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Procedures for Emission Inventory Preparation - Vol IV: Mobile Sources

Several people in EPA's Emission Planning and Strategies Division have contributed to this document. Their names and contributions are listed below. Chapter 1 Natalie Dobie Introduction Chapter 2 Natalie Dobie Overview Chapter 3 Terry Newell MOBILE4.1 Natalie Dobie Vehicle Miles Traveled Chapter 4 Greg Janssen Nonroad Sources Joe Somers Chapter 5 Richard Wilcox Aircraft Chapter 6 Peter Okurowski Locomotives NOTICE The Procedures For Emission Inventory Preparation consists of these five volumes: Volume I - Emission Inventory Fundamentals Volume II - Point Sources Volume III - Area Sources Volume IV - Mobile Sources Volume V - Bibliography Volume I is a guide to the managerial and technical aspects of the emission inventory. It outlines the information sources available, methods of estimating emissions, data validation and quality assurance techniques, as well as procedures to maintain and update the inventory. Also included are a detailed analysis of the manpower and resources required to derive each component of an emission inventory and a comprehensive glossary. Volume II discusses point sources identification, data collection, emissions calculation, and data presentation. It establishes standardized methods and procedures to develop a point source data base. Volume III outlines the methods of collecting and handling emission data from sources too small and/or too numerous to be surveyed individually. Collectively, these sources are known as area sources. Procedures are presented to identify area source categories. Important reference material that can be used to determine the activity levels associated with area source categories are also listed. Finally, emission factors, emission calculations, pollutant allocation and projection techniques, and methods of data presentation are included to assist in the preparation and maintenance of the area source emission inventories. Volume IV presents an overview of the mobile source category as a whole and identifies specific methods that can be used to identify and inventory sources, estimate emissions, and establish and maintain a useful, current mobile source emissions inventory. Volume V presents an extensive listing of currently available reference material designed to assist in the development of an emission inventory. A concise abstract is provided for each reference cited, outlining the pertinent emission inventory information. These volumes are intended to present emission inventory procedures and techniques applicable to state and local air programs. Please forward comments and suggestions for improvement to the U. S. Environmental Protection Agency, Monitoring And Reports Branch (MD- 14), Research Triangle Park, North Carolina 27711. Other U.S. EPA emission inventory procedures publications include: Emission Inventory Requirements For Ozone State Implementation Plans, EPA-450/4-91-010, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, March 1991. Procedures for the Preparation of Emission Inventories for Carbon Monoxide and Precursors of Ozone, Volume 1: General Guidance for Stationary Sources EPA-450/4-91-016, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research, Triangle Park, North Carolina, May 1991. Procedures for the Preparation of Emission Inventories for Carbon Monoxide and Precursors of Ozone, Volume II: Emission Inventory Requirements for Photochemical Air Quality Simulation Models, EPA- 45014-9-014, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, May 1991. Emission Inventory Requirements for Carbon Monoxide State Implementation Plans, EPA-450/4-91-011, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, March 1991. Example Documentation Report For 1990 Base Year Ozone and Carbon Monoxide State Implementation Plan Emission Inventories, EPA-450/4- 92-007, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, March 1992. AIRS Facility Subsystem Source Classification Codes (SCCs) and Emission Factor Listing for Criteria Pollutants, EPA-450/4-90-003, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, March 1990. Revised edition to be issued Summer 1992. Guidance for the Preparation of Quality Assurance Plans O3/CO SIP Emission Inventories, EPA-450/4-88-023, U. S. Environmental Protection Agency, Office of Air Quality Planning And Standards, Research Triangle Park, North Carolina, December 1988. Quality Review Guidelines For 1990 Base Year Emission Inventories, EPA450/4-91-022, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, September 1991. SIP Air Emission Inventory Management System (SAMS) Version 4.1 and SAMS User's Guide, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, September 1991. User's Guide to MOBILE4.1 (Mobile Source Emission Factor Model), EPA-AA-TEB-91-01, U. S. Environmental Protection Agency, Office of Mobile Sources, Ann Arbor, Michigan, July 1991. Procedures for Estimating and Applying Rule Effectiveness in Post- 1987 Base Year Emission Inventories for Ozone and Carbon Monoxide State Implementation Plans, U. S. Environmental Protection Agency, Office of Air Quality Planning and Standards, Research Triangle Park, North Carolina, June 1989. Surface Impoundment Modeling System (SIMS) Version 2.0 User's Manual, EPA-450/4-90-019a, U. S. Environmental Protection Agency, Research Triangle Park, North Carolina, September 1990. Background Document for Surface Impoundment Modeling System (SIMS) Version 2.0, EPA-450/4-90-019b, U. S. Environmental Protection Agency, Research Triangle Park, North Carolina, September 1990. TABLE OF CONTENTS Page 1.0 INTRODUCTION 1 2.0 OVERVIEW OF THE MOBILE SOURCE CATEGORY 2 2.1 INDIVIDUAL MOBILE SOURCE CATEGORIES 2 2.1.1 Highway Vehicles 2 2.1.2 Nonroad Sources 3 2.1.3 Aircraft 3 2.1.4 Locomotives 4 3.0 EMISSIONS FROM HIGHWAY VEHICLES 5 3.1 GUIDANCE ON THE USE OF MOBILE4.1 VS MOBILE5 FOR THE 1990 BASE YEAR INVENTORY AND OTHER INVENTORIES 5 3.2 MOBILE SOURCE EMISSION ESTIMATION PROCESS 6 3.2.1 Overview of Factors Influencing Motor Vehicle Emission Inventories 6 3.2.1.1 Vehicle Fleet Activity 7 3.2.1.2 Emission Factors 7 3.2.1.3 Fleet Characteristics 7 3.2.1.4 Fuel Characteristics 7 3.2.1.5 Correction Factors 8 3.2.1.6 Control Programs 8 3.2.2 Overview of MOBILE4.1 Input Requirements 8 3.2.2.1 Fleet Characteristics 9 3.2.2.1.1 VMT Mix 9 3.2.2.1.2 Annual Mileage Accumulation Rates 9 3.2.2.1.3 Registration Distributions 10 3.2.2.2 Fuel Specifications 10 3.2.2.2.1 RVP 10 3.2.2.3 Correction Factors 10 3.2.2.3.1 Speed 10 3.2.2.3.2 Temperature 10 3.2.2.3.3 Operating Modes 11 3.2.2.3.4 Minor Correction Factors 11 3.2.2.4 Tampering and Misfueling 12 3.2.2.5 Control Programs 12 3.2.2.5.1 Refueling Emissions 12 3.2.2.5.2 Inspection and Maintenance Programs 12 3.2.2.5.3 Anti-Tampering Programs (ATPs) 12 3.3 GUIDANCE ON SELECTING MOBILE4.1 INPUTS 13 3.3.1 Emission Factors 13 3.3.1.1 Region 14 3.3.1.2 Calendar Year 14 TABLE OF CONTENTS Page 3.3.2 Fleet Characteristics 15 3.3.2.1 Vehicle Miles Traveled Mix by Vehicle Type 15 3.3.2.2 Annual Mileage Accumulation Rates and Registration Distributions by Vehicle Type and Age 16 3.3.2.3 Trip Length Distribution 18 3.3.2.4 Diesel Sales Fractions 20 3.3.3 RVP Determination 22 3.3.3.1 EPA-Provided 1990 RVP Estimates 26 3.3.3.2 "Period 1" RVP and "Period 2" RVP 26 3.3.3.3 Interpolation 27 3.3.3.4 Inputs for Future Year RVP 27 3.3.3.4.1 Future Summer RVP 27 3.3.3.4.2 Future Winter RVP 28 3.3.4 Oxygenated Fuels 29 3.3.5 Correction Factors 30 3.3.5.1 Speed 30 3.3.5.2 Temperature 34 3.3.5.3 Operating Modes 38 3.3.5.4 Additional Correction Factors for Light- Duty Gasoline-Fueled Vehicle Types 40 3.3.6 Control Programs 43 3.3.6.1 Refueling Emissions 43 3.3.6.2 Inspection and Maintenance Programs 45 3.3.6.2.1 I/M 47 3.3.6.2.2 Start Year 47 3.3.6.2.3 Stringency 47 3.3.6.2.4 First Model Year 47 3.3.6.2.5 Last Model Year 48 3.3.6.2.6 Waiver Rates 48 3.3.6.2.7 Compliance Rate 49 3.3.6.2.8 Inspection Frequency 50 3.3.6.2.9 Vehicle Classes 51 3.3.6.2.10 I/M Test Types 51 3.3.6.2.11 Alternate I/M Credits 53 3.3.6.2.12 Centralized Programs 53 3.3.6.2.13 Decentralized Programs (Manual) 53 3.3.6.2.14 Computerized Inspection 54 3.3.6.2.15 Tech I-II and Tech IV+ 55 3.3.6.3 Anti-Tampering Programs 55 3.3.6.3.1 ATP 57 3.3.6.3.2 Tampering and Misfueling 57 3.3.6.3.3 Air Pump Inspection 57 TABLE OF CONTENTS Page 3.3.6.3.4 Catalyst Inspection 57 3.3.6.3.5 Fuel Inlet Restrictor Inspection 58 3.3.6.3.6 Tailpipe Lead Detection Test 58 3.3.6.3.7 EGR Inspection 59 3.3.6.3.8 Evaporative Control System 59 3.3.6.3.9 PCV Inspection 60 3.3.6.3.10 Gas Cap Inspection 60 3.3.6.3.11 Tampering Rates 60 3.4 VEHICLE MILES TRAVELED 62 3.4.1 Highway Performance Monitoring System 62 3.4.1.1 Role of the HPMS in SIP Development 62 3.4.1.2 Overview of HPMS 63 3.4.1.3 Consistency Between HPMS and SIP VMT 65 3.4.1.3.1 Expansion Factors 65 3.4.1.3.1.1 Non-Attainment Area the Same As the Federal Aid Urbanized Area 65 3.4.1.3.1.2 Non-Attainment Area Inside of the Federal Aid Urbanized Area 66 3.4.1.3.1.3 Non-Attainment Area Outside of the Federal Aid Urbanized Area 66 3.4.1.3.1.4 Non-Attainment Area and Federal Aid Urbanized Area Crossover 67 3.4.1.3.2 Local Functional System 67 3.4.1.3.3 Seasonal Adjustment 68 3.4.1.3.4 Daily Adjustment 68 3.4.1.4 Allocating VMT to Time of Day 68 3.4.1.5 Allocating VMT to Functional Systems 69 3.4.1.6 Estimating VMT in Rural and Small Urban Areas 69 3.4.1.6.1 Apportionment of Statewide VMT- Recommended Method 72 3.4.1.6.2 Apportionment of Statewide VMT- Alternative Methods 74 3.4.1.6.2.1 Motor Vehicle Registrations 74 3.4.1.6.2.2 Population 74 3.4.1.6.2.3 Fuel Sales 75 3.4.2 Travel Demand Network Models 78 3.4.2.1 Role of Transportation Models in SIP Development 78 3.4.2.2 Background. 78 3.4.2.3 Overview of Network Models 79 3.4.2.3.1 Level of Service 81 3.4.2.3.2 Physical Attributes 83 3.4.2.3.3 Locational Link Attributes 83 3.4.2.3.4 Trip Generation 86 TABLE OF CONTENTS Page 3.4.2.3.5 Trip Distribution 86 3.4.2.3.6 Modal Split 86 3.4.2.3.7 Traffic Assignment 86 3.4.2.3.8 Feedback 87 3.4.2.4 Consistency Between Transportation Model VMT and HPMS 87 3.4.2.4.1 Non-Attainment Area the Same As the Network Model Area 88 3.4.2.4.2 Non-Attainment Area Inside of the Network Model Area 89 3.4.2.4.3 Non-Attainment Area Outside of the Network Model Area 89 3.4.2.4.4 Non-Attainment Area and Network Model Area Crossover 90 3.4.2.5 Local Functional System 90 3.4.2.6 Seasonal Adjustment 91 3.4.2.7 Daily Adjustment 91 3.4.2.8 Allocating VMT to Time of Day 91 3.4.2.9 Allocating VMT to Functional Systems 91 3.4.3 Exception to the Use of HPMS VMT 92 Appendix 3-A 94 4.0 EMISSIONS FROM NONROAD, SOURCES 98 4.1 Introduction 98 4.2 Inventory Options Under This Guidance 99 4.2.1 Options for Areas With EPA Provided Inventories 99 4.2.2 Options For Areas With EPA Provided Inventories 101 4.2.3 Options For Areas Without EPA Provided Inventories 102 4.3 Explanation of EPA Provided Inventory 102 4.3.1 Derivation of AMS Inputs 103 4.3.2 AMS Inputs 105 4.4 General Methodology Used In Deriving Emission Inventories For 33 Areas 107 4.4.1 Explanation of Methodologies to Distribute Equipment Within Each Category Type at the County Level 108 4.4.2 Explanation of Methodologies For Distributing Equipment Within Each Category at the Sub- County Level 112 4.4.3 Seasonal Adjustment Methodology 113 4.5 New York Non-Attainment Area Example 115 Appendix 4-A 117 Appendix 4-B 124 Appendix 4-C 132 Appendix 4-D 135 TABLE OF CONTENTS Page 5.0 EMISSIONS FROM AIRCRAFT 137 5.1 OVERVIEW OF THE INVENTORY METHODOLOGY 137 5.1.1 Factors Affecting Emissions 138 5.1.1.1 Aircraft Categorization 138 5.1.1.2 Pollutant Emissions 139 5.1.1.3 Aircraft Engines 140 5.1.1.4 Operating Modes 140 5.2 INVENTORY METHODOLOGY 144 5.2.1 Airport Selection 144 5.2.2 Mixing Height Determination 145 5.2.3 Activity and Emissions for Commercial Aircraft 149 5.2.4 Activity and Emissions for General Aviation Aviation and Air Taxi Aircraft 173 5.2.4.1 Aircraft-Specific Procedure 173 5.2.4.2 Alternative, Fleet-Average Procedure 176 5.2.5 Activity and Emissions for Military Aircraft 178 5.3 VARIATIONS TO THE INVENTORY CALCULATION PROCEDURE 190 5.3.1 Variability of Activity - Daily and Seasonal 190 5.3.2 Operational Activity that Affects Aircraft Emissions 191 5.3.2.1 Reduced Engine Taxiing 191 5.3.2.2 Derated Take-off 192 5.3.3 Particulate Emissions 192 5.4 OTHER EMISSION SOURCES 192 5.4.1 Auxiliary Power Units 192 5.4.2 Evaporative Emissions 197 5.5 EFFECT OF FUTURE CHANGES TO THE FLEET 197 5.6 CONVERTING FROM TOTAL HYDROCARBONS (THC) TO VOLATILE ORGANIC COMPOUNDS (VOC) 198 5.6.1 Commercial and Military Conversions 198 5.6.2 General Aviation and Air Taxi Conversions 199 6.0 EMISSIONS FROM LOCOMOTIVES 200 6.1 OVERVIEW OF RECOMMENDED INVENTORY METHODOLOGY 202 6.2 RECOMMENDED METHODS 202 6.2.1 Class I Line Haul Locomotives 202 6.2.1.1 Fuel Consumption 202 6.2.1.2 Emission Factors: 204 6.2.2 Class II and III Line Haul Locomotives 205 6.2.2.1 Fuel Consumption 205 6.2.2.2 Emission Factors 206 6.2.3 Yard Operations 206 6.2.3.1 Number of Yard Locomotives 206 6.2.3.2 Emissions Per Yard Locomotive 206 TABLE OF CONTENTS Page 6.3 TAILORING METHODS 208 6.3.1 Locomotive Roster Tailoring Method 208 6.3.1.1 Identify the locomotives in the area 208 6.3.1.2 Determine the engine type 209 6.3.1.3 Sum the total of the conversions 209 6.3.1.4 Calculate the new fleet average emission factors 210 6.3.1.5 Multiply the new emission factors by fuel consumption 210 6.3.2 Duty Cycle Tailoring Method 210 6.3.3 SO2 Tailoring Method 212 6.4 ALTERNATIVE METHOD 213 6.5 RE-ENGINED LOCOMOTIVES 213 6.6 CONVERTING FROM TOTAL HYDROCARBONS (THC) TO VOLATILE ORGANIC COMPOUNDS (VOC) 213 Appendix 6-1 215 Appendix 6-2 216 Appendix 6-3 217 Appendix 6-4 219 Appendix 6-5 222 Appendix 6-6 223 Appendix 6-7 225 Appendix 6-8 227 1.0 INTRODUCTION A fundamental requirement in the effort to control pollution in any form is to quantify the emissions being released. This is necessary to understand the relationships between emissions and the ambient concentrations that result, and to develop appropriate policies and methods to ensure that ambient pollutant concentrations remain within acceptable limits. Specific air pollution requirements are set forth in Title 40, Code Of Federal Regulations, Part 51.321 (40 CFR 51), and in the Clean Air Act as amended, for the development and maintenance of ongoing programs to inventory specific pollutant emissions. States are required by 40 CFR 51 to prepare and submit annual reports to the U.S. Environmental Protection Agency (EPA) regarding the emissions of particulate matter, sulfur oxides, carbon monoxide, nitrogen oxides, and volatile organics from point sources within their boundaries. The amendments to the Clean Air Act require the development of "...comprehensive, accurate, and current..." inventories from all sources of each pollutant for every non- attainment area, in conjunction with the preparation of revised State Implementation Plans (SIPs). EPA recognizes that a significant effort will continue to be needed to develop and maintain emission inventories to meet the requirements for both technical analysis and administrative reporting. To assist the states in meeting the requirements for emission inventory development, a five volume series has been prepared that describes in detail many of the technical aspects of the inventory process. This document is the fourth volume in the series, and it focuses on mobile sources. Specifically, this document presents specific methods that can be used to identify sources, estimate emissions, and establish and maintain a useful, current mobile source emissions inventory. Special attention has been given to preparing the 1990 SIP inventories. Following this introductory chapter, Chapter 2 gives an overview of the mobile source category. Chapters 3 through 6 present specific methods that should be used to derive emission estimates for each of the primary mobile source subcategories. Chapter 1 - Introduction Chapter 2 - Overview Chapter 3 - Highway Vehicles Chapter 4 - Nonroad Sources Chapter 5 - Aircraft Chapter 6 - Locomotives 2.0 OVERVIEW OF THE MOBILE SOURCE CATEGORY An inventory of pollutant emission sources should classify sources into two major categories - point sources and area sources. The point source category is described in detail in Volume II of this series. The area source category is described in detail in Volume III of this series. Mobile sources are a subcategory within the area source category of pollutant emission sources. However, the procedures for preparing and maintaining an inventory of emissions from mobile sources are presented herein, as a separate document in this series, because the inventorying procedures are different from those for other area source subcategories and because the mobile source emissions inventory represents a major portion of the total emissions of volatile organics (VOC), nitrogen oxides (NOx ), and carbon monoxide (CO). The mobile sources for which inventory and emission calculation procedures are presented in this document are highway vehicles, nonroad mobile sources, aircraft, and locomotives. Recreational marine equipment and commercial marine vessels are discussed in the nonroad mobile source section. The procedures describe how to calculate tailpipe emissions and emissions from the fuel carried on the vehicle (evaporative VOC emissions) for these four mobile source categories. The emissions that result from tire wear and travel over roads or other surfaces should be calculated from the procedures in Volume III of this series and are specifically excluded from consideration in this document. 2.1 INDIVIDUAL MOBILE SOURCE CATEGORIES 2.1.1 Highway Vehicles Highway vehicles include all vehicles registered to use the public roadways. The predominant emissions source in this category is the automobile, although trucks and buses are also significant sources of emissions. The total highway vehicle population can be characterized by eight individual vehicle type categories: - Light duty gasoline powered vehicles (LDGV); - Light duty gasoline powered trucks, from 0 to 6000 lb. gross vehicle weight (LDGT1); - Light duty gasoline powered trucks, from 6001 to 8500 lb. gross vehicle weight (LDGT2); - Heavy duty gasoline powered vehicles (HDGV); - Light duty diesel powered vehicles, from 0 to 6000 lb. gross vehicle weight (LDDV); - Light duty diesel powered trucks (LDDT); - Heavy duty diesel powered vehicles (HDDV); - Motorcycles (MC). 2 Numerous characteristics for each vehicle type are necessary before emissions can be calculated. These characteristics include, among others, model year, the age distribution of vehicles within the class, annual mileage by vehicle age, and average speed. Chapter 3 of this document presents detailed procedures for identifying and using these and other key characteristics. 2.1.2 Nonroad Sources This mobile source category includes a diverse set of source types. The movement of sources in this category occurs on surfaces other than the public highways. Nonroad vehicles can be classified into ten categories: - Lawn and Garden Equipment, - Industrial Equipment, - Airport Service Equipment, - Construction Equipment, - Recreational Equipment, - Agricultural Equipment, - Recreational Marine Equipment, - Logging Equipment, - Light Commercial Equipment, - Commercial Marine Vessels. These categories are difficult to inventory, since few data are available to determine either their activity levels or operating characteristics. Chapter 4 of this document provides procedures for inventorying and estimating emissions from these categories. 2.1.3 Aircraft Aircraft include all types of aircraft, whether civilian, commercial, or military. Emissions from idling, taxiing, and during landings and takeoffs are included. Landing and takeoff cycle (LTO) emissions are those that occur between ground level and an attitude of about 3000 feet. Aircraft emissions above 3000 feet need not be included in either the base year emission inventory or in the modeling inventory. The larger civil and commercial airports with continuously manned control towers maintain records of LTO cycles by type of aircraft as part of their standard operating procedure. Smaller airports also maintain these records to the extent that their control towers are manned or landing fees are recorded. Difficulty may be encountered in obtaining data on military aircraft operations at military airports. EPA has compiled a complete set of emission factors for different types of aircraft operating in the different modes (idle, taxi, LTO). Chapter 5 of this document provides instruction on how to calculate emissions from this mobile source category. 3 2.1.4 Locomotives Locomotives include all fossil fuel fired locomotive engines operated on railways. The quantity of fuel used by locomotives and the size, in horsepower, of the locomotives are necessary to calculate emissions from this source. This information is discussed in Chapter 6. 0 3.0 EMISSIONS FROM HIGHWAY VEHICLES In most urban areas, highway vehicles represent the largest single source of carbon monoxide (CO) emissions and contribute significantly to the area's production of volatile organic compounds (VOC), sulfur oxides (SO2) and oxides of nitrogen (NOx ). Emission estimates for highway vehicles are usually based on the combination of two fundamental measures of activity: travel and the average rate of pollutants emitted in the course of travel. Both measures reflect complex patterns of behavior. The Environmental Protection Agency and the Department of Transportation Federal Highway Administration (FHWA) have developed a series of tools/models to estimate the rate of emissions produced by vehicles per mile of travel and the amount of travel itself. The knowledge base and disciplines required to understand and operate these models are distinct, as are their audiences. This distinction generally ensures that environmental analysts have little appreciation for the accuracy of the travel estimates produced by transportation analysts and vice versa. The purpose of this chapter is to provide guidance for preparing the highway vehicle portion of mobile source emission inventories, particularly those associated with the development of State Implementation Plans (SIPs) for ozone (03) and CO. The accuracy of the inventory will be no better than the accuracy of the estimates of either the emission rates or vehicle miles traveled (VMT). This chapter responds to concerns that little effort has been devoted to the development of accurate projections of travel within non-attainment areas, that projections of attainment dates have been based on dated information and that highway vehicles are responsible for a greater portion of the emissions inventory than recent estimates have suggested. Because of these concerns, the earlier guidance on the use of available travel estimates has been carefully reviewed and updated. 3.1 GUIDANCE ON THE USE OF MOBILE4.1 VS MOBILE5 FOR THE 1990 BASE YEAR INVENTORY AND OTHER INVENTORIES At the time of this writing, MOBILE4.1 is EPA's current emission factor model. MOBILE5 will be available within months of the publication of this document. EPA will accept 1990 base year emission inventories prepared with either MOBILE4.1 or MOBILE5 emission factors. The November 15, 1992 submittal date for inventories will apply no matter which version of the model is used. Since MOBILE5 will incorporate the new vehicle standards for VOC and NOx mandated by the Clean Air Act (CAA), estimates of those emissions for years after 1990 will be significantly different than those estimated by MOBILE4.1. Therefore, ozone non- attainment areas should submit projections using MOBILE5. However, the 1990 highway vehicle emissions inventories should be recalculated as soon as possible after November 15, 1992 using MOBILE5 so that all required inventories are consistent. CO 5 non-attainment areas may use MOBILE4.1 for the November 15, 1992 projection submittal, and if they do, recalculation of the 1990 inventory is not necessary. The SIP Attainment/Reasonable Further Progress Demonstration, including projection year inventories, should use MOBILE5 for ozone non-attainment areas.' In addition, if the base year inventory was originally developed using MOBILE4.1, it should be recalculated using MOBILE5 and resubmitted.' For CO non-attainment areas, the base year and projection year inventories may be developed using either MOBILE4.1 or MOBILE5. Submissions after the November 15, 1992 submission should use MOBILE5. Such submissions may be voluntary or due to bump up or other provisions of the Clean Air Act. The release of MOBILE5 will be accompanied by a supplement to this document explaining the differences between MOBILE4.1 and MOBILE5 and the additional inputs contained in MOBILE5. 3.2 MOBILE SOURCE EMISSION ESTIMATION PROCESS 3.2.1 Overview of Factors Influencing Motor Vehicle Emission Inventories Many complex processes govern the formation of pollutants in motor vehicles. The EPA and the California Air Resources Board (CARB) maintain large data collection program to quantify the rate at which pollutants are emitted by individual categories of motor vehicles. Both organizations have used this information to develop models that help analysts in estimating motor vehicle contributions to the local emissions inventory. These models, commonly known as emission factor models, are designed to account for the effect of numerous vehicle parameters on the volume of pollutants emitted. The current EPA model is called MOBILE4. 1. The primary components of an emission factor model include the base emission factors, characterization of the vehicle fleet, fuel characteristics, vehicle operating conditions and the effect of local ambient conditions, the effect of alternative I/M programs and the effect of tampering and misfueling. None of these factors is static: technology is continually evolving, leading to changing in-use emission performance. Changes in fuel prices and economic conditions lead to changes in vehicle sales and travel patterns. A substantial effort is required to accurately quantify these factors and to stay current with the influence of all of these factors on vehicular emission levels. ___________________________ 1 The SIP Attainment/Reasonable Further Progress and projection year inventories are due on either November 15, 1993 or November 15, 1994, depending upon the non-attainment classification. 2 EPA may set a date prior to November, 1993 for submission of draft projection and recalculated base year inventories, similar to the current requirement to submit the draft base year inventory no later than May, 1992. 6 3.2. 1.1 Vehicle Fleet Activity It is standard practice in preparing highway vehicle emission inventories to express vehicle activity in terms of vehicle miles traveled, and the emission factors in units of grams per mile of travel. Actually, vehicles also emit hydrocarbons while stationary. Estimates of emission-producing activities that do not involve travel are built into MOBILE4.1. These non-moving emissions are spread over estimated miles of travel by vehicles of a particular age and output as an equivalent per mile emission factor. Therefore, EPA will accept VMT as the measure of local vehicle activity for all inventories required under the Clean Air Act.3 VMT can be estimated in several possible ways. Direct observation via traffic counts (usually at a sample of roadway points with statistical expansion to represent the universe of all roadways in the area) and highway/transit network models are the more preferred approaches. EPA does not recommend reliance on fuel sales data, owner reports, or periodic odometer surveys as substitutes. The two recommended methods are discussed in Section 3.4. 3.2.1.2 Emission Factors Emission rates are computed from test measurements of in-use vehicles at various odometer readings designed to capture two fundamental processes: the baseline emission rate and the deterioration that takes place as the vehicle ages. Linear regressions are performed on the data to quantify the level of pollutants emitted by each model year's vehicles. The results are commonly referred to as the intercept, or zero-mile (ZM), emission rate and the slope, or deterioration rate (DR), that occurs over each 10,000 mile interval. 3.2.1.3 Fleet Characteristics The emission factors quantify the performance of individual model year vehicle fleets by vehicle type. The age distribution, the rate of mileage accumulation and the mix of travel experienced by each vehicular category can significantly alter the fleet average emission rate. While the emission factor models employ national average distributions for each of the factors, local input is allowed, often encouraged, and, for some inputs, required. Differences between local and national average distributions can alter the emissions contributions of the individual vehicle categories. 3.2.1.4 Fuel Characteristics Emission test measurements are conducted on a standardized test fuel known as Indolene. The characteristics of this fuel are well defined and ensure that test results are repeatable. Since consumers cannot purchase Indolene at their local service stations and ___________________________ 3 VMT must usually be disaggregated such that each subset of it can be reasonably represented by a single emission factor determined by one set of inputs of the types described below. EPA also accepts the trip-based activity methods described in this document. 7 differences between the volatility of local fuels and Indolene can influence the level of both evaporative and tailpipe pollutants, MOBILE4.1 requires local input of fuel volatility. 3.2.1.5 Correction Factors To ensure the repeatability of measurements, standardized test conditions have been specified for each vehicle category. They include driving cycle, temperature, humidity, vehicle load, and the distribution of starting conditions. Since not all vehicle trips match these test conditions, a series of correction factors has been developed to allow the emission factor model to account for differences. 3.2.1.6 Control Programs Emission factors are based on the performance of vehicles independent of any local control programs such as I/M, anti- tampering and Stage II refueling. Each of these programs is designed to reduce the level of pollutants emitted by vehicles operating under in-use conditions. Further, differences in program designs can have a significant impact on their effectiveness in reducing emissions. Therefore, it is important to specify correctly program parameters in order to estimate correctly their effect on vehicular emissions. 3.2.2 Overview of MOBILE4.1 Input Requirements MOBILE4.1, EPA's emission factor model, computes separate emission estimates for eight vehicle categories: - Light-duty gasoline-powered vehicles (LDGV), i.e., passenger cars; - Light-duty diesel-powered vehicles (LDDV), i.e., diesel- powered passenger cars; - Light-duty gasoline-powered trucks, type 1 (LDGT1), i.e., pickup trucks and vans that have a gross vehicle weight (GVW) of 0 - 6000 pounds; - Light-duty gasoline-powered trucks, type 2, (LDGT2), i.e., pickup trucks, vans, and other, small trucks that have a GVW of 6001 - 8500 pounds; - Light-duty diesel-powered trucks, types 1 & 2 (LDDT); - Heavy-duty gasoline-powered trucks (HDGV), i.e., all vehicles with a GVW greater than 8,500 pounds, powered by gasoline engines; - Heavy-duty diesel-powered vehicles (HDDV), i.e., all diesel powered trucks with a GVW greater than 8,500 pounds; and - Motorcycles (MC). There are large differences in the emission characteristics of the vehicles represented by these categories; therefore, it is important that estimates of local or regional emission rates incorporate the distribution of VMT by vehicle type. The emission factors produced by MOBILE4.1 are derived from measurements conducted under standardized test conditions. For light-duty vehicles, the standard set of test conditions is referred to as the Federal Test Procedure (FTP). It involves the simulated 8 operation of a vehicle over a specific driving cycle, the Urban Driving Cycle, under controlled operating and environmental conditions, during which emissions are measured in three sequences. The Urban Driving Cycle represents an average trip over an urban network that includes travel on local and arterial streets, major arterials, and expressways. The basic test conditions include: - Ambient temperature range of 68'F to 86'F; - Absolute humidity adjusted to 75 grains of water per pound of dry air; - Average speed of 19.6 mph with 18 percent idle operation; - Average percent of VMT` in cold start operation of 20.6 percent; - Average percent of VMT in hot start operation of 27.3 percent; - Average percent of VMT` in stabilized operation of 52.1 percent; and - Average trip length of 7.5 miles. In order to understand fully the derivation of emission factors and the influence of these conditions on emission levels, refer to Chapter 2 of the MOBILE4.1 User's Guide. A condensation of that material is included in Section 3.3 of this report. MOBILE4.1 inputs can be altered to reflect city-specific conditions. A brief review of each of the primary options is presented below. They are not organized as they are in the MOBILE4.1 User's Guide, but rather in the order in which they will be discussed in more detail later in this chapter. 3.2.2.1 Fleet Characteristics 3.2.2.1.1 VMT Mix The distribution of travel across the eight vehicle categories determines how the individual emission factors are weighted to produce a composite emission factor for the entire highway vehicle fleet. The LDGVs generally comprise over 50 percent of the travel recorded in any area of the country and, therefore, tend to be the dominant source of highway emissions. (HDDVs are an important source of NOx emissions.) MOBILE4.1 will calculate the VMT mix based on national data characterizing registration distributions, annual mileage accumulation rates by age, diesel sales fractions, and vehicle counts. These values may not, however, be representative of certain areas, such as western states where pickup trucks form a larger share of the vehicle population or rural areas where a broader distribution of vehicles exists. 3.2.2.1.2 Annual Mileage Accumulation Rates The primary effect of the rate of mileage accumulation by age (in combination with registration data) is to determine the relative weighting of each model year's contribution to the average emission factor computed for each vehicle category. MOBILE4.1 provides the option of using a national average value or inputting data characterizing local conditions. The rate of mileage accumulation may be different from national average conditions in both rural and urban areas at either end of the economic spectrum. 9 3.2.2.1.3 Registration Distributions These are used in concert with mileage accumulation rates to determine the relative weighting of each model year's contribution to the average emission factor for each vehicle category. MOBILE4.1 provides the option of using national average values or inputting data characterizing local registrations. The areas most likely to be distinct from national average values are rural areas, areas in which cars do not rust out and urban areas at either end of the economic spectrum. 3.2.2.2 Fuel Specifications 3.2.2.2.1 RVP Evaporative and, to a lesser extent, exhaust emissions vary with fuel volatility. EPA's new vehicle certification program and much of its in-use vehicle testing program use gasoline with a fuel volatility (RVP) of 9.0 psi. In recent years much of the country has been supplied with gasoline of higher volatility. MOBILE4.1 adjusts estimated emission factors to account for the effects of volatility. No national average value for this variable is available in MOBILE4.1; one must supply this input. 3.2.2.3 Correction Factors 3.2.2.3.1 Speed Emission factors are very sensitive to the average speed that is assumed. In general, emissions tend to increase as average speeds decrease from the 19.6 mph average FTP speed. MOBILE4.1 does not assume an average speed; rather it requires that an estimate of the speed experienced by vehicles operating in the area and roadway segment or collection of interest be specified. MOBILE4.1 adjusts the emission factors for speeds other than 19.6 mph through the use of speed correction factors. These multiplicative adjustments to the base emission factors tend to follow a non-linear relationship that increases the emission levels as speeds decline from 19.6 mph and increase beyond 48 mph.4 3.2.2.3.2 Temperature Emissions from mobile sources are significantly influenced by the ambient temperatures under which they are operating. Temperature has an effect on both the exhaust and the evaporative emission levels. MOBILE4.1 deals with these effects separately. In general, exhaust emissions are at a minimum at the temperature specified for the FTP (75'F), with emissions increasing as temperature either increases or decreases from that value. No ambient temperature is assumed by MOBILE4.1. One must be provided as an input to the model. ___________________________ 4 The speed correction factors in MOBILE5 may be significantly revised at speeds above 48 mph. 10 3.2.2.3.3 Operating Modes Emission factors based on FTP measurements are collected for three separate segments, usually referred to as bags because the vehicle exhaust is collected in three separate teflon bags, each with differing emissions performance. The three bags correspond to the following modes of operation: cold start, hot stabilized, and hot start. Bag 1, the cold start mode, reflects conditions experienced at the beginning of a trip when the engine and the emission control system begin operation at ambient temperature and are not performing at optimum levels (i.e., the catalyst is cold and has not reached the "light off" temperature needed to efficiently control emissions coming from the engine) until part way through the trip.5 The hot start mode, Bag 3, reflects the condition of an engine that has been restarted after being turned off for 10 minutes and, therefore, has not cooled to ambient conditions. Under this circumstance the engine and catalyst are warm and, although not at peak operating efficiency when started, still have significantly improved emissions performance relative to the cold start mode. Bag 2, the hot stabilized mode, reflects the condition of the engine when the vehicle has been in continuous operation long enough for all systems to have attained stable operating temperatures. The proportion of VMT accumulated in cold and hot start modes must be specified based on the conditions in the area to be modeled. Specifications must be made for catalyst and non-catalyst vehicles separately. 3.2.2.3.4 Minor Correction Factors This category has been added to cover the effects of four special correction factors that are available: - Air conditioning; - Extra vehicle loading; - Trailer towing; - NOx humidity. These factors are designed to account for the effect of unusual vehicle operating conditions relative to those experienced in the FTP. Generally, it is difficult to quantify the extent of these vehicle operating parameters, and their effect on emission factors tends to be small. Therefore, EPA recommends that few resources be expended to develop the inputs needed. The effect of the NOx humidity correction factor is also slight, and, unless NOx is of particular concern, little effort should be devoted to its use. 5 "Bag 1" is usually a mix of cold and warmed operation, since, except under very cold ambient conditions, the 505 seconds of driving represented by this bag constitutes a longer period than is needed for the engine and catalyst to get warm. 11 3.2-2.4 Tampering and Misfueling The basic emission factors in MOBILE4.1 receive an adjustment to account for estimates of vehicle tampering rates as a function of accumulated mileage for each gasoline-fueled vehicle category and eight categories of tampering (e.g., air pump disablement, misfueling, etc.). These rates are combined with offsets (the increase in emissions that results from the given type of tampering) and added to the non-tampered emission factors. Options are available to input local tampering rates. The use of local information must be supported by an approved survey. If locally developed information is not available, a national average rate will be used by MOBILE4.1. 3.2.2.5 Control Programs 3.2.2.5.1 Refueling Emissions The refueling of gasoline-fueled vehicles results in the displacement of fuel vapor from the vehicle fuel tank to the atmosphere. There are two basic approaches to the control of vehicle refueling emissions, generally referred to as "Stage III" (at the pump) and "onboard" (in the vehicle) vapor recovery systems. MOBILE4.1 can model refueling emissions with no controls as well as with either or both of the control options. 3.2.2.5.2 Inspection and Maintenance Programs Many areas of the country have implemented I/M programs as a means of further reducing mobile source air pollution. MOBILE4.1 can model the impact of an operating I/M program on the calculated emission factors. There is no average national I/M program; local inputs must be supplied. Details are given in Section 3.3.6.2 of this document and in the MOBILE4.1 User's Guide. 3.2.2.5.3 Anti-Tampering Programs (ATPs) Some areas of the country have implemented these programs to reduce the frequency and related emission impacts of emission control system tampering. MOBILE4.1 allows the effects of such a program on the calculated emission factors to be estimated. Due to the wide variation in the characteristics of ATPs and the lack of a national program, there is no national average estimate of ATP parameters. Details of the required inputs are given in Section 3.3.6.3 of this document and in the MOBILE4.1 User's Guide. 12 3.3 GUIDANCE ON SELECTING MOBILE4.1 INPUTS6 MOBILE4.1 may be used to develop highway vehicle emission factors and emission inventories for use in the State Implementation Plan process.7 The proper version of MOBILE4.1 to use in preparing SIP inventories is the one dated November 4, 1991. Older versions should be discarded or erased.8 This section contains EPA's recommendations and suggestions with regard to determining appropriate MOBILE4.1 inputs. However, for many inputs there is no single correct answer or recommendation that is best for every local area. For those using MOBILE4.1 for SIP-related modeling purposes, it is important that the appropriate EPA Regional Office personnel be kept involved in decisions concerning questionable or controversial assumptions in the MOBILE4.1 modeling and inventory development process. 3.3.1 Emission Factors Description The basic emission rates (BERs) used in MOBILE4.1 are expressed as linear equations and consist of a zero-mile level and one or two deterioration rates.9 There are different BER equations in MOBILE4.1 for each vehicle type/pollutant/model year group, with the model year groups defined on the basis of applicable emission standards and emission control technologies used. Although MOBILE4.1 provides the capability to change the BER equations, the BERs in MOBILE4.1 accurately reflect all promulgated emission standards as of late 1990, and no locality-specific changes to these equations are warranted for use in developing emission factors or inventories for calendar years through 1992. Specifically, no need exists for modification of the BERs in MOBILE4.1 in order to develop emission factors for the development of base year 1990 emission inventories by the states in response to the requirements of the Clean Air Act. ___________________________ 6 This section is in part a condensation of material that appears in the User's Guide to MOBILE4.1, Chapter 2. It is not a substitute for the User's Guide. You are advised to obtain and thoroughly read the User's Guide before running the model. It is available from the National Technical Information Service (NTIS), 5285 Port Royal Road, Springfield, VA 22161 (703/487-4650). The NTIS accession number is PB91-228759. 7 Highway vehicle emission factors and emission inventories for non-attainment areas in California may be developed using the FISAFAC model. 8 While future year inventories are discussed in this document, MOBILE4.1 should not be used for projecting VOC or NOx emissions beyond January 1, 1994, since it does not reflect new standards that begin to have an effect after that date. MOBILE4.1 may be used for CO inventory projections. MOBILE5 will be released in final form in August, 1992 and will allow VOC and NOx projections. 9 A deterioration rate is the gram per mile increase in emissions per 10,000 miles accumulated mileage. 13 Guidance No need exists for modifying the BERs in MOBILE4.1 in order to develop VOC or NOx emission factors for any calendar year through 1992 inclusive,10 or to develop CO emission factors for any calendar year through 2020. 3.3. 1.1 Region Description MOBILE4.1 provides two options for region: low-altitude and high-altitude. Low-altitude emission factors are based on conditions representative of approximately 500 feet above mean sea level (+500 ft MSL), and high-altitude factors are based on conditions representative of approximately +5500 ft MSL. MOBILE4.1, like MOBILE4, does not calculate California emission factors. There have been no revisions to this variable or how it is input to the model since the release of MOBILE4. Guidance For the majority of MOBILE4.1 applications, low-altitude is the appropriate choice. For those areas designated as high- altitude by EPA for mobile source regulatory purposes, generally those counties that lie "substantially" above +4000 ft MSL, high- altitude should be selected.11 3.3.1.2 Calendar Year Description The value used for calendar year in MOBILE4.1 defines the year (as of January 1) for which emission factors are to be calculated. It is frequently referred to as the calendar year of evaluation. MOBILE4.1 has the ability to model emission factors for the years 1960 through 2020 inclusive. There have been no revisions to this variable or how it is input to the model since the release of MOBILE4. ___________________________ 10 EPA expects to update the model to version 5.0 to incorporate all of the requirements of the November 1990 CAA in time for states to project mobile source HC and NOx emissions and demonstrate attainment of the National Ambient Air Quality Standard for ozone. 11 A list of those counties EPA has designated as high- altitude appears in 86.088-30, paragraphs (a)(5)(ii) and (iv), Code of Federal Regulations. 14 Guidance The 1990 base year SIP inventories represent emissions during a typical day in the pollutant season, most commonly summer for ozone and winter for CO. Thus, base year VOC inventories should be based on interpolation of the calendar year 1990 and 1991 MOBILE4.1 emission factors.12, 13, 14 CO SIP inventories should be based on emission factors from January 1990 regardless of the three-month period for which CO is being modeled. Similar instructions apply to the development of Reasonable Further Progress (RFP) inventories. For modeling of specific episode days, the best results will be obtained by interpolating exactly to the day being modeled. In attainment demonstrations, it is acceptable to account for fleet turnover through November 15th of the year being modeled. 3.3.2 Fleet Characteristics 3.3.2.1 Vehicle Miles Traveled Mix by Vehicle Type Description The vehicle miles traveled mix specifies the fraction of total highway VMT that is accumulated by each of the eight regulated vehicle types. The VMT mix is used in MOBILE4.1 only to calculate the composite (all vehicle) emission factor for a given scenario on the basis of the model's eight vehicle class-specific emission factors. ___________________________ 12 For example, if most exceedances of the ozone National Ambient Air Quality Ozone Standard occur during the months of June, July, and August, then the appropriate base year emission factor is the average of the January 1, 1990 and January 1, 1991 emission factors. 13 Since the accuracy gained by interpolating for typical summer days other than July 1st is minimal and since the AIRSAMS mainframe version of MOBILE4.1 for VOC and NOx inventories automatically generates July I emission factors, EPA will accept 1990 VOC and NOx emissions estimates based on July 1st emission factors. Areas preparing draft 1990 inventories may select an input of January 1, 1990 for their ozone season inventory and note this prominently in the documentation. However, the inventory must be switched to a July 1, 1990 basis for the final submission to EPA. 14 January 1st and July 1st evaluations only differ in that the July 1st vehicle fleet is composed of more of the latest model year vehicles and fewer of the 25th and older model year vehicles, as a result of new car sales and scrappage of older vehicles between January I and June 30. The January I vs. July I choice is independent of all temperature and other vehicle operating conditions, which should represent the appropriate pollutant season. 15 MOBILE4.1 calculates a typical urban area VMT mix based on national data characterizing model-year-specific registration distributions and annual mileage accumulation rates by age for each vehicle and fuel type,15 the fraction of travel by each vehicle type that occurs in typical urban areas, and the total number of vehicles of each vehicle type. For SIP-related highway vehicle emission inventory development in moderate and above non-attainment areas, EPA expects states to develop and use their own specific estimates of VMT by vehicle type and highway functional system.16 VMT fractions based on local estimates of VMT by vehicle type should be used as input to MOBILE4.1.17 Each VMT mix supplied as input must consist of a set of eight fractional values, representing the fraction of total mobile source VMT accumulated by each of the eight vehicle types. All values must be between zero and one, and the eight values must sum to 1.0. There have been no revisions to how alternate VMT mixes are supplied to the program as input data since the release of MOBILE4. Guidance Techniques for calculating estimated VMT by vehicle type (and thus, total VW and the VMT mix fractions) from available data sources are described in Chapter 6 of the report, "Techniques for Estimating MOBILE2 Variables.18 Metropolitan Planning Organizations (MPOs) and state Departments of Transportation (DOTs) should also be consulted. Information from these agencies can be used to determine the proportion of passenger vehicles and light duty trucks relative to heavy duty trucks by time of day and facility class. These two groups of vehicles can then be allocated into the eight MOBILE4.1 vehicle classes using the national default mix within each group provided by MOBILE4.1. 3.3.2.2 Annual Mileage Accumulation Rates and Registration Distributions by Vehicle Type and Age Description MOBILE4.1's emission factor calculations rely in part on travel fractions for vehicles of each given age within a vehicle type, which in turn are based on estimates of the average annual mileage accumulation by age (first year to 25th-and-greater years of operation) for ___________________________ 15 Total HDDV registrations and annual mileage accumulations are also distributed within the model by truck weight class. 16 Highway functional systems are commonly designated as the interstate system, other freeways and expressways, other principal arterials, minor arterials, and collectors. 17 Ozone and carbon monoxide non-attainment areas classified as marginal, submarginal, or transitional may use the MOBILE4.1 default VMT mix if no local estimate is readily available. 18 Techniques for Estimating MOBILE2 Variables" and "Additional Techniques for Estimating MOBILE2 Variables," Energy and Environmental Analysis, Inc. for EPA (EPA Contract Number 68- 03-2888). 16 each of the eight vehicle types, and the registration distributions by age (age 0-1 to age 24 and 25+) for each vehicle type, except motorcycles, for which annual mileage accumulation rates and registration distributions are only provided for the first to 12th- and-later years of operation (ages 0-1 to 11 and 12+). For all vehicles except motorcycles, this represents an increase in detail from the 20 years of operation used in MOBILE4.19 To use locality-specific annual mileage accumulation rates by age, a total of 200 input values is required: the estimated annual mileage accumulated by vehicles of each of the eight types for each of 25 ages. To use locality-specific registration distributions by age, a total of 200 input values is also required. For each vehicle type, a set of 25 values is required to represent the fraction of all vehicles of the given type that are of a given age. If both annual mileage accumulation rates by age and registration distributions by age are supplied, the annual mileage accumulation rate corresponding to any vehicle type/age combination accounting for a non-zero fraction of registrations must be positive. That is, if vehicles of a certain type and age are registered, then they are assumed to be driven.20 If locality-specific mileage accumulation rates and/or registration distributions by age are not used, the information in MOBILE4.1 is used for all calendar years evaluated. Guidance Mileage Accumulation EPA recommends, the use of the national annual mileage accumulation rates by age that are included in MOBILE4. 1. Most local sources of data on mileage accumulation rates by age are subject to sampling bias or data entry errors, and the use of such data should be approached with caution. States that wish to use alternate mileage accumulation rates in their development of highway vehicle emission inventories in response to the requirements of the new CAA should obtain prior approval from their EPA Regional Office before using such rates in their emission factor modeling.20 ___________________________ 19 MOBILE4.0 modeled vehicles from age 0 through age 19 with the 20th year representing all vehicles 20 years and older. 20 MOBILE4.1 will issue an error warning if vehicles of a certain type and age are registered but do not accumulate mileage. A warning will also be issued if there are no vehicles of a certain type and age yet the mileage accumulation distribution includes a positive value for that category. 21 If local annual mileage accumulation rates are used, they normally should not change from one evaluation year to the next. 17 Registration Distributions EPA recommends and encourages the use of actual locality- specific 1990 registration distributions by age to develop base year SIP emission inventories.22, 23 Local registration distributions are particularly appropriate for those inventory areas where there are significant differences from the national average. The exception to the use of local data would be in those areas that have relatively few local HDDV registrations, but that experience significant interstate trucking activity. Such areas may want to retain and use the MOBILE4.1 national registration distributions. EPA will issue at a later date additional guidance on how 1990 registration distributions by age can be adjusted to reflect future years. This guidance will provide a mathematical routine that preserves the average age of the fleet in 1990, while retaining the general shape of the local distribution for 1990 and earlier model years.24, 25 Methods for estimating the annual mileage accumulation rates by age and the registration distributions by vehicle type and age are presented in Chapters 2 and 3, respectively, of the report Techniques for Estimating MOBILE2 Variables.26 3.3.2.3 Trip Length Distribution Description Running loss emissions are a form of evaporative volatile organic compound (VOC) emissions that occur while the vehicle is being operated. Running loss emissions are different from "traditional" evaporative emissions that occur after the vehicle has been driven(hot soak evaporative emissions) and while it is parked during periods of rising ambient temperatures (diurnal evaporative emissions). MOBILE4 was the first version of the emission factor model to account for these emissions. In MOBILE4.1 estimates of running loss emissions have been extensively revised. ___________________________ 22 Marginal, sub-marginal, and transitional non-attainment areas may use the MOBILE4.1 distributions for all vehicle types, if local distributions are not available. 23 Registration distributions by age may be developed from data available through state motor vehicle registration records, either directly or commercially through R.L Polk Company. 24 Effectively, the routine will apply a scrappage curve to the existing 1990 registration distribution. The result will be that the pattern of high and low vehicle sales will propagate down the Registration distribution as vehicles age with successive evaluation years. 25 EPA will not accept a locally developed registration distribution that implies that the average age of the vehicle fleet is becoming younger in the future than is reflected in the registration distribution used for the base year unless the state provides adequate justification for the new distribution . 26 "Techniques for Estimating MOBILE2 Variables" and "Additional Techniques for Estimating MOBILE2 Variables," Energy and Environmental Analysis, Inc. for EPA (EPA Contract Number 68- 03-2888). 18 EPA has determined through its running loss emission test programs that the level of running loss emissions depends on several variables: average vehicle speed, ambient temperature, fuel volatility, and the length of the trip.27 Test data show that for any given set of conditions (average speed, ambient temperature, and fuel volatility), running loss emissions are zero to negligible at first, but increase significantly as trip duration lengthens. In MOBILE4, running loss emissions were modeled as direct functions of the input temperature and volatility; average speed and trip duration were held constant within the model to values representative of typical urban area traffic patterns. In MOBILE4.1 running loss emissions are modeled as a direct function of the input temperature, fuel volatility, average speed and trip duration. The input data record of the VMT-weighted trip duration distribution must list the fraction of all travel (VMT) being accumulated over the time period that the emission factors apply: - Under 10 minutes - 11 to 20 minutes - 21 to 30 minutes - 31 to 40 minutes - 41 to 50 minutes - 51 minutes and longer Note that the first value should be the fraction of VMT that occurs in trips that end within 10 minutes of their start, not the fraction of VMT that occurs within 10 minutes of trip start for longer trips. The other values are defined similarly. Note also that the running loss emission factor that is calculated by MOBILE4.1 is a fleet and area-wide average that applies to all of the VMT in all of the trips for each vehicle type. Any geographic disaggregation by VMT density will be only approximate. Situations more heavily affected by emission rates at the end of trips, such as a central business district in the morning rush hour, are more complex to model. EPA staff should be consulted in such cases. If this option of specifying trip length distributions is not selected, then MOBILE4.1 will calculate the running loss emission factors on the basis of the typical trip duration included in the model. Guidance Since reliable local data on the distribution of trip durations is often unavailable, EPA will accept the use of the model's typical distributions for the estimation of running loss VOC emission factors for the 1990 emission inventory. Where the transportation modeling process ___________________________ 27 "Length of trip" as used here refers to the duration of the trip (how long, in minutes, the vehicle has been traveling), not on the distance traveled in the trip (how far the vehicle has been driven). 19 can produce reliable inputs for trip duration, use of such inputs will produce a more accurate estimate of the benefits attributable to SIP measures which shorten average trip lengths without eliminating entire trips.28 Most SIP inventories will be constructed by adding together emission estimates for several functional classifications of roadway. EPA recommends that one area-wide trip length distribution be used for all roadway classifications, due to the complexity of trying to develop separate distributions. 3.3.2.4 Diesel Sales Fractions Description Sales of diesel powered light-duty vehicles and trucks underwent a surge in the late 1970's and early 1980's, peaking at 5.9% of LDV sales in the 1981 model year, and at 9.3% of LDT sales in the 1982 model year. Since then diesel sales have fallen precipitously, to virtually zero for LDVs29 and to about 0.2% of LDTs since the 1988 model year. While MOBILE4 contained forecasts of increasing diesel sales for both LDVs and LDTs through the early 1990's, MOBILE4.1 assumes a more limited and slower increase from the current, very low diesel sales rates. MOBILE4.1 assumes that future LDV diesel sales never exceed 0.3% and that future LDT sales never exceed 2.15%. MOBILE4.1, like earlier versions of the model, uses a single set of registration distributions by age and annual mileage accumulation rates to describe all LDVs, and another set to describe all LDTs. This is due in part to the fact that it is nearly impossible to develop such information for gas and diesel LDVs and LDTs separately, and in part since there is little evidence to suggest that typical use patterns and mileage accumulation rates are different for gas and diesel LDVs and for gas and diesel LDTs. Diesel sales fractions represent the share of all sales30 in a given model year that are diesel-fueled vehicles. The use of model-year-specific diesel sales fractions allows MOBILE4.1 to internally split the LDVs and LDTs into gas and diesel sub- categories, which have distinctly different emission rates. If vehicle registration data that distinguish between gas and diesel LDVs and gas and diesel LDTs exist, it is possible to input local diesel sales fractions by model year. These data must be supplied for every calendar year of evaluation; since they apply to vehicles of ___________________________ 28 The use of trip length distributions other than those included in MOBILE4.1 should be adequately documented in the SIP. 29 LDV diesel sales accounted for less than 0.05% of total LDV sales in the 1988-1990 model years. 30 Diesel sale fractions apply only to LDVs and LDTs. Heavy duty gasoline and diesel vehicles are treated separately within the MOBILE models. 20 Ages 1, 2, 3, ..., to 25-and-older, different sets of fractions are required for each calendar year. Including this information will create a more accurate highway mobile source emission inventory estimate. For each scenario, the fractions of LDV and of LDT sales that were diesel for each model year from the calendar year of evaluation back to 25 model years ago must be entered as a model input. For example, if the calendar year of evaluation is 1990, then diesel sales fractions for model year 1990, 1989, 1988, ..., 1967, and 1966-and-older LDVs and LDTs must be provided. If two different scenarios are being run, both for calendar year 1990 but with other differences, then the same set of diesel fractions would have to be supplied again as part of the second scenario. If a scenario with calendar year 1995 was also being run, then the diesel sales fractions would represent model year 1995, 1994,..., 1972, and 1971-and-older vehicles. The same values would be used for the model years in common to the two sets of sales fractions, but the five oldest model year values would not be used in the second sequence to make room for the five most recent model years sales fractions. The 50 diesel sales fractions, 25 each for LDVs and LDTs, must be specified as fractions. For example, if in a given area the 1990 model year had diesel sales of 1.1% of LDVs and 1.8% of LDTs, the diesel sales fractions are 0.011 and 0.018 respectively. The values are supplied in pairs: The first two values on the first record are the diesel sales fractions for one year old LDVs and LDTs;31 the second two values are the sales fractions for two year old LDVs and LDTs, and so on, with the last two values on the third record being the sales fractions for LDVs and LDTs 25 years and older. Guidance This option has been provided in MOBILE4.1 for two reasons. First, some users performing highway vehicle emission factor modeling may have access to vehicle registration data, or data from other sources, enabling them to characterize diesel sales of LDVs and LDTs in the area being modeled. Particularly if these sales fractions differ significantly from those included in MOBILE4.1, it will enhance the accuracy of the emission factors and inventory to use those sales fractions as model input. Second, as can be seen by the sharp rise and equally sharp fall of diesel sales in the late 1970's and early 1980's, it is extremely difficult to forecast diesel sales fractions for future model years. This provision will allow modelers to account for future increases in diesel sales, if such increases occur.32 ___________________________ 31 A vehicle is assumed to be one year old if the model year of that vehicle is the same as the evaluation year. Thus, a 1990 model year vehicle is assumed to be one year old in 1990. Similarly, a 1989 model year vehicle is assumed to be two years old in 1990. 32 EPA does not envision any circumstances in which a state or locality should substitute its own projection of future diesel sales for that built into MOBILE4.1. 21 3.3.3 RVP Determination Description The basic emission rates that underlie the emission factor calculations are developed from vehicles tested at FTP conditions, including a fuel volatility of 9 psi Reid Vapor Pressure (RVP). For other fuel volatility levels, MOBILE4.1 adjusts the emission factors for exhaust and evaporative emissions as well as for running loss, resting loss, and refueling loss emissions. Vehicle emission rates increase as the volatility of the fuel increases, for temperatures between 45'F and 75'F and for RVP values between 9.0 and 11.7 psi. This effect is most pronounced at higher RVP levels and at higher ambient temperatures. Since there is a significant interaction effect between RVP and temperature, it is important that RVP and temperature inputs to MOBILE4.1 be consistent. That is, RVP and temperature should be chosen in such a way that they represent the same time period.33 In general, use July 1990 RVP levels to estimate VOC and CO emissions during the ozone non-attainment season . Use January 1990 RVP levels to estimate CO emissions during the CO non-attainment season. Guidance Gasoline survey data should be used to determine historical RVP, if quality-assured survey data are available. The survey samples should be drawn at the pump, not "upstream" of the pump at a refinery or fuel distribution terminal.34, 35, 36 ___________________________ 33 High RVP fuel is used in the winter months to facilitate vehicle starting. If the same high RVP fuel were used in the summer, a vehicle could experience vapor lock and stall. 34 EPA will also accept the use of RVP determined from either of two regularly published gasoline volatility surveys, one performed by oil companies and compiled by the National Institute for Petroleum and Energy Research (NEPER) and the other sponsored by the Motor Vehicle Manufacturers' Association (MVMA) and conducted by the Southwest Research Institute (SwRI). Since the NIPER survey is not city-specific, the MVMA survey is the preferred choice. 35 A third survey is sponsored by a consortium of oil companies, the American Petroleum Institute (API), and is also conducted by Southwest Research Institute. This survey includes more cities and sampling months, but the data from it axe proprietary. 36 A final possible source of RVP data is the sampling done by some states to enforce their state RVP limits. However, before using this approach, it should be discussed with EPA to determine if RVP data collected for enforcement purposes are suitable for determining average RVP for inventory purposes. 22 Procedure for Determining RVP Using the MVMA Survey Obtain the appropriate edition of the MVMA National Gasoline Survey, published semi-annually37 by the Motor Vehicle Manufacturers' Association. Ordering and price information is available from: Motor Vehicle Manufacturers' Association 300 New Center Building Detroit, NE 48202 Phone (313) 872-4311 Use the summer MVMA survey to estimate VOC and CO emissions during the ozone non-attainment season. Use the winter MVMA survey to estimate CO emissions during the CO non-attainment season. If the average RVP for a specific city is desired and that city is included in the MVMA survey, use the RVP for that city.38 Find the average RVP value(s) for the city or cities selected from the summary table that appears near the end of the MVMA survey. The average RVP for regular unleaded gasoline is provided for all cities; the average RVP for premium and/or mid-grade unleaded and/or regular leaded gasoline is also provided for many cities. Ignore RVP values for any ethanol blends that may also be listed.39 Calculate the overall average RVP from the averages supplied for different grades of gasoline as follows: ___________________________ 37 The data reflected in MVMA National Gasoline Survey are generally collected as of January 15th and July 15th. 38 If no city from the inventory area is included in the MVMA survey, use the RVP for a city that is both geographically close to the city with the largest population within the inventory area and that was subject to the same EPA, state, or ASTM volatility limit at the time. If fuel distribution patterns are known, give preference to a survey city with the same distribution system. If the RVP for outlying areas of a state is desired (for example, to complete the inventory for the fringes of an Airshed modeling domain) and a city within that state is included in the MVMA survey, use the RVP for that city. If two or more cities in that state are included in the MVMA survey, average the RVPs from those cities. If no city within the state is included in the MVMA survey, use the RVP for a city that is both geographically close to the state and that was subject to the same EPA, state, or ASTM volatility limit at the time. If fuel distribution patterns are known, give preference to a survey city with the same distribution system. 39 As the use (and market share) of regular leaded fuel continues to decline, survey values for mid-grade unleaded are replacing those for regular leaded. 23 - If only the average RVP for regular unleaded gasoline is provided, use that value; - If the average RVP for regular unleaded and one of the other fuel grades (premium unleaded, mid-grade unleaded, or regular leaded) is provided, weight the values using the local sales mix, if known, or at 75 percent regular unleaded and 25 percent of the other grade for which the RVP is provided, according to equation 3-1. Average RVP = 0.75 - (average RVP of regular unleaded) + 0.25 - (average RVP of premium unleaded or mid-grade unleaded or regular leaded) (3-1) - If the average RVP is provided for three fuel grades, weight the values, using the local sales mix, if known, or at 50 percent regular unleaded, 25 percent premium unleaded, and 25 percent mid-grade unleaded or regular leaded, according to equation 3-2. Average RVP = 0.50 - (average RVP of regular unleaded) + 0.25 - (average RVP of premium unleaded) + 0.25 - (average RVP of mid-grade unleaded or regular leaded) (3-2) If the average RVP is provided for all four fuel grades, weight the values using the local sales mix, if known, or at 50 percent regular unleaded, 20 percent premium unleaded, 20 percent mid-grade unleaded, and 10 percent regular leaded, according to equation 3-3. Average RVP = 0.50 - (average RVP of regular unleaded) + 0.20 - (average RVP of premium unleaded) + 0.20 - (average RVP of mid-grade unleaded) + 0.10 - (average RVP of regular leaded) (3-3) The RVP thus calculated is used as the value of historical RVP in MOBILE4.1. Procedure for Determination of RVP Using the NIPER Survey Obtain the appropriate edition of the report Motor Gasolines, published semi-annually by NIPER. Samples for the summer survey are taken in June, July, and August. Samples for the winter survey are taken in December, January, and February. 24 The cost per report is $60, and it is available from: Cheryl L. Dickson National Institute for Petroleum and Energy Research P. 0. Box 2128 Bartlesville, OK 74005 Phone (918) 336-2400 Use the summer NIPER survey to estimate VOC and CO emissions during the ozone non-attainment season. Use the winter NIPER survey to estimate CO emissions during the CO non-attainment season. The NIPER survey divides the country into seventeen districts, which are described in a table and illustrated on a map of the U.S. Use the district in which the inventory area is located. If the RVP for an entire state is desired and that state lies entirely within one district, use that district. If the state lies within two or more districts, average the RVPs from the districts within which the state lies. Table 4 of the NIPER survey presents the average RVP of three grades of gasoline for each district: regular unleaded, regular leaded, and premium unleaded.40 Determine the overall average RVP of gasoline in a district by weighting these three values by the local sales mix, or, in the absence of local data, by an assumed sales mix of 50 percent regular unleaded, 25 percent premium unleaded and 25 percent regular leaded according to equation 3-4. Average RVP = 0.50 - (average RVP of regular unleaded) + 0.25 - (average RVP of premium unleaded) + 0.25 - (average RVP of regular leaded) (3-4) The calculated RVP (or the average of the calculated RVPs, if the area for which the RVP is being determined resides within two or more districts) is then used as the value of historical RVP in MOBILE4.1.

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