Strict Compliance with Construction Contract Notice Provisions
Notice of Construction Application
Transcript of Notice of Construction Application
Notice of Construction Application
A notice of construction permit is required before installing a new source of air pollution or modifying an existing source of air pollution. This application applies to facilities in Ecology’s jurisdiction. Submit this application for review of your project. For general information about completing the application, refer to Ecology Forms ECY 070-410a-g, “Instructions for Ecology’s Notice of Construction Application.”
Ecology offers up to 2 hours of free pre-application help. We encourage you to schedule a pre-application meeting with the contact person specified for the location of your proposal (see below). For more help than the initial 2 free hours, submit Part 1 of the application and the application fee. You may schedule a meeting with us at any point in the process.
Completing the application, enclose it with a check for the initial fee and mail to:
To request ADA accommodation, call (360) 407-6800, 711 (relay service), or 877-833-6341(TTY). ECY
070-410 (Rev. 03/2018) Page 1 of 6
Check the box for the location of your proposal. For help, call the contact listed below. Ecology Permitting Office Contact
CRO Chelan, Douglas, Kittitas, Klickitat, or Okanogan County
Ecology Central Regional Office – Air Quality Program
Lynnette Haller (509) 457-7126
ERO
Adams, Asotin, Columbia, Ferry, Franklin, Garfield, Grant, Lincoln, Pend Oreille, Stevens,
Walla Walla, or Whitman County Ecology Eastern Regional Office – Air Quality Program
Karin Baldwin (509) 329-3452
NWRO San Juan County
Ecology Northwest Regional Office – Air Quality Program
Dave Adler (425) 649-7267
IND
Kraft and Sulfite Paper Mills and Aluminum Smelters Ecology Industrial Section – Waste 2 Resources Program
Permit manager: ____________________________________
James DeMay (360) 407-6868
NWP U.S. Department of Energy Hanford Reservation
Ecology Nuclear Waste Program
Lilyann Murphy(509) 372-7951
WA Department of Ecology Cashiering Unit P.O. Box 47611 Olympia, WA 98504-7611
For Fiscal Office Use Only: 001-NSR-216-0299-000404
Notice of Construction Application
ECY 070-410 (Rev. 03/2018) Page 2 of 6
Check the box for the fee that applies to your application.
New project or equipment
$1,500: Basic project initial fee covers up to 16 hours of review
$10,000: Complex project initial fee covers up to 106 hours of review
Change to an existing permit or equipment $200: Administrative or simple change initial fee covers up to 3 hours of review Ecology may determine your change is complex during completeness review of your application. If your project is complex, you must pay the additional $675 before we will continue working on your application.
$875: Complex change initial fee covers up to 10 hours of review
$350 flat fee: Replace or alter control technology equipment (WAC 173-400-114) Ecology will contact you if we determine your change belongs in another fee category. You must pay the fee associated with that category before we will continue working on your application.
Read each statement, then check the box next to it to acknowledge that you agree.
The initial fee you submitted may not cover the cost of processing your application. Ecology will track the number of hours spent on your project. If the number of hours Ecology spends exceeds the hours included in your initial fee, Ecology will charge you $95 per hour for the extra time.
You must include all information in this application. Ecology may not process your application if it does not include all the information requested.
Submittal of this application allows Ecology staff to inspect your facility.
Notice of Construction Application
ECY 070-410 (Rev. 03/2018) Page 3 of 6
Part 1: General Information I. Project, Facility, and Company Information1. Project Name
2. Facility Name
3. Facility Street Address
4. Facility Legal Description
5. Company Legal Name (if different than Facility Name)
6. Company Mailing Address (street, city, state, zip)
II. Contact Information and Certification1. Facility Contact Name (who will be on-site)
2. Facility Contact Mailing Address (if different than Company Mailing Address)
3. Facility Contact Phone Number 4. Facility Contact Email
5. Billing Contact Name (who should receive billing information)
6. Billing Contact Mailing Address (if different than Company Mailing Address)
7. Billing Contact Phone Number 8. Billing Contact Email
9. Consultant Name (optional – if 3rd party hired to complete application)
10. Consultant Organization/Company
11. Consultant Mailing Address (street, city, state, zip)
12. Consultant Phone Number 13.Consultant Email
14. Responsible Official Name and Title (person responsible for project policy or decision-making)
15. Responsible Official Mailing Address
16. Responsible Official Phone 17. Responsible Official Email
18. Responsible Official Certification and SignatureI certify that the information on this application is accurate and complete.
Signature ____________________________________________________________ Date____________________ January 11, 2021
Notice of Construction Application
ECY 070-410 (Rev. 03/2018) Page 4 of 6
Part 2: Technical Information The Technical Information may be sent with this application to the Ecology Cashiering Unit, or may be sent directly to the appropriate Ecology office along with a copy of this application.
For all sections, check the box next to each item as you complete it.
III. Project DescriptionAttach the following to your application:
Description of your proposed project Projected construction start and completion dates Operating schedule and production rates List of all major process equipment with manufacturer and maximum rated capacity Process flow diagram with all emission points identified Plan view site map Manufacturer specification sheets for major process equipment components Manufacturer specification sheets for pollution control equipment Fuel specifications, including type, consumption (per hour and per year), and percent sulfur
IV. State Environmental Policy Act (SEPA) ComplianceCheck the appropriate box below.
SEPA review is complete. Include a copy of the final SEPA checklist and SEPA determination (e.g., DNS, MDNS, EIS) with your application.
SEPA review has not been conducted.
If SEPA review will be conducted by another agency, list the agency. You must provide a copy of the final SEPA checklist and SEPA determination before Ecology will issue your permit.
Agency Reviewing SEPA:
_________________________________________________________________
If SEPA review will be conducted by Ecology, fill out a SEPA checklist and submit it with your application. You can find a SEPA checklist online at www.ecology.wa.gov/Regulations-Permits/SEPA/Environmental-review/SEPA-document-templates
Notice of Construction Application
ECY 070-410 (Rev. 03/2018) Page 5 of 6
V. Emissions Estimations of Criteria PollutantsDoes your project generate air pollutant emissions? Yes No
If yes, provide the following information about your air pollutant emissions:
Air pollutants emitted, such as carbon monoxide (CO2), lead (Pb), nitrogen dioxide (NO2), ozone (O3), and volatile organic compounds (VOC), particulate matter (PM2.5, PM10, TSP), sulfur dioxide (SO2)
Potential emissions of criteria air pollutants in tons per hour, tons per day, and tons per year (include calculations)
Fugitive air pollutant emissions – pollutant and quantity
VI. Emissions Estimations of Toxic Air PollutantsDoes your project generate toxic air pollutant emissions? Yes No
If yes, provide the following information about your toxic air pollutant emissions:
Toxic air pollutants emitted (specified in WAC 173-460-1501)
Potential emissions of toxic air pollutants in pounds per hour, pounds per day, and pounds per year (include calculations)
Fugitive toxic air pollutant emissions - pollutant and quantity
VII. Emission Standard ComplianceDoes your project comply with all applicable standards identified? Yes No
Provide a list of all applicable new source performance standards, national emission standards for hazardous air pollutants, national emission standards for hazardous air pollutants for source categories, and emission standards adopted under the Washington Clean Air Act, Chapter 70.94 RCW.
VIII. Best Available Control Technology Provide a complete evaluation of Best Available Control Technology (BACT) for your proposal.
1 http://apps.leg.wa.gov/WAC/default.aspx?cite=173-460-150
Notice of Construction Application
ECY 070-410 (Rev. 03/2018) Page 6 of 6
IX. Ambient Air Impacts AnalysesDoes your project cause or contribute to a violation of any ambient air quality standard or acceptable source impact level? Yes No
Provide the following:
Ambient air impacts analyses for criteria air pollutants (including fugitive emissions)
Ambient air impacts analyses for toxic air pollutants (including fugitive emissions)
Discharge point data for each point included in ambient air impacts analyses (include only if modeling is required)
Exhaust height Exhaust inside dimensions (diameter or length and width) Exhaust gas velocity or volumetric flow rate Exhaust gas exit temperature Volumetric flow rate Discharge description (i.e., vertically or horizontally) and if there are any obstructions (e.g., raincap)
Emission unit(s) discharging from the point Distance from the stack to the nearest property line Emission unit building height, width, and length Height of tallest building on-site or in the vicinity, and the nearest distance of that building to the exhaust
Facility location (urban or rural)
US Electrodynamics, Inc. December 29, 2020
NOC Application – 2021 Generator Installation x3 Attachment 1
Attachment 1
Project Description
US Electrodynamics, Inc.
Project Description
Background:
US Electrodynamics, Inc. (USEI) provides government and commercial satellite teleport services
including TT&C (tracking, telemetry, and command), broadcast video, aviating, and internet
services delivery. USEI is headquartered and operates a teleport facility at 66C Teleport Drive in
Brewster, Washington. The facility has emergency power supply via six diesel-fired emergency
generators which are permitted under Washington State Department of Ecology’s Central Region
Office (Ecology – CRO) Notice of Construction No. 09AQ-C085, 2nd revision. USEI intends to
add three additional 1.5-MW diesel-fired emergency generators to support work the local Public
Utility District is doing to add an additional sub station and feed the facility.
Project Description:
USEI intends to install three 1.5-MW Cummins 1500DQGAB diesel-fired emergency
generators. Only two of the three generators will ever operate simultaneously. Two 20,000-
gallon diesel storage tanks will be installed along with the three emergency generators. See
Attachment 1-3 for a facility map with the location of the three generators and the two 20,000-
gallon diesel storage tanks highlighted in yellow.
Emission Sources:
The three Cummins generators will be powered with diesel fuel with a maximum sulfur content
of 15 ppm. Criteria pollutants potential to emit (PTE) were calculated using manufacturer data
(see Attachment 4). Particulate emissions include both the manufacturer’s particulate emission
factor and hydrocarbon emission factor. Diesel engine particulate (DEEP) is considered a toxic
air pollutant (TAP) in the state of Washington, and is calculated based on the manufacturer’s
PM2.5 emission factor, excluding hydrocarbons. Nitrogen dioxide (NO2) is also considered a
TAP, and is calculated based on the manufacturer nitrous oxide (NOX) emission factor. Other
TAP emissions were calculated using emission factors from AP-42 Chapter 3.4.
The generators will operate between 40% and 90% load during both testing and emergency
scenarios. To be conservative, manufactures data at 25% and 100% load were used for the
emission inventory and modeling. Values in between were not evaluated since the two extremes
account for the worst-case emissions. To be conservative, the highest load value for each
pollutant will be used for the PTE calculations. Emissions were calculated and modeled based on
73 hours of operation per generator per year for an aggregate of 219 hours per year between the
three generators. The calculations and modeling assume two generators operating for short-term
averaging and aggregate for long-term averaging. Standby performance data was used in the
emissions calculations rather than prime data since emergency generators fit the standby
designation.
Federal Rule Applicability:
• USEI is an area source of hazardous air pollutants (HAPs) and non-major source
of criteria pollutants. The facility is unchanged based on this project.
• New Source Performance Standard (40 CFR 60) Subpart IIII is applicable to this
project.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 1-1
• National Emission Standards for Hazardous Air Pollutants (40 CFR 63) Subpart
ZZZZ is applicable to this project.
Project Timeline:
• The gensets are tentatively scheduled for delivery March 1, 2021.
• Commissioning the units is tentatively scheduled for April 1-15, 2021.
Operations Schedule:
The generators will operate for an aggregate maximum of 219 hours per year (approximately 73
hours per unit. Fuel consumption at 100% load is defined by the manufacturer at 108 gallons of
diesel per hour per generator.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 1-2
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US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 23, 2020 Attachment 1-3
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 1-3
US Electrodynamics, Inc. December 29, 2020
NOC Application – 2021 Generator Installation x3 Attachment 2
Attachment 2
Manufacturer Specifications
power.cummins.com ©2019 Cummins Inc. | PDS-1512 (11/19)
Specification Sheet
Diesel Generator Set QSK50 Series Engine
1100 kW – 1500 kW 60 Hz
Description
Cummins® commercial generator sets are fully integrated power generation systems providing optimum performance, reliability and versatility for stationary standby and prime power applications. Codes or standards compliance may not be available with all model configurations – consult factory for availability.
Control System - Standard PowerCommand® electronic control provides total system integration including automatic remote starting/stopping, precise frequency and voltage regulation, alarm and status message display, AmpSentry™ protection, output metering, auto-shutdown at fault detection and NFPA 110 Level 1 compliance.
Cooling System - Standard integral set- mounted radiator system, designed and tested for rated ambient temperatures, simplifies facility design requirements for rejected heat.
NFPA - The genset accepts full rated load in a single step in accordance with NFPA 110 for Level 1 systems.
Warranty and Service - Backed by a comprehensive warranty and worldwide distributor network.
Features
Cummins Heavy-Duty Engine - Rugged 4-cycle, industrial diesel delivers reliable power, low emissions and fast response to load changes.
Alternator - Several alternator sizes offer selectable motor starting capability with low reactance 2/3 pitch windings; low waveform distortion with non-linear loads, fault clearing short-circuits capability.
Permanent Magnet Generator (PMG) - Offers enhanced motor starting and fault clearing short-circuit.
Standby Rating Prime Rating Continuous Rating Data Sheets
Model 60 Hz kW (kVA)
50 Hz kW (kVA)
60 Hz kW (kVA)
50 Hz kW (kVA)
60 Hz kW (kVA)
50 Hz kW (kVA) 60 Hz 50 Hz
DQGAA 1250 (1563)
1100 (1375)
D-3333
DQGAB 1500 (1875)
1350 (1688)
D-3334
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-1
power.cummins.com ©2019 Cummins Inc. | PDS-1512 (11/19)
Generator Set Specifications
Governor regulation class ISO8528 Part 1 Class G3
Voltage regulation, no load to full load ± 0.5%
Random voltage variation ± 0.5%
Frequency regulation Isochronous
Random frequency variation ± 0.25%
Radio frequency emissions compliance IEC 801.2 through IEC 801.5; MIL STD 461C, Part 9
Engine Specifications
Bore 158.8 mm (6.25 in.)
Stroke 158.8 mm (6.25 in.)
Displacement 50.3 Liters (3067 in3)
Configuration Cast iron, V 16 cylinder
Battery capacity 1800 amps minimum at ambient temperature of 0 �C (32 �F)
Battery charging alternator 35 amps
Starting voltage 24 volt, negative ground
Fuel system Cummins’ Modular Common Rail System
Fuel filter Dual Element 10 micron filtration spin-on fuel filter with 15 micron water separator
Air cleaner type Dry replaceable element
Lube oil filter type(s) Four spin-on, combination full flow filter and bypass filters
Standard cooling system High ambient radiator
Alternator Specifications
Design Brushless, 4 pole, drip-proof revolving field
Stator 2/3 pitch
Rotor Single bearing, flexible disc
Insulation system Class H
Standard temperature rise 150 °C standby at 40 °C ambient
Exciter type PMG (Permanent Magnet Generator)
Phase rotation A (U), B (V), C (W)
Alternator cooling Direct drive centrifugal blower fan
AC waveform Total Harmonic Distortion (THDV) < 5% no load to full linear load, < 3% for any single harmonic
Telephone Influence Factor (TIF) < 50 per NEMA MG1-22.43
Telephone Harmonic Factor (THF) < 3
Available Voltages
60 Hz Line–Neutral/Line-Line 50 Hz Line-Neutral/Line-Line
220/380 255/440
277/480 347/600
2400/4160
*Note: Consult factory for other voltages.
Generator Set Options Engine
208/240/480 V thermostatically controlled coolant heater for ambient above 4.5 °C (40 °F)
208/240/480 V thermostatically controlled coolant heater for ambient below 4.5 °C (40 °F)
Dual 120 V 300 W lube oil heaters Dual 208/240 V 300 W lube oil
heaters Dual 480 V 300 W lube oil heaters
Control Panel
120/240 V 100 W control anti-condensation heater
Paralleling configuration Remote fault signal package Run relay package Exhaust pyrometer Fuel pressure indication Ground fault indication
Alternator
80 °C rise 105 °C rise 125 °C rise 120/240 V 300 W anti-
condensation heater
Exhaust System
Industrial grade exhaust silencer
Residential grade exhaust silencer
Critical grade exhaust silencer
Exhaust packages
Cooling System
Remote indicator
Generator Set
AC entrance box Battery Battery charger Circuit breaker – set mounted Disconnect switch - set
mounted PowerCommand Network Remote annunciator panel Spring isolations 2 year warranty 5 year warranty 10 year major components
warranty
*Note: Some options may not be available on all models - consult factory for availability.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-2
power.cummins.com ©2019 Cummins Inc. | PDS-1512 (11/19)
Control System PCC 3201
The PowerCommand Control is an integrated generator set control system providing governing, voltage regulation, engine protection and operator interface functions. Major features include:
• Integral AmpSentry Protective Relay providing a full range of alternator protection functions that are matched to the alternator provided.
• Battery monitoring and testing features and smart starting control system.
• Three phase sensing, full wave rectified voltage regulation system, with a PWM output for stable operation with all load types.
• Control suitable for operation in ambient temperatures from -40 °C to +70 °C (-40 °F to +158 °F) and altitudes to 5000 meters (13,000 feet).
• Prototype tested; UL, CSA, and CE compliant.
• InPower™ PC-based service tool available for detailed diagnostics.
• Optional Echelon® LONWORKS® network interface.
Operator/Display Panel
• Off/manual/auto mode switch
• Manual run/stop switch
• Panel lamp test switch
• Emergency stop switch
• Exercise switch
• Alpha-numeric display with pushbutton access for viewing engine and alternator data and providing setup, controls and adjustments
• LED lamps indicating not in auto, common warning, common shutdown, remote start
• Configurable for local language
Engine Protection
• Overspeed shut down
• Low oil pressure warning and shut down
• High coolant temperature warning and shut down
• High oil temperature warning
• Low coolant level warning or shut down
• Low coolant temperature warning
• High and low battery voltage warning
• Weak battery warning
• Dead battery shut down
• Fail to start (overcrank) shut down
• Fail to crank shut down
• Redundant start disconnect
• Cranking lockout
• Sensor failure indication
Engine Data
• DC voltage
• Lube oil pressure
• Coolant temperature
• Lube oil temperature
• Engine speed
• Engine ECM data
AmpSentry AC Protection
• Over current and short-circuit shut down
• Over current warning
• Single and three phase fault regulation
• Over and under voltage shut down
• Over and under frequency shut down
• Overload warning with alarm contact
• Reverse power and reverse Var shut down
Alternator Data
• Line-to-Line and Line-to-Neutral AC volts
• Three phase AC current
• Frequency
• Total and individual phase power factor, kW and kVA
• Bus voltage and frequency (with paralleling options)
Other Data
• Genset model data
• Start attempts, starts, running hours
• kW hours (total and since reset)
• Fault history
• Load profile (accessible with InPower)
Governing
• Digital electronic isochronous governor
• Temperature dynamic governing
• Smart idle speed mode
Voltage Regulation
• Digital PWM electronic voltage regulation
• Three phase Line-to-Neutral sensing
• Single and three phase fault regulation Configurable torque matching
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-3
power.cummins.com ©2019 Cummins Inc. | PDS-1512 (11/19)
Control Functions
• Data logging on faults
• Fault simulation (requires InPower)
• Time delay start and cooldown
• Cycle cranking
• Configurable customer outputs (4)
• Configurable network inputs (8) and outputs (16) (with optional network)
• Remote emergency stop
Paralleling (Option)
• Active digital phase lock loop synchronizer
• Isochronous kW and kVar load sharing controls kW import/export and kVar/PF control for utility (mains) paralleling
Options
• Thermostatically controlled space heater
• Key-type mode switch
• Ground fault module
• Auxiliary relays (3)
• Echelon LONWORKS interface
• Modion Gateway to convert to Modbus (loose)
• PowerCommand iWatch web server for remote monitoring and alarm notification (loose)
• Digital input and output module(s) (loose)
• Remote annunciator (loose)
• Paralleling
• Power transfer control
For further detail see document S-1444.
Ratings Definitions Emergency Standby Power (ESP): Applicable for supplying power to varying electrical load for the duration of power interruption of a reliable utility source. Emergency Standby Power (ESP) is in accordance with ISO 8528. Fuel Stop power in accordance with ISO 3046, AS 2789, DIN 6271 and BS 5514.
Limited-Time Running Power (LTP): Applicable For Supplying power to a constant electrical load for limited hours. Limited-Time Running Power (LTP) is in accordance with ISO 8528.
Prime Power (PRP): Applicable for supplying power to varying electrical load for unlimited hours. Prime Power (PRP) is in accordance with ISO 8528. Ten percent overload capability is available in accordance with ISO 3046, AS 2789, DIN 6271 and BS 5514.
Base Load (Continuous) Power (COP): Applicable for supplying power continuously to a constant electrical load for unlimited hours. Continuous Power (COP) in accordance with ISO 8528, ISO 3046, AS 2789, DIN 6271 and BS 5514.
This outline drawing is for reference only. See respective model data sheet for specific model outline drawing number.
Do not use for installation design
Model Dim ‘A’ (mm) (in.)
Dim ‘B’ (mm) (in.)
Dim ‘C’ (mm) (in.)
Set Weight dry* kg (lbs)
Set Weight* wet kg (lbs)
DQGAA 5969 (235) 2007 (79) 2840 (112) 10989 (24220) 11493 (25330)
DQGAB 5969 (235) 2007 79) 2840 (112) 10989 (24220) 11493 (25330)
* Note: Weights represent a set with standard features. See outline drawings for weights of other configurations.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-4
For more information contact your local Cummins distributor or visit power.cummins.com
©2019 Cummins Inc. All rights reserved. Cummins is a registered trademark of Cummins Inc. PowerCommand, AmpSentry, InPower and “Our energy working for you.” are trademarks of Cummins Inc. Other company, product, or service names may be trademarks or service marks of others. Specifications are subject to change without notice. PDS-1512 (11/19)
Codes and Standards
This generator set is designed in facilities certified to ISO 9001 and manufactured in facilities certified to ISO 9001 or ISO 9002.
The generator set is available listed to UL 2200, Stationary Engine Generator Assemblies for all 60 Hz low voltage models. The PowerCommand control is Listed to UL 508 – Category NITW7 for U.S and Canadian usage. Circuit breaker assemblies are UL 489 Listed for 100% continuous operation and also UL 869A Listed Service Equipment.
The Prototype Test Support (PTS) program verifies the performance integrity of the generator set design. Cummins products bearing the PTS symbol meet the prototype test requirements of NFPA 110 for Level 1 systems.
U.S EPA Engine certified to Stationary Emergency U.S. EPA New Source Performance Standards, 40 CFR 60 subpart IIII Tier 2 exhaust emission levels. U.S. applications must be applied per this EPA regulation.
All low voltage models are CSA certified to product class 4215-01.
International Building Code
The generator set package set is available certified for seismic application in accordance with the following International Building Code: IBC2000, IBC2003, IBC2006 and IBC2009.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-5
Generator set data sheet
Model: Frequency: Fuel type: KW rating: Emissions level:
DQGAB 60 Hz Diesel 1500 standby 1350 prime EPA NSPS Stationary Emergency Tier 2
Exhaust emission data sheet: EDS-1059
Exhaust emission compliance sheet: EPA-1093
Sound performance data sheet: MSP-1034
Cooling performance data sheet: MCP-152
Prototype test summary data sheet: PTS-265
Standard set-mounted radiator cooling outline: 0500-4357
Optional remote radiator cooling outline: 0500-4309
Fuel consumption Standby Prime
kW (kVA) kW (kVA) Ratings 1500 (1875) 1350 (1688) Load 1/4 1/2 3/4 Full 1/4 1/2 3/4 Full US gph 35.4 58.2 81 103.8 33.1 53.6 74.2 94.7 L/hr 133.9 220.3 306.6 393 125.3 203 208.7 358.4
Engine Standby rating
Prime rating
Engine manufacturer Cummins Inc. Engine model QSK50-G4 NR2 Configuration Cast iron, V 16 cylinder Aspiration Turbocharged and low temperature aftercooled Gross engine power output, kWm (bhp) 1656 (2220) 1470 (1971) BMEP at set rated load, kPa (psi) 2192 (318) 1957 (284) Bore, mm (in) 159 (6.25) Stroke, mm (in) 159 (6.25) Rated speed, rpm 1800 Piston speed, m/s (ft/min) 9.5 (1875) Compression ratio 15:1 Lube oil capacity, L (qt) 235 (248) Overspeed limit, rpm 2100 ±50 Regenerative power, kW 168
Maximum fuel flow, L/hr (US gph) 912 (241) Maximum fuel inlet restriction, kPa (in Hg) 16.9 (5) Maximum fuel inlet temperature, °C (°F) 71 (160)
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-6
Air Standby rating
Prime rating
Combustion air, m3/min (scfm) 139 (4895) 133 (4700) Maximum air cleaner restriction, kPa (in H2O) 3.7 (15) Alternator cooling air, m3/min (cfm) 207 (7300)
Exhaust
Exhaust flow at set rated load, m3/min (cfm) 342 (12065) 312 (11000) Exhaust temperature, °C (°F) 491 (915) 446 (835) Maximum back pressure, kPa (in H2O) 6.78 (27)
Standard set-mounted radiator cooling Ambient design, °C ( °F) 40 (104) Fan load, kWm (HP) 45 (60) Coolant capacity (with radiator), L (US gal) 541 (143) Cooling system air flow, m3/min (scfm) 1705 (60150) Total heat rejection, MJ/min (Btu/min) 72.3 (68580) 64.8 (61510) Maximum cooling air flow static restriction, kPa (in H2O) 0.12 (0.5) Maximum fuel return line restriction kPa (in Hg) 34 (10)
Optional remote radiator cooling1
Set coolant capacity, L (US gal) Max flow rate at max friction head, jacket water circuit, L/min (US gal/min)
1893 (500)
Max flow rate at max friction head, aftercooler circuit, L/min (US gal/min)
537 (142)
Heat rejected, jacket water circuit, MJ/min (Btu/min) 35.44 (33610) 32.11 (30455) Heat rejected, aftercooler circuit, MJ/min (Btu/min) 26.93 (25545) 23.96 (22725) Heat rejected, fuel circuit, MJ/min (Btu/min) Total heat radiated to room, MJ/min (Btu/min) 13.1 (12420) 11.9 (11275) Maximum friction head, jacket water circuit, kPa (psi) 67 (10) Maximum friction head, aftercooler circuit, kPa (psi) 48 (7) Maximum static head, jacket water circuit, m (ft) 18.3 (60) Maximum static head, aftercooler circuit, m (ft) 18.3 (60) Maximum jacket water outlet temp, °C (°F) 104 (220) 100 (212) Maximum aftercooler inlet temp at 25 °C (77 °F) ambient, °C (°F) 49 (120) Maximum aftercooler inlet temp, °C (°F) 71 (160) 66 (150) Maximum fuel flow, L/hr (US gph) 469 (124) Maximum fuel return line restriction, kPa (in Hg) 34 (10)
Weights2
Unit dry weight kgs (lbs) 12700 (28000) Unit wet weight kgs (lbs) 13270 (29260)
Notes: 1 For non-standard remote installations contact your local Cummins Power Generation representative. 2 Weights represent a set with standard features. See outline drawing for weights of other configurations.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-7
Derating factors
Standby
Full rated power available up to 1134.0m (3719.6 ft) elevation at ambient temperatures up to 40 °C (104 °F). Full rated power available up to 702.5m (2304.2 ft) elevation at ambient temperatures up to 50 °C (120 °F). Above these conditions derate by 6.6% per 305m (1000 ft) and derate by an additional 10.3% per 10 °C (18 °F).
Prime Full rated power available up to 1334.9m (4378.6 ft) elevation at ambient temperatures up to 40 °C (104 °F). Above these conditions derate by 5.8% per 305m (1000 ft) and derate by an additional 14.0% per 10 °C (18 °F).
Ratings definitions
Emergency standby power (ESP):
Limited-time running power (LTP):
Prime power (PRP):
Base load (continuous) power (COP):
Applicable for supplying power to varying electrical load for the duration of power interruption of a reliable utility source. Emergency Standby Power (ESP) is in accordance with ISO 8528. Fuel Stop power in accordance with ISO 3046, AS 2789, DIN 6271 and BS 5514.
Applicable for supplying power to a constant electrical load for limited hours. Limited Time Running Power (LTP) is in accordance with ISO 8528.
Applicable for supplying power to varying electrical load for unlimited hours. Prime Power (PRP) is in accordance with ISO 8528. Ten percent overload capability is available in accordance with ISO 3046, AS 2789, DIN 6271 and BS 5514.
Applicable for supplying power continuously to a constant electrical load for unlimited hours. Continuous Power (COP) is in accordance with ISO 8528, ISO 3046, AS 2789, DIN 6271 and BS 5514.
Alternator data
Voltage Connection1 Temp rise degrees C Duty2
Single phase factor3
Max surge kVA4
Winding No.
Alternator data sheet
Feature Code
380 Wye, 3-phase 125 P 5743 ADS-332 B596-2 380 Wye, 3-phase 150/105 S/P 6716 ADS-333 B595-2 380 Wye, 3-phase 80 P 6716 ADS-333 B687-2 380 Wye, 3-phase 105/80 S/P 7361 ADS-334 B599-2 380 Wye, 3-phase 80 S 7695 ADS-335 B660-2 440 Wye, 3-phase 125 P 4602 ADS-330 B692-2 440 Wye, 3-phase 150/125 S/P 5521
ADS-331 B691-2
440 Wye, 3-phase 125/105 S/P 5743 ADS-332 B663-2 440 Wye, 3-phase 80 S 6716 ADS-333 B688-2 440 Wye, 3-phase 80 P 7695 ADS-331 B689-2 480 Wye, 3-phase 105 P 4602 ADS-330 B693-2 480 Wye, 3-phase 125/105 S/P 5521 ADS-331 B276-2 480 Wye, 3-phase 80 P 5521 ADS-331 B694-2 480 Wye, 3-phase 105/80 S/P 5743 ADS-332 B600-2 480 Wye, 3-phase 80 S 6716 ADS-333 B601-2 600 Wye, 3-phase 105 P 4602 ADS-330 B581-2 600 Wye, 3-phase 125/105 S/P 5521 ADS-331 B602-2 600 Wye, 3-phase 80 P 5521 ADS-331 B695-2 600 Wye, 3-phase 105/80 S/P 5743 ADS-332 B603-2 600 Wye, 3-phase 80 S 6716 ADS-333 B604-2 4160 Wye, 3-phase 105 P 6204 ADS-322 B312-2 4160 Wye, 3-phase 105/80 S/P 7005 ADS-323 B313-2
Notes: 1 Limited single phase capability is available from some three phase rated configurations. To obtain single phase rating, multipy the three phase kW rating by the Single Phase Factor3. All single phase ratings are at unity power factor.
2 Standby (S), Prime (P) and Continuous ratings (C). 3 Factor for the Single Phase Output from Three Phase Alternator formula listed below. 4 Maximum rated starting kVA that results in a minimum of 90% of rated sustained voltage during starting.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-8
Formulas for calculating full load currents: Three phase output Single phase output
Warning: Back feed to a utility system can cause electrocution and/or property damage. Do not connect to any building’s electrical system except through an approved device or after building main switch is open.
Voltage1000 x eFactorSinglePhas x kW
0.8 x 1.73 x Voltage
1000 x kW
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-9
REQUEST
DATE:
Renton WA GENERATOR:
Jeff Delauney JOB NAME:
REAR MOUNT GENSET CONTROL REQUIRED
Qty: Description: Part #: Vendor:
Weather Protective Enclosure, UL2200 FTPP-E336241
1 Genset Enclosure - Level III, 75dB(A) at 25'; 8 Point Average 4085026-L3 CRM-Shop
(When Tested In A Free Field Environment, +/- 3dB)
UL2200 Listed & Labeled 135H x 100W x 456" OAL; PLUS TANK HGHT14 Gauge Steel Construction
Four Point Lifting System For Enclosure OnlyAll Doors Keyed Alike, Flush Mnt SS D-Ring Handles Allegis
Roton Continous Geared Closed Leaf Aluminum Hinges Roton
Two Sets of Double 72" Doors Per Side
One Single 24" Door Duct Service Access Cleanout
Motorized Inlet Louver, Belimo Motors GMD Spec ACP
Fixed Air Inlets Exterior Accupac BrentwoodGravity Radiator Discharge Louver Dayton Grainger
Vertical Air Discharge Duct With Screen (Radiator)
Interior Mounted Exhaust Silencer
Paint Color: Cummins Beige or TBD Crane/Truck to & From Paint>
Exhaust System KIT-90038720
1 Hospital Grade - Cool Series - Exhaust Silencer 14" K-H2-6-4085024 InExhaust
Compressed Thermal/Acoustical Fiberglass Packed- 200408R3 Freight In>>
Shell With 2" Compressed Internal Packing 722H3-14-08-T-FM-12195
Corrugated Flex Connectors and Rain Cap
Nut, Bolt and Gasket Hardware
ADD 10' OUTLET EXTENSION with Guide Wires
Vibration Isolators
12 Ace Mounting Spring Isolator, Zone 3 632-H Ace Mntg
Freight In>>
Engine Starting System
1 Set Battery Boxes 0416-1263
M3-22-1210-D Add Angle Battery Holder to Top of Genset Frame
Genset Enclosure Electrical
1 125A 120-240 1ph QO124M125PRB LDCNTR Nema 3R; MCB 24 space
NEMA 3R Enclosure, With 125A Main Breaker
1 PK15GTA LDCNTR GND BAR KIT PK15GTA
1 Circuit Breaker-15 Amp, 1P QO115 Border States
1 Circuit Breaker-20 Amp, 1P QO120 Border States
2 Circuit Breaker-30 Amp, 2P QO230 Border States
5 SAT - 20WA21/LED/HID/50K/120-277VE26 S8738 SAT p/n 340000 ITIAL LUMEN OUTPUT = 2910Border States5 AC Lighting Package- vapor tight fixture, Stonco VCXL21GC Border States
5 AC Lighting Package- LED Lights, A19 11W Gela 3243766 Border States
3 GFI Receptacles, HUB-GFTWRST201 20A GFTWRST20I Border States
2 Emergency Lighting with Two LED Lamp Heads ELM2-LED Border States
INSTALL ELECTRICAL Armendariz
2 5kW 208/240VAC, kW 5.0/2.5; 1 PH Space Heater w/ Internal T Stat, Mounted To Ceiling3UG73 Grainger
TO:
BRANCH:
CONTACT: USEI Brewster WA
1500DQGAB
Fuel Tank & Enclosure Spec Sheet5/21/2020
QUOTE NO:
DWG LINK:
QUOTED BY: JLJ
Q2020-0047
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-10
Genset Sub-Base Fuel Tank
1 UL2085, Concrete Lined Double Wall Sub-Base Fuel Tank SST07538 CRM/ SST
2625G Useable Capacity, 3080G Maximum Capacity SBGVT-3080 Freight In>>
24 Hour Useable Full Load Capacity 109.4GPH
384"L x 100"W x 48"T, 33,700# Dry Weight12) Ace Mounting Spring Isolator, Zone 3; 632-H
Engine Supply & Return Connections Tank Fitings Shop Supplies
Integral Welded 5G Fuel Fill Spill Containment
Stub-Up Zone
Pads for ACE Mountings Vibration Isolators
1 2" Normal Vent-Fuel Cell - C&B (Extend 12" Above Grade) 401-01-2000 BR55 Tech
1 2" Normal Vent-Containment Basin - C&B 401-01-2000 SST
1 6" Emergency Vent-Fuel Cell - OPW 201M-6081 SST
1 6" Emergency Vent-Containment Basin - OPW 201M-6081 SST
Extend Normal Cell Vent Per NFPA
1 Mechanical Fuel Level Gauge - Krueger KRG SST
1 Low Level Float Switch - 50% Fuel Level - Madison M4500 SST
1 High Level Float Switch - 90% Fuel Level - Madison M4500 Br55 INV tall per dwg 9000022
1 High Level Float Switch - 95% Fuel Level - Madison M4500 Br55 INV tall per dwg 9000022
1 Basin Leak Detection Float Switch - Madison M4500 SST
1 High Fuel Level Alarm Kit - Audible HLA2 Br55 INV per dwg 9000022
Set High Fuel Level Float Switch @ 90%
1 2" Solenoid Valve, 24VDC - Fuel Shut Off - Normally Open 2W500-2-2-D-V Br55 INV SNA Tech to Install
1 Aluminum Dust Cap, Coupling Type DC, Female Coupler 3LX34 Grainger
1 Aluminum Adapter, Coupling Type F, Male Adapter x MNPT Connection Type3LX40 Grainger
1 Static Discharge Tube; Fuel Fill Dip Tube SST
1 Inlet Spout 633AST-2061 SST
1 Exterior Color - Black Paint Paint
1 4-20mA Level Sensor C-Series; ‘To be sized by AE’ Madison
Enclosure Stair/Platforms REF ONLY
1 Set Aluminum Stairs and Platforms w/ Handrails; 50" Tall GO-19548
(2) Platforms, (1) On Each Side of Enclosure, In Front of All Doors
Pad MUST BE FLAT and Level Per Submittal Drawing to Install Freestanding Platforms
OSHA Compliant
Exterior Access Fuel Fill Package
1 Exterior Fuel Fill Access Box 9000031 CRM-Shop
Recessed Wall Mount, 5G Spill Container W/ Locking Door *INCLUDES PIPING
Standard Upfit:
Includes General upfit of genset, enclosure, exhaust sys., & Fuel Tank. Shop Supplies
Pre-Wiring of battery warming pads and Battery Charger (If Supplied).
Fuel system plumbing & hoses. Batteries & Warming pad installation.
Quality Control Inspection
COMMENTS & EXCEPTIONS:
Freight to Site Not Included. *TWO TO THREE TRUCKS- CANNOT SHIP STACKED
*PLEASE REVIEW FOR ACCURACY OR AMENDMENTS
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-11
Sound Data
1500DQGAB 60Hz
Sound Pressure Level @ 7 meters, dB(A) See Notes 1-8 listed below
Configuration Measurement Location Number Average 1 2 3 4 5 6 7 8
Standard - Unhoused Infinite Exhaust 100.4 96.8 95.3 96.6 93.4 96.3 94.2 99.0 97.1
Sound Power Level, dB(A) See Notes 2-6, 9, 10 listed below
Configuration Octave Band Center Frequency (Hz) Overall Sound Power Level 63 125 250 500 1000 2000 4000 8000
Standard - Unhoused Infinite Exhaust 82.5 101.1 119.3 119.5 117.5 114.9 109.7 108.0 124.5
Exhaust Sound Power Level, dB(A) Open Exhaust
(No Muffler Rated Load)
Octave Band Center Frequency (Hz) Sound Power Level 63 125 250 500 1000 2000 4000 8000
94.6 118.5 123.4 128.1 126.6 128.6 126.9 125.7 135.1
Note: 1. Position 1 faces the engine front. The positions proceed around the generator set in a counter-clockwise direction in 45° increments. All
positions are at 7m (23 ft) from the surface of the generator set and 1.2m (48”) from floor level.2. Sound levels are subject to instrumentation, measurement, installation and manufacturing variability.3. Sound data with remote-cooled generator sets are based on rated loads without cooling fan noise.4. Sound levels for aluminum enclosures are approximately 2 dB(A)s higher than listed sound levels for steel enclosures.5. Sound data for generator set with infinite exhaust do not include exhaust noise.6. Data is based on full rated load with standard radiator-cooling fan package7. Sound Pressure Levels are measured per ANSI S1.13 and ANSI S12.18, as applicable.8. Reference sound pressure is 20 µPa.9. Sound Power Levels per ISO 3744 and ISO 8528-10, as applicable.
10. Reference power = 1 pw (10-12 W) 11. Exhaust Sound Pressure Levels are per ISO 6798, as applicable.
Cummins Power Generation Data and Specification Subject to Change Without Notice Bulletin msp-1034c
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-12
PROTOTYPE TEST SUPPORT (PTS)
60 HZ TEST SUMMARYGENERATOR SET MODELS REPRESENTATIVE PROTOTYPE1250DQGAA Model:1500DQGAB1500DQGAB Alternator: P734C
Engine: QSK50-G4 NR2
The following summarizes prototype testing conducted on the designated representative prototype of the specified models. This testing is conducted to verify the complete generator set electrical and mechanical design integrity. Prototype testing is conducted only on generator sets not sold as new equipment.
Maximum Surge Power: 1580 kW Steady State Performance:
The generator set was evaluated to determine the statedmaximum surge power.
The generator set was tested to verify steady state operating performance was within the specified maximum limits.
Voltage Regulation: ±0.50% Random Voltage Variation: ±0.50%
Frequency Regulation: Isochronous
Random Frequency Variation: ±0.25%
Transient Performance: Torsional Analysis and Testing:
The generator set was tested to verify that the design is not subjected to harmful torsional stresses. A spectrum analysis of the transducer output was conducted over the
speed range of 1200 to 2000 RPM.
The generator set was tested with the standard alternator to verify single step loading capability as required by NFPA 110. Voltage and frequency response on load addition or rejection were evaluated. The following results were recorded:
Cooling System: 40 °C Ambient Full Load Acceptance:0.5 in. H2O restriction Voltage Dip: 40.4 %
Recovery Time: 4.2 Second
Frequency Dip: 7.5 %
Recovery Time: 5.6 Second
The cooling system was tested to determine ambient temperature and static restriction capabilities. The test was performed at full rated load in elevated ambient temperature under stated static restriction conditions. Full Load Rejection: Voltage Rise: 26.4 %
Recovery Time: 2.8 Second Frequency Rise: 3.5 %
Recovery Time: 1.3 Second
Harmonic Analysis:
(per MIL-STD-705B, Method 601.4) Line to Line Line to NeutralElectrical and Mechanical Strength: Harmonic No Load Full Load No Load Full Load
3 0.18 0.01 0.13 0.085 0.2 2.3 0.13 2.37 0.52 1.46 0.48 0.749 0.08 0.03 0.03 0.0711 0.65 0.49 0.64 0.4613 0.21 0.28 0.19 0.31
The generator set was tested to several single phase and three phase faults to verify that the generator can safely withstand the forces associated with short circuit conditions. The generator set was capable of producing full rated output at the conclusion of the testing.
15 0.05 0.05 0.03 0.1
Cummins Power Generation Specification May Change Without Notice pts-265a
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-13
Cooling System Data
DQGAB
High Ambient Air Temperature Radiator Cooling System
Max Cooling @ Air Flow Static Restriction, Unhoused
(inches water/mm water)
Housed in Free Air, No Air Discharge Restriction
0.0/0.0 0.25/6.4 0.5/12.7 0.75/19.1 1.0/25.4 Duty Rating
(kW) Maximum Allowable Ambient Temperature, Degree C
Standby 1500 45.7 44.4 43.2 39.4 37.8 N/A N/A N/A N/A 60 Hz Prime 1350 46.1 44.7 43.4 41.1 39.7 N/A N/A N/A N/A Continuous N/A N/A N/A N/A N/A N/A N/A N/A N/A Standby N/A N/A N/A N/A N/A N/A N/A N/A N/A 50 Hz Prime N/A N/A N/A N/A N/A N/A N/A N/A N/A Continuous N/A N/A N/A N/A N/A N/A N/A N/A N/A
Enhanced High Ambient Air Temperature Radiator Cooling System
Max Cooling @ Air Flow Static Restriction, Unhoused (inches water/mm water)
Housed in Free Air, No Air Discharge Restriction
0.0/0.0 0.25/6.4 0.5/12.7 0.75/19.1 1.0/25.4 Duty Rating
(kW) Maximum Allowable Ambient Temperature, Degree C
Standby 1500 N/A N/A N/A N/A N/A N/A N/A N/A N/A 60 Hz Prime 1350 N/A N/A N/A N/A N/A N/A N/A N/A N/A Continuous N/A N/A N/A N/A N/A N/A N/A N/A N/A Standby N/A N/A N/A N/A N/A N/A N/A N/A N/A 50 Hz Prime N/A N/A N/A N/A N/A N/A N/A N/A N/A Continuous N/A N/A N/A N/A N/A N/A N/A N/A N/A Notes: 1. Data shown are anticipated cooling performance for typical generator set.
2. Cooling data is based on 1000 ft (305 m) site test location.
3. Generator set power output may need to be reduced at high ambient conditions. Consult generator set data sheet for derate schedules.
4. Cooling performance may be reduced due to several factors including but not limited to: Incorrect installation, improper operation, fouling of the cooling system, and other site installation variables.
Cummins Power Generation Specification May Change Without Notice Bulletin mcp-152b
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-14
Exhaust emission data sheet 1500DQGAB
60 Hz Diesel generator set
Cummins Inc. Data and specification subject to change without notice EDS-1059 (08/17)
Engine information:
Model: Cummins Inc. QSK50-G4 NR2 Bore: 6.25 in. (159 mm)
Type: 4 cycle, 60 °V, 16 cylinder diesel Stroke: 6.25 in. (159 mm)
Aspiration: Turbocharged and low temperature after-cooled
Displacement: 3067 cu. in. (50.2 liters)
Compression ratio: 15.0:1
Emission control device: Turbocharged and low temperature after-cooled
1/4 1/2 3/4 Full Full
Performance data Standby Standby Standby Standby Prime
BHP @ 1800 RPM (60 Hz) 555 1110 1665 2220 1971
Fuel consumption (gal/hr) 33 57 82 108 96
Exhaust gas flow (CFM) 4755 7557 9751 11783 10838
Exhaust gas temperature (°F) 659 709 745 880 811
Exhaust emission data
HC (Total unburned hydrocarbons) 0.32 0.19 0.11 0.07 0.08
NOx (Oxides of nitrogen as NO2) 3.5 3.93 4.38 5.38 5.1
CO (Carbon monoxide) 0.95 0.51 0.32 0.58 0.45
PM (Particular matter) 0.22 0.08 0.03 0.02 0.02
SO2 (Sulfur dioxide) 0.01 0.01 0.01 0.01 0.01
Smoke (Bosch) 0.63 0.33 0.14 0.12 0.12
All values are Grams per HP-Hour, Smoke is Bosch#
Test conditions
Data was recorded during steady-state rated engine speed (± 25 RPM) with full load (±2%). Pressures, temperatures, and emission rates were stabilized.
Fuel specification: ASTM D975 No. 2-D diesel fuel with ULSD, and 40-48 cetane number.
Fuel temperature: 99 ±9 °F (at fuel pump inlet)
Intake air temperature: 77 ±9 °F
Barometric pressure: 29.6 ±1 in. Hg
Humidity: NOX measurement corrected to 75 grains H2O/lb dry air
Reference standard: ISO 8178
The NOX, HC, CO and PM emission data tabulated here are representative of test data taken from a single engine under the test conditions shown above. Data for the other components are estimated. These data are subjected to instrumentation and engine-to-engine variability. Field emission test data are not guaranteed to these levels. Actual field test results may vary due to test site conditions, installation, fuel specification, test procedures and instrumentation. Engine operation with excessive air intake or exhaust restriction beyond published maximum limits, or with improper maintenance, may results in elevated emission levels.
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December 29, 2020 Attachment 2-15
Compliance Information: The engine used in this generator set complies with Tier 2 emissions limit of U.S. EPA New Source Performance Standards for stationary non-emergency engines under the provisions of 40 CFR 60 Subpart IIII when tested per ISO8178 D2. Engine Manufacturer: Cummins Inc. EPA Certificate Number: LCEXL050.AAD-033 Effective Date: 07/08/2019 Date Issued: 07/08/2019 EPA Engine Family (Cummins Emissions Family): LCEXL050.AAD
Engine Information: Model: QSK50 / QSK50-G / QSK50-G4 NR2 Bore: 6.25 in. (159 mm) Engine Nameplate HP: 2220 Stroke: 6.25 in. (159 mm) Type: 4 Cycle, 60°V, 16 Cylinder Diesel Displacement: 3067 cu. in. (50.3 liters) Aspiration: Turbocharged & CAC Compression Ratio: 15.0:1 Emission Control Device: Electronic Control Exhaust Stack Diameter: 2 – 10 in.
Diesel Fuel Emissions Limits D2 cycle exhaust emissions Grams per BHP-hr Grams per kWm-hr
NOX + NMHC CO PM NOX +
NMHC CO PM
Test Results 4.6 0.9 0.06 6.1 1.2 0.08 EPA Emissions Limit 4.8 2.6 0.15 6.4 3.5 0.20
Test methods: EPA emissions recorded per 40 CFR Part 60, 89, 1039, 1065 and weighted at load points prescribed in the regulations for constant speed engines. Diesel fuel specifications: Cetane number: 40-50. Reference: ASTM D975 No. 2-D, 300-500 ppm Sulfur. Reference conditions: Air inlet temperature: 25°C (77°F), Fuel inlet temperature: 40°C (104°F). Barometric pressure: 100 kPa (29.53 in Hg), Humidity: 10.7 g/kg (75 grains H2O/lb) of dry air; required for NOx correction, Restrictions: Intake restriction set to a maximum allowable limit for clean filter; Exhaust back pressure set to a maximum allowable limit. Tests conducted using alternate test methods, instrumentation, fuel or reference conditions can yield different results. Engine operation with excessive air intake or exhaust restriction beyond published maximum limits, or with improper maintenance, may result in elevated emission levels.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 2-16
US Electrodynamics, Inc. December 29, 2020
NOC Application – 2021 Generator Installation x3 Attachment 3
Attachment 3
SEPA DNS
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 3-1
US Electrodynamics, Inc. December 29, 2020
NOC Application – 2021 Generator Installation x3 Attachment 4
Attachment 4
Emissions Inventory
Generator Data
Cummins 1500DQGAB Number of generator 3
% Load125% 40% 50% 75% 90% 100%
bhp @ 1,800 RPM 555 888 1110 1665 1998 2220Fuel consumption (gal/hr) 33 47 57 82 98 108Exhaust Gas Flow (CFM) 4755 6436 7557 9751 10970 11783Exhaust Gas Temperature 659 689 709 745 826 880
HC 0.32 0.24 0.19 0.11 0.09 0.07NOX 3.50 3.76 3.93 4.38 4.98 5.38
CO 0.95 0.69 0.51 0.32 0.48 0.58PM10=PM2.5 0.22 0.14 0.08 0.03 0.02 0.02
SO2 0.01 0.01 0.01 0.01 0.01 0.01
Criteria Emissions
Pollutant lb/hr lb/hr lb/hr lb/hr lb/hr lb/hr
M + HC (VOC) =PM10=PM2 1.98 2.22 1.98 1.54 1.45 1.32
NOX 12.8 22.1 28.9 48.2 65.8 79.0
CO 3.49 4.03 3.74 3.52 6.29 8.52
SO2 0.037 0.059 0.073 0.110 0.132 0.147
Notes:1. 25%, 50%, 75%, and 100% loads from manufacturer specifications (pg. 2-15). 40% and 90% interpolated.
Exhaust Emission Data (grams/hp-hr)1
Performance Data1
2. Per USEI 2019 permit discussion conservatively assuming the hydrocarbons condense, and as such are ifor particulate emissions.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 4-1
Emergency Generator and Tank Emissions
Generator Specs Operating Assumptions Conversions
108 73 7.1
100% load Energy Input (MMBtu/hr) 44.4 24 19,300
3
PTE Criteria Pollutants
PollutantGenerator
Emissions 1 (lb/hr)
Tank Emissions
(lb/hr)Emissions (tpy)
De minimis levels 3
(tpy)
Exceed de
minimis?
PM + HC (VOC) =PM10 =PM2.5 2.22 -- 0.08 0.5 No
NOX 79.0 -- 2.88 2 Yes
CO 8.52 -- 0.31 5 No
SO2 0.147 -- 0.01 2 No
VOCs 1.2 2.42E-03 0.05 2 No
Greenhouse Gases
Emission Factor4
(lb/MMBtu) (lb/hr) (metric tons/yr)
CO2 165 7,326 243 1
Methane 0.09 4.0 1.3E-01 25
246
Toxic Air Pollutants
Pollutant
Emission Factor4
(lb/MMBtu) Emissions (lb/hr)
Emissions
(lbs/day)Emissions (lb/yr)
Averaging
Period6
De minimis levels6
(lb/avg per)
Exceed de
minimis?
SQER levels6
(lb/avg per)
Exceed SQER
levels?
Acetaldehyde 2.52E-05 1.12E-03 2.69E-02 8.17E-02 year 3.0 No 60.0 --
Acrolein 7.88E-06 3.50E-04 8.40E-03 2.55E-02 24-hr 1.30E-03 Yes 2.60E-02 No
Benz(a)anthracene 6.22E-07 2.76E-05 6.63E-04 2.02E-03 year 4.50E-02 No 8.90E-01 --
Benzene 7.76E-04 3.45E-02 8.27E-01 2.52E+00 year 1 Yes 21.0 No
Benzo(a)pyrene 2.57E-07 1.14E-05 2.74E-04 8.33E-04 year 8.20E-03 No 1.60E-01 --
Benzo(b)fluoranthene 1.11E-06 4.93E-05 1.18E-03 3.60E-03 year 4.50E-02 No 8.90E-01 --
Benzo(k)fluoranthene 2.18E-07 9.68E-06 2.32E-04 7.07E-04 year 4.50E-02 No 8.90E-01 --
Chrysene 1.53E-06 6.79E-05 1.63E-03 4.96E-03 year 4.50E-01 No 8.9 --
Dibenz(a,h)anthracene 3.46E-07 1.54E-05 3.69E-04 1.12E-03 year 4.10E-03 No 8.20E-02 --
Diesel Engine Exhaust,
Particulate7 -- 8.08E-01 19.4 58.95 year 2.70E-02 Yes 5.40E-01 Yes
Formaldehyde 7.89E-05 3.50E-03 8.41E-02 2.56E-01 year 1.4 No 27.0 --
Indeno(1,2,3-cd)pyrene 4.14E-07 1.84E-05 4.41E-04 1.34E-03 year 4.50E-02 No 5.50E-03 --
Naphthalene 1.30E-04 5.77E-03 1.39E-01 4.21E-01 year 2.40E-01 Yes 4.8 No
Nitrogen dioxide 8 -- 7.90E+01 1.90E+03 5,766 1-hr 4.60E-01 Yes 8.70E-01 Yes
Propylene 2.79E-03 1.24E-01 2.97 9.04E+00 24-hr 11.0 No 220 --
Toluene 2.81E-04 1.25E-02 2.99E-01 9.11E-01 24-hr 19.00 No 370 --
Xylenes 1.93E-04 8.57E-03 2.06E-01 6.26E-01 24-hr 8.20E-01 No 16.0 --
Notes:
1. From Cummins 1500DQGAB performance data page 2-15. PTE calculated for engine loading between 25% and 100%. Worst case values used for de minimis determination.
2. Maximum anticipated hours per generator for testing, maintenance, and emergency operation.
3. Per WAC 173-400-102.
4. Emission factors and diesel properties from AP-42 Chapter 3.4, Large Stationary Diesel Engines (10/1996), Tables 3.4-3, and 3.4-4.
5. 40 CFR Part 98 Table A-1 (August 2016).
6. Per WAC 173-460-150.
7. DEEP emissions equivalent to PM2.5 emissions.
8. NO2 emissions equivalent to NO X emissions.
Pollutant GWP5Emission Estimate
CO2e, tpy
Diesel fuel density (lb/gal) 4:
Maximum hours/day: Average heating value of diesel fuel (Btu/lb) 4:
Number of Generators:
100% load Fuel Consuption 1 (gal/hr/gen): Maximum hours/year/generator 2:
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 4-2
Tank Specs
Number of Tanks=2 Pollutant
Working LossEmissions (lb/hr)
Breathing LossEmissions (lb/hr)
Total TankEmissions
Tank Volume= 20,000 gallon VOCs 3.25E-04 2.09E-03 2.42E-03Contents= Diesel Fuel
Annual Usage= 105,782 gallons# Turnovers= 2.6Tank Length= 41 ftTank Width= 14.8 ftTank Depth= 16.2 ft
Tank Equiv Diam= 26 ftVapor Space Height 8.1 ft
MW of diesel fuel= 200Vapor Pressure= 0.0056 psi
where:MW= Molecular weight of vapor in storage vessel (pound per pound mole)PV = True vapor pressure of the HAP at liquid storage temperature (pounds per square inch abso
V = Tank capacity (gallon)N = Number of turnovers per yearKN = Turnover factor (dimensionless) = (180 + N)/6N, for turnovers > 36 = 1, for turnov< 36
KC = Product factor (dimensionless) = 1
PA = Average atmospheric pressure (pounds per square inch absolute) = 14.969
D = Tank diameter [or equivalent diameter = 1.3 x (LxW)0.625 / (L+W)0.25] (feet)L = Tank Length (feet)W = Tank Width (feet)H = Average vapor space height (feet), assume half fullΔT = Average ambient diurnal temperature chang°F). Assume = 10°FFP = Paint factor (dimensionless) = 0.17 for new white pa
C = Adjustment factor for small diameter tanks (dimensionless) = 0.0771 x D - 0.0013 x D2 - 0.1334, for diameter <30 feet. Assumed CX = Concentration of chemical in tank, assuming 100% V
#T = number of tank
Working Loss (pounds/hour) = LW = 2.741 x 10-9 x MW x PV x V x N x KN x KC x CX x #T
Breathing Loss (pounds/hour) = LB = 2.580 x 10-6 x MW x [PV/(PA-PV)]0.68 x D1.73 x H0.51 x ΔT0.5 x FP x C x KC x CX x #T
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 4-3
Modeling Inputs
Emissions Inputs25% loading 100% loading
PollutantAveraging
PeriodGEN A (g/s)
GEN B (g/s)
GEN C (g/s)
Pollutant
AveragingPeriod
GEN A (g/s)
GEN B (g/s)
GEN C (g/s)
Spacing Distance
1-hr 0.00 0.54 0.54 1-hr 0.00 3.32 3.32 12.5 150Annual 4.50E-03 4.50E-03 4.50E-03 Annual 2.76E-02 2.76E-02 2.76E-02 25 400
DEEP Annual 2.83E-04 2.83E-04 2.83E-04 DEEP Annual 1.03E-04 1.03E-04 1.03E-04 50 900100 2,000
Source Inputs 300 4,500Point Source 600 10,000
Direction
UTM1 299602.2 E 5336087.8 N 299603.3 E 5336082.2 N 299379.8 E 5336241.9 N
Stack Height2 29 ft 8.84 m 29 ft 8.84 m 29 ft 8.84 m
Stack Diameter2 1.6 ft 0.48 m 1.6 ft 0.48 m 1.6 ft 0.48 m
Stack Temperature 25% loading3 626 °F
Stack Temperature 100% loadi 836 °F
Stack Flow Rate 25% loading3= 4,517 ft3/m
Stack Flow Rate 100% loading3= 11,194 ft3/m
Notes:. From Google Earth2. Stack height and diameter from client.3. Per manufacturer specifications (pg. 2-15) with a 5% correction to accound for low ambient temperatures for part of the year.
Vertical Vertical Vertical
Receptor Grid (m)
Generator A (GEN_A) Generator B (GEN_B) Generator C (GEN_C)
NO2 NO2
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 4-4
Modeling Results
Criteria Modeling Analysis - supplemented with Airport Met Data and Mesowest Data
PollutantAveraging
Period
Design Value
μg/m3
Background
Value μg/m 3
Total Impact
μg/m3 NAAQS μg/m 3 NAAQS
Exceeded?
NO2 at 25% load 1-hr1 90.51 7.71 98.21 188 No
NO2 at 100% load 1-hr1 153.70 7.71 161.41 188 No
NO2 at 25% load Annual2 0.043 1.69 1.73 100 No
NO2 at 100% load Annual2 0.104 1.69 1.80 100 No
TAPS Modeling Analysis - supplemented with Airport Met Data and Mesowest Data
PollutantAveraging
Period
Design Value
μg/m3 ASIL μg/m 3 Exceed
ASIL?
DEEP at 25% load Annual3 2.98E-03 3.30E-03 No
DEEP at 100% load Annual3 4.30E-04 3.30E-03 No
NO2 at 25% load 1-hr4 98.94 470 No
NO2 at 100% load 1-hr4 189.44 470 No
Notes:
1. 5-year mean of the 8th highest daily 1-hr maximum modeled concentration for each year of meteorological data modeled per 40 CFR part 50.
2. Maximum 1st highest at any receptor per 40 CFR part 50.
3. Maximum 1st highest per WAC 173-460-080.
4. Maximum 1st highest per WAC 173-460-080.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 4-5
US Electrodynamics, Inc. December 29, 2020
NOC Application – 2021 Generator Installation x3 Attachment 5
Attachment 5
tBACT Analysis
US Electrodynamics, Inc. December 23, 2020
NOC Application – 2021 Generator Installation x3 Attachment 5–1
tBACT Analysis US Electrodynamics, Inc. – Okanogan County, Washington
Introduction
US Electrodynamics, Inc. (USEI) operates a teleport services facility under Approval Order No. 09AQ-
C085, 2nd revision in Okanogan County, Washington. USEI has emergency power supply via six diesel
fired emergency generators, and proposes to add three additional diesel-fired emergency generators for
a project with the Okanogan Public Utility District (PUD).
Two pollutants emitted during diesel fuel combustion of the three new emergency generators at the
facility trigger tBACT.
Regulated Emissions
Emissions of the following toxic pollutants are greater than the de minimis of WAC 173-460-150 and
will be the subject of this tBACT analysis:
• Diesel engine exhaust, particulate (DEEP)
• Nitrogen dioxide (NO2)
Selected Acronyms Used Throughout This Report
• BACT – Best Available Control Technology
• DOC – Diesel Oxidation Catalyst
• DPF – Diesel Particulate Filter
• Ecology – Washington State Department of Ecology
• EPA – United States Environmental Protection Agency
• ITR – Injection Timing Retardation
• NOC – Notice of Construction
• NSR – New Source Review
• RBLC – RACT/BACT/LAER Clearinghouse
• SCR – Selective Catalytic Reduction
• SNCR – Selective Non-Catalytic Reduction
• tBACT – Toxics Best Available Control Technology
• TPY – Tons Per Year, unit of measure for emission rate
• VOC – Volatile Organic Compounds
• WAC – Washington Administrative Code
US Electrodynamics, Inc. December 23, 2020
NOC Application – 2021 Generator Installation x3 Attachment 5–2
Step 1: Identify Technologies
Under the State of Washington’s NSR rules, which are promulgated and enforced by Ecology and local
air quality districts, best available control technologies (BACT) are required for construction and
modification of specified stationary sources.
BACT is defined as an emission limitation (including a visible emission standard) based on the maximum degree of reduction
for each pollutant subject to regulation under the Clean Air Act which would be emitted from any proposed
major stationary source or major modification which the Administrator, on a case-by-case basis, taking
into account energy, environmental, and economic impacts and other costs, determines is achievable for
such source or modification through application of production processes or available methods, systems,
and techniques, including fuel cleaning or treatment or innovative fuel combustion techniques for control
of such pollutant.1
The purpose of this investigation was to identify potential control technologies for controlling emissions
from the diesel fuel combustion.
Control techniques for criteria pollutants may be classified into two broad categories – (1) inherently
lower emitting processes/practices and (2) emission controls2.
The control techniques potentially available for control of DEEP emissions from diesel fuel combustion
include:
o Inherently lower emitting process/practices
o Good combustion practices
o Emission controls
o Diesel oxidation catalyst (DOC)
o Diesel particulate filters (DPF)
The control techniques potentially available for control of NO2 emissions from diesel fuel combustion
include: o Inherently lower emitting process/practices
o Injection Timing Retardation (ITR)
o Air-to-fuel ratio adjustment
o Derating
o Post-combustion controls
o Selective Non-catalytic reduction (SNCR)
o Selective catalytic reduction (SCR)
1 “New Source Review Workshop Manual”, DRAFT October 1990, Section I. 2 “New Source Review Workshop Manual”, DRAFT October 1990, Section IV.A.
US Electrodynamics, Inc. December 23, 2020
NOC Application – 2021 Generator Installation x3 Attachment 5–3
DEEP Combustion Emissions Based on proposed maximum throughput, the facility has the potential to emit 59.0 pounds per year of
DEEP from combustion emissions.
Step 2: Infeasible Technologies
None of the technologies are infeasible.
Step 3: Effectiveness Ranking
According to the 1990 Draft New Source Review Manual, feasible technologies are next ranked by the
degree of reduction (i.e. “% reduction).
Based on 2010 technical bulletins from EPA on pages 5-7 through 5-10 of this report, the control
efficiencies are as follows:
Type of Control % Reduction
PM
Potential Emissions
DEEP (lbs/yr)
Diesel Particulate Filter (DPF) 85-90% 5.9 – 8.9
Diesel Oxidation Catalyst (DOC) 20-40% 35.4 – 47.2
None 0% 59.0
Step 4: Evaluate Controls
Spring Environmental obtained a cost estimate from Nett Technologies for a DPF and DOC and the
estimate is included in pages 5-11 and 5-12 of this report. Capital costs were estimated by multiplying
the cost estimates from Nett Technologies by 3 to account for the three generators included in Spring
Environmental’s DEEP emission calculations. Annual capital costs were estimated assuming an
equipment life of 10 years and an interest rate of 7%. Annual labor costs for the DPFs were calculated
using wages from the U.S. Bureau of Labor Statistics. DOCs require little to no maintenance, hence
minimal operation and maintenance cost. The detailed cost analysis is included in page 5-6 of this report.
Control Technology Capital Cost1 Annual Capital
Cost
Annual O&M
Costs Annualized Cost
Cost per Ton per Year
DEEP Removed
DPF $93,600 $13,300 $110 $13,400 $3,644,000
DOC $18,700 $2,700 $0 $2,700 $129,000
Notes:
1. Capital cost is for three installations of a particular piece of control equipment, as there are three
generators that emit DEEP emissions.
Step 5: BACT Recommendation
Spring Environmental recommends that DPF and DOC controls are not cost effective for USEI’s
operations.
US Electrodynamics, Inc. December 23, 2020
NOC Application – 2021 Generator Installation x3 Attachment 5–4
NO2 Combustion Emissions Based on the proposed operating hours, the facility has the potential to emit 2.88 tons per year of NO2
from combustion of diesel fuel.
Step 2: Infeasible Technologies
• ITR has rarely been applied to either small or large internal combustion engines. Although ITR
reduces NO2 emissions, it correspondingly reduces engine power, which is necessary for facility
operations in an emergency situation.
• Air to fuel ratio adjustment has not been applied to either small or large internal combustion
engines per the EPA RACT/BACT/LAER Clearinghouse (RBLC). The generators will operate
according to manufacturer specifications.
• Derating is not a feasible pollution prevention strategy because the current capacity of the
generators is necessary for facility operations in an emergency situation. Only two of the
generators will operate at a time.
• SCR has not been applied to either small or large internal combustion engines per the EPA
RBLC. Although the technology may be feasible, it is not demonstrated technology for the size
of the generators under consideration. Personnel and environmental risks related to the storage
and management of ammonia far outweigh the benefits of reducing 2.88 tons of NO2 per year.
• SNCR has not been applied to either small or large internal combustion engines per the EPA
RBLC. Although the technology may be feasible, it is not demonstrated technology for the size
of the generators under consideration. Personnel and environmental risks related to the storage
and management of ammonia far outweigh the benefits of reducing 2.88 tons of NO2 per year.
Step 3: Evaluate Controls
According to EPA’s RBLC, there are no proven NO2 control technologies for emergency internal
combustion engines. The generators will operate according to manufacturer specifications with limited
operating hours, only running two of the three generators at a time.
Step 4: BACT Recommendation
Spring Environmental recommends that operating according to manufacturer specification and limited
operation is BACT for control of NO2 from combustion.
Summary
Spring Environmental recommends that BACT be defined as operating according to manufacturer specification and limited operation for control of NO2 from diesel combustion. NOx emissions would be a maximum of2.88 tpy.
Spring Environmental recommends that DPF and DOC controls for DEEP are not cost effective for USEI. DEEP emissions would be a maximum of59.0 lbs/year.
Contact Information
If you have any questions on the enclosed information, contact Beth Hodgson or Betsy Cochran at (509) 328-7500.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
Sincerely,
Beth Fifield Hodgson, PE Principal Engineer
December 29, 2020 Attachment 5-5
US Electrodynamics
t-BACT Analysis
Constants
Financial Assumptions: 10 years at 7% interest
Labor (hourly): 27.53$ Wages from U.S. Bureau of Labor Statistics for occupation code 49-0000
Maintenance: 1 hour/year for DPF (cleaning out every 2000 hours [every 3 years], assume 3 hours per instance of maintenance, or 1 hour/year)0 hour/year for DOC, typically maintenance-free
Control Technology Total Installed Cost1 Annual Capital Cost2 Annual O&M Costs Annualized CostDEEP Reduction
(tons/yr)
DEEP Removal Cost (per
year per ton)
DPF3 93,600$ 13,327$ 110.12$ 13,437$ 3.69E-03 3,643,838$
DOC4 18,720$ 2,665$ -$ 2,665$ 2.07E-02 129,071$
1. Accounts for three installations of control technology at $30,000 per installation for the DPF and $6,000 per installation for the DOC.2. Annual Capital Cost = TIC*interest*(1+interest)^years / ((1+interest)^years-1)* 1.04. Capital cost converted to 2020 values using a factor of 1.04.3. Assuming an average emission reduction: 87.5%4. Assuming an average emission reduction: 30%
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 5-6
EPA-420-F-10-031 May 2010
National Clean Diesel Campaignwww.epa.gov/cleandiesel
Diesel Oxidation CatalystGeneral Information
Technical Bulletin
Technical Overview Diesel Oxidation Catalysts, also known as DOCs, are exhaust aftertreatment devices that reduce emissions from diesel fueled vehicles and equipment. Engine manufacturers have used DOCs in different in-use applications for many years, and DOCs are widely used as a retrofit technology because of their simplicity and limited maintenance requirements. DOCs generally consist of a precious metal coated flow-through honeycomb structure contained in a stainless steel housing. As hot diesel exhaust flows through the honeycomb structure, the precious metal coating causes a catalytic reaction that breaks down pollutants into less harmful components.
Emissions Reduction The United States Environmental Protection Agency (EPA) and the California Air Resources Board (CARB) evaluate the emission reduction performance of DOCs and identify engine operating criteria and conditions that must exist for DOCs to achieve those reductions.
DOCs verified by EPA and CARB are typically effective at reducing emissions of particulate matter (PM) by 20 to 40 percent. EPA’s Verified Technology List also shows that DOCs may reduce hydrocarbons by 40 to 75 percent and carbon monoxide by 10 to 60 percent. The PM removed by DOCs is largely the soluble organic fraction that comes from unburned fuel and oil. DOCs generally
have little impact on elemental carbon and oxides of nitrogen (NOx) emissions. DOCs have also been verified in combination with crankcase ventilation systems for additional emissions reduction.
EPA is aware of concerns that DOCs may increase the nitrogen dioxide (NO2) fraction of total NOx emissions. The NO2 produced by a DOC is dependent on the catalyst formulation. EPA and CARB have established a limit on increases in NO2 emissions from diesel retrofit devices and all DOCs on the lists of verified products comply with this limit.
Application Verified DOCs are available for nonroad and highway heavy-duty diesel engines including those on buses, school buses, trucks, mining equipment, construction equipment, cargo handling equipment, marine vessels, auxiliary power units and stationary generators.
Each DOC is verified for use with specific engines and/or with specific configurations over a range of model years. In addition to vehicle and engine specifications, the intended application should be evaluated for exhaust temperature, fuel sulfur levels and lubrication oil consumption. EPA and CARB’s lists of verified diesel retrofit technologies define the specific engine operating criteria required to successfully apply a particular retrofit technology: www.epa.gov/otaq/retrofit/verif-list.htm.
Fuel DOCs perform best with Ultra Low Sulfur Diesel fuel (ULSD), and some DOCs are verified for use with Low Sulfur Diesel (LSD). ULSD, which contains up to 15 parts per million sulfur, is required for highway vehicles and will begin to be phased in for the nonroad sector beginning in 2010.
EPA is aware of concerns that DOCs may release some ultrafine particulates. Such concerns are associated with high sulfur levels in diesel fuel and the potential for sulfur
Diesel Oxidation Catalyst (DOC)
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 5-7
to accumulate in the DOC and then be released as sulfate particles. This characteristic may also be associated with the precious metal loading and vehicle operation. When used with ULSD EPA does not believe DOCs increase ultrafine PM. Although nonroad diesel fuel will not be required to meet ULSD sulfur levels until 2010, nonroad equipment equipped with DOCs should preferably be fueled with ULSD.
Cost DOCs generally cost between $600 to $2,000 or more, including installation, depending on engine size, installation requirements or other unique needs. Because a DOC is likely to be heavier than a muffler, it is likely that special mounting is necessary.
LongevityWhen properly installed and maintained, DOCs should remain effective for the life of the vehicle, generally five to ten years or 10,000 or more hours of operation. Engine problems with fuel control or oil consumption may quickly deteriorate the performance of a DOC. Consequently, regular engine maintenance is essential to DOC performance.
Warranty coverage is typically part of the commercial contract negotiated between the product suppliers and their customers. Such warranties typically cover defects in materials or workmanship for a specified period defined in years, miles and/or operating hours.
As part of their verification program, CARB has established detailed warranty periods for CARB-verified retrofit technologies as shown in the following table.
Vehicle Category Warranty Period
GVWR > 33,000 lbs. hp > 250 hp and miles/year > 100,000 Vehicle miles < 300k
Two years; unlimited mileage
GVWR > 33,000 lbs. hp > 250
Five years or 150,000 miles
GVWR 19,500 to 33,000 lbs.
Five years or 100,000 miles
GVWR < 19,000 lbs. Five years or 60,000 miles
California Air Resources Board Warranty Period
Refuse Truck with Diesel Oxidation Catalyst (DOC)
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 5-8
EPA-420-F-10-029 May 2010
National Clean Diesel Campaignwww.epa.gov/cleandiesel
Diesel Particulate FilterGeneral Information
Technical Bulletin
Technical Overview Diesel Particulate Filters, also known as DPFs, are exhaust aftertreatment devices that significantly reduce emissions from diesel fueled vehicles and equipment. DPFs typically use a porous ceramic or cordierite substrate or metallic filter, to physically trap particulate matter (PM) and remove it from the exhaust stream.
After it is trapped by the DPF, collected PM is reduced to ash during filter regeneration. Regeneration occurs when the filter element reaches the temperature required for combustion of the PM. “Passive” regeneration occurs when the exhaust gas temperatures are high enough to initiate combustion of the accumulated PM in the DPF, without added fuel, heat or driver action. “Active” regeneration may require driver action and/or other sources of fuel or heat to raise the DPF temperature sufficiently to combust accumulated PM. The frequency of regeneration is determined by the engine’s duty cycle, PM emission rate, filter technology and other factors. When using an active filter, it is particularly important to follow the manufacturer’s instructions for regeneration.
In addition to regeneration, the filter must be periodically cleaned to remove noncombustible materials and ash. It is important to avoid excessive PM and ash accumulation in a DPF, so proper maintenance and cleaning instructions should be followed closely. Cleaning of DPFs is typically
required every 6 to 12 months. The cleaning process involves manually removing the filter element from the vehicle and placing it in a cleaning station designed for this purpose. An engine emitting excessive PM or inadequate filter regeneration will cause a DPF to require more frequent cleaning. Diagnostics should be performed to identify the cause for more frequent cleaning intervals. A backpressure monitoring system should always be used with a DPF and periodic inspection of the monitoring system should be performed to confirm proper operation.
Emissions Reduction The United States Environmental Protection Agency (EPA) and the California Air Resources Board (CARB) evaluate the emission reduction performance of DPFs and identify engine operating criteria and conditions that must exist for DPFs to achieve those reductions.
DPFs verified by EPA and CARB are typically effective at reducing emissions of PM by 85 to 90 percent or more. EPA’s Verified Technology List also shows that certain DPFs reduce emissions of hydrocarbons and CO by 70 to 90 percent. DPFs generally do not reduce oxides of nitrogen (NOx) emissions. DPFs can be combined with crankcase ventilation systems for additional emission reductions.
EPA is aware of concerns that catalyzed DPFs may increase the nitrogen dioxide (NO2) fraction of total NOx emissions. Some DPFs generate NO2 as a means to help filter regeneration at lower temperatures. The NO2 produced by a DPF is dependent on the catalyst formulation. EPA and CARB have established a limit on increases in NO2 emissions from diesel retrofit devices and all DPFs on the lists of verified products comply with this limit.
ApplicationVerified DPFs are available for nonroad and highway heavy-duty diesel engines including those on buses, trucks, construction equipment, auxiliary power units and stationary generators.
Outlet Section
Inlet Section
FilterSection
Diesel Particulate Filter
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 5-9
Each DPF is verified for use with specific engines and/or with specific configurations over a range of model years. In addition to vehicle and engine specifications, the intended application should be evaluated for exhaust temperature, duty cycle, fuel sulfur levels, lubrication oil consumption and engine-out PM emission levels. Exhaust temperature data logging should be performed with each installation over a range of vehicle duty cycles and, if possible, over a range of ambient temperatures. A copy of results and analysis from data logging should be retained by the fleet for each installation. EPA and CARB’s lists of verified diesel retrofit technologies define the specific engine operating criteria required to successfully apply a particular retrofit technology: www. epa.gov/otaq/retrofit/verif-list.htm.
Fuel DPFs are verified for use with Ultra Low Sulfur Diesel fuel (ULSD), which contains up to 15 parts per million sulfur. Fuel additives should not be used unless explicitly approved by the DPF manufacturer.
Cost DPFs generally cost between $5,000 to $15,000 or more, including installation, depending on engine size, filter technology and installation requirements. Active DPF systems are more expensive than passive DPF systems and can cost up to $50,000 for a large piece of nonroad equipment. Vehicle inspection, data logging and backpressure monitoring systems are required with each installation and these costs are typically included in the cost of the DPF. Because a DPF is likely to be heavier than a muffler, it is likely that special mounting is necessary. Costs for cleaning stations or cleaning services should also be considered when purchasing DPFs.
Longevity When properly installed and maintained, DPFs should remain effective for the life of the vehicle, generally five
to ten years or 10,000 or more hours of operation. Engine problems with fuel control or oil consumption may quickly deteriorate the performance of a DPF. Consequently, regular engine maintenance is essential to DPF performance.
Warranty coverage is typically part of the commercial contract negotiated between the product suppliers and their customers. Such warranties typically cover defects in materials or workmanship for a specified period defined in years, miles and/or operating hours.
As part of their verification program, CARB has established detailed warranty periods for CARB-verified retrofit technologies as shown in the following table.
Vehicle Category Warranty Period
GVWR > 33,000 lbs. hp > 250 hp and miles/year > 100,000 Vehicle miles < 300k
Two years; unlimited mileage
GVWR > 33,000 lbs. hp > 250
Five years or 150,000 miles
GVWR 19,500 to 33,000 lbs.
Five years or 100,000 miles
GVWR < 19,000 lbs. Five years or 60,000 miles
California Air Resources Board Warranty Period
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 5-10
1
David Finley
From: Wayne Moffat <[email protected]>Sent: Tuesday, November 12, 2019 12:42 PMTo: [email protected]: RE: New QUOTE REQUEST submission from David Finley,Spring
Environmental,[email protected],509-328-7500
Follow Up Flag: Follow upFlag Status: Flagged
Hello David Thanks for your interest in Nett Technologies as an emission solution provider. I can give you some ballpark numbers for the DOC as well as DPF systems but keep in mind that on an engine this size there may be configuration issues to deal with especially on the multiple DPF assembly required to address exhaust flow on an engine this size. You could expect approximately $6000.00 USD for the DOC assembly and for a DPF approximately $30,000.00 USD plus the installation costs. The DPF would require 4 elements and would need to be configured so the cores can be accessed for servicing. In addition a temperature profile of the engine in service is recommended to assure adequate temperature for regeneration. I hope this rough estimate is suitable for your needs. Please let me know if you have any questions. Regards Wayne Moffat, Senior Technical Sales Sales Department [email protected]
6154 Kestrel Road Mississauga, Ontario L5T 1Z2, Canada Map
tel: 905.672.5453 x124 fax: 905.672.5949 toll-free 1-800-361-6388 web: www.nettinc.com
From: <Marketing Group> Sent: Tuesday, November 12, 2019 11:43 AM To: [email protected] <[email protected]> Subject: New QUOTE REQUEST submission from David Finley,Spring Environmental,[email protected],509-328-7500 1. Contact Information
Full Name Company Email Phone
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 5-11
2
David Finley Spring Environmental [email protected] 509-328-7500
2. Equipment Details
Make Model Type
Peterson Pacific HC5400 Grinder
3. Engine Details
Make Model Fuel Type
Caterpillar 3412E Diesel
4. Other Details
Engine Power (hp) Displacement (L) OEM Muffler P/N
860
5. Additional Information
We are looking for ballpark estimates on a metallic DOC for this engine and a passive DPF for this engine. Separate cost estimates would be appreciated. Thank you.
The information contained in this message or any of its attachments may be confidential and is intended for the exclusive use of the addressee(s). Any disclosure, reproduction, distribution or other dissemination or use of this communication is strictly prohibited without the express permission of the sender. If you have received this message in error, please notify the sender by reply e-mail and delete it from your system. Thank you.
US Electrodynamics, Inc. NOC Application - 2021 Generator Installation x3
December 29, 2020 Attachment 5-12
US Electrodynamics, Inc. December 29, 2020
NOC Application – 2021 Generator Installation x3 Attachment 6
Attachment 6
Modeling Report
AIR DISPERSION MODELING REPORT
SPRING Environmental, Inc.
US ELECTRODYNAMICS, INC.
Prepared for:
Prepared by:
Issue date:
BREWSTER, WA
DECEMBER 2020
US Electrodynamics, Inc. Attn: Timothy Baird 66 C Teleport Drive Brewster, WA 98812 (509) 689-1000
Spring Environmental, Inc. 1011 N. Cedar Street Spokane, Washington 99201-1914 (509) 328-7500
December 29, 2020
.BnAJ ~ AL~ Beth Fifield ~dgson (} Principal Engineer
US Electrodynamics December 2020
Air Dispersion Modeling Report Page i
AIR DISPERSION MODELING US ELECTRODYNICS – GENSETS X 3
TABLE OF CONTENTS
1. Purpose .................................................................................................................................... 1
2. Model Description ................................................................................................................... 1
3. Emission and Source Data ....................................................................................................... 3
4. Receptor Network .................................................................................................................... 5
5. Elevation Data ......................................................................................................................... 6
6. Surface Data ............................................................................................................................ 6
7. Meteorological Data ................................................................................................................ 6
8. Land Use Classification ........................................................................................................... 6
9. Buildings .................................................................................................................................. 6
10. Background Concentration ...................................................................................................... 6
11. Evaluation of Compliance with Standards .............................................................................. 7
12. Conclusion ............................................................................................................................... 7
Appendices:
A – Site Plan and Source Locations
B – AERMOD Input and Results Summary
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AIR DISPERSION MODELING US ELECTRODYNICS – GENSETS X 3
US Electrodynamics, Inc. (USEI) provides government and commercial satellite teleport services
including TT&C (tracking, telemetry, and command), broadcast video, aviating, and internet
services delivery. USEI is headquartered and operates one of two teleport facilities at 66C Teleport
Drive in Brewster, Washington. The facility has emergency power supply via six diesel-fired
generators, which are permitted under Washington State Department of Ecology’s Central Region
Office (Ecology-CRO) Notice of Construction No. 09AQ-C085, 2nd revision. USEI intends to add
three additional 1.5 MW diesel-fired emergency generators to support work the local Public Utility
District is doing to add an additional sub station and feed the facility. USEI has engaged Spring
Environmental to prepare an NOC application package and complete the air dispersion modeling
analysis. Spring Environmental submitted a modeling protocol on November 11, 2020 to Ranil
Dhammapala, atmospheric scientist with Ecology, and received comments from Tes Ghidey, Ryan
Vicente, and Gary Palcisko on 12/10/2020. The modeling was updated accordingly. The following
is a summary of the air dispersion analysis.
1. Purpose
To determine the potential impact of the proposed project in relation to the acceptable source impact
level (ASIL) for toxic air emissions per WAC 176-460-150.
2. Model Description
EPA provides guidance in Subpart W of 40 CFR Part 51 on applicability of specific air quality
dispersion models in the review and preparation of new source permits and State Implementation
Plans (SIP) revisions. Based on the topography, land use, and meteorology, AERMOD was
selected to model the air emissions.
The American Meteorological Society/Environmental Protection Agency Regulatory Model
(AERMOD) is a steady-state Gaussian plume model which can be used to assess pollutant
concentrations from a wide variety of sources. AERMOD utilizes surface boundary layer parameters
and meteorological data profiles calculated by AERMET, which processes hourly surface observations
and upper air data. AERMAP is a terrain preprocessor for AERMOD.
AERMOD: Since AERMOD was specifically developed to support EPA’s regulatory modeling
programs, the regulatory modeling options, as specified in the Guideline of Air Quality Models
(Revised), are the default mode of operation for the generator model. These options include a routine
for processing averages when calm winds or missing meteorological data occur.
The user may select either rural or urban dispersion parameters, depending on the characteristics of the
source location. The user also has the option of calculating several short-term (1-, 2-, 3-, 4-, 6-, 8-, 12-,
or 24-hr) averages in addition to long term (monthly, annual, or period) averages for concentration
values or deposition values for a particular run.
The model is capable of handling multiple sources, including point, volume, and area source types. Line
sources may also be modeled using a string of volume or area sources. Several sources and groups of
US Electrodynamics December 2020
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sources may be specified in a single run. The emission rates of the sources can be treated as constant or
varied according to time of day, month or season.
The user has the capability of specifying multiple receptor networks in a single run, and may mix
Cartesian grid receptor networks and polar grid receptor networks. This is useful for applications where
the user may need a coarse grid over the entire modeling domain, but a denser grid in the area of
maximum expected impacts. The user has the option of specifying receptor elevations above ground to
model flagpole receptors. Receptor elevations and hill height scales are calculated by AERMAP from
USGS Digital Elevation Model files. In AERMOD, there is no distinction between elevated terrain
below release height and terrain above release height as with earlier regulatory models that distinguished
between simple and complex terrain.
The user has various options of printed output including summaries of high values, summaries of overall
maximum values and tables of multiple receptors for each averaging period and source group
combinations. The latter group of data may be used to generate contour and grid maps.
The latest version of AERMOD (19191) was used in the air dispersion modeling analysis for USEI’s
three emergency diesel generators. Further information is available in the User’s Guide in the EPA
Guidance of Air Quality Models.
AERSURFACE: When applying the AERMET meteorological processor, the user must determine
appropriate values for three surface characteristics: surface roughness length, noontime albedo, and
daytime Bowen ratio. The AERSURFACE tool aids users in obtaining realistic and reproducible surface
characteristic values for the three surface characteristics. The tool uses data from the National Land
Cover Database (NLCD) from the United States Geological Survey (USGS) and look-up tables of
surface characteristic values that vary by land cover type and season.
The latest version of AERSURFACE (20060) was used in the air dispersion modeling analysis for the
ACRL. Further information is available in the User’s Guide in the EPA Guidance of Air Quality
Models.
AERMET: Surface observations are available from meteorological towers operated by various
agencies including local environmental agencies and the National Weather Service of the National
Oceanic & Atmospheric Administration (NOAA). Remote Automatic Weather Stations (RAWS) is a
network of automated weather stations run by the U. S. Forest Service and the Bureau of Land
Management (BLM) and monitored by the National Interagency Fire Center. National Weather Service
stations are usually located at significant airports while RAWS data is often located in remote areas.
Upper air data is also collected by NOAA’s National Weather Service and stored in the NOAA Forecast
Systems Laboratory Radiosonde Database (http://raob.fsl.noaa.gov). See Section 6 for more
information about the data selected for this modeling demonstration.
There are three stages to processing meteorological data. The first stage extracts meteorological data
from archive data files and processes the data through various quality assessment checks. The second
stage merges all data available for 24-hour periods (NWS and site-specific data) and stores these data
together in a single file. The third stage reads the merged meteorological data and estimates the
necessary boundary layer parameters for use by AERMOD. Two files are written for AERMOD: a file
of hourly boundary layer parameter estimates and a file of multiple-level observations of wind speed
and direction, temperature, and standard deviation of the fluctuating components of the wind.
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AERMINUTE was used to process 1-minute wind data which helps reduce the number of calms and
missing winds in the surface data.
The latest version of AERMET (19191) was used to assess the meteorological data for USEI. Further
information is available in the User’s Guide for the AERMOD Meteorological Pre-processor.
AERMAP: AERMAP processes commercially available Digital Elevation Data and creates a file
suitable for use within an AERMOD control file. See Sections 4 and 5 for more information about the
data selected for this modeling demonstration. This file would contain elevation and hill-height scaling
factors for each receptor in the air dispersion study. AERMAP can also calculate the base elevations of
the sources.
For complex terrain situations, AERMOD captures the essential physics of dispersion in complex
terrain and therefore needs elevation data that conveys the features of the surrounding terrain. In
response to this need, AERMAP searches for the terrain height and location that has the greatest
influence on dispersion for each individual receptor. This height is the referred to as the hill height scale.
Both the base elevation and hill height scale data are produced by AERMAP as a file or files which can
be directly inserted into an AERMOD input control file. Further information is available in the User’s
Guide for the AERMOD Terrain Pre-processor.
3. Emission and Source Data
Facility Layout
See Appendix A for the site plan and locations of each modeled source. A regional map is provided in
Figure 1.
Figure 1: Regional Map
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Process Overview
USEI intends to install three Cummins 1500DQGAB diesel-fired emergency generators. See
Appendix A for a facility map with the location of the three generators. Each generator will
operate approximately 73 hours per year, for an aggregate total of 219 hours per year. Only two of
the three generators will ever operate simultaneously. The generators will be installed upon
approval of this application.
Emissions Data
Based on preliminary emissions calculations, diesel engine particulate matter (DEEP) and nitrogen
dioxide NO2 are the only toxic air pollutants with emissions estimated to exceed de minimis and
small quantity emission rate (SQER) levels defined in WAC 173-460-150. Therefore, DEEP and
NO2 require modeling. NO2 is the only criteria pollutant to have emissions estimated to exceed de
minimis levels defined in WAC 173-400-110(5). Therefore, 1-hr and annual NO2 require
modeling.
Potential emissions from the generators were calculated using the operational specifications of the
Cummins 1500DQGAB generators. USEI expects the generators to operate between 40% and 90%
load during both testing and emergency scenarios, but 25% and 100% loads were used for this
analysis for a safety factor. Values in between were not evaluated since the two extremes account
for the worst-case emissions. The maximum DEEP emissions occur at 25% load, and the
maximum NO2 emissions occur at 100% load. Only two of the three generators will operate
simultaneously; two of the generators are backup generators. Emissions were calculated and
modeled based on 73 hours of operation per generator per year for a total of 219 hours per year.
Emissions estimates were developed by using emissions data provided by the manufacturer, and
from AP-42 Section 1.3 when equipment specific factors are not available. A summary of criteria
pollutants that have the potential to exceed the de minimis level can be found in Table 1. A
summary of TAPs that have the potential to exceed their respective SQER can be found in Table
2.
Table 1: Criteria Pollutant Emissions
Pollutant Averaging Period Emissions
(lbs/hr)
Emissionsa
(gr/second)
NO2 at 25% load Annual 12.8 1.35E-2
NO2 at 100% load Annual 79.0 8.29E-2
NO2 at 25% load 1-hr 12.8 1.08
NO2 at 100% load 1-hr 79.0 6.64 a. Short-term NO2 emissions for Gen A entered as zero in AERMOD, because Gen A and Gen B will never run at the
same time.
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Table 2: Toxic Pollutant Emissions
Pollutant Averaging Period Emissions
(lbs/hr)
Emissionsa
(gr/second)
DEEP at 25% load Annual 8.08E-1 8.48E-4
DEEP at 100% load Annual 2.94E-1 3.08E-4
NO2 at 25% load 1-hr 12.8 1.08
NO2 at 100% load 1-hr 79.0 6.64 a. Short-term NO2 emissions for Gen A entered as zero in AERMOD, because Gen A and Gen B will never run at the
same time.
Modeling Parameters
Modeling was performed for two scenarios: the generators operating at 25% load and at 100% load.
The worst-case impacts were compared to their corresponding acceptable source impact levels (ASIL). The default ARM2 method will be used for NO2 modeling. Per the EPA AERMOD User’s Guide
Addendum section 3.3.6.3, the default upper and lower limits on the ambient ratio applied to the
modeled NO2 concentrations are 0.9 and 0.5 respectively.
Each generator was modeled as an individual point source. Table 2 presents a summary of the point
source modeling parameters used for each generator. These parameters are consistent with manufacturer
specifications and USEI’s installation plans.
Table 2: Point Source Modeling Parameters
Source Stack Height
(ft)
Stack
Diametera
(ft)
Stack
Temperature
(°F) at 25%
loadb
Stack
Temperature
(°F) at 100%
loadb
Stack Flow
Rate
(ACFM) at
25% loadb
Stack Flow
Rate (ACFM)
at 100% loadb
Generators
(A-C) 29 1.6 626 836 4,517 11,194
a. No correction was made to stack width for stack cap. Per discussion with Ecology, issues have been identified at or below 10% load. USEI
will not operate at loads below 25% and has a hinged stack cap that will open to a 45° angle or greater when the equipment is in operation. b. A 5% correction factor was applied to stack temperatures and flow rates from the manufacturers specifications per discussion with Ecology
to account for low ambient temperatures for part of the year.
4. Receptor Network
A receptor flagpole height of 1.5 meters was used in the analysis. The ambient air boundary was
considered to be the site boundary and the receptor grid extends beyond that. USEI is fenced to prevent
public access. A receptor grid was established based on Ecology’s “Guidance Document; First, Second,
and Third Tier Review of Toxic Air Pollutant Sources”.
• 12.5-m spacing from the source out to 150 meters
• 25-m spacing from 150 to 400 meters
• 50-m spacing from 400 to 900 meters
• 100-m spacing from 900 to 2,000 meters
• 300-m spacing from 2,000 to 4,500 meters
• 600-m spacing from 4,500 meters to 10,000 meters
US Electrodynamics December 2020
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5. Elevation Data
Spring Environmental ran AERMAP (version 18081) for the area and point sources and all receptors
using a NED file (datum NAD 83) covering the area between 47.875 to 48.50 degrees North latitude
and 119.25 to 120.125 degrees West longitude. Terrain data was obtained from the following website:
https://viewer.nationalmap.gov/basic/ and converted from the ArcGrid format to the GeoTIFF format.
Coordinates, elevations, hill heights, and flagpole heights for all receptors (datum WGS 84) are included
in the AERMOD input file (Appendix B).
6. Surface Data
Spring Environmental ran AERSURFACE (version 20060) to process land cover data to determine the
surface characteristics for use in AERMET. Landcover, impervious, and tree canopy data was obtained
from the following website: https://www.mrlc.gov/viewer/.
7. Meteorological Data
Per Ecology’s response to the modeling protocol, a Remote Automatic Weather Station (RAWS)
is available near the site. The station E6379 is located about 2 miles northwest of the site. Spring
Environmental downloaded the RAWS data from https://developers.synopticdata.com/ and
performed basic quality control on the data. The National Weather Service (NWS) data from the
Omak Airport was used to fill in any missing variables in the RAWS data. Spring Environmental
used RAWS data for years 2015-2019 from E6379 as “on-site” data in AERMET.
Supplemental surface data and one-minute ASOS data from the Omak Airport, station ID 94197, were
used to fill in missing information from the RAWS on-site data. The surface data was obtained at
ftp://ftp.ncdc.noaa.gov/pub/data/noaa and the one-minute ASOS data was obtained at
ftp://ftp.ncdc.noaa.gov/pub/data/asos-onemin/. Upper air data was obtained from Spokane International
Airport, site ID 04106, at http://esrl.noaa.gov/raobs/. Both stations are believed to be the best available
data for the Brewster area.
8. Land Use Classification
Most of the immediate area surrounding the facility is used for agriculture. More than 50% of the
surrounding area within a 3-km radius of the site is zoned other than industrial, commercial, or
multi-family residential; therefore, the land-use classification has been defined as Rural in
accordance with EPA1 guidelines.
9. Buildings
Three on-site buildings (designated 66 C, Building 2, and Power Building) have the potential to interact
with exhaust plumes from the generators, and were included in the modeling analysis. No other
buildings were within 145-feet of any proposed generator stack. See Appendix A for the building
locations. Building downwash was included in AERMOD using BPIP-Prime (version 04274).
10. Background Concentration
Background concentrations were obtained using
https://idahodeq.maps.arcgis.com/apps/MapSeries/index.html?appid=0c8a006e11fe4ec5939804b
873098dfe, a collaboration between the Idaho Department of Environmental Quality, Washington
1 40 C.F.R. §51 Appendix W, Section 7.2.3
US Electrodynamics December 2020
Air Dispersion Modeling Report Page 7
State Department of Ecology, and Oregon Department of Environmental Quality. The 1-hr NO2
value is 4.1 ppm and the annual NO2 value is 0.9 ppm.
Per WAC 173-460-150(2)(a), the background concentrations for toxic air pollutants do not need
to be included as this is a first-tier New Source Review.
11. Evaluation of Compliance with Standards
Modeling was performed based on the parameters defined in this report. Table 3 provides the modeled
off-site impacts for 1-hr and annual NO2 in comparison to NAAQS limits. Table 4 provides the modeled
off-site impacts for DEEP and NO2 in comparison to ASILs. The AERMOD output summary is
provided in Appendix B. An electronic copy of the AERMOD files will be provided.
Table 3: AERMOD Results Compared to NAAQS
Pollutant Averaging
Period
Modeled
Impact
(µg/m3)
Background
Value
(µg/m3)
Total
Impact
(µg/m3)
NAAQS
(µg/m3)
Standard
Exceeded?
(Yes/No)
NO2 at 25% load Annuala 0.043 1.69 1.73 100 No
NO2 at 100% load Annuala 0.104 1.69 1.80 100 No
NO2 at 25% load 1-hrb 90.51 7.71 98.2 188 No
NO2 at 100% load 1-hrb 153.70 7.71 161 188 No a. Modeled design value used is the maximum 1st highest.
b. Modeled design value used is the mean of maximum 8th highest.
Table 4: AERMOD Results Compared to ASIL
Pollutant Averaging
Period
Modeled Impact
(µg/m3) ASIL (µg/m3)
Standard
Exceeded?
(Yes/No)
DEEP at 25% load Annuala 2.98E-3 3.30E-3 No
DEEP at 100% load Annuala 4.30E-4 3.30E-3 No
NO2 at 25% load 1-hrb 98.9 470 No
NO2 at 100% load 1-hrb 189 470 No a. Modeled design value used is the maximum predicted concentration. b. Modeled design value used is the maximum predicted concentration.
12. Conclusion
The results of the refined modeling indicate that the addition of three emergency diesel generators
at USEI’s facility will not cause an exceedance of NAAQS for NO2 or ASILs for DEEP and NO2.
This Air Quality Monitoring Report was prepared by Elizabeth Cochran, P.E. under the direction of
Beth Fifield Hodgson, P.E. of Spring Environmental, Inc. Spring Environmental Inc.
1011 N. Cedar Street
Spokane, WA 99201-1914
Tel: (509) 328-7500
Fax: (509) 328-7501
US Electrodynamics December 2020
Air Dispersion Modeling Report Appendix A
Appendix A
Site Plan and Source Locations
US Electrodynamics December 2020
Air Dispersion Modeling Report Appendix A-1
Generator C
Building 2
Site Boundary
Building 66C
Generator A
Generator B
Power Building
US Electrodynamics December 2020
Air Dispersion Modeling Report Appendix B
Appendix B
AERMOD Input and Results Summary
DEEP at 25% load .......................................................B-1
DEEP at 100% load .....................................................B-6
1-hr NO2 at 25% load ................................................B-11
1-hr NO2 at 100% load ..............................................B-17
Annual NO2 at 25% load ...........................................B-23
Annual NO2 at 100% load .........................................B-28
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:08:03
PAGE 1
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** MODEL SETUP OPTIONS SUMMARY ***
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
**Model Is Setup For Calculation of Average CONCentration Values.
-- DEPOSITION LOGIC --
**NO GAS DEPOSITION Data Provided.
**NO PARTICLE DEPOSITION Data Provided.
**Model Uses NO DRY DEPLETION. DRYDPLT = F
**Model Uses NO WET DEPLETION. WETDPLT = F
**Model Uses RURAL Dispersion Only.
**Model Uses Regulatory DEFAULT Options:
1. Stack-tip Downwash.
2. Model Accounts for ELEVated Terrain Effects.
3. Use Calms Processing Routine.
4. Use Missing Data Processing Routine.
5. No Exponential Decay.
**Other Options Specified:
ADJ_U* - Use ADJ_U* option for SBL in AERMET
**Model Accepts FLAGPOLE Receptor Heights.
**The User Specified a Pollutant Type of: DEEP
**Model Calculates ANNUAL Averages Only
**This Run Includes: 3 Source(s); 1 Source Group(s); and 6840 Receptor(s)
with: 3 POINT(s), including
0 POINTCAP(s) and 0 POINTHOR(s)
and: 0 VOLUME source(s)
and: 0 AREA type source(s)
and: 0 LINE source(s)
and: 0 RLINE/RLINEXT source(s)
and: 0 OPENPIT source(s)
and: 0 BUOYANT LINE source(s) with 0 line(s)
**Model Set To Continue RUNning After the Setup Testing.
**The AERMET Input Meteorological Data Version Date: 19191
**Output Options Selected:
Model Outputs Tables of ANNUAL Averages by Receptor
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-1
Model Outputs External File(s) of High Values for Plotting (PLOTFILE Keyword)
Model Outputs Separate Summary File of High Ranked Values (SUMMFILE Keyword)
**NOTE: The Following Flags May Appear Following CONC Values: c for Calm Hours
m for Missing Hours
b for Both Calm and Missing Hours
**Misc. Inputs: Base Elev. for Pot. Temp. Profile (m MSL) = 396.20 ; Decay Coef. = 0.000 ; Rot. Angle = 0.0
Emission Units = GRAMS/SEC ; Emission Rate Unit Factor = 0.10000E+07
Output Units = MICROGRAMS/M**3
**Approximate Storage Requirements of Model = 3.7 MB of RAM.
**Input Runstream File: C:\Current Projects\USE-001\USEI 25% load_5yrs_DEEP.DTA
**Output Print File: C:\Current Projects\USE-001\USEI 25% load_5yrs_DEEP.LST
**File for Summary of Results: C:\Current Projects\USE-001\USEI 25% load_5yrs_DEEP.SUM
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:08:03
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** METEOROLOGICAL DAYS SELECTED FOR PROCESSING ***
(1=YES; 0=NO)
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
NOTE: METEOROLOGICAL DATA ACTUALLY PROCESSED WILL ALSO DEPEND ON WHAT IS INCLUDED IN THE DATA FILE.
*** UPPER BOUND OF FIRST THROUGH FIFTH WIND SPEED CATEGORIES ***
(METERS/SEC)
1.54, 3.09, 5.14, 8.23, 10.80,
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-2
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:08:03
PAGE 3
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** UP TO THE FIRST 24 HOURS OF METEOROLOGICAL DATA ***
Surface file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si Met Version: 19191
Profile file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si
Surface format: FREE
Profile format: FREE
Surface station no.: 94197 Upper air station no.: 4106
Name: OMAK AIRPORT, WA Name: UNKNOWN
Year: 2015 Year: 2015
First 24 hours of scalar data
YR MO DY JDY HR H0 U* W* DT/DZ ZICNV ZIMCH M-O LEN Z0 BOWEN ALBEDO REF WS WD HT REF TA HT
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
15 01 01 1 01 -10.1 0.134 -9.000 -9.000 -999. 117. 20.9 0.06 0.71 1.00 1.89 297. 10.0 262.0 2.0
15 01 01 1 02 -9.3 0.128 -9.000 -9.000 -999. 111. 20.0 0.06 0.71 1.00 1.82 277. 10.0 262.5 2.0
15 01 01 1 03 -7.1 0.111 -9.000 -9.000 -999. 89. 17.1 0.06 0.71 1.00 1.59 235. 10.0 261.4 2.0
15 01 01 1 04 -2.3 0.070 -9.000 -9.000 -999. 44. 13.0 0.06 0.71 1.00 0.82 141. 10.0 261.4 2.0
15 01 01 1 05 -10.3 0.135 -9.000 -9.000 -999. 120. 21.1 0.06 0.71 1.00 1.91 289. 10.0 261.4 2.0
15 01 01 1 06 -3.8 0.082 -9.000 -9.000 -999. 57. 13.1 0.06 0.71 1.00 1.14 189. 10.0 260.4 2.0
15 01 01 1 07 -6.9 0.110 -9.000 -9.000 -999. 87. 16.9 0.06 0.71 1.00 1.57 240. 10.0 261.4 2.0
15 01 01 1 08 -4.6 0.090 -9.000 -9.000 -999. 65. 14.0 0.06 0.71 1.00 1.28 181. 10.0 260.9 2.0
15 01 01 1 09 -16.2 0.178 -9.000 -9.000 -999. 180. 34.9 0.06 0.71 0.63 2.45 181. 10.0 263.1 2.0
15 01 01 1 10 -2.8 0.171 -9.000 -9.000 -999. 170. 156.9 0.06 0.71 0.45 2.27 191. 10.0 264.9 2.0
15 01 01 1 11 16.0 0.176 0.365 0.007 106. 176. -29.6 0.06 0.71 0.38 1.98 163. 10.0 265.9 2.0
15 01 01 1 12 27.0 0.205 0.512 0.007 174. 223. -27.9 0.06 0.71 0.35 2.30 160. 10.0 267.0 2.0
15 01 01 1 13 27.3 0.224 0.557 0.007 221. 255. -36.3 0.06 0.71 0.35 2.57 139. 10.0 268.8 2.0
15 01 01 1 14 16.8 0.262 0.491 0.010 246. 322. -93.5 0.06 0.71 0.38 3.17 140. 10.0 269.2 2.0
15 01 01 1 15 4.7 0.324 0.324 0.013 252. 444. -638.6 0.06 0.71 0.45 4.12 159. 10.0 269.2 2.0
15 01 01 1 16 -20.6 0.262 -9.000 -9.000 -999. 323. 76.1 0.06 0.71 0.62 3.52 166. 10.0 269.2 2.0
15 01 01 1 17 -25.1 0.245 -9.000 -9.000 -999. 291. 65.9 0.06 0.71 1.00 3.32 172. 10.0 268.1 2.0
15 01 01 1 18 -26.5 0.259 -9.000 -9.000 -999. 316. 73.5 0.06 0.71 1.00 3.50 179. 10.0 268.1 2.0
15 01 01 1 19 -29.3 0.286 -9.000 -9.000 -999. 368. 90.2 0.06 0.71 1.00 3.86 194. 10.0 268.1 2.0
15 01 01 1 20 -37.1 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 207. 10.0 268.8 2.0
15 01 01 1 21 -41.3 0.403 -9.000 -9.000 -999. 614. 178.7 0.06 0.71 1.00 5.36 210. 10.0 267.5 2.0
15 01 01 1 22 -37.4 0.364 -9.000 -9.000 -999. 528. 145.7 0.06 0.71 1.00 4.86 202. 10.0 267.0 2.0
15 01 01 1 23 -25.4 0.248 -9.000 -9.000 -999. 304. 67.5 0.06 0.71 1.00 3.36 200. 10.0 267.0 2.0
15 01 01 1 24 -37.3 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 190. 10.0 267.5 2.0
First hour of profile data
YR MO DY HR HEIGHT F WDIR WSPD AMB_TMP sigmaA sigmaW sigmaV
15 01 01 01 10.0 1 297. 1.89 262.1 99.0 -99.00 -99.00
F indicates top of profile (=1) or below (=0)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-3
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:08:03
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** POINT SOURCE DATA ***
NUMBER EMISSION RATE BASE STACK STACK STACK STACK BLDG URBAN CAP/ EMIS RATE
SOURCE PART. (GRAMS/SEC) X Y ELEV. HEIGHT TEMP. EXIT VEL. DIAMETER EXISTS SOURCE HOR SCALAR
ID CATS. (METERS) (METERS) (METERS) (METERS) (DEG.K) (M/SEC) (METERS) VARY BY
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
GEN_A 0 0.28300E-03 299602.2 5336087.8 383.3 8.84 603.15 11.41 0.49 YES NO NO
GEN_B 0 0.28300E-03 299603.3 5336082.2 383.2 8.84 603.15 11.41 0.49 YES NO NO
GEN_C 0 0.28300E-03 299379.8 5336241.9 385.1 8.84 603.15 11.41 0.49 YES NO NO
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:08:03
PAGE 4
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM ANNUAL RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF DEEP IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 0.00298 AT ( 299600.00, 5335950.00, 381.06, 381.06, 1.50) DC
2ND HIGHEST VALUE IS 0.00298 AT ( 299600.00, 5335962.50, 381.25, 381.25, 1.50) DC
3RD HIGHEST VALUE IS 0.00296 AT ( 299587.50, 5335962.50, 381.43, 381.43, 1.50) DC
4TH HIGHEST VALUE IS 0.00295 AT ( 299587.50, 5335950.00, 381.23, 381.23, 1.50) DC
5TH HIGHEST VALUE IS 0.00294 AT ( 299600.00, 5335937.50, 380.90, 380.90, 1.50) DC
6TH HIGHEST VALUE IS 0.00292 AT ( 299587.50, 5335975.00, 381.62, 381.62, 1.50) DC
7TH HIGHEST VALUE IS 0.00292 AT ( 299600.00, 5335975.00, 381.43, 381.43, 1.50) DC
8TH HIGHEST VALUE IS 0.00291 AT ( 299587.50, 5335937.50, 381.06, 381.06, 1.50) DC
9TH HIGHEST VALUE IS 0.00288 AT ( 299600.00, 5335925.00, 380.75, 380.75, 1.50) DC
10TH HIGHEST VALUE IS 0.00287 AT ( 299612.50, 5335950.00, 380.90, 380.90, 1.50) DC
*** RECEPTOR TYPES: GC = GRIDCART
GP = GRIDPOLR
DC = DISCCART
DP = DISCPOLR
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-4
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:08:03
PAGE 5
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** Message Summary : AERMOD Model Execution ***
--------- Summary of Total Messages --------
A Total of 0 Fatal Error Message(s)
A Total of 1 Warning Message(s)
A Total of 1086 Informational Message(s)
A Total of 43824 Hours Were Processed
A Total of 471 Calm Hours Identified
A Total of 615 Missing Hours Identified ( 1.40 Percent)
******** FATAL ERROR MESSAGES ********
*** NONE ***
******** WARNING MESSAGES ********
ME W187 1841 MEOPEN: ADJ_U* Option for Stable Low Winds used in AERMET
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-5
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:17:56
PAGE 1
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** MODEL SETUP OPTIONS SUMMARY ***
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
**Model Is Setup For Calculation of Average CONCentration Values.
-- DEPOSITION LOGIC --
**NO GAS DEPOSITION Data Provided.
**NO PARTICLE DEPOSITION Data Provided.
**Model Uses NO DRY DEPLETION. DRYDPLT = F
**Model Uses NO WET DEPLETION. WETDPLT = F
**Model Uses RURAL Dispersion Only.
**Model Uses Regulatory DEFAULT Options:
1. Stack-tip Downwash.
2. Model Accounts for ELEVated Terrain Effects.
3. Use Calms Processing Routine.
4. Use Missing Data Processing Routine.
5. No Exponential Decay.
**Other Options Specified:
ADJ_U* - Use ADJ_U* option for SBL in AERMET
**Model Accepts FLAGPOLE Receptor Heights.
**The User Specified a Pollutant Type of: DEEP
**Model Calculates ANNUAL Averages Only
**This Run Includes: 3 Source(s); 1 Source Group(s); and 6840 Receptor(s)
with: 3 POINT(s), including
0 POINTCAP(s) and 0 POINTHOR(s)
and: 0 VOLUME source(s)
and: 0 AREA type source(s)
and: 0 LINE source(s)
and: 0 RLINE/RLINEXT source(s)
and: 0 OPENPIT source(s)
and: 0 BUOYANT LINE source(s) with 0 line(s)
**Model Set To Continue RUNning After the Setup Testing.
**The AERMET Input Meteorological Data Version Date: 19191
**Output Options Selected:
Model Outputs Tables of ANNUAL Averages by Receptor
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-6
Model Outputs External File(s) of High Values for Plotting (PLOTFILE Keyword)
Model Outputs Separate Summary File of High Ranked Values (SUMMFILE Keyword)
**NOTE: The Following Flags May Appear Following CONC Values: c for Calm Hours
m for Missing Hours
b for Both Calm and Missing Hours
**Misc. Inputs: Base Elev. for Pot. Temp. Profile (m MSL) = 396.20 ; Decay Coef. = 0.000 ; Rot. Angle = 0.0
Emission Units = GRAMS/SEC ; Emission Rate Unit Factor = 0.10000E+07
Output Units = MICROGRAMS/M**3
**Approximate Storage Requirements of Model = 3.7 MB of RAM.
**Input Runstream File: C:\Current Projects\USE-001\USEI 100% load_5yrs_DEEP.DTA
**Output Print File: C:\Current Projects\USE-001\USEI 100% load_5yrs_DEEP.LST
**File for Summary of Results: C:\Current Projects\USE-001\USEI 100% load_5yrs_DEEP.SUM
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:17:56
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** METEOROLOGICAL DAYS SELECTED FOR PROCESSING ***
(1=YES; 0=NO)
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
NOTE: METEOROLOGICAL DATA ACTUALLY PROCESSED WILL ALSO DEPEND ON WHAT IS INCLUDED IN THE DATA FILE.
*** UPPER BOUND OF FIRST THROUGH FIFTH WIND SPEED CATEGORIES ***
(METERS/SEC)
1.54, 3.09, 5.14, 8.23, 10.80,
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-7
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:17:56
PAGE 3
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** UP TO THE FIRST 24 HOURS OF METEOROLOGICAL DATA ***
Surface file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si Met Version: 19191
Profile file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si
Surface format: FREE
Profile format: FREE
Surface station no.: 94197 Upper air station no.: 4106
Name: OMAK AIRPORT, WA Name: UNKNOWN
Year: 2015 Year: 2015
First 24 hours of scalar data
YR MO DY JDY HR H0 U* W* DT/DZ ZICNV ZIMCH M-O LEN Z0 BOWEN ALBEDO REF WS WD HT REF TA HT
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
15 01 01 1 01 -10.1 0.134 -9.000 -9.000 -999. 117. 20.9 0.06 0.71 1.00 1.89 297. 10.0 262.0 2.0
15 01 01 1 02 -9.3 0.128 -9.000 -9.000 -999. 111. 20.0 0.06 0.71 1.00 1.82 277. 10.0 262.5 2.0
15 01 01 1 03 -7.1 0.111 -9.000 -9.000 -999. 89. 17.1 0.06 0.71 1.00 1.59 235. 10.0 261.4 2.0
15 01 01 1 04 -2.3 0.070 -9.000 -9.000 -999. 44. 13.0 0.06 0.71 1.00 0.82 141. 10.0 261.4 2.0
15 01 01 1 05 -10.3 0.135 -9.000 -9.000 -999. 120. 21.1 0.06 0.71 1.00 1.91 289. 10.0 261.4 2.0
15 01 01 1 06 -3.8 0.082 -9.000 -9.000 -999. 57. 13.1 0.06 0.71 1.00 1.14 189. 10.0 260.4 2.0
15 01 01 1 07 -6.9 0.110 -9.000 -9.000 -999. 87. 16.9 0.06 0.71 1.00 1.57 240. 10.0 261.4 2.0
15 01 01 1 08 -4.6 0.090 -9.000 -9.000 -999. 65. 14.0 0.06 0.71 1.00 1.28 181. 10.0 260.9 2.0
15 01 01 1 09 -16.2 0.178 -9.000 -9.000 -999. 180. 34.9 0.06 0.71 0.63 2.45 181. 10.0 263.1 2.0
15 01 01 1 10 -2.8 0.171 -9.000 -9.000 -999. 170. 156.9 0.06 0.71 0.45 2.27 191. 10.0 264.9 2.0
15 01 01 1 11 16.0 0.176 0.365 0.007 106. 176. -29.6 0.06 0.71 0.38 1.98 163. 10.0 265.9 2.0
15 01 01 1 12 27.0 0.205 0.512 0.007 174. 223. -27.9 0.06 0.71 0.35 2.30 160. 10.0 267.0 2.0
15 01 01 1 13 27.3 0.224 0.557 0.007 221. 255. -36.3 0.06 0.71 0.35 2.57 139. 10.0 268.8 2.0
15 01 01 1 14 16.8 0.262 0.491 0.010 246. 322. -93.5 0.06 0.71 0.38 3.17 140. 10.0 269.2 2.0
15 01 01 1 15 4.7 0.324 0.324 0.013 252. 444. -638.6 0.06 0.71 0.45 4.12 159. 10.0 269.2 2.0
15 01 01 1 16 -20.6 0.262 -9.000 -9.000 -999. 323. 76.1 0.06 0.71 0.62 3.52 166. 10.0 269.2 2.0
15 01 01 1 17 -25.1 0.245 -9.000 -9.000 -999. 291. 65.9 0.06 0.71 1.00 3.32 172. 10.0 268.1 2.0
15 01 01 1 18 -26.5 0.259 -9.000 -9.000 -999. 316. 73.5 0.06 0.71 1.00 3.50 179. 10.0 268.1 2.0
15 01 01 1 19 -29.3 0.286 -9.000 -9.000 -999. 368. 90.2 0.06 0.71 1.00 3.86 194. 10.0 268.1 2.0
15 01 01 1 20 -37.1 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 207. 10.0 268.8 2.0
15 01 01 1 21 -41.3 0.403 -9.000 -9.000 -999. 614. 178.7 0.06 0.71 1.00 5.36 210. 10.0 267.5 2.0
15 01 01 1 22 -37.4 0.364 -9.000 -9.000 -999. 528. 145.7 0.06 0.71 1.00 4.86 202. 10.0 267.0 2.0
15 01 01 1 23 -25.4 0.248 -9.000 -9.000 -999. 304. 67.5 0.06 0.71 1.00 3.36 200. 10.0 267.0 2.0
15 01 01 1 24 -37.3 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 190. 10.0 267.5 2.0
First hour of profile data
YR MO DY HR HEIGHT F WDIR WSPD AMB_TMP sigmaA sigmaW sigmaV
15 01 01 01 10.0 1 297. 1.89 262.1 99.0 -99.00 -99.00
F indicates top of profile (=1) or below (=0)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-8
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:17:56
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** POINT SOURCE DATA ***
NUMBER EMISSION RATE BASE STACK STACK STACK STACK BLDG URBAN CAP/ EMIS RATE
SOURCE PART. (GRAMS/SEC) X Y ELEV. HEIGHT TEMP. EXIT VEL. DIAMETER EXISTS SOURCE HOR SCALAR
ID CATS. (METERS) (METERS) (METERS) (METERS) (DEG.K) (M/SEC) (METERS) VARY BY
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
GEN_A 0 0.10300E-03 299602.2 5336087.8 383.3 8.84 719.82 28.28 0.49 YES NO NO
GEN_B 0 0.10300E-03 299603.3 5336082.2 383.2 8.84 719.82 28.28 0.49 YES NO NO
GEN_C 0 0.10300E-03 299379.8 5336241.9 385.1 8.84 719.82 28.28 0.49 YES NO NO
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:17:56
PAGE 4
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM ANNUAL RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF DEEP IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 0.00043 AT ( 299587.50, 5335925.00, 380.91, 380.91, 1.50) DC
2ND HIGHEST VALUE IS 0.00043 AT ( 299587.50, 5335937.50, 381.06, 381.06, 1.50) DC
3RD HIGHEST VALUE IS 0.00043 AT ( 299587.50, 5335912.50, 380.77, 380.77, 1.50) DC
4TH HIGHEST VALUE IS 0.00042 AT ( 299600.00, 5335925.00, 380.75, 380.75, 1.50) DC
5TH HIGHEST VALUE IS 0.00042 AT ( 299587.50, 5335900.00, 380.65, 380.65, 1.50) DC
6TH HIGHEST VALUE IS 0.00042 AT ( 299600.00, 5335912.50, 380.61, 380.61, 1.50) DC
7TH HIGHEST VALUE IS 0.00042 AT ( 299587.50, 5335950.00, 381.23, 381.23, 1.50) DC
8TH HIGHEST VALUE IS 0.00042 AT ( 299575.00, 5335925.00, 381.11, 381.11, 1.50) DC
9TH HIGHEST VALUE IS 0.00042 AT ( 299600.00, 5335937.50, 380.90, 380.90, 1.50) DC
10TH HIGHEST VALUE IS 0.00042 AT ( 299575.00, 5335912.50, 380.96, 380.96, 1.50) DC
*** RECEPTOR TYPES: GC = GRIDCART
GP = GRIDPOLR
DC = DISCCART
DP = DISCPOLR
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-9
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:17:56
PAGE 5
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT RURAL ADJ_U*
*** Message Summary : AERMOD Model Execution ***
--------- Summary of Total Messages --------
A Total of 0 Fatal Error Message(s)
A Total of 1 Warning Message(s)
A Total of 1086 Informational Message(s)
A Total of 43824 Hours Were Processed
A Total of 471 Calm Hours Identified
A Total of 615 Missing Hours Identified ( 1.40 Percent)
******** FATAL ERROR MESSAGES ********
*** NONE ***
******** WARNING MESSAGES ********
ME W187 1841 MEOPEN: ADJ_U* Option for Stable Low Winds used in AERMET
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-10
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:13:51
PAGE 1
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** MODEL SETUP OPTIONS SUMMARY ***
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
**Model Is Setup For Calculation of Average CONCentration Values.
-- DEPOSITION LOGIC --
**NO GAS DEPOSITION Data Provided.
**NO PARTICLE DEPOSITION Data Provided.
**Model Uses NO DRY DEPLETION. DRYDPLT = F
**Model Uses NO WET DEPLETION. WETDPLT = F
**Model Uses RURAL Dispersion Only.
**Model Uses Regulatory DEFAULT Options:
1. Stack-tip Downwash.
2. Model Accounts for ELEVated Terrain Effects.
3. Use Calms Processing Routine.
4. Use Missing Data Processing Routine.
5. No Exponential Decay.
6. Ambient Ratio Method Ver 2 (ARM2) Used for NO2 Conversion
with a Minimum NO2/NOx Ratio of 0.500
and a Maximum NO2/NOx Ratio of 0.900
**Other Options Specified:
ADJ_U* - Use ADJ_U* option for SBL in AERMET
**Model Accepts FLAGPOLE Receptor Heights.
**The User Specified a Pollutant Type of: NO2
**Note that special processing requirements apply for the 1-hour NO2 NAAQS - check available guidance.
Model will process user-specified ranks of daily maximum 1-hour values averaged across the number of years modeled.
For annual NO2 NAAQS modeling, the multi-year maximum of PERIOD values can be simulated using the MULTYEAR keyword.
Multi-year PERIOD and 1-hour values should only be done in a single model run using the MULTYEAR option with a
single multi-year meteorological data file using STARTEND keyword.
**Model Calculates 1 Short Term Average(s) of: 1-HR
**This Run Includes: 2 Source(s); 1 Source Group(s); and 6840 Receptor(s)
with: 2 POINT(s), including
0 POINTCAP(s) and 0 POINTHOR(s)
and: 0 VOLUME source(s)
and: 0 AREA type source(s)
and: 0 LINE source(s)
and: 0 RLINE/RLINEXT source(s)
and: 0 OPENPIT source(s)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-11
and: 0 BUOYANT LINE source(s) with 0 line(s)
**Model Set To Continue RUNning After the Setup Testing.
**The AERMET Input Meteorological Data Version Date: 19191
**Output Options Selected:
Model Outputs Tables of Highest Short Term Values by Receptor (RECTABLE Keyword)
Model Outputs External File(s) of High Values for Plotting (PLOTFILE Keyword)
Model Outputs Separate Summary File of High Ranked Values (SUMMFILE Keyword)
**NOTE: The Following Flags May Appear Following CONC Values: c for Calm Hours
m for Missing Hours
b for Both Calm and Missing Hours
**Misc. Inputs: Base Elev. for Pot. Temp. Profile (m MSL) = 396.20 ; Decay Coef. = 0.000 ; Rot. Angle = 0.0
Emission Units = GRAMS/SEC ; Emission Rate Unit Factor = 0.10000E+07
Output Units = MICROGRAMS/M**3
**Approximate Storage Requirements of Model = 3.9 MB of RAM.
**Input Runstream File: C:\Current Projects\USE-001\USEI 25% load_5yrs_NO2.DTA
**Output Print File: C:\Current Projects\USE-001\USEI 25% load_5yrs_NO2.LST
**File for Summary of Results: C:\Current Projects\USE-001\USEI 25% load_5yrs_NO2.SUM
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:13:51
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** METEOROLOGICAL DAYS SELECTED FOR PROCESSING ***
(1=YES; 0=NO)
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
NOTE: METEOROLOGICAL DATA ACTUALLY PROCESSED WILL ALSO DEPEND ON WHAT IS INCLUDED IN THE DATA FILE.
*** UPPER BOUND OF FIRST THROUGH FIFTH WIND SPEED CATEGORIES ***
(METERS/SEC)
1.54, 3.09, 5.14, 8.23, 10.80,
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-12
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:13:51
PAGE 3
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** UP TO THE FIRST 24 HOURS OF METEOROLOGICAL DATA ***
Surface file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si Met Version: 19191
Profile file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si
Surface format: FREE
Profile format: FREE
Surface station no.: 94197 Upper air station no.: 4106
Name: OMAK AIRPORT, WA Name: UNKNOWN
Year: 2015 Year: 2015
First 24 hours of scalar data
YR MO DY JDY HR H0 U* W* DT/DZ ZICNV ZIMCH M-O LEN Z0 BOWEN ALBEDO REF WS WD HT REF TA HT
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
15 01 01 1 01 -10.1 0.134 -9.000 -9.000 -999. 117. 20.9 0.06 0.71 1.00 1.89 297. 10.0 262.0 2.0
15 01 01 1 02 -9.3 0.128 -9.000 -9.000 -999. 111. 20.0 0.06 0.71 1.00 1.82 277. 10.0 262.5 2.0
15 01 01 1 03 -7.1 0.111 -9.000 -9.000 -999. 89. 17.1 0.06 0.71 1.00 1.59 235. 10.0 261.4 2.0
15 01 01 1 04 -2.3 0.070 -9.000 -9.000 -999. 44. 13.0 0.06 0.71 1.00 0.82 141. 10.0 261.4 2.0
15 01 01 1 05 -10.3 0.135 -9.000 -9.000 -999. 120. 21.1 0.06 0.71 1.00 1.91 289. 10.0 261.4 2.0
15 01 01 1 06 -3.8 0.082 -9.000 -9.000 -999. 57. 13.1 0.06 0.71 1.00 1.14 189. 10.0 260.4 2.0
15 01 01 1 07 -6.9 0.110 -9.000 -9.000 -999. 87. 16.9 0.06 0.71 1.00 1.57 240. 10.0 261.4 2.0
15 01 01 1 08 -4.6 0.090 -9.000 -9.000 -999. 65. 14.0 0.06 0.71 1.00 1.28 181. 10.0 260.9 2.0
15 01 01 1 09 -16.2 0.178 -9.000 -9.000 -999. 180. 34.9 0.06 0.71 0.63 2.45 181. 10.0 263.1 2.0
15 01 01 1 10 -2.8 0.171 -9.000 -9.000 -999. 170. 156.9 0.06 0.71 0.45 2.27 191. 10.0 264.9 2.0
15 01 01 1 11 16.0 0.176 0.365 0.007 106. 176. -29.6 0.06 0.71 0.38 1.98 163. 10.0 265.9 2.0
15 01 01 1 12 27.0 0.205 0.512 0.007 174. 223. -27.9 0.06 0.71 0.35 2.30 160. 10.0 267.0 2.0
15 01 01 1 13 27.3 0.224 0.557 0.007 221. 255. -36.3 0.06 0.71 0.35 2.57 139. 10.0 268.8 2.0
15 01 01 1 14 16.8 0.262 0.491 0.010 246. 322. -93.5 0.06 0.71 0.38 3.17 140. 10.0 269.2 2.0
15 01 01 1 15 4.7 0.324 0.324 0.013 252. 444. -638.6 0.06 0.71 0.45 4.12 159. 10.0 269.2 2.0
15 01 01 1 16 -20.6 0.262 -9.000 -9.000 -999. 323. 76.1 0.06 0.71 0.62 3.52 166. 10.0 269.2 2.0
15 01 01 1 17 -25.1 0.245 -9.000 -9.000 -999. 291. 65.9 0.06 0.71 1.00 3.32 172. 10.0 268.1 2.0
15 01 01 1 18 -26.5 0.259 -9.000 -9.000 -999. 316. 73.5 0.06 0.71 1.00 3.50 179. 10.0 268.1 2.0
15 01 01 1 19 -29.3 0.286 -9.000 -9.000 -999. 368. 90.2 0.06 0.71 1.00 3.86 194. 10.0 268.1 2.0
15 01 01 1 20 -37.1 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 207. 10.0 268.8 2.0
15 01 01 1 21 -41.3 0.403 -9.000 -9.000 -999. 614. 178.7 0.06 0.71 1.00 5.36 210. 10.0 267.5 2.0
15 01 01 1 22 -37.4 0.364 -9.000 -9.000 -999. 528. 145.7 0.06 0.71 1.00 4.86 202. 10.0 267.0 2.0
15 01 01 1 23 -25.4 0.248 -9.000 -9.000 -999. 304. 67.5 0.06 0.71 1.00 3.36 200. 10.0 267.0 2.0
15 01 01 1 24 -37.3 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 190. 10.0 267.5 2.0
First hour of profile data
YR MO DY HR HEIGHT F WDIR WSPD AMB_TMP sigmaA sigmaW sigmaV
15 01 01 01 10.0 1 297. 1.89 262.1 99.0 -99.00 -99.00
F indicates top of profile (=1) or below (=0)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-13
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:13:51
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** POINT SOURCE DATA ***
NUMBER EMISSION RATE BASE STACK STACK STACK STACK BLDG URBAN CAP/ EMIS RATE
SOURCE PART. (GRAMS/SEC) X Y ELEV. HEIGHT TEMP. EXIT VEL. DIAMETER EXISTS SOURCE HOR SCALAR
ID CATS. (METERS) (METERS) (METERS) (METERS) (DEG.K) (M/SEC) (METERS) VARY BY
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
GEN_B 0 0.54000E+00 299603.3 5336082.2 383.2 8.84 603.15 11.41 0.49 YES NO NO
GEN_C 0 0.54000E+00 299379.8 5336241.9 385.1 8.84 603.15 11.41 0.49 YES NO NO
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:13:51
PAGE 4
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM 1ST-HIGHEST MAX DAILY 1-HR RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF NO2 IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 98.93557 AT ( 299500.00, 5336312.50, 385.64, 385.64, 1.50) DC
2ND HIGHEST VALUE IS 97.95387 AT ( 299512.50, 5336312.50, 385.71, 385.71, 1.50) DC
3RD HIGHEST VALUE IS 95.32878 AT ( 299525.00, 5336312.50, 385.69, 385.69, 1.50) DC
4TH HIGHEST VALUE IS 93.86038 AT ( 299475.00, 5336325.00, 385.67, 385.67, 1.50) DC
5TH HIGHEST VALUE IS 93.46279 AT ( 299537.50, 5336312.50, 385.55, 385.55, 1.50) DC
6TH HIGHEST VALUE IS 92.54896 AT ( 299500.00, 5336325.00, 385.68, 385.68, 1.50) DC
7TH HIGHEST VALUE IS 91.92030 AT ( 299462.50, 5336325.00, 385.65, 385.65, 1.50) DC
8TH HIGHEST VALUE IS 91.91136 AT ( 299487.50, 5336325.00, 385.68, 385.68, 1.50) DC
9TH HIGHEST VALUE IS 91.80646 AT ( 299512.50, 5336325.00, 385.68, 385.68, 1.50) DC
10TH HIGHEST VALUE IS 91.65529 AT ( 299450.00, 5336325.00, 385.61, 385.61, 1.50) DC
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-14
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:13:51
PAGE 5
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM 8TH-HIGHEST MAX DAILY 1-HR RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF NO2 IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 90.50503 AT ( 299500.00, 5336312.50, 385.64, 385.64, 1.50) DC
2ND HIGHEST VALUE IS 88.01664 AT ( 299512.50, 5336312.50, 385.71, 385.71, 1.50) DC
3RD HIGHEST VALUE IS 85.92315 AT ( 299525.00, 5336312.50, 385.69, 385.69, 1.50) DC
4TH HIGHEST VALUE IS 84.81408 AT ( 299475.00, 5336325.00, 385.67, 385.67, 1.50) DC
5TH HIGHEST VALUE IS 82.75688 AT ( 299487.50, 5336325.00, 385.68, 385.68, 1.50) DC
6TH HIGHEST VALUE IS 82.67158 AT ( 299462.50, 5336325.00, 385.65, 385.65, 1.50) DC
7TH HIGHEST VALUE IS 82.47136 AT ( 299512.50, 5336325.00, 385.68, 385.68, 1.50) DC
8TH HIGHEST VALUE IS 82.06458 AT ( 299525.00, 5336325.00, 385.58, 385.58, 1.50) DC
9TH HIGHEST VALUE IS 81.80487 AT ( 299450.00, 5336325.00, 385.61, 385.61, 1.50) DC
10TH HIGHEST VALUE IS 81.38006 AT ( 299500.00, 5336325.00, 385.68, 385.68, 1.50) DC
*** RECEPTOR TYPES: GC = GRIDCART
GP = GRIDPOLR
DC = DISCCART
DP = DISCPOLR
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-15
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:13:51
PAGE 6
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** Message Summary : AERMOD Model Execution ***
--------- Summary of Total Messages --------
A Total of 0 Fatal Error Message(s)
A Total of 1 Warning Message(s)
A Total of 1086 Informational Message(s)
A Total of 43824 Hours Were Processed
A Total of 471 Calm Hours Identified
A Total of 615 Missing Hours Identified ( 1.40 Percent)
******** FATAL ERROR MESSAGES ********
*** NONE ***
******** WARNING MESSAGES ********
ME W187 1809 MEOPEN: ADJ_U* Option for Stable Low Winds used in AERMET
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-16
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:13:19
PAGE 1
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** MODEL SETUP OPTIONS SUMMARY ***
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
**Model Is Setup For Calculation of Average CONCentration Values.
-- DEPOSITION LOGIC --
**NO GAS DEPOSITION Data Provided.
**NO PARTICLE DEPOSITION Data Provided.
**Model Uses NO DRY DEPLETION. DRYDPLT = F
**Model Uses NO WET DEPLETION. WETDPLT = F
**Model Uses RURAL Dispersion Only.
**Model Uses Regulatory DEFAULT Options:
1. Stack-tip Downwash.
2. Model Accounts for ELEVated Terrain Effects.
3. Use Calms Processing Routine.
4. Use Missing Data Processing Routine.
5. No Exponential Decay.
6. Ambient Ratio Method Ver 2 (ARM2) Used for NO2 Conversion
with a Minimum NO2/NOx Ratio of 0.500
and a Maximum NO2/NOx Ratio of 0.900
**Other Options Specified:
ADJ_U* - Use ADJ_U* option for SBL in AERMET
**Model Accepts FLAGPOLE Receptor Heights.
**The User Specified a Pollutant Type of: NO2
**Note that special processing requirements apply for the 1-hour NO2 NAAQS - check available guidance.
Model will process user-specified ranks of daily maximum 1-hour values averaged across the number of years modeled.
For annual NO2 NAAQS modeling, the multi-year maximum of PERIOD values can be simulated using the MULTYEAR keyword.
Multi-year PERIOD and 1-hour values should only be done in a single model run using the MULTYEAR option with a
single multi-year meteorological data file using STARTEND keyword.
**Model Calculates 1 Short Term Average(s) of: 1-HR
**This Run Includes: 2 Source(s); 1 Source Group(s); and 6840 Receptor(s)
with: 2 POINT(s), including
0 POINTCAP(s) and 0 POINTHOR(s)
and: 0 VOLUME source(s)
and: 0 AREA type source(s)
and: 0 LINE source(s)
and: 0 RLINE/RLINEXT source(s)
and: 0 OPENPIT source(s)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-17
and: 0 BUOYANT LINE source(s) with 0 line(s)
**Model Set To Continue RUNning After the Setup Testing.
**The AERMET Input Meteorological Data Version Date: 19191
**Output Options Selected:
Model Outputs Tables of Highest Short Term Values by Receptor (RECTABLE Keyword)
Model Outputs External File(s) of High Values for Plotting (PLOTFILE Keyword)
Model Outputs Separate Summary File of High Ranked Values (SUMMFILE Keyword)
**NOTE: The Following Flags May Appear Following CONC Values: c for Calm Hours
m for Missing Hours
b for Both Calm and Missing Hours
**Misc. Inputs: Base Elev. for Pot. Temp. Profile (m MSL) = 396.20 ; Decay Coef. = 0.000 ; Rot. Angle = 0.0
Emission Units = GRAMS/SEC ; Emission Rate Unit Factor = 0.10000E+07
Output Units = MICROGRAMS/M**3
**Approximate Storage Requirements of Model = 3.9 MB of RAM.
**Input Runstream File: C:\Current Projects\USE-001\USEI 100% load_5yrs_NO2.DTA
**Output Print File: C:\Current Projects\USE-001\USEI 100% load_5yrs_NO2.LST
**File for Summary of Results: C:\Current Projects\USE-001\USEI 100% load_5yrs_NO2.SUM
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:13:19
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** METEOROLOGICAL DAYS SELECTED FOR PROCESSING ***
(1=YES; 0=NO)
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
NOTE: METEOROLOGICAL DATA ACTUALLY PROCESSED WILL ALSO DEPEND ON WHAT IS INCLUDED IN THE DATA FILE.
*** UPPER BOUND OF FIRST THROUGH FIFTH WIND SPEED CATEGORIES ***
(METERS/SEC)
1.54, 3.09, 5.14, 8.23, 10.80,
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-18
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:13:19
PAGE 3
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** UP TO THE FIRST 24 HOURS OF METEOROLOGICAL DATA ***
Surface file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si Met Version: 19191
Profile file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si
Surface format: FREE
Profile format: FREE
Surface station no.: 94197 Upper air station no.: 4106
Name: OMAK AIRPORT, WA Name: UNKNOWN
Year: 2015 Year: 2015
First 24 hours of scalar data
YR MO DY JDY HR H0 U* W* DT/DZ ZICNV ZIMCH M-O LEN Z0 BOWEN ALBEDO REF WS WD HT REF TA HT
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
15 01 01 1 01 -10.1 0.134 -9.000 -9.000 -999. 117. 20.9 0.06 0.71 1.00 1.89 297. 10.0 262.0 2.0
15 01 01 1 02 -9.3 0.128 -9.000 -9.000 -999. 111. 20.0 0.06 0.71 1.00 1.82 277. 10.0 262.5 2.0
15 01 01 1 03 -7.1 0.111 -9.000 -9.000 -999. 89. 17.1 0.06 0.71 1.00 1.59 235. 10.0 261.4 2.0
15 01 01 1 04 -2.3 0.070 -9.000 -9.000 -999. 44. 13.0 0.06 0.71 1.00 0.82 141. 10.0 261.4 2.0
15 01 01 1 05 -10.3 0.135 -9.000 -9.000 -999. 120. 21.1 0.06 0.71 1.00 1.91 289. 10.0 261.4 2.0
15 01 01 1 06 -3.8 0.082 -9.000 -9.000 -999. 57. 13.1 0.06 0.71 1.00 1.14 189. 10.0 260.4 2.0
15 01 01 1 07 -6.9 0.110 -9.000 -9.000 -999. 87. 16.9 0.06 0.71 1.00 1.57 240. 10.0 261.4 2.0
15 01 01 1 08 -4.6 0.090 -9.000 -9.000 -999. 65. 14.0 0.06 0.71 1.00 1.28 181. 10.0 260.9 2.0
15 01 01 1 09 -16.2 0.178 -9.000 -9.000 -999. 180. 34.9 0.06 0.71 0.63 2.45 181. 10.0 263.1 2.0
15 01 01 1 10 -2.8 0.171 -9.000 -9.000 -999. 170. 156.9 0.06 0.71 0.45 2.27 191. 10.0 264.9 2.0
15 01 01 1 11 16.0 0.176 0.365 0.007 106. 176. -29.6 0.06 0.71 0.38 1.98 163. 10.0 265.9 2.0
15 01 01 1 12 27.0 0.205 0.512 0.007 174. 223. -27.9 0.06 0.71 0.35 2.30 160. 10.0 267.0 2.0
15 01 01 1 13 27.3 0.224 0.557 0.007 221. 255. -36.3 0.06 0.71 0.35 2.57 139. 10.0 268.8 2.0
15 01 01 1 14 16.8 0.262 0.491 0.010 246. 322. -93.5 0.06 0.71 0.38 3.17 140. 10.0 269.2 2.0
15 01 01 1 15 4.7 0.324 0.324 0.013 252. 444. -638.6 0.06 0.71 0.45 4.12 159. 10.0 269.2 2.0
15 01 01 1 16 -20.6 0.262 -9.000 -9.000 -999. 323. 76.1 0.06 0.71 0.62 3.52 166. 10.0 269.2 2.0
15 01 01 1 17 -25.1 0.245 -9.000 -9.000 -999. 291. 65.9 0.06 0.71 1.00 3.32 172. 10.0 268.1 2.0
15 01 01 1 18 -26.5 0.259 -9.000 -9.000 -999. 316. 73.5 0.06 0.71 1.00 3.50 179. 10.0 268.1 2.0
15 01 01 1 19 -29.3 0.286 -9.000 -9.000 -999. 368. 90.2 0.06 0.71 1.00 3.86 194. 10.0 268.1 2.0
15 01 01 1 20 -37.1 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 207. 10.0 268.8 2.0
15 01 01 1 21 -41.3 0.403 -9.000 -9.000 -999. 614. 178.7 0.06 0.71 1.00 5.36 210. 10.0 267.5 2.0
15 01 01 1 22 -37.4 0.364 -9.000 -9.000 -999. 528. 145.7 0.06 0.71 1.00 4.86 202. 10.0 267.0 2.0
15 01 01 1 23 -25.4 0.248 -9.000 -9.000 -999. 304. 67.5 0.06 0.71 1.00 3.36 200. 10.0 267.0 2.0
15 01 01 1 24 -37.3 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 190. 10.0 267.5 2.0
First hour of profile data
YR MO DY HR HEIGHT F WDIR WSPD AMB_TMP sigmaA sigmaW sigmaV
15 01 01 01 10.0 1 297. 1.89 262.1 99.0 -99.00 -99.00
F indicates top of profile (=1) or below (=0)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-19
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:13:19
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** POINT SOURCE DATA ***
NUMBER EMISSION RATE BASE STACK STACK STACK STACK BLDG URBAN CAP/ EMIS RATE
SOURCE PART. (GRAMS/SEC) X Y ELEV. HEIGHT TEMP. EXIT VEL. DIAMETER EXISTS SOURCE HOR SCALAR
ID CATS. (METERS) (METERS) (METERS) (METERS) (DEG.K) (M/SEC) (METERS) VARY BY
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
GEN_B 0 0.33200E+01 299603.3 5336082.2 383.2 8.84 719.82 28.28 0.49 YES NO NO
GEN_C 0 0.33200E+01 299379.8 5336241.9 385.1 8.84 719.82 28.28 0.49 YES NO NO
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:13:19
PAGE 4
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM 1ST-HIGHEST MAX DAILY 1-HR RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF NO2 IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 189.43753 AT ( 299450.00, 5336325.00, 385.61, 385.61, 1.50) DC
2ND HIGHEST VALUE IS 181.15248 AT ( 299462.50, 5336325.00, 385.65, 385.65, 1.50) DC
3RD HIGHEST VALUE IS 180.41633 AT ( 299425.00, 5336337.50, 385.81, 385.81, 1.50) DC
4TH HIGHEST VALUE IS 176.72352 AT ( 298000.00, 5336400.00, 428.36, 562.66, 1.50) DC
5TH HIGHEST VALUE IS 169.47156 AT ( 299437.50, 5336337.50, 385.77, 385.77, 1.50) DC
6TH HIGHEST VALUE IS 166.86432 AT ( 299450.00, 5336337.50, 385.79, 385.79, 1.50) DC
7TH HIGHEST VALUE IS 162.72634 AT ( 299462.50, 5336337.50, 385.78, 385.78, 1.50) DC
8TH HIGHEST VALUE IS 160.83452 AT ( 299437.50, 5336350.00, 385.96, 385.96, 1.50) DC
9TH HIGHEST VALUE IS 159.78756 AT ( 299475.00, 5336325.00, 385.67, 385.67, 1.50) DC
10TH HIGHEST VALUE IS 157.11738 AT ( 299475.00, 5336337.50, 385.74, 385.74, 1.50) DC
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-20
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:13:19
PAGE 5
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM 8TH-HIGHEST MAX DAILY 1-HR RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF NO2 IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 153.69949 AT ( 299450.00, 5336325.00, 385.61, 385.61, 1.50) DC
2ND HIGHEST VALUE IS 148.81732 AT ( 299437.50, 5336337.50, 385.77, 385.77, 1.50) DC
3RD HIGHEST VALUE IS 145.05537 AT ( 299425.00, 5336337.50, 385.81, 385.81, 1.50) DC
4TH HIGHEST VALUE IS 142.93136 AT ( 299450.00, 5336337.50, 385.79, 385.79, 1.50) DC
5TH HIGHEST VALUE IS 141.50364 AT ( 299462.50, 5336325.00, 385.65, 385.65, 1.50) DC
6TH HIGHEST VALUE IS 141.12328 AT ( 299437.50, 5336350.00, 385.96, 385.96, 1.50) DC
7TH HIGHEST VALUE IS 139.78979 AT ( 299462.50, 5336337.50, 385.78, 385.78, 1.50) DC
8TH HIGHEST VALUE IS 139.60225 AT ( 299475.00, 5336325.00, 385.67, 385.67, 1.50) DC
9TH HIGHEST VALUE IS 139.42097 AT ( 299450.00, 5336350.00, 385.95, 385.95, 1.50) DC
10TH HIGHEST VALUE IS 139.16589 AT ( 299412.50, 5336337.50, 385.85, 385.85, 1.50) DC
*** RECEPTOR TYPES: GC = GRIDCART
GP = GRIDPOLR
DC = DISCCART
DP = DISCPOLR
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-21
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:13:19
PAGE 6
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** Message Summary : AERMOD Model Execution ***
--------- Summary of Total Messages --------
A Total of 0 Fatal Error Message(s)
A Total of 1 Warning Message(s)
A Total of 1086 Informational Message(s)
A Total of 43824 Hours Were Processed
A Total of 471 Calm Hours Identified
A Total of 615 Missing Hours Identified ( 1.40 Percent)
******** FATAL ERROR MESSAGES ********
*** NONE ***
******** WARNING MESSAGES ********
ME W187 1809 MEOPEN: ADJ_U* Option for Stable Low Winds used in AERMET
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-22
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:25:32
PAGE 1
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** MODEL SETUP OPTIONS SUMMARY ***
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
**Model Is Setup For Calculation of Average CONCentration Values.
-- DEPOSITION LOGIC --
**NO GAS DEPOSITION Data Provided.
**NO PARTICLE DEPOSITION Data Provided.
**Model Uses NO DRY DEPLETION. DRYDPLT = F
**Model Uses NO WET DEPLETION. WETDPLT = F
**Model Uses RURAL Dispersion Only.
**Model Uses Regulatory DEFAULT Options:
1. Stack-tip Downwash.
2. Model Accounts for ELEVated Terrain Effects.
3. Use Calms Processing Routine.
4. Use Missing Data Processing Routine.
5. No Exponential Decay.
6. Ambient Ratio Method Ver 2 (ARM2) Used for NO2 Conversion
with a Minimum NO2/NOx Ratio of 0.500
and a Maximum NO2/NOx Ratio of 0.900
**Other Options Specified:
ADJ_U* - Use ADJ_U* option for SBL in AERMET
**Model Accepts FLAGPOLE Receptor Heights.
**The User Specified a Pollutant Type of: NO2
**NOTE: Special processing requirements applicable for the 1-hour NO2 NAAQS have been disabled!!!
User has specified non-standard averaging periods:
High ranked 1-hour values are NOT averaged across the number of years modeled, and
complete years of data are NOT required.
**Model Calculates ANNUAL Averages Only
**This Run Includes: 3 Source(s); 1 Source Group(s); and 6840 Receptor(s)
with: 3 POINT(s), including
0 POINTCAP(s) and 0 POINTHOR(s)
and: 0 VOLUME source(s)
and: 0 AREA type source(s)
and: 0 LINE source(s)
and: 0 RLINE/RLINEXT source(s)
and: 0 OPENPIT source(s)
and: 0 BUOYANT LINE source(s) with 0 line(s)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-23
**Model Set To Continue RUNning After the Setup Testing.
**The AERMET Input Meteorological Data Version Date: 19191
**Output Options Selected:
Model Outputs Tables of ANNUAL Averages by Receptor
Model Outputs External File(s) of High Values for Plotting (PLOTFILE Keyword)
Model Outputs Separate Summary File of High Ranked Values (SUMMFILE Keyword)
**NOTE: The Following Flags May Appear Following CONC Values: c for Calm Hours
m for Missing Hours
b for Both Calm and Missing Hours
**Misc. Inputs: Base Elev. for Pot. Temp. Profile (m MSL) = 396.20 ; Decay Coef. = 0.000 ; Rot. Angle = 0.0
Emission Units = GRAMS/SEC ; Emission Rate Unit Factor = 0.10000E+07
Output Units = MICROGRAMS/M**3
**Approximate Storage Requirements of Model = 3.7 MB of RAM.
**Input Runstream File: C:\Current Projects\USE-001\USEI 25% load annual NO2_5yrs_NO2.DTA
**Output Print File: C:\Current Projects\USE-001\USEI 25% load annual NO2_5yrs_NO2.LST
**File for Summary of Results: C:\Current Projects\USE-001\USEI 25% load annual NO2_5yrs_NO2.SUM
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:25:32
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** METEOROLOGICAL DAYS SELECTED FOR PROCESSING ***
(1=YES; 0=NO)
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
NOTE: METEOROLOGICAL DATA ACTUALLY PROCESSED WILL ALSO DEPEND ON WHAT IS INCLUDED IN THE DATA FILE.
*** UPPER BOUND OF FIRST THROUGH FIFTH WIND SPEED CATEGORIES ***
(METERS/SEC)
1.54, 3.09, 5.14, 8.23, 10.80,
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-24
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:25:32
PAGE 3
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** UP TO THE FIRST 24 HOURS OF METEOROLOGICAL DATA ***
Surface file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si Met Version: 19191
Profile file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si
Surface format: FREE
Profile format: FREE
Surface station no.: 94197 Upper air station no.: 4106
Name: OMAK AIRPORT, WA Name: UNKNOWN
Year: 2015 Year: 2015
First 24 hours of scalar data
YR MO DY JDY HR H0 U* W* DT/DZ ZICNV ZIMCH M-O LEN Z0 BOWEN ALBEDO REF WS WD HT REF TA HT
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
15 01 01 1 01 -10.1 0.134 -9.000 -9.000 -999. 117. 20.9 0.06 0.71 1.00 1.89 297. 10.0 262.0 2.0
15 01 01 1 02 -9.3 0.128 -9.000 -9.000 -999. 111. 20.0 0.06 0.71 1.00 1.82 277. 10.0 262.5 2.0
15 01 01 1 03 -7.1 0.111 -9.000 -9.000 -999. 89. 17.1 0.06 0.71 1.00 1.59 235. 10.0 261.4 2.0
15 01 01 1 04 -2.3 0.070 -9.000 -9.000 -999. 44. 13.0 0.06 0.71 1.00 0.82 141. 10.0 261.4 2.0
15 01 01 1 05 -10.3 0.135 -9.000 -9.000 -999. 120. 21.1 0.06 0.71 1.00 1.91 289. 10.0 261.4 2.0
15 01 01 1 06 -3.8 0.082 -9.000 -9.000 -999. 57. 13.1 0.06 0.71 1.00 1.14 189. 10.0 260.4 2.0
15 01 01 1 07 -6.9 0.110 -9.000 -9.000 -999. 87. 16.9 0.06 0.71 1.00 1.57 240. 10.0 261.4 2.0
15 01 01 1 08 -4.6 0.090 -9.000 -9.000 -999. 65. 14.0 0.06 0.71 1.00 1.28 181. 10.0 260.9 2.0
15 01 01 1 09 -16.2 0.178 -9.000 -9.000 -999. 180. 34.9 0.06 0.71 0.63 2.45 181. 10.0 263.1 2.0
15 01 01 1 10 -2.8 0.171 -9.000 -9.000 -999. 170. 156.9 0.06 0.71 0.45 2.27 191. 10.0 264.9 2.0
15 01 01 1 11 16.0 0.176 0.365 0.007 106. 176. -29.6 0.06 0.71 0.38 1.98 163. 10.0 265.9 2.0
15 01 01 1 12 27.0 0.205 0.512 0.007 174. 223. -27.9 0.06 0.71 0.35 2.30 160. 10.0 267.0 2.0
15 01 01 1 13 27.3 0.224 0.557 0.007 221. 255. -36.3 0.06 0.71 0.35 2.57 139. 10.0 268.8 2.0
15 01 01 1 14 16.8 0.262 0.491 0.010 246. 322. -93.5 0.06 0.71 0.38 3.17 140. 10.0 269.2 2.0
15 01 01 1 15 4.7 0.324 0.324 0.013 252. 444. -638.6 0.06 0.71 0.45 4.12 159. 10.0 269.2 2.0
15 01 01 1 16 -20.6 0.262 -9.000 -9.000 -999. 323. 76.1 0.06 0.71 0.62 3.52 166. 10.0 269.2 2.0
15 01 01 1 17 -25.1 0.245 -9.000 -9.000 -999. 291. 65.9 0.06 0.71 1.00 3.32 172. 10.0 268.1 2.0
15 01 01 1 18 -26.5 0.259 -9.000 -9.000 -999. 316. 73.5 0.06 0.71 1.00 3.50 179. 10.0 268.1 2.0
15 01 01 1 19 -29.3 0.286 -9.000 -9.000 -999. 368. 90.2 0.06 0.71 1.00 3.86 194. 10.0 268.1 2.0
15 01 01 1 20 -37.1 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 207. 10.0 268.8 2.0
15 01 01 1 21 -41.3 0.403 -9.000 -9.000 -999. 614. 178.7 0.06 0.71 1.00 5.36 210. 10.0 267.5 2.0
15 01 01 1 22 -37.4 0.364 -9.000 -9.000 -999. 528. 145.7 0.06 0.71 1.00 4.86 202. 10.0 267.0 2.0
15 01 01 1 23 -25.4 0.248 -9.000 -9.000 -999. 304. 67.5 0.06 0.71 1.00 3.36 200. 10.0 267.0 2.0
15 01 01 1 24 -37.3 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 190. 10.0 267.5 2.0
First hour of profile data
YR MO DY HR HEIGHT F WDIR WSPD AMB_TMP sigmaA sigmaW sigmaV
15 01 01 01 10.0 1 297. 1.89 262.1 99.0 -99.00 -99.00
F indicates top of profile (=1) or below (=0)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-25
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:25:32
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** POINT SOURCE DATA ***
NUMBER EMISSION RATE BASE STACK STACK STACK STACK BLDG URBAN CAP/ EMIS RATE
SOURCE PART. (GRAMS/SEC) X Y ELEV. HEIGHT TEMP. EXIT VEL. DIAMETER EXISTS SOURCE HOR SCALAR
ID CATS. (METERS) (METERS) (METERS) (METERS) (DEG.K) (M/SEC) (METERS) VARY BY
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
GEN_A 0 0.45000E-02 299602.2 5336087.8 383.3 8.84 603.15 11.41 0.49 YES NO NO
GEN_B 0 0.45000E-02 299603.3 5336082.2 383.2 8.84 603.15 11.41 0.49 YES NO NO
GEN_C 0 0.45000E-02 299379.8 5336241.9 385.1 8.84 603.15 11.41 0.49 YES NO NO
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:25:32
PAGE 4
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM ANNUAL RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF NO2 IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 0.04263 AT ( 299600.00, 5335950.00, 381.06, 381.06, 1.50) DC
2ND HIGHEST VALUE IS 0.04263 AT ( 299600.00, 5335962.50, 381.25, 381.25, 1.50) DC
3RD HIGHEST VALUE IS 0.04235 AT ( 299587.50, 5335962.50, 381.43, 381.43, 1.50) DC
4TH HIGHEST VALUE IS 0.04221 AT ( 299587.50, 5335950.00, 381.23, 381.23, 1.50) DC
5TH HIGHEST VALUE IS 0.04207 AT ( 299600.00, 5335937.50, 380.90, 380.90, 1.50) DC
6TH HIGHEST VALUE IS 0.04178 AT ( 299587.50, 5335975.00, 381.62, 381.62, 1.50) DC
7TH HIGHEST VALUE IS 0.04175 AT ( 299600.00, 5335975.00, 381.43, 381.43, 1.50) DC
8TH HIGHEST VALUE IS 0.04159 AT ( 299587.50, 5335937.50, 381.06, 381.06, 1.50) DC
9TH HIGHEST VALUE IS 0.04115 AT ( 299600.00, 5335925.00, 380.75, 380.75, 1.50) DC
10TH HIGHEST VALUE IS 0.04103 AT ( 299612.50, 5335950.00, 380.90, 380.90, 1.50) DC
*** RECEPTOR TYPES: GC = GRIDCART
GP = GRIDPOLR
DC = DISCCART
DP = DISCPOLR
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-26
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 25% load *** 07:25:32
PAGE 5
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** Message Summary : AERMOD Model Execution ***
--------- Summary of Total Messages --------
A Total of 0 Fatal Error Message(s)
A Total of 1 Warning Message(s)
A Total of 1086 Informational Message(s)
A Total of 43824 Hours Were Processed
A Total of 471 Calm Hours Identified
A Total of 615 Missing Hours Identified ( 1.40 Percent)
******** FATAL ERROR MESSAGES ********
*** NONE ***
******** WARNING MESSAGES ********
ME W187 1842 MEOPEN: ADJ_U* Option for Stable Low Winds used in AERMET
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-27
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:34:17
PAGE 1
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** MODEL SETUP OPTIONS SUMMARY ***
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
**Model Is Setup For Calculation of Average CONCentration Values.
-- DEPOSITION LOGIC --
**NO GAS DEPOSITION Data Provided.
**NO PARTICLE DEPOSITION Data Provided.
**Model Uses NO DRY DEPLETION. DRYDPLT = F
**Model Uses NO WET DEPLETION. WETDPLT = F
**Model Uses RURAL Dispersion Only.
**Model Uses Regulatory DEFAULT Options:
1. Stack-tip Downwash.
2. Model Accounts for ELEVated Terrain Effects.
3. Use Calms Processing Routine.
4. Use Missing Data Processing Routine.
5. No Exponential Decay.
6. Ambient Ratio Method Ver 2 (ARM2) Used for NO2 Conversion
with a Minimum NO2/NOx Ratio of 0.500
and a Maximum NO2/NOx Ratio of 0.900
**Other Options Specified:
ADJ_U* - Use ADJ_U* option for SBL in AERMET
**Model Accepts FLAGPOLE Receptor Heights.
**The User Specified a Pollutant Type of: NO2
**NOTE: Special processing requirements applicable for the 1-hour NO2 NAAQS have been disabled!!!
User has specified non-standard averaging periods:
High ranked 1-hour values are NOT averaged across the number of years modeled, and
complete years of data are NOT required.
**Model Calculates ANNUAL Averages Only
**This Run Includes: 3 Source(s); 1 Source Group(s); and 6840 Receptor(s)
with: 3 POINT(s), including
0 POINTCAP(s) and 0 POINTHOR(s)
and: 0 VOLUME source(s)
and: 0 AREA type source(s)
and: 0 LINE source(s)
and: 0 RLINE/RLINEXT source(s)
and: 0 OPENPIT source(s)
and: 0 BUOYANT LINE source(s) with 0 line(s)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-28
**Model Set To Continue RUNning After the Setup Testing.
**The AERMET Input Meteorological Data Version Date: 19191
**Output Options Selected:
Model Outputs Tables of ANNUAL Averages by Receptor
Model Outputs External File(s) of High Values for Plotting (PLOTFILE Keyword)
Model Outputs Separate Summary File of High Ranked Values (SUMMFILE Keyword)
**NOTE: The Following Flags May Appear Following CONC Values: c for Calm Hours
m for Missing Hours
b for Both Calm and Missing Hours
**Misc. Inputs: Base Elev. for Pot. Temp. Profile (m MSL) = 396.20 ; Decay Coef. = 0.000 ; Rot. Angle = 0.0
Emission Units = GRAMS/SEC ; Emission Rate Unit Factor = 0.10000E+07
Output Units = MICROGRAMS/M**3
**Approximate Storage Requirements of Model = 3.7 MB of RAM.
**Input Runstream File: C:\Current Projects\USE-001\USEI 100% load annual NO2_5yrs_NO2.DTA
**Output Print File: C:\Current Projects\USE-001\USEI 100% load annual NO2_5yrs_NO2.LST
**File for Summary of Results: C:\Current Projects\USE-001\USEI 100% load annual NO2_5yrs_NO2.SUM
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:34:17
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** METEOROLOGICAL DAYS SELECTED FOR PROCESSING ***
(1=YES; 0=NO)
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
NOTE: METEOROLOGICAL DATA ACTUALLY PROCESSED WILL ALSO DEPEND ON WHAT IS INCLUDED IN THE DATA FILE.
*** UPPER BOUND OF FIRST THROUGH FIFTH WIND SPEED CATEGORIES ***
(METERS/SEC)
1.54, 3.09, 5.14, 8.23, 10.80,
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-29
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:34:17
PAGE 3
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** UP TO THE FIRST 24 HOURS OF METEOROLOGICAL DATA ***
Surface file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si Met Version: 19191
Profile file: C:\Current Projects\USE-001\Met Development\AERMET\Omak airport plus mesowest si
Surface format: FREE
Profile format: FREE
Surface station no.: 94197 Upper air station no.: 4106
Name: OMAK AIRPORT, WA Name: UNKNOWN
Year: 2015 Year: 2015
First 24 hours of scalar data
YR MO DY JDY HR H0 U* W* DT/DZ ZICNV ZIMCH M-O LEN Z0 BOWEN ALBEDO REF WS WD HT REF TA HT
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
15 01 01 1 01 -10.1 0.134 -9.000 -9.000 -999. 117. 20.9 0.06 0.71 1.00 1.89 297. 10.0 262.0 2.0
15 01 01 1 02 -9.3 0.128 -9.000 -9.000 -999. 111. 20.0 0.06 0.71 1.00 1.82 277. 10.0 262.5 2.0
15 01 01 1 03 -7.1 0.111 -9.000 -9.000 -999. 89. 17.1 0.06 0.71 1.00 1.59 235. 10.0 261.4 2.0
15 01 01 1 04 -2.3 0.070 -9.000 -9.000 -999. 44. 13.0 0.06 0.71 1.00 0.82 141. 10.0 261.4 2.0
15 01 01 1 05 -10.3 0.135 -9.000 -9.000 -999. 120. 21.1 0.06 0.71 1.00 1.91 289. 10.0 261.4 2.0
15 01 01 1 06 -3.8 0.082 -9.000 -9.000 -999. 57. 13.1 0.06 0.71 1.00 1.14 189. 10.0 260.4 2.0
15 01 01 1 07 -6.9 0.110 -9.000 -9.000 -999. 87. 16.9 0.06 0.71 1.00 1.57 240. 10.0 261.4 2.0
15 01 01 1 08 -4.6 0.090 -9.000 -9.000 -999. 65. 14.0 0.06 0.71 1.00 1.28 181. 10.0 260.9 2.0
15 01 01 1 09 -16.2 0.178 -9.000 -9.000 -999. 180. 34.9 0.06 0.71 0.63 2.45 181. 10.0 263.1 2.0
15 01 01 1 10 -2.8 0.171 -9.000 -9.000 -999. 170. 156.9 0.06 0.71 0.45 2.27 191. 10.0 264.9 2.0
15 01 01 1 11 16.0 0.176 0.365 0.007 106. 176. -29.6 0.06 0.71 0.38 1.98 163. 10.0 265.9 2.0
15 01 01 1 12 27.0 0.205 0.512 0.007 174. 223. -27.9 0.06 0.71 0.35 2.30 160. 10.0 267.0 2.0
15 01 01 1 13 27.3 0.224 0.557 0.007 221. 255. -36.3 0.06 0.71 0.35 2.57 139. 10.0 268.8 2.0
15 01 01 1 14 16.8 0.262 0.491 0.010 246. 322. -93.5 0.06 0.71 0.38 3.17 140. 10.0 269.2 2.0
15 01 01 1 15 4.7 0.324 0.324 0.013 252. 444. -638.6 0.06 0.71 0.45 4.12 159. 10.0 269.2 2.0
15 01 01 1 16 -20.6 0.262 -9.000 -9.000 -999. 323. 76.1 0.06 0.71 0.62 3.52 166. 10.0 269.2 2.0
15 01 01 1 17 -25.1 0.245 -9.000 -9.000 -999. 291. 65.9 0.06 0.71 1.00 3.32 172. 10.0 268.1 2.0
15 01 01 1 18 -26.5 0.259 -9.000 -9.000 -999. 316. 73.5 0.06 0.71 1.00 3.50 179. 10.0 268.1 2.0
15 01 01 1 19 -29.3 0.286 -9.000 -9.000 -999. 368. 90.2 0.06 0.71 1.00 3.86 194. 10.0 268.1 2.0
15 01 01 1 20 -37.1 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 207. 10.0 268.8 2.0
15 01 01 1 21 -41.3 0.403 -9.000 -9.000 -999. 614. 178.7 0.06 0.71 1.00 5.36 210. 10.0 267.5 2.0
15 01 01 1 22 -37.4 0.364 -9.000 -9.000 -999. 528. 145.7 0.06 0.71 1.00 4.86 202. 10.0 267.0 2.0
15 01 01 1 23 -25.4 0.248 -9.000 -9.000 -999. 304. 67.5 0.06 0.71 1.00 3.36 200. 10.0 267.0 2.0
15 01 01 1 24 -37.3 0.364 -9.000 -9.000 -999. 527. 145.7 0.06 0.71 1.00 4.86 190. 10.0 267.5 2.0
First hour of profile data
YR MO DY HR HEIGHT F WDIR WSPD AMB_TMP sigmaA sigmaW sigmaV
15 01 01 01 10.0 1 297. 1.89 262.1 99.0 -99.00 -99.00
F indicates top of profile (=1) or below (=0)
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-30
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:34:17
PAGE 2
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** POINT SOURCE DATA ***
NUMBER EMISSION RATE BASE STACK STACK STACK STACK BLDG URBAN CAP/ EMIS RATE
SOURCE PART. (GRAMS/SEC) X Y ELEV. HEIGHT TEMP. EXIT VEL. DIAMETER EXISTS SOURCE HOR SCALAR
ID CATS. (METERS) (METERS) (METERS) (METERS) (DEG.K) (M/SEC) (METERS) VARY BY
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
GEN_A 0 0.27600E-01 299602.2 5336087.8 383.3 8.84 719.82 28.28 0.49 YES NO NO
GEN_B 0 0.27600E-01 299603.3 5336082.2 383.2 8.84 719.82 28.28 0.49 YES NO NO
GEN_C 0 0.27600E-01 299379.8 5336241.9 385.1 8.84 719.82 28.28 0.49 YES NO NO
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:34:17
PAGE 4
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** THE SUMMARY OF MAXIMUM ANNUAL RESULTS AVERAGED OVER 5 YEARS ***
** CONC OF NO2 IN MICROGRAMS/M**3 **
NETWORK
GROUP ID AVERAGE CONC RECEPTOR (XR, YR, ZELEV, ZHILL, ZFLAG) OF TYPE GRID-ID
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
ALL 1ST HIGHEST VALUE IS 0.10398 AT ( 299587.50, 5335925.00, 380.91, 380.91, 1.50) DC
2ND HIGHEST VALUE IS 0.10351 AT ( 299587.50, 5335937.50, 381.06, 381.06, 1.50) DC
3RD HIGHEST VALUE IS 0.10348 AT ( 299587.50, 5335912.50, 380.77, 380.77, 1.50) DC
4TH HIGHEST VALUE IS 0.10248 AT ( 299600.00, 5335925.00, 380.75, 380.75, 1.50) DC
5TH HIGHEST VALUE IS 0.10233 AT ( 299587.50, 5335900.00, 380.65, 380.65, 1.50) DC
6TH HIGHEST VALUE IS 0.10224 AT ( 299600.00, 5335912.50, 380.61, 380.61, 1.50) DC
7TH HIGHEST VALUE IS 0.10191 AT ( 299587.50, 5335950.00, 381.23, 381.23, 1.50) DC
8TH HIGHEST VALUE IS 0.10190 AT ( 299575.00, 5335925.00, 381.11, 381.11, 1.50) DC
9TH HIGHEST VALUE IS 0.10173 AT ( 299600.00, 5335937.50, 380.90, 380.90, 1.50) DC
10TH HIGHEST VALUE IS 0.10152 AT ( 299575.00, 5335912.50, 380.96, 380.96, 1.50) DC
*** RECEPTOR TYPES: GC = GRIDCART
GP = GRIDPOLR
DC = DISCCART
DP = DISCPOLR
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-31
*** AERMOD - VERSION 19191 *** *** U.S. Electrodynamics *** 12/22/20
*** AERMET - VERSION 19191 *** *** 73 hrs runtime per generator 100% load *** 10:34:17
PAGE 5
*** MODELOPTs: RegDFAULT CONC ELEV FLGPOL NODRYDPLT NOWETDPLT ARM2 RURAL ADJ_U*
*** Message Summary : AERMOD Model Execution ***
--------- Summary of Total Messages --------
A Total of 0 Fatal Error Message(s)
A Total of 1 Warning Message(s)
A Total of 1086 Informational Message(s)
A Total of 43824 Hours Were Processed
A Total of 471 Calm Hours Identified
A Total of 615 Missing Hours Identified ( 1.40 Percent)
******** FATAL ERROR MESSAGES ********
*** NONE ***
******** WARNING MESSAGES ********
ME W187 1842 MEOPEN: ADJ_U* Option for Stable Low Winds used in AERMET
US Electrodynamics, Inc. Air Dispersion Modeling Report
December 2020 Appendix B-32