver 1990 1
0.0 0.0 2
0.0 0.0 0.0 0.0 0.0
<.001 Thyroid 0.0
<.001 Bone
.002
.023
.003 Liver
.035 Liver
~Note:
All calculated doses are below limits specified in Appendix I to 10 CFR 50.
Enclosure 1
Page 51 of 53 FIGURE l BFN;Airborne Effluents Fission Gases Released and Resulting Doses Legend BFH releases 0
o 500000 0
$,0 Gamma dose Beta dose
" mme L4 0a Da o 300000 00 00 C0 200000 E
4I r
~
I I
I I
II II I
I I
I
"~
II 2.0 1.0
'D 0
E 0000 80 81 82 N
84 85 SS 87 88 89 90 (YlD) bfn1
FIGURE 2 Enclosure I Page 52 of 53 BFN Airborne Effluents lodines and Particulates Released and Resulting Doses Legend BFN releases AO C
1.6 Maximum organ dose L0
'0 a
30 00 0K a0 0 g gO 30
~0 Q.
'D C
D
.15 0
C 00
.10 E
L E
a 1.0 0O C0 0
.6 80 82 84 86 88 90 (YlD) 81 N
85 87 89
Enclosure 1
Page 53 of 53 FIGURE 3 BFN Liquid Effluents Fission and Activation Products Released and Resulting Doses Legend BFN releases 1.6 Total body dose Maximum organ dose 0
C l9 0
0 VO OL.3 0 g O~
Ow 0K 2
~
~
~
~
~
~I II I
r r
I I
I r ~
)r
~
E0 1.0 ~
E 000Q
.6 s
~
~
~
~
~r a
I
~
~
1 80 81 82 Q
84 85 86 87 88 89 90Y1D
ENCLOSURE 2 TENNESSEE VALLEY AUTHORITY SEMI-ANNUAL RADIOACTIVE EFFLUENT RELEASE REPORT BROWNS FERRY NUCLEAR PLANT EFFLUENT AND WASTE DISPOSAL REPORT JANU Y THROUGH JUNE 1990
Enclosure 2
Page 1 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT
'UMMARY FIRST HALF 1990 The radioactive effluents for tlie first half of 1990 were normal for a three unit boiling water reactor plant. in its fifth year of an extended outage.
Because of the extended
outage, only radionuclides with a long half-life (longer than a few months) have not decayed away and are being released to the environment.
The radioactive decay is particularly significant for gaseous effluents because no fission gases or radioactive iodines are being released.
The only radioactive gaseous releases are very small quantities of particulate matter.
The radioactivity being released now in liquid effluents is primarily long half-life radionuclides that have been deposited on the surfaces of piping and components.
During normal outage work this radioactivity is removed by process water that is purified and released to the river.
The water purification process is unable to remove all the radioactivity before it is released to the river.
The release of radioactive material to the environment from Browns Ferry Nuclear Plant has been a small fraction of the 10 CFR 20 Appendix B and 10 CFR 50 Appendix I limits during the first half of 1990.
Enclosure 2
Page 2 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT SUPPLEMENTAL INFORMATION FIRST HALF 1990 Re ulato Li ts A.
Fission and Activation Gases in Gaseous Effluent:
1.
The release of fiss'ion and activation gases is regulated by the dose limits of 10 CFR 50 Appendix I.
The air dose to areas at and beyond the site boundary due to noble gases released in gaseous effluents per unit shall be limited during any calendar quarter to g 5 mrad for gamma radiation and g 10 mrad for beta radiation; and during any calendar year to g 10 mrad for gamma radiation and g 20 mrad for beta radiation.
B and C
Iodines and Particulates with half lives greater than eight days in gaseous effluents.
1.
The release of iodines and particulates in gaseous effluent is regulated by the dose limits of 10 CFR 50 Appendix I.
The dose to a member o'f the public from radioiodines, radioactive materials in particulate form, and radionuclides other than noble gases with half live greater than 8 days in gaseous effluent released per unit to area at and beyond the site boundary shall be limited to any organ during any calendar quarter to g 7.5 mrem, and during any calendar year to g 15 mrem.
D.
Liquid Effluents 1.
The release of radioactive liquid effluents is regulated by the dose limits of 10 CFR 50 Appendix I.
The doses or dose commitment to a member of the public from radioactive materials in liquid effluents released from each unit to unrestricted areas shall be limited during any calendar quarter to g 1.5 mrem to the total body and 5 mrem to any organ and, during any calendar year to
< 3 mrem to the total body and
< 10 mrem to any organ.
Enclosure 2
Page 3 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT SUPPLEMENTAL INFORMATION FIRST HALF 1990 II.
Maximum Pe ss b e Concentrations A.
Fission and Activation Gases in Gaseous Effluent 1
1.
The instantaneous release rate of fission and activation gases is regulated by the dose rate limit of 10 CFR 20 Appendix B.
The dose rate at any time to areas at and beyond the site boundary due to noble gases released in gaseous effluents from the site shall be limited to
< 500 mrem/year to the total body and
< 3000 mrem/year to the skin.
2.
The BFN Offsite Dose Calculation Manual (ODCM) determines the maximum noble gas release rate based upon the dose rate limits in II.A.1.
The instantaneous noble gas release rates are limited by the following equation:
+g2<1 0.15 14.4 Ql ='he release rate from the building exhaust vents in Ci/sec.
Q2 = The release rate from the main stack in Ci/sec.
B and C.
Iodines and Particulates with Half Lives Greater than 8 Days in Gaseous Effluents.
1.
The instantaneous release rate of particulates and iodines is regulated by the =dose rate limit of 10 CFR 20 Appendix B.
Th' dose rate at any time to areas at and beyond the site boundary due to I-131, I-133, H-3 and particulates with greater than eight days half-lives released in gaseous effluents from the site shall be limited to <1500 mrem/yr to any organ.
2.
The BFN ODCM determines the maximum particulate and iodine release rate based upon the.dose rate limit of II. B and C.l.
The instantaneous iodine and particulate release rates are limited by the following equation:
+
M
<1 2.19 35.7 Q3 = The release
'rate from the building exhaust vents in pCi/sec Q4 = The release rate from the main stack in pCi/sec.
Enclosure 2
Page 4 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT SUPPLEMENTAL INFORMATION FIRST HALF 1990 D.
Liquid Effluents The concentrqtioh of radionuclides in liquid effluents released at any time from "the site to unrestricted areas shall be limited to the concentrations specified in 10 CFR 20, Appendix B, Table II, Column 2 for radionuclides other than dissolved or entrained noble gases.
2.
For dissolved or entrained noble gases, the concentration shall be limited to 2E-4 pCi/ml total activity.
III.
Average Energy Not applicable IV.
Measurements and rox at ons o
Total Rad oactivit A. Fission and Activation Gases:
1.
Noble gases in the building vent and stack, gaseous effluent are continuously monitored.
The flow rate of the stack is "continuously monitored and the building vent effluent'flow rates are calculated once a shift based on the configuration of operating exhaust fans.
The flow rate data is consolidated weekly to determine the volume of. airborne effluent released from the plant.
The noble gas monitor data is consolidated monthly to determine the total curies of noble gases released during the month.
2.
Gas grab samples are taken and analyzed monthly to determine the relative noble gas activity concentrations.
This information is used to apportion the total curies of noble gases r'eleased between different noble gas radionuclides.
3.
The tritium concentration is determined by the analysis of a monthly grab sample for each release point.
B and C.
Iodines and Particulates l.
Iodines and particulates are continuous1y sampled on impregnated charcoal filters and particulate filters, respectively.
The charcoal and particulate samples are replaced at least weekly and analyzed to determine specific activity concentrations.
The specific activity concentrations and vent flow rate data are used weekly to verify that release rate limits were not exceeded.
The specific activity concentrations and total volume of gaseous effluent are used on a monthly basis to determine the total curies of each particulate and iodine released during the month.
Enclosure 2
Page 5 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT SUPPLEMENTAL INFORMATION FIRST HALF 1990 IV.
casu e ents a d o
at o s o
ota R d oac v t (Continued) 2.
The gross alpha concentration is determined by analysis of a monthly particulate filter composite sample and strontium -89 and -90 are determined by analysis of a quarterly particulate filter composite sample for each release point.
D.
Liquid Effluents 1.
The gamma ray emitting radionuclide concentrations are determined for each batch by gamma ray spectroscopy analysis of a grab sample.
The allowable release rate is calculated for each batch based upon the known dilution flop.
The flow rate of the liquid effluent is continuously monitored and the total volume released in each batch is determined.
The total gamma activity released in each batch is determined by multiplying the radionuclide concentrations by the total volume discharged.
The, total gamma activity released during the month is then determined by summing the gamma activity content of each batch discharged during the month.
2.
The gross alpha and tritium concentrations are measured on a monthly composite sample.
The strontium -89 and -90 and iron
-55 are measured on a quarterly composite sample.
V.
Batch Value FIRST SECOND Units A. Liquid 1.
Number of batches released 2.
Total time period for batch releases 3.
Maximum time period for a batch release 4.
Average time period for batch releases 5.
Minimum time period for a batch release-210 83 40 34 11,157 9,696 330 455 279' 285 Each Minutes Minutes Minutes Minutes 6.
Average stream flow during period of release of effluent into a flowing streaml B. Gaseous t
None 1 To be supplied by others.
Enclosure 2
Page 6 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 LIQUID EFFLUENTS SUMMATION OF ALL RELEASES First Second U~t Quua. te
~ua ~te
$ Error A.
B.
Fission and Activation Products 1.
Total Releases 2.
Average Diluted Concentration During Period 3.
Percent of Applicable Limit (1.00E-7 pCi/ml)
Tritium Curies 2.46E-02 6.91E-02 9
pCi/ml 1.46E-09 4.70E-09 1.46E+00 4.70E+00 1.
Total Releases Curies 5.24E-02 6.03E-02 C.
2.
Average Diluted Concentration During Period 3.
Percent of Applicable Limit (3E-03 pCi/ml)
Dissolved and Entrained Noble Gases>
pCi/ml 3.10E-09 4.10E-09 1.03E-04 1.37E-04 Total Releases Curies 2 ~
3 ~
Average Diluted Concentration During Period Percent of Applicable Limit (2E-04 pCi/ml) pCi/ml ag D.
Gross Alpha Radioactivity Total Releases Curies 1.53E-04 48 2.
Average Diluted Concentration During Period pCi/ml 9.04E-12 E.
F.
G.
Volume of Waste Release (Before dilution)
Volume of Dilution Water for Period Total CCW flow for Six Months Liters 4.45E+06 3.68E+06 Liters 1.69E+10
. 1.47E+10 688 gigagallons 10 1 Includes Xe-133, Xe-135, and others.
Enclosure 2
Page 7 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT LIQUID RELEASES FOR FIRST HALF 1990 BATCH MODE
~sots e
(Required by REG Guide 1.21) t First Quarter Second Quarter 2 ~
3 ~
5.
Cr-51 Mn-54 Co-58 Fe-59 Co-60 2.61E-03 3.76E-03 6.
Zn-65 7.
Nb-95 8.
Zr-95 9.
Mo-Tc-99m ND 10.
I-131 11.
Xe-133 12.
Cs-134 13.
Xe-135 14.
Cs-137 15.
Ba-140 16.
La-140 17.
Ce-141 18.
Sr-89 19.
Sr-90 ND 3.20E-03 ND 1.88E-02 8.27E-03 5.71E-02 ND
~Isoto e
Others (Not Required by REG Guide 1.21) 1.
Fe-55 This section was prepared by S. B. Jordan.
Enclosure 2
Page 8 of 16 0
EFFLUENT AND HASTE 'DISPOSAL SEMIANNUAL,REPORT FIRST HALF 19901 GASEOUS EFFLUENTS SUMMATION OF ALL RELEASES Summation of All Releases First U~ft
~ua te Second guarter
~t rer A.
Fission and Activation Gases 1.
Total Releases Ci 45 2.
Average Release Rate for Period pCi/sec 3.
Percent of T.S. limit2 B.
Iodines 1.
Total Iodine-131 Ci 36 2.
Average Release Rate for Period pCi/sec 3 ~
Percent of T.S. Limit>
Particulates 1.
Particulates with half-lives
>8 days 2.
, Avg. release rate for period 3.
Percent of T.S. limit>
4.
Gross alpha radioactivity D.
~
Tritium Ci pCi/sec Ci 2.98E-07 4.38E-05 5.57E-06
.2.19E-01 35 Total release Ci 3.91E-02 3.86E-02 21 2.
Average release rate for period pCi/sec 4.98E-03 4.91E-03 3.
Percent of T.S. limit2 4.
Ground level release 5.
Elevated release 1 Reporting period 189 days.
Ci Ci 2.16E-01 2.19E-01 3.70E-02 3.75E-02 2.14E-03 1.11E-03 2 The dose rate limit for noble gases shall be
< 3000 mrem/year to the skin and the dose rate particulates with g eight day half lives shall 500 mrem/year to the'total body and limit for I-131, I-133, H-3, and be
< 1500 mrem/year to any organ.
i
Enclosure 2
Page 9 of 16 EFFLUENT AND HASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 GASEOUS EFFLUENTS ELEVATED RELEASE 1.
Fission Gases First U~t
~ea te Second gua ~te Krypton-85m Krypton-85 Krypton-87 Krypton-88 Xenon-133 Xenon-135m
.Xenon-135 Xenon-138 ota for eriod Ci Ci Ci Ci Ci Ci Ci
.Ci ND 2 ~
Iodines Iodine-131 Iodine-133 Iodine-135 Ci Ci'i ND'ota or e
od Ci ND
Enclosure 2
Page 10 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 GASEOUS EFFLUENTS ELEVATED RELEASE (Continued)
Particulates Sr-891 Sr-901 Cs-134 Cs-137 Ba-140 La-140
'it'i Ci Ci Ci Ci Ci First
~u:~te Second gua ~ter:
ND ota or er od Ci Tritium 2.14E-03 1.11E-03
Enclosure 2
Page ll of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL'REPORT FIRST HALF 1990 GASEOUS EFFLUENTS GROUND LEVEL RELEASE Fission Gases Krypton-85m Krypton-85 Krypton-87 Krypton-88 Xenon-133 Xenon-135m Xenon-135 gnn t Ci Ci Ci Ci Ci Ci Ci First guarter ND Second
~tarte t
Xenon-138 ota or er od Ci 2 ~
Iodines Iodine-131 Iodine-133 Iodine-135 Ci Ci Ci ND Total for eriod Ci
Enclosure 2
Page 12 of 16 e
EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 GASEOUS EFFLUENTS GROUND LEVEL RELEASE 3 ~
Particulates Sr-891 Sr-901 Cs-134 Cs-137 Ba-140 La-140 Unit Ci Ci Ci First guarter ND Second
~ua ter 4.38E-05 Total for Per od Ci 4.38E-05 1 Predicted estimation of releases.
Ci a
3.70E-02 3.75E-02 This section was prepared by S.
B. Jordan.
Enclosure 2
Page 13 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 SOLID WASTE AND IRRADIATED FUEL SHIPMENTS Solid Waste Shipped Off-Site for Burial 1.
Type of Waste a.
Spent resins, filter sludges, evaporator bottoms, etc.
b.
Dry compressible
waste, contaminated equip., etc.
c.
Irradiated components, control rods, etc.
d.
Absorbed oily material U~)~ts m3 Ci m3 Ci m3 Ci m3 Ci
/mount 1.17E+01 7.32E+00 7.16E+Ol 5.17E+00 O.OOE+00 O.OOE+00 1.44E+01 1.56E+Ol rror 1.50E+Ol 1.50E+01 N/A 1.50E+01 or Disposal (Not Irradiated Fuel) 2.
Estimate of major nuclide compositions (by type of waste) a.
Spent resins, filter sludges, evaporator bottoms, etc.
guuc i de U~nt Unit 1.
Manganese-54 (1) 2.
Iron-55 (2) 3.
Cobalt-60 (1) 4.
Zine-65 (1) 5.
Celsium-134 (1) 6.
Celsium-137 (1) 7.
Other Nuclides (2) 5.96E-02 Ci 4.40E-03 2.49E+01 Ci 2.72E+01 Ci 1.82E+00 1.99E+00 1.28E+00 Ci 9.37E-02 5.30E+00 Ci 3.88E-01 3.89E+Ol Ci 2.85E+00 2.33E+00 Ci 1.70E-Ol (1)
Measured (2)
Estimated through the use of scaling factors
Enclosure 2
Page 14 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 SOLID WASTE AND IRRADIATED FUEL SHIPMENTS (Continued) 2.
Estimate of major nuclide compositions (by waste type) (Continued) b.
Dry compressible
waste, contaminated equipment, etc.
~uc ~de Unit U~t 1.
Manganese-54 (2) 2.
Iron-55 (2) 3 ~
4',
5.
6.
7 ~
8.
I o -59 Cobalt-60 Zinc-65 Silver 110m (2)
Cesium-134(
Cesium-137(
).
9.
Other Nuclides (2)
%%d 2.11E-01 Ci 1.09E-02 4.30E+01 Ci 2.22E+00 3.78E-03 Ci 2.00E-04 4.67E+01 Ci 2.41E+00 1.92E+00 Ci 9.90E-02 7.74E-03 Ci 4.00E-04 1.04E+00 Ci 5.39E-02 5.98E+00 Ci 3.09E-01
'I 1.15E+00 Ci 5.95E-02 (1)
Measured (2)
Estimated through the use of scaling factors c.
Irradiated Components, Control Rods, etc.
NONE
Enclosure 2
Page 15 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 SOLID WASTE AND IRRADIATED FUEL SHIPMENTS (Continued) 2.
Estimate of major nuclide compositions (by waste type) (Continued) d.
Absorbed oily material Quuc ide U~t Unit 1.
Manganese-54 (1) 2.
Iron-55 (2) 3.
Cobalt-60 4.
Zinc-65 (1) 5.
Cesium-134 (1) 6.
Cesium-137 (1) 7..
Other Nuclides (2) 2.16E-01
'Ci 3.40E-03 4.66E+01 Ci 1.91E+01 Ci 7.28E-01 2.99E-02 1.04E+00 Ci
. 1.63E-02 3.83E+00 Ci 3.34E+00 Ci 5.98E-02 5;22E-02 4.30E+01 Ci 6.72E-01 (1)
Measured (2)
Estimated through the use of scaling factors 3.
Solid waste disposition umbe of shi me ts 36 ode of Trans ortatio Sole Use Truck Sole Use Truck
Barnwell, SC
Richland, WA Irradiated Fuel Disposition Number of shi ments Mode of Trans ortat o
Destination NONE N/A N/A
Enclosure 2
Page 16 of 16 EFFLUENT AND WASTE DISPOSAL SEMIANNUAL REPORT FIRST HALF 1990 SOLID WASTE AND IRRADIATED FUEL SHIPMENTS (Continued)
C.
Waste Sources, Burial Class and Type Quantity, Container Type, Total Volume in Cubic Feqt and Number of Containers Used.
Type of Type Burial Container Number of Disposal Waste uant t C ass e
Containe s
Volume DEWATERED (Resin)
RX CLEANUP COND/WASTE (Filters)
DRY ACTIVE WASTE (Compacted)
DRUM BOX N/A N/A A-LSA A-Stable N/A N/A A-LSA A-Unstable A-LSA A-Unstable N/A HIC N/A STC STC NONE 2
NONE 64 4
NONE 411.6 NONE 480.0 372.0 (Uncompacted)
DRUM BOX (Brokered)
A-LSA A-LSA'-Unstable A-Unstable A-LSA A-Unstable STC STC STC NONE 6
N/A NONE 562.8 1114.5 IRRADIATED COMPONENTS N/A N/A SOLIDIFIED N/A N/A N/A N/A NONE NONE NONE NONE ABSORBED A/LSA A-Unstable DOT-7A 68 510.0 Solidification Agent Used:
NONE Absorbents Used:
Floor Dri 85
ENCLOSURE 3 TENNESSEE VALLEY AUTHORITY BROWHS"FERRY NUCLEAR PLANT SEMI-ANNUAL RADI(ACTIVE EFFLUENT RELEASE REPORT INOPERABLE RADIOACTIVE EFFLUENT INSTRUMENTATION REPORT JANUARY THROUGH JUNE 1990
Enclosure 3
Page 1 of 4 o
e ab e Radioactive Eff ue t nstrumentation Re ort Browns Ferry Nuclear Plant (BFN) Technical Specifications (TSs) 3.2.D.2 and 3.2.K.2 requires the semi-annual Radioactive Effluent Release Report to include an explanation of why the required radioactive effluent monitoring instrumentation was inoperable for more than 30 days.
This report covers the period from January through June 30, 1990.
The Radiological Effluent Technical Specification (RETS) became effective at BFN on May 6, 1987 during the current administrative outage.
Due to changes in the operability requirements of radioactive effluent monitoring instruments resulting from RETS, a number of radioactive effluent monitoring instruments were declared technically inoperable on May 6, 1987, that were previously considered operable.
Resources have been allocated to resolve these problems and others in order to establish compliance with the RETS.
The instruments that were inoperable for more than 30 days are:
Offgas post-treatment
monitors, 2-RM-90-265, 2-RM-90-266, 3-RM-90-265, and 3-RM-90-266 Sample flow abnormal annunciator, 2-PA-90-262 The liquid radiological effluent instrumentation that were inoperable for more than 30 days include:
Residual Heat'Removal (RHR) Service Water Monitors,'-RM-90-133,'0-RM-90-134, 2-RM-90-133, 2-RM-90-134, 3-RM-90-133, and 3-RM-90-134 Liquid Radwaste Effluent Flow Loop, 0-FR-77-60
Enclosure 3
Page 2,of 4 Off as Post-t eat e t Monito s and Sam e F ow Annunciator LCO Numbers 2
a d a
BFH TS Table 3.2.K requires the offgas post-treatment noble gas activity monitors and the associated abnormal sample flow alarm channels to be operable at all times.
Contrary to this requirement, four of the monitors and one of the sample flow annunciators were inoperable for periods greater than 30 days.
On December 22, 1989, the Offgas Sample Flow Abnormal annunciator, 2-PA-90-262, was declared inoperable following normal surveillance testing.
In turn, the inoperable status of the pressure annuciator resulted in the inoperability determination of both Offgas Post-treatment
Monitors, 2-RM-90-265 and 2-RM-90-266.
A Maintenance Request (MR) 1020850 was written to troubleshoot and correct the annunci'ator.
The root cause for the failed annunciator was traced to a defective offgas sample pump.
(MR) 1029002 was written to replace the pump with the radiation monitors remaining. in an inoperable status.
On February 17, 1990, the 24 VDC power supply board to the Offgas Post-treatment Monitors, 3-RM-90-265 and 3-RM-90-266, was deenergized to support neutron monitoring system penetration work.
The power suply board was returned to service and the monitors are awaiting functional testing.
Effluent releases via both pathways wex'e not permitted during'he inoperable periods.
This was accomplished bP maintaining the unit offgas isolation flow control valves in the closed position which resulted in no additional compensatory sampling requirements.
Enclosure 3
Page 3 of 4 u d Radwaste Ef lue ow Loo
-FR-LCO be BFN TS Table 3.2.D requires the Liquid Radwaste Effluent Flow Loop, O-FR-77-60, to be operable during releases via the radwaste system.
Contrary to this requirement, the flow loop was inoperable during the entire reporting period.
Manual compensatory measures were observed for all liquid releases for the reporting period.
The flow loop was declared technically inoperable on June 21,
1989, due to.
inaccuracies between the flow transmitter as compared to the actual tank levels.
A Design Change Notice (DCN) H4536A was written to replace the dual channel flow instrumentation with a single channel digital instrumentation.
All field work and associated post-modification testing should be completed and the flow loop returned to an operable status within the next reporting period.
Enclosure 3
Page 4 of 4 es dua eat emova RHR Se vice Water onito s LCO Number a d DCR Number 1
and DCN Number H
4 BFN TS Table 3.2.D requires the RHR Service Water monitors, 1-RM-90-133, 1-RM-90134, 2-RM-90-133, 2-RM-90-134, 3-RM-90-133, and 3-RM-90-134, to be oeprable during the operation of an RHR loop and the associated RHR service water system.
Contrary to this requirements, the six monitors were inoperable for periods greater than 30 days.
Footnote 2 of BFN TS Table 4.2.D requires that the RHR service monitors provide for control room annunciation if the monitor is not set in operate mode.
The current 1-RM-90-133, 3-RM-90-133, and 3-RM-90-134 monitors do not provide this capability.
Revision 1 of Design Change Request (DCR) 1687 was approved on September 29, 1986, to correct this issue.
To support unit 2
restart, the RHR service water piping associated with these monitors has been physically cut and capped as a positive isolation boundary.
Monitor 1-RM-90-134 has been out of service due to seismic concerns which are being resolved under DCN H3949.
A hold order has been placed to isolate and to remove from service the RHR service water piping associated with this monitor.
The monitor should be returned to service upon completion of DCN H3949.
As a result of problems related to sample pump automatic starting circuitry, unit 2 RHR service water monitor, '2-RM-90-133, was'elared in inoperable on September 24; 1989.
After an investigation, it was determined that the automatic pump start time delay logic does not allow fo'r charging the RHR service water headers.
A DCN has been written to correct the problem.
Unit 2 RHR service water monitor, 2-RM-90-134, was declared inoperable when the 480V shutdown board 2B was deenergized on February 15, 1990.
The RHR service water was isolated to the heat exchangers.
The monitor was returned to service on June 18, 1990.
ENCLOSURE a TENNESSEE VALLEY AUTHORITY BROWNS FERRY NUCLEAR PLANT SEMIANNUAL RADIOACTIVE EFFLUENT REIEASE REPORT CHANGES TO THE BFN OFFSITE DOSE CALCULATION MANUAL JANUARY THROUGH JUNE 1990
Enclosure 4
Page 1 of 1 CHANGES TO THE OFFSITE DOSE CALCULATION MANUAL BFN Technical Specification 6.12.2 requires that changes to the Offsite Dose Calculation Manual (ODCM) be submitted to the Commission with the semiannual Radioactive Effluent Release Report for the period in which the changes were made.
This report covers the period between January through June 30, 1990.
I During this period, one change to the ODCM was made.
The description, justification and analysis of each change are discussed by the following BFN ODCM Change Description Forms.
The changes were implemented by Revision 8 to the Radiological Effluent Technical Specification (RETS) Manual, of which the ODCM is a part.
Revision 8 of the RETS Manual is also provided for review.
~c
. ~riuy-.
Tttle.
Handling of Changes to the BFN Offsite Dose Calculation Hanual RARC OP 9
Revision 0 Page 4 of 4 Appendix l BFN ODCH Change Description Form Description of change:
Pages affected:
3usti fi cation for change:
~
~
5c.
i i
0 4
~
e Ana ysis of effect of change on dose calculations, pr ections, or setpoint calculations:
I
'is Attach marked-up pages from the current revision of the SQN ODCM which. show the change.
RARC Review:
RAR C airman Date:
067Bo/COC4 TVA19l9C (Oao.s.aa>
Title.
Handling of Changes tahe BFN Offsite Dose Calculation Manual
(
PAh~
~e Revision 0 Page 4 of 4 Appendix 1
BFN ODCM Change Description Form Description of change:
'i u~
z.
rani ~n'3 cUrW RC,<
Pages affected:
l
)
0 Justification for change:
Analysis of effect of change on dose calculations, projections, or setpoint calculations:
Attach marked-up pages from the current revi ion of the SQN ODCM which show the change.
RARC Review:
RC Chairman Date:
IJ 0678o/COC4 TVA7929C (ONo I.nas

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