• Military

• WMD Menu                           

• Introduction
• Systems
• Facilities
• Agencies
• Operations
• Countries
• Hot Documents
• News
• Reports
• Policy
• Budget
• Congress
• Links

• Intelligence
• Homeland Security
• Space

E.3.0 LONG-TERM MANAGEMENT ALTERNATIVE

This section analyzes the risk resulting from potential accidents associated with the Long-Term Management alternative. The Long-Term Management alternative is to continue safe storage activities. This includes:

• Perform routine management and maintenance activities;
• Continue pumping and evaporation of liquid;
• Construct replacement DSTs and associated evaporators;
• Waste transfer system upgrade (W314); and
• Transfers waste via pipeline to the Evaporator Facility or replacement tanks.

E.3.1 CONSTRUCTION ACCIDENTS

The construction activities associated with the Long-Term Management alternative are discussed in Volume Two, Appendix B of the EIS. It should be noted that there are no radiological or chemical consequences associated with construction accidents because the replacement tanks and associated transfer lines and evaporators would be constructed in uncontaminated areas. Occupational injuries, illnesses, and fatalities resulting from potential construction accidents are calculated in the following text.

Construction would require an estimated 3.75E+03 person-years (Jacobs 1996). The total recordable injuries and illnesses, lost workday cases, and fatalities for the 10 years of construction were calculated using the incidence rates from Table E.1.2.1 as follows:

Total Recordable Cases = (3.75E+03 person-years) · (9.75E+00 incidences/100 person-years) = 3.66E+02

Lost Workday Cases = (3.75E+03 person-years) · (2.45E+00 incidences/100 person-years) = 9.19E+01

Fatalities= (3.75E+03 person-years) · (3.2E-03 fatalities/100 person-years) = 1.2E-01

E.3.2 TRANSPORTATION ACCIDENTS

Transportation activities associated with this alternative are 1) transporting construction material from offsite; and 2) employees commuting to work each day.

E.3.2.1 Radiological Cancer Risk

All operations would be conducted within established operating parameters for the tanks and would not involve transporting radioactive materials by container. Therefore, there would be no radiological cancer risks resulting from transportation. Accidents involving the transfer of waste in the transfer lines are discussed in Section E.3.3.

E.3.2.2 Chemical Exposure

Because there would be very limited transportation of toxic materials (e.g., lubricants for routine operations), it is extremely unlikely there would be any accidents resulting in chemical exposures. Therefore, transportation accidents involving chemical exposures were not quantified.

E.3.2.3 Occupational Injuries and Fatalities Truck and Rail Transportation Accident

Injuries and fatalities resulting from direct impact of transportation accidents are analyzed in this subsection. Truck and rail transportation activities to transport material and supplies to the Hanford Site for this alternative are summarized in Table E.3.2.1. The total distance was calculated by multiplying the number of trips by the round-trip distance.

Table E.3.2.1 Summary of Transportation Activities for the Long-Term Management Alternative

The number of injuries and fatalities were calculated by multiplying the total distance traveled in each zone shown in Table E.3.2.2 by the appropriate unit risk factors shown in Table E.3.2.1. The distance traveled in the population zones were calculated using the methodology previously discussed in Section E.1.3. The expected injuries and fatalities resulting from truck and rail transportation accidents associated with the Long-Term Management alternative are summarized in Table E.3.2.3.

Table E.3.2.2 Distance Traveled in Population Zones for the Long-Term Management Alternative

Table E.3.2.3 Injuries and Fatalities Resulting from Truck and Rail Transportation Accidents for the Long-Term Management Alternative

Employee Traffic

In addition to transporting materials and supplies to and from the Hanford Site by truck and rail, Site workers and other personnel required to perform the various activities would drive to the Site in their vehicles. The total person-years to perform the activities was estimated at 1.08E+05 (Jacobs 1996).

To calculate the expected number of injuries and fatalities resulting from vehicle accidents, the injury/fatality rates discussed in Section E.1.3 were used. The expected number of injuries and fatalities resulting from employee vehicle accidents are calculated as follows:

Injuries = (2.91E+09 km) · (7.1E-07 injuries/km) = 2.08E+03

Fatalities = (2.91E+09 km) · (8.98E-09 fatalities/km) = 2.61E+01

Cumulative Transportation Injuries and Fatalities

The cumulative nonradiological and nontoxicological injuries and fatalities incurred as a direct result of traffic accident impacts are the sum of the truck and rail transport and employee vehicle accidents and are summarized in Table E.3.2.4.

Table E.3.2.4 Cumulative Injuries and Fatalities from Traffic Impacts for the Long-Term Management Alternative

Each person was assumed to work 260 days of the year. The round trip distance traveled to work from the Tri-Cities area was estimated at 140 km (87 mi) with an estimated 1.35 passengers per vehicle (DOE 1994a). The total employee vehicle distance was therefore calculated to be 2.91E+09 km (1.81E+09 mi).

E.3.3 OPERATION ACCIDENTS

The potential exists for accidents resulting from continued operation activities. The continued operations are discussed in Volume Two, Appendix B.

E.3.3.1 Continued Operations Accident - Tank Waste Transfers

The dominant continued operations accident during tank waste transfers is the "mispositioned jumper accident" previously discussed in the No Action (Tank Waste) alternative Section E.2.2.1 and summarized as follows:

Source-term - The source-term resulting from a spray release in Section E.2.2.1.1 was calculated to be 52 L (14 gal).

Probability - The frequency of a mispositioned jumper in Section E.2.2.1.2 was 1.1E-02 per year. The probability of occurrence is based on 20 years of waste transfers to accommodate the retanking operations. Therefore, the probability was calculated to be 2.2E-01.

Radiological Consequences - The radiological consequences presented in Table E.2.2.2 are reproduced in Table E.3.3.1.

Table E.3.3.1 Dose Consequence from Mispositioned Jumper

Radiological Cancer Risk - The LCFs calculated in Section E.2.2.1.4 are the same for the Long-Term Management alternative; however, the LCF risk (point estimate) is not the same because of the difference in probabilities. The LCFs and the LCF risks are calculated in Table E.3.3.2.

Table E.3.3.2 Latent Cancer Fatality Risk from Mispositioned Jumper

The bounding scenario calculations show all 10 workers would potentially receive a fatal dose and would assumably die directly after the exposure if the accident occurred. Approximately seven noninvolved workers would receive fatal cancers, and two LCFs would be incurred to the general public. The nominal scenario calculators show there would be no LCFs.

Chemical Consequences

For the Long-Term Management alternative, the potential acute hazards associated with the mispositioned jumper are the same as the acute hazards presented in Tables E. 2.2.4 and E.2.2.7 for the No Action alternative.

Toxic Impact From Chemical Exposure

Under nominal conditions (Table E.2.2.4), the cumulative acute hazard ratios for the MEI worker, MEI noninvolved worker and MEI general public were less than 1.0, indicating that no adverse acute health effects would be expected for these three receptors. Under bounding conditions (Table E.2.2.5), the MEI worker was not evaluated because death would occur from exposure to radionuclides. The cumulative acute hazard ratio for the MEI noninvolved worker was 5.36E+00 for ERPG-2, indicating that reversible acute health effects would be expected. This acute hazard ratio was primarily attributable to mercury (approximately 89 percent of the overall hazard ratio). No adverse acute health effects were predicted for the MEI general public under bounding conditions.

Corrosive/Irritant Impact from Chemical Exposure

Under nominal conditions (Table E.2.2.6), the cumulative acute hazard ratio for the MEI worker was 2.70E+00 for ERPG-3, indicating the potential for irreversible health effects that could be life-threatening. This acute hazard ratio was almost entirely attributable to sodium assumed to be equivalent to sodium hydroxide in corrosive/irritant effects. For the MEI noninvolved worker, the cumulative acute hazard ratio for ERPG-1 was 3.0E+00, indicating that only mild, reversible irritant effects would be expected. No acute health impacts were predicted for the MEI general public under nominal conditions. Under bounding conditions (Table E.2.2.7), the MEI worker was not evaluated because death would occur from exposure to radionuclides. For the MEI noninvolved worker, the cumulative acute hazard ratio for ERPG-1 was 4.36E+00, indicating that only mild reversible irritant effects would be expected. No acute health impacts were predicted for the MEI general public under bounding conditions.

Under both nominal and bounding conditions, the probability of a mispositioned jumper is 2.20E-01.

E.3.3.2 Continued Operations Accident - Waste Storage Tanks

The dominant accident is a hydrogen deflagration in a waste storage tank previously discussed in the No Action alternative in Section E.2.2.2.1 and is summarized as follows:

Source-term - The source-term resulting from a hydrogen deflagration in Section E.2.2.2.1 was calculated to be 2.4 L (0.6 gal).

Probability - The frequency of the hydrogen deflagration in a waste storage tank in Section E.2.2.2.2 was estimated to be 7.2E-03 per year. The probability of the scenario based on 100 years of operation was therefore estimated to be 7.2E-01.

Radiological Consequences - The radiological consequences presented in Table E.2. 2.8 are reproduced in Table E.3.3.3.

Table E.3.3.3 Dose Consequence from Hydrogen Deflagration in Waste Storage Tank

Radiological Cancer Risk

The LCFs calculated in Section E.2.2.2.4 are reproduced in Table E.3.3.4.

Table E.3.3.4 Latent Cancer Fatality Risk from Hydrogen Deflagration in Waste Storage Tank

In the bounding scenario all 10 workers would potentially receive a fatal dose and would assumably die directly after the exposure. T here would also be 10 LCFs attributed to the exposure to the noninvolved workers and 2 LCFs to the general public if the accident occurred. The nominal scenario calculations show there would be no LCFs.

Chemical Consequences

The potential acute hazards associated with the hydrogen deflagration in a waste storage tank are summarized in Table E. 2.2.10 through E.2.2.13 for toxic and corrosive/irritant effects, respectively.

Under bounding conditions c hemical impacts were not evaluated for the worker because all workers would receive a lethal radiation dose as discussed previously.

Toxic Impact from Chemical Exposure

Under nominal conditions (Table E.2.2.10), the cumulative acute hazard ratio for the MEI worker was 1.57 for ERPG-2, indicating that reversible acute health effects would be expected. This acute hazard ratio was primarily attributable to TOC (approximately 87 percent of the overall ERPG-2 ratio). The TOC is assumed to be equivalent in toxicity to tributylphosphate which is the most acutely toxic constituent of the organic analytes identified. Tributylphosphate was used as a surrogate because an inventory of the various chemicals that make up the TOC class is not available. For the MEI noninvolved worker, the cumulative acute hazard ratio for ERPG-3 was 9.38, indicating the potential for irreversible health effects that could be life-threatening. This acute hazard ratio was also primarily attributable to TOC (approximately 90 percent of the overall ERPG-3 ratio) However, the MEI noninvolved worker is a hypothetical worker assumed to be located 100m (330 ft)from the source area. The first, anticipated noninvolved worker population is located 290 m (950 ft) from the source area and had no cumulative acute hazard ratios greater than 1.0 for any of the ERPGs, indicating that no acute health effects would be expected for the nearest noninvolved worker population. Likewise, no acute health effects were predicted for the MEI general public under nominal conditions.

Under bounding conditions (Table E.2.2.11), the cumulative acute hazard ratio for the MEI noninvolved worker was 4.54E+02 for ERPG-3, indicating the potential for irreversible health effects that could be life-threatening. This acute hazard ratio is primarily attributable to:

• Oxalate (approximately 37 percent of the total hazard ratio);
• Beryllium (approximately 13 percent of the total hazard ratio);
• Cadmium (approximately 14 percent of the total hazard ratio);
• Uranium (approximately 12 percent of the total hazard ratio); and
• TOC (approximately 8 percent of the total hazard ratio).

As discussed previously, this is a hypothetical receptor located 100m (330 ft)from the source. The cumulative acute hazard ratio for the nearest noninvolved worker population located 290 m (950 ft) from the source was 1.65 for ERPG-3, indicating the potential for irreversible health effects that could be life-threatening for 335 workers. This hazard ratio was attributable to the same toxic chemicals listed above. This exceedance of the ERPG-3 criterion for the nearest noninvolved worker population would not be expected to result in irreversible health effects or place these workers in a life-threatening situation for the following reasons.

• ERPG-3 is defined as a concentration in which a receptor can be exposed for 1 hour without irreversible health effects. Because the Hanford Site has an in-place emergency response plan designed to evacuate workers within 1 hour of an accident, workers would be expected to evacuate their location and move to an area where potential exposures would be well below ERPG-3. Therefore, this worker population would not be exposed to airborne concentrations that would be either life threatening or result in irreversible health effects.
• The estimated air concentrations of chemicals as a result of this accident were based on very conservative meteorology, which results in movement of a plume directly toward the worker population at a relatively slow rate with minimal wind dispersion. If less conservative meteorological parameters were used, wind dispersion would cause the estimated air concentrations of chemicals to be substantially less, and the ERPG-3 criterion would not be exceeded.
• Only the bounding toxic chemical evaluation exceeded ERPG-3, while the nominal evaluation was well below 1.00 for ERPG-3, suggesting that the noninvolved worker population would not receive an exposure that would result in any permanent health effects.

The next nearest noninvolved worker population is located 1,780 (5,840 ft) from the source and contains 1,500 workers. The cumulative acute hazard ratio was less than 1.0 for all ERPGs, indicating that no acute health effects would be expected for this population of workers. No acute health impacts were predicted for the MEI general public.

Corrosive/Irritant Impact from Chemical Exposure

Under nominal conditions (Table E.2.2.12), the cumulative acute hazard ratio for the MEI worker was 3.82 for ERPG-3, indicating the potential for irreversible corrosive/irritant effects that could be life-threatening. For the MEI noninvolved worker, the cumulative acute hazard ratio for ERPG-3 was 7.89E+01 and would indicate irreversible corrosive/irritant effects that could be life threatening for this hypothetical receptor. This hazard ratio was primarily attributable to sodium which was assumed to be equivalent to sodium hydroxide in corrosive/irritant effects. For the nearest noninvolved worker population (290 m [950 ft]) composed of 335 workers, the cumulative acute hazard ratio for ERPG-1 was 1.38E+01, indicating that only mild reversible effects would be expected. No acute health impacts were predicted for the MEI general public under nominal conditions.

Under bounding conditions (Table E.2.2.13), the cumulative acute hazard ratio for the MEI noninvolved worker was 1.91E+02 for ERPG-3, indicating irreversible health effects that could be life threatening for this hypothetical receptor. This hazard ratio was primarily attributable to :

• Sodium as sodium hydroxide (approximately 75 percent of the total hazard ratio);
• Chromium (approximately 14 percent of the total hazard ratio); and
• Calcium (approximately 6 percent of the total hazard ratio).

For the nearest noninvolved worker population (290 m [950 ft]) composed of 335 workers, the cumulative acute hazard ratio was 1.74 for ERPG-2, indicating that reversible acute effects would be expected. No acute health impacts were predicted for the MEI general public under nominal conditions.

Under both nominal and bounding conditions the probability of a hydrogen deflagration event in a waste storage tank is 7.20E-01.

E.3.3.3 Beyond Design Basis Accidents

The beyond design basis accident is a seismic event resulting in the collapse of a SST. In the event of a 0.43 g earthquake, a SST could potentially collapse (LANL 1995). This event is not dependent on the remediation alternative but has the same annual frequency regardless of the alternative that is chosen. The length of time unremediated waste would remain in tanks that have not been backfilled would vary depending on the alternative and would affect the probability of the event. The probability of the event is the product of the annual frequency of the earthquake and the number of years the waste remains untreated in the unstabilized tanks.

At smaller annual frequencies, larger earthquakes could occur resulting in greater destruction and larger numbers of LCF to the onsite and offsite populations. In addition to population exposures from the collapsed SSTs, the impact to other Hanford Site facilities and operations would potentially add to the chemical and radiological risk. This would be a severe earthquake that would cause catastrophic structural damage in the Tri-Cities and the Hanford Site with expected extensive loss of life. There would be injuries and fatalities resulting from collapsed buildings and homes, fires, and traffic accidents. However, this section evaluates the radiological and chemical impacts resulting from the collapse of one SST.

E.3.3.3.1 Source-Term Development

It was conservatively assumed that the radiological and chemical contaminants in the headspace are available for release. The collapse of a portion of the dome and overburden compresses the vapor in the headspace as it descends, enhancing the vapor release rate by a sudden pressure difference. Assuming for each tank a respirable concentration of contaminants in the headspace of 100 mg/m³, a liquid SpG of 1.5, and a headspace volume of 1,000 m³ (Shire et al. 1995 and Jacobs 1996), the potential source-term contribution from the headspace release was calculated as follows:

(100 mg/m³) · (1 g/1,000 mg) · (1 L/1,000 g) · (1,000 m³) · (1/1.5) = 6.67E-02 L (1.8E-02 gal).

It was conservatively assumed that the liquids had been pumped from the tanks so that the tanks contained only solids and the MAR was 2,500 L (660 gal) for each tank. It was postulated that the fall of the dome and overburden generated a air movement sufficient to suspend a fraction the MAR. Assuming the respirable release fraction to be 2.0E-03 (Shire et al. 1995 and Jacobs 1996), the potential source-term contribution was calculated as follows:

(2,500 L) · (2.0E-03) = 5.0 L (1.3 gal).

It was postulated that prevailing winds resuspend a respirable fraction of the MAR (2,500 L [660 gal]). A respirable release fraction of 4.0E-05/hr for 24 hours was assumed. The potential source-term contribution from resuspension was calculated as follows:

(2,500 L) · (4.0E-05/hr) · (24 hr) = 2.4 L (0.6 gal).

The combined source-term for the acute release is calculated as follows:

(6.67E-02 L) + (5.00E+00 L) + (2.4 L) = 7.4 L (2.0 gal).

E.3.3.3.2 Probability of a Beyond Design Basis Earthquake

This earthquake has a calculated annual exceedance frequency of approximately 1.40E-04 (WHC 1996b). The probability for this scenario based on 100 years of operation was therefore estimated to be 1.40E-02.

E.3.3.3.3 Radiological Consequences from a Beyond Design Basis Earthquake

The radiological dose to the receptors from the previous source-term was calculated by the GENII computer code (Napier et al. 1988) using the methodology previously discussed in Section E.1.1.6. The results are presented in Table E.3.3.5.

Table E.3.3.5 Dose Consequence from Seismic Event

E.3.3.3.4 Radiological Cancer Risk from a Beyond Design Basis Earthquake

The LCFs and LCF point estimate risk are presented in Table E.3.3.6

Table E.3.3.6 Latent Cancer Fatality Risk from Seismic Event

In the bounding scenario, all 10 workers would potentially receive a fatal dose and assumably die directly after the exposure. There would also be 10 LCFs attributed to the exposure to the noninvolved workers and two LCFs to the general public if the accident occurred. The nominal scenario calculations show there would be no LCFs.

E.3.3.3.5 Chemical Consequences from a Beyond Design Basis Earthquake

For the Long-Term Management alternative, the potential acute hazards associated with a beyond design basis earthquake are the same as the acute hazards presented in Tables E.2.2.16 (toxic chemicals, nominal conditions), E.2.2.17 (toxic chemicals, bounding conditions), E.2.2.18 (corrosive/irritant chemicals, nominal conditions) and E.2.2.19 (corrosive/irritant chemicals, bounding conditions) for the No Action alternative.

Under bounding conditions, chemical impacts were not evaluated for the MEI worker because all workers would receive a lethal radiation dose, as discussed previously.

Toxic Impact from Chemical Exposure

Under nominal conditions (Table E.2.2.16), the cumulative acute hazard ratio for the MEI worker was 2.64E+00 for ERPG-1, indicating that only mild transient effects would be expected. For the MEI noninvolved worker, the cumulative acute health hazard was 2.59E+00 for ERPG-3, indicating the potential for irreversible health effects that could be life threatening. This acute hazard ratio was primarily attributable to TOC (approximately 84 percent of the total hazard ratio). The TOC is assumed to be equivalent in toxicity to tributylphosphate which is the most acutely toxic constituent of the organic analytes identified. Tributylphosphate was used as a surrogate because an inventory of the various chemicals that make up the TOC class is not available. The cumulative acute hazard ratio for the nearest noninvolved worker population consisting of 335 workers located 290 m (950 ft) away was less than 1.0 for all ERPGs, suggesting that no acute health effects would be expected.

Under bounding conditions (Table E.2.2.17), the cumulative hazard ratios for the MEI and nearest noninvolved worker (335 workers located 290 m [950 ft] away) were 2.15E+03 and 7.80E+00 for ERPG-3, respectively. These ratios were primarily attributable to:

• Uranium (approximately 47 percent of the total hazard ratio);
• Oxalate (approximately 24 percent of the total hazard ratio); and
• Mercury (approximately 13 percent of the total hazard ratio).

This exceedance of the ERPG-3 criterion for the nearest noninvolved worker population would not be expected to result in irreversible health effects or place these workers in a life-threatening situation for the following reasons.

• ERPG-3 is defined as a concentration in which a receptor can be exposed for 1 hour without irreversible health effects. Because the Hanford Site has an in-place emergency response plan designed to evacuate workers within 1 hour of an accident, workers would be expected to evacuate their location and move to an area where potential exposures would be well below ERPG-3. Therefore, this worker population would not be exposed to airborne concentrations that would be either life threatening or result in irreversible health effects.
• The estimated air concentrations of chemicals as a result of this accident were based on very conservative meteorology, which results in movement of a plume directly toward the worker population at a relatively slow rate with minimal wind dispersion. If less conservative meteorological parameters were used, wind dispersion would cause the estimated air concentrations of chemicals to be substantially less, and the ERPG-3 criterion would not be exceeded.
• Only the bounding toxic chemical evaluation exceeded ERPG-3, while the nominal evaluation was well below 1.00 for ERPG-3, suggesting that the noninvolved worker population would not receive an exposure that would result in any permanent health effects.

The cumulative acute hazard ratio for the next nearest noninvolved worker population, composed of 1,500 people and located 1,780 (5,840 ft) away, was 2.15E+00 for ERPG-2, indicating that reversible acute health effects would be expected. The cumulative acute hazard ratio for the MEI general public was 1.76E+00 for ERPG-2, indicating that reversible acute health effects would be expected.

Corrosive/Irritant Impact from Chemical Exposure

Under nominal conditions (Table E.2.2.18), the cumulative acute hazard ratios for the MEI worker, MEI noninvolved worker and nearest noninvolved worker (335 workers at 290 m [950 ft]) were 2.47E+01, 5.10E+02 and 1.85E+00, respectively for ERPG-3, indicating the potential for irreversible health effects that could be life threatening. These ratios were almost entirely attributable to sodium which was assumed to be equivalent to sodium hydroxide in corrosive/irritant effects. This exceedance of the ERPG-3 criterion for the nearest noninvolved worker population would not be expected to result in irreversible health effects or place these workers in a life-threatening situation for the following reasons.

• ERPG-3 is defined as a concentration in which a receptor can be exposed for 1 hour without irreversible health effects. Because the Hanford Site has an in-place emergency response plan designed to evacuate workers within 1 hour of an accident, workers would be expected to evacuate their location and move to an area where potential exposures would be well below ERPG-3. Therefore, this worker population would not be exposed to airborne concentrations that would be either life threatening or result in irreversible health effects.
• The estimated air concentrations of chemicals as a result of this accident were based on very conservative meteorology, which results in movement of a plume directly toward the worker population at a relatively slow rate with minimal wind dispersion. If less conservative meteorological parameters were used, wind dispersion would cause the estimated air concentrations of chemicals to be substantially less, and the ERPG-3 criterion would not be exceeded.
• Only the bounding toxic chemical evaluation exceeded ERPG-3, while the nominal evaluation was well below 1.00 for ERPG-3, suggesting that the noninvolved worker population would not receive an exposure that would result in any permanent health effects.

For the next nearest noninvolved worker population (1,500 workers at 1,780 m [5,840 ft]), the cumulative acute hazard ratio was 1.20E+00 for ERPG-1, indicating that only mild, irreversible irritant effects would be anticipated. For the MEI general public, the cumulative acute hazard ratio was less than 1.0 for all ERPGs and no acute health effects would be expected.

Under bounding conditions, the cumulative acute hazard ratios for the MEI noninvolved worker and nearest noninvolved worker (335 workers at 290 m [950 ft]) were 7.31E+02 and 2.65E+00, respectively for ERPG-3, indicating the potential for irreversible health effects that could be life threatening. These acute hazard ratios were primarily attributable to:

• Sodium (approximately 83 percent of the total hazard ratio); and
• Calcium (approximately 10 percent of the total hazard ratio).

Based in the discussion presented above, even through the acute hazard ratio exceeded ERPG-3, the noninvolved worker population would not experience irreversible health effects.

For the next nearest noninvolved worker and MEI general public, the cumulative acute hazard ratios were 1.74E+00 and 1.42E+00, respectively for ERPG-1, indicating that only mild, transient irritant effects would be expected.

Under both nominal and bounding conditions, the probability of a seismic event is 1.40E-02.

E.3.3. 4 Occupational Injuries and Fatalities from Operations

The number of operation personnel was estimated at 1.04E+05 person-years (Jacobs 1996) during 100 years of routine operations. The total recordable injuries or illnesses, lost workday cases, and fatalities were calculated as follows:

Total Recordable Cases = (1.04E+05 person-years) · (2.2E+00 incidences/100 person-years) = 2.29E+03

Lost Workday Cases = (1.04E+05 person-years) · (1.1E+00 incidences/100 person-years) = 1.14E+03

Fatalities = (1.04E+05 person-years) · (3.2E-03 fatalities/100 person-years) = 3.33E+00

E.3.4 POST-REMEDIATION ACCIDENT

The post remediation accident for the Long-Term Management alternative would be the tanks collapsing due to an earthquake, as discussed in Section E.2.3. The radiological consequences to the onsite population would result in approximately 42 LCFs. E xposure to toxic chemicals would exceed the ERPG-3 threshold values by a factor of 2.25E+02.

The radiological consequences to the offsite population would result in approximately 4 LCFs. The population living closest to the Hanford Site would receive an exposure to toxic chemicals that would exceed the ERPG-2 threshold value by a factor of 1.08E+01 indicating they would suffer from mild, transient health effects.

E.3.5 SUMMARY OF ACCIDENTS

The potential consequences from nonradiological and nonchemical accidents that include occupational and transportation impacts are summarized in Table E.3.5.1. The LCFs associated with representative accidents for each component of the alternative are summarized in Table E.3.5.2 along with the probability of the accident. The chemical hazards associated with representative accidents for each component of the alternative are summarized in Table E.3.5.3. The chemical hazard is expressed as an exceedance of the ERPG threshold values.

Table E.3.5.1 Summary of Potential Nonradiological/Nonchemical Accident Consequences

Table E.3.5.2 Summary of Potential Radiological Accident Consequences

Table E.3.5.3 Chemical Exposures Resulting from Potential Operations and Transportation Accidents