Presentation is loading. Please wait.

Presentation is loading. Please wait.

Napa Plant Site Desalting Modeling Summary November 10, 2009.

Published byTyrone Marshall Modified over 9 years ago

Similar presentations

Presentation on theme: "Napa Plant Site Desalting Modeling Summary November 10, 2009."— Presentation transcript:

1 Napa Plant Site Desalting Modeling Summary November 10, 2009

2 Overview 1.Background 2.Approach to Salt Removal 3.Breach Concept 4.Field Experiments (Salt Dissolution) 5.2-D Modeling

3 DFG Agreement included Cargill removal of residual salt in the plant to the extent possible to facilitate restoration Cargill successfully harvested and removed approximately 350,000 tons (since 2003) Estimated 300,000 to 350,000 tons remain in the plant –Pickle Ponds (Unit 3, B1, B2, B3) salt removed –Residual salt remains in crystallizer beds with 2 to 6-inch salt crust Continued harvesting not physically possible Cargill explored other ways to meet desalination obligation Background

4 Approach to Salt Removal Other salt pond breach successes –NSM Pond 4 - temporary, localized effects (within natural variability at 5 days; ambient at 26 days) –NPS Ponds 9 and 10 - met RWQCB requirements within 24 hrs Develop breach concept to minimize impacts Field experiments to understand salt crust dissolution –Redwood City –Napa Plant Site Modeling to size breach for minimal impact –2-D Model –Validation

5 Breach Concept Napa River Crystallizer Bed Salt Crust Less Saline Layer Mudflat Weir High Saline Layer Dissolution tons/day Tidal Exchange Two layers exist within Site Mudflat Breach

6 Goal: better understand expected salt dissolution mechanism and rates Redwood City crystallizer dissolution tests showed dissolution rate over first 12 days <0.05 in/day Napa dissolution tests showed: –More dissolution in higher velocity areas –Clear stratification within the test area –Middle and top salinity levels 30 to 44 ppt Field Experiments

7 2-D Modeling Advection/Dispersion Model Objective: Evaluate breach concept for desalting the South Unit given restoration breach location 2-Dimensional for internal Plant Site and Napa River 1-Dimensional for sloughs and external ponds

8 Dissolution is the primary mechanism for salt loss Salt dissolves at a constant rate (0.05 in/day) Stratified high salinity layer within internal Plant Site remains throughout simulation Low velocities exist within internal Plant Site External breach occurs at Mudflat elevation Internal breaches per proposed Restoration Plan 2-D Modeling Assumptions

9 Modeling Period (August-October 2000) –Flow (USGS Gauging Stations at Oak Knoll Avenue and Agua Caliente) –Tides (NOAA Tide Stations at Mare Island and mouth of Sonoma Creek) –Ambient salinity (USGS Mare Island Causeway Station) Seasonally variability > 20 ppt Daily variability on the order of 5 ppt –Salt dissolution (Schaaf & Wheeler) 2-D Modeling Input Data

10 Salt Mass Estimate BedsSalt Mass (tons) B1+B216,000 B332,000 Unit 332,000 Crystallizers240,000 Total320,000 Unit 3 B-2 B-3 B-1

11 Rate of Salt Dissolution B-1 & B-2 Salt Mass Dissolved Unit 3 Salt Mass Dissolved B-3 Salt Mass Dissolved Crystallizer Beds Salt Mass Dissolved

12 Input Data -Salinity Salinity Data Typical (1999-2005) Seasonal Variability of 20 ppt Average Salinity Readings at Mare Island Causeway Station

13 Input Data - Salinity Daily Variability of 5 ppt

14 Model Results

15 Modeling Results Evaluation Points Internal External (Breach & River)

16 Modeling Results - Salinity

17 70-foot Breach Modeling Results - Salinity Maximum Salinity – after 6 days

18 70-foot Breach Modeling Results - Salinity after 8 days

19 70-foot Breach Modeling Results - Salinity after 28 days

20 70-foot Breach Modeling Results - Salinity after 42 days

21 Loc. A Loc. C Loc. B Modeling Results – Location C

22 Loc. A Loc. C Loc. B Modeling Results – Location B

23 Loc. A Loc. C Loc. B Modeling Results – Location A

24 2-D Modeling 70’ Breach Maximum Salinity Difference (ppt) Max. Salinity Duration Location C: Outside Breach Max. Hourly10 Once a day for three days Max. Tidally Averaged 46 days Location B: Outside Mudflat Max. Hourly2 Once a day for two days Max. Tidally Averaged <2- Location A: Napa River Max. Hourly<2- Max. Tidally Averaged <2- Experience demonstrates saline brines can be released in an environmentally acceptable manner Field experiments clarified dissolution mechanism and rates Modeling results showed that Salinity within Napa River remains within natural variability

25 Questions?

26 Input Data - Flow Flow Data Typical (1999-2005)

27 Input Data - Tidal Tidal Data Typical per Historical Means

Download ppt "Napa Plant Site Desalting Modeling Summary November 10, 2009."

Similar presentations

HydroQual, Inc. Application of the SWMM Storage-Treatment Block for Analysis/Design of Extended-Detention Ponds Thomas L. Newman II, P.E. Tarig A. Omer.

HydroQual, Inc. Application of the SWMM Storage-Treatment Block for Analysis/Design of Extended-Detention Ponds Thomas L. Newman II, P.E. Tarig A. Omer.
3.4-37.ppt Tularosa Basin National Desalination Research Center Feasibility Study Presented by Mike Hightower, Sandia National Laboratories Tom Jennings,

ppt Tularosa Basin National Desalination Research Center Feasibility Study Presented by Mike Hightower, Sandia National Laboratories Tom Jennings,
Upstream and Downstream Passage of American Eels at the Medway Project, Penobscot River, Maine Scott Hall ————————————— PPL Maine, LLC Milford, Maine Steve.

Upstream and Downstream Passage of American Eels at the Medway Project, Penobscot River, Maine Scott Hall ————————————— PPL Maine, LLC Milford, Maine Steve.
CE 370 Sedimentation.

CE 370 Sedimentation.
WATER I NNOVATE Pascal Harper Product Manager. 2 Application Areas for Greenfield Sites –Incorporate odour emissions into process selection. Process Upgrades.

WATER I NNOVATE Pascal Harper Product Manager. 2 Application Areas for Greenfield Sites –Incorporate odour emissions into process selection. Process Upgrades.
Fluidyn FLOWCOAST FLOOIL 3D Fluid Dynamics Model to Simulate Oil slick movement in coastal waters or rivers FLOOIL.

Fluidyn FLOWCOAST FLOOIL 3D Fluid Dynamics Model to Simulate Oil slick movement in coastal waters or rivers FLOOIL.
Solar Evaporation Ponds at the Salton Sea for Salinity Control

Solar Evaporation Ponds at the Salton Sea for Salinity Control
U.S. Department of the Interior U.S. Geological Survey Bathymetric Surveys on Ponds 3, 4, & 5, Napa-Sonoma Marshes U.S. Geological Survey John Y. Takekawa,

U.S. Department of the Interior U.S. Geological Survey Bathymetric Surveys on Ponds 3, 4, & 5, Napa-Sonoma Marshes U.S. Geological Survey John Y. Takekawa,
U.S. Department of the Interior U.S. Geological Survey Bathymetric & Bird Surveys Ponds 9 & 10, Wash Ponds, and Napa Plant Site U.S. Geological Survey.

U.S. Department of the Interior U.S. Geological Survey Bathymetric & Bird Surveys Ponds 9 & 10, Wash Ponds, and Napa Plant Site U.S. Geological Survey.
Oceans.

Oceans.
Visualization of SUNTANS model Using ArcGIS ——Dongyu Feng.

Visualization of SUNTANS model Using ArcGIS ——Dongyu Feng.
Illinois Drainage Water Management Demonstration Project Don Pitts Agricultural Engineer State Water Quality Specialist Champaign, IL NRCS USDA.

Illinois Drainage Water Management Demonstration Project Don Pitts Agricultural Engineer State Water Quality Specialist Champaign, IL NRCS USDA.
Investigating the Colorado River Simulation Model James Prairie Bureau of Reclamation.

Investigating the Colorado River Simulation Model James Prairie Bureau of Reclamation.
Determination of Station Depths Relative to NGVD29 Methods and results Jan 24, 2003 Charles Seaton.

Determination of Station Depths Relative to NGVD29 Methods and results Jan 24, 2003 Charles Seaton.
Temperature and Flow Dynamics of the Klamath River Technical Memorandum 7 Leon Basdekas Mike Deas Watercourse Engineering, Inc 424 2 nd Street, Suite B.

Temperature and Flow Dynamics of the Klamath River Technical Memorandum 7 Leon Basdekas Mike Deas Watercourse Engineering, Inc nd Street, Suite B.
Hydrological Modeling FISH 513 April 10, 2002. Overview: What is wrong with simple statistical regressions of hydrologic response on impervious area?

Hydrological Modeling FISH 513 April 10, Overview: What is wrong with simple statistical regressions of hydrologic response on impervious area?
Introduction to the ISC Model Marti Blad NAU College of Engineering.

Introduction to the ISC Model Marti Blad NAU College of Engineering.
St. Johns River Water Supply Impact Study by Getachew Belaineh Ph. D., P.H. 1 Brian McGurk P.G. 1 Louis Motz Ph. D., P.E 2 Follow up Review meeting March,

St. Johns River Water Supply Impact Study by Getachew Belaineh Ph. D., P.H. 1 Brian McGurk P.G. 1 Louis Motz Ph. D., P.E 2 Follow up Review meeting March,
Annapolis Royal Tidal Generating Station By: Melissa Bullen.

Annapolis Royal Tidal Generating Station By: Melissa Bullen.
Combining Long-term And High Frequency Water Quality Data To Understand Ecological Processes In Estuaries Jane Caffrey Center for Environmental Diagnostics.

Combining Long-term And High Frequency Water Quality Data To Understand Ecological Processes In Estuaries Jane Caffrey Center for Environmental Diagnostics.

Similar presentations

Ads by Google