Vehicle inspection in the United States

In the United States, vehicle safety inspection is goverened by each state individually. 18 states have a periodic (annual or biannual) safety inspection program, while Maryland requires an inspection prior to registration or transfer of ownership only.

Under the Clean Air Act (1990), states are required to implement vehicle emission inspection programs in metropolitan areas whose air quality does not meet federal standards. The specifics of those programs vary from state to state. Some states, including Kentucky and Minnesota, have discontinued their testing programs in recent years with approval from the federal government.

In most states, such inspections are done at state-operated garages, usually near the local DMV office. Pennsylvania is a notable exception, instead opting to have privately-owned garages doing inspections with approval from PennDOT. The flip side to this though is that some independently-run garages will do what is commonly known in Pennsylvania as a "lick-'em-and-stick-'em", which simply has the person pay the inspection fee and has the sticker replaced without actually checking the vehicle. This is illegal in Pennsylvania, which among other penalties could lead to a fine for the garage and a revocation of their inspection privileges. Other independently-run garages as well as chains like Pep Boys, Midas, and car dealerships are more stringent and follow PennDOT guidelines for inspections.

States and Federal Districts with periodic (e.g., annual) vehicle safety inspections

* Delaware (every year or every two years; brand new cars are exempt for the first four years provided the car remains with the same owner. Older cars registered as antiques do not require emissions testing.)
* District of Columbia (every two years; the requirement for safety inspection for private cars will end October 1, 2009)
* Hawaii (every year, except brand new vehicles receive an inspection valid for two years, emergency vehicles, school vehicles, rental cars, vehicles used in public transportation, and other, every six months)
* Louisiana (every year; emission test in the Baton Rouge metropolitan area parishes of Ascension, East Baton Rouge, Iberville, Livingtston and West Baton Rouge)
* Maine (every year; emission test in Cumberland County)
* Massachusetts (safety inspection and emissions testing annually). In 2008 the tailpipe test for 1995 model year and older vehicles was discontinued, vehicles without OBD-II systems receive a visual check of exhaust components
* Mississippi (safety inspection every year)
* Missouri (Odd numbered model year renews in odd numbered year, even model year renews in even year, except new vehicles not previously titled which are exempt during the model year and the year following, or vehicles displaying historical plates, which are completely exempt.; emissions testing in St. Louis city, St. Louis County, St. Charles County, Franklin County, and Jefferson County)
* New Hampshire (annually, emissions testing for model year 1996 and newer vehicles))
* New Jersey (safety and emissions testing every two years, brand new cars are exempt for the first four years. Effective 2010, the new car four-year exemption will transfer to the next owner if sold before the end of the four years . Older cars registered as antiques do not require emissions testing. Diesel cars under 10000 lb are also exempt.
* New York (annual safety and emissions). Model year 1996 and newer vehicles are subject to an OBD-II emissions inspection while older cars receive a visual check of exhaust components. Vehicles registered in the five boroughs of New York City as well as Long Island, Westchester County and Rockland County require a tailpipe smog-test if they are not OBD II equipped. All OBD II vehicles in those areas (1996 model year or newer) require only the OBD II test. And any vehicle 26 model years old or more does not require an emissions check of any sort. Newly registered vehicles from another state with a current inspection sticker are exempt until the out-of-state sticker expires or for one year, whichever is sooner.
* North Carolina (every year; emissions inspections in 48 of 100 counties (1996-newer, except new cars), exempting diesels and cars 35 years or older. Starting Nov 1, 2008 there won't be an inspection decal issued upon passing. )
* Pennsylvania every year for most vehicles; every six months for tractor-trailers, school vehicles (including school buses and school vans), motor coaches, mass transit buses, ambulances, fire department trucks, etc.; emissions inspections every year in 25 of 67 counties (stricter in the Pittsburgh and Philadelphia metro areas) (no emission inspection for diesel vehicles))annual inspection, emission, and semi-annual inspection stickers are color-coded, which tells which month of the year they expire. This makes it easier for police to be aware of expired stickers.
* Rhode Island (safety and emission inspection every two years)
* Texas (every year; emission test in the largest urban areas - Houston Metro, Dallas Metroplex, Austin, San Antonio, and El Paso)
* Utah (every two years for the first eight years, then every year)
* Vermont (every year)
* Virginia (every year; emission inspection every two years in urban and suburban jurisdictions in Northern Virginia)
* West Virginia (every year - safety)

States with safety inspection only required prior to sale or transfer

* Alabama
* Maryland (emission inspection required every two years in all counties)(not required in every county. The VEIP testing network consists of 18 centralized inspection stations located in 13 counties and Baltimore City)

States which only require federally mandated emissions inspections

* Arizona (Phoenix and Tucson metro areas only) annually, depending on age and type of vehicle)
* California (for most ZIP codes, every two years for all vehicles made after 1975 which are more than six years old)
* Colorado (in some localities, every year or two, depending on age and type of vehicle)
* Connecticut (every two years)
* Georgia (metropolitan Atlanta area only, every year, most recent three model year cars are exempt)
* Illinois every two years after the vehicle is four years old (Chicagoland and eastern suburbs of St. Louis, Missouri)
* Indiana (Lake and Porter counties only, every two years)
* New Mexico (Albuquerque metro area)
* Nevada (Clark County and Washoe County areas)
* Ohio (Cuyahoga, Geauga, Lake, Lorain, Medina, Portage, and Summit counties only) cars that are four years old or less do not have tested, after that period they have to tested. Testing is based on a odd-even year system. If a car was bought in 2000, it wont tested until 2010, if a car was purchased in 2003, then it will need to be tested in 2009. Franklin County (Columbus) and Hamilton County (Cincinnati) will also have be under emission testing effective in 2010. Ohio does not charge a fee for emission testing, due to Ohio's tobacco settlement.
* Oregon (Portland and Medford metro areas only)
* Tennessee in conjunction with annual registration renewal (Davidson, Hamilton, Rutherford, Sumner, Williamson or Wilson counties and city of Memphis only)
* Washington (urban areas of Clark, King, Pierce, Snohomish and Spokane counties)
* Wisconsin (Kenosha, Milwaukee, Ozaukee, Racine, Sheboygan, Washington and Waukesha; every two years)

States requiring an inspection only when bringing a vehicle from another State or jurisdiction

* Nebraska (all vehicles, ATVs, minibikes and trailers brought into Nebraska from Out-of-State)

States without safety or emissions inspections

* Alaska
* Arkansas
* Florida
* Idaho (Ada County has a county level program that requires testing)
* Iowa
* Kansas
* Kentucky
* Michigan
* Minnesota
* Montana
* North Dakota
* Oklahoma
* South Carolina
* South Dakota
* Wyoming

From http://en.wikipedia.org/

Vehicle inspection

Vehicle inspection is a procedure mandated by national or subnational governments in many countries, in which a vehicle is inspected to ensure that it conforms to regulations governing safety, emissions, or both. Inspection can be required at various times, e.g., periodically or on transfer of title to a vehicle. If required periodically, it is often termed periodic motor vehicle inspection; typical intervals are every two years and every year.

In some jurisdictions, proof of inspection is required before a vehicle licence or license plate can be issued or renewed. In others, once a vehicle passes inspection, a decal is attached to the windshield, and police can enforce the inspection law by seeing whether the vehicle displays an up-to-date decal. In the case of a vehicle lacking a windshield (e.g., a trailer or motorcycle), the decal is typically attached to the vehicle body or license plate.

With regard to safety inspection, there is some controversy over whether it is a cost-effective way to improve road-traffic safety.

From http://en.wikipedia.org/

Supplementarity

The supplementarity principle, also referred to as the supplementary principle, is one of the main principles of the Kyoto Protocol. The concept is that internal abatement of emissions should take precedent before external participation in flexible mechanisms. These mechanisms include emissions trading, Clean Development Mechanism (CDM), and Joint Implementation (JI).

Emissions trading basically refers to the trading of emissions allowances (carbon credits) between one regulated entity and a less pollutive entity. This trading of permits results in a marginal economic disincentive to the buyer and a marginal economic incentive the abater.

CDM and JI are flexible mechanisms based on the concept of a carbon project. These projects reduce GHG voluntarily (outside the capped sectors) and therefore can be imported into the capped sector to aid in compliance.

The supplementarity principle is found in three articles of the Kyoto Protocol: article 6 and 17 with regards to trading, and article 12 with regards to the clean development mechanism.

Article 6.1 states that "The acquisition of emission reduction units shall be supplemental to domestic actions for the purposes of meeting commitments under Article 3". Article 17 states that "Any such trading shall be supplemental to domestic actions for the purpose of meeting quantified emission limitation and reduction commitments under that article". Article 12.3.b states that "Parties included in Annex I may use the certified emission reductions accruing from such project activities to contribute to compliance with part of their quantified emission limitation and reduction commitments under Article 3".

The actual meaning of the principle has been heavily argued since the signing of Kyoto Protocol in 1997. The COP/MOP is the body that represents the signers/ratifiers of the protocol and they have not been able to agree on a specific definition of the limit on use of flexible mechanisms. The original text has been interpreted to mean that anywhere from 3-50% of emissions could be offset by trading mechanisms. However, the only determination that has been thustly made is that the actual value of supplementarity should be decided at the country level.

In the United States RGGI (Regional Greenhouse Gas Initiative) has set a precedent in that it will initially allow only up to 3.3% compliance occur by means of offset projects (carbon projects). This value can increase to 5% and ultimately 10% if certain price thresholds are exceeded in the region.

From http://en.wikipedia.org/

Sandbag (non-profit organisation)

Sandbag is a non-profit campaign group designed to increase public awareness of emissions trading. The organisation was announced in 2008 by Bryony Worthington and was the first (and founding) member of The Guardian's Environment Network.

The Sandbag website centres on the European Union's Emission Trading Scheme and allows its members to campaign to reduce the number of permits in circulation and to purchase permits and cancel them. Large corporations (such as vehicle manufacturers) must obtain these permits from the EU if they need to emit greenhouse gases during production. The purchase of these permits by the public prevents their use by corporations. Worthington described her organisation as "a bit like burning money in front of someone so they can't spend it on something bad."

Worthington gave the first public talk on Sandbag (as well as emissions trading in general) at a geeKyoto meeting in London during May 2008.

From http://en.wikipedia.org/

Portable Emissions Measurement System

A Portable Emissions Measurement System (PEMS) is essentially a lightweight ‘laboratory’ that is used to test and/or assess mobile source emissions (i.e. cars, trucks, buses, construction equipment, generators, trains, cranes, etc.) for the purposes of compliance, regulation, or decision-making. Governmental entities like the United States Environmental Protection Agency (USEPA), the European Union, as various states and private sector entities have begun to utilize PEMS in order to reduce both the costs and time of mobile emissions decisions. Various state, federal, and international agencies began referring to this shorthand term in early 2000, and the nickname became part of industry parlance.

Background

Since the mid-1800’s, Dynamometers (or "dyno" for short) has been used to measure torque and rotational speed (rpm) from which power produced by an engine, motor or other rotating prime mover can then be calculated. A chassis dynamometer measures power from the engine through the wheels. The vehicle is parked on rollers which the car then turns and the output is measured. These dynos can be fixed or portable. Because of frictional and mechanical losses in the various drivetrain components, the measured horsepower is generally 15-20 percent less than the brake horsepower measured at the crankshaft or flywheel on an engine dynamometer . Historically though, dynamometer emission tests are very expensive, and have usually involved removing fleet vehicles from service for a long period of time. Also, the data derived from such testing is not representative of “real world” driving conditions, and cannot be deemed as quantifiable, especially due to the relatively low amount of repeatable tests at such a facility.

Introduction of PEMS

Portable systems began to be developed in the late 1990’s in order to better identify actual in-use performance of vehicles. PEMS are designed to measure emissions during the actual use of an internal-combustion engine vehicle or equipment in its regular daily operation, in a manner similar to operation on a chassis Dynamometer. This methodology and approach has been recognized by the USEPA

Many governmental entities (such as the USEPA and the United Nations Framework Convention on Climate Change or UNFCCC) have identified target mobile-source pollutants in various mobile standards as CO2, NOx, Particulate Matter (PM), Carbon Monoxide (CO), Hydrocarbons(HC), to ensure that emissions standards are being met. Further, these governing bodies have begun adopting in-use testing program for non-road diesel engines, as well as other types of internal combustion engines, and are requiring the use of PEMS testing. It is important to delineate the various classifications of the latest ‘transferable’ emissions testing equipment from PEMS equipment, in order to best understand the desire of portability in field-testing of emissions.

Defining Portability

An important step in the evaluation of a “Portable Emissions Measurement System” (PEMS) device is to define what a PEMS device is as well as to understand various classifications of ‘transferable vehicle testing equipment’:

Definition of the Term “Portable”

The word portable typically conveys an object that is “Carried or moved with ease, such as a light or small typewriter.”

Definition of the Term “Mobile”

The definition of mobile is essentially “…capable of moving or of being moved readily from place to place: a mobile organism; a mobile missile system.”

Definition of the Term “Instrumented”

Instrumented means to be “a device for recording, measuring, or controlling, especially such a device functioning as part of a control system.”

Therefore, the subtle difference between ‘portable’ and ‘mobile’ is that a portable system is a lightweight device able to be carried, whereas a mobile system can be readily moved, and ‘Instrumented’ means that the testing equipment has been incorporated into the host system. These distinctions are critical, especially considering additional guidelines from various US and International standards.

Definition determined by the National Institute for Occupational Safety and Health (NIOSH)

The National Institute for Occupational Safety and Health (NIOSH) defines these terms based on an equation known as the “NIOSH Lifting Equation” (http://www.cdc.gov/niosh/docs/94-110/pdfs/94-110-b.pdf

) and the “NIOSH Procedures for Analyzing Lifting Jobs (http://www.cdc.gov/niosh/docs/94-110/pdfs/94-110-c.pdf

). These clearly outline safety procedures and equipment. (these are also specified in the “Occupational Safety Hazard Act 29 CFR parts 1903, 1904, and 1910)

Safety Guidelines and Standards (the NIOSH Lifting Equation)

It is imperative to refer to existing federal standards and guidelines when determining a proper ergonomically safe and correct procedure. Not only is this important to ensure the safety of the worker(s), but also to ensure the reduction in potential future liability. Therefore, the revised NIOSH Lifting Equation is an excellent source of information to determine what a single worker should or shouldn’t perform.

Based upon the NIOSH lifting equation and assuming that this diagram is analgous to the lifting of a PEMS into the cab of a heavy duty truck the upper threshold of the total weight of a PEMS device typically should not exceed 45 lb (20 kg)., in order to be congruent with national and international safety standards. This not only allows for much more safe maneuverability and ease of use, but it also reduces the amount of workers required to safely perform such tasks.

Economic Advantage of PEMS Equipment

Because a PEMS unit is able to be carried easily by one person from jobsite to jobsite, and can be used without the requirement of ‘team lifting’, the required emissions testing projects are economically viable. Simply put, more testing can be done more quickly, by less workers, dramatically increasing the amount of testing done in a certain time period. This in turn, significantly reduces the ‘cost per test’, yet at the same time increases the overall accuracy required in a ‘real-world’ environment. Due to the fact that the law of large numbers will create a convergence of results, it means that repeatability, predictability, and accuracy are enhanced, while simultaneously reducing the overall cost of the testing.

On-road Emissions Patterns Identified by PEMS

Nearly all modern engines, when tested new and according to the accepted testing protocols in a laboratory, produce relatively low emissions well within the set standards. As all individual engines of the same series are supposed to be identical, only one or several engines of each series get tested. The tests have shown that:

1. The bulk of the total emissions can come from relatively short high-emissions episodes
2. Emissions characteristics can be different even among otherwise identical engines
3. Emissions outside of the bounds of the laboratory test procedures are often higher than under the operating and ambient conditions comparable to those during laboratory testing
4. Emissions deteriorate significantly over the useful life of the vehicles
5. There are large variances among the deterioration rates, with the high emissions rates often attributable to various mechanical malfunctions

These findings are consistent with published literature, and with the data from a myriad of subsequent studies. They are more applicable to spark-ignition engines and considerably less to diesels, but with the regulation-driven advances in diesel engine technology (comparable to the advances in spark-ignition engines since 1970’s) it can be expected that these findings are likely to be applicable to the new generation diesel engines. Since 2000, multiple entities have utilized PEMS data to measured in-use, on-road emissions on hundreds of diesel engines installed in school buses, transit buses, delivery trucks, plow trucks, over-the-road trucks, pickups, vans, forklifts, excavators, generators, loaders, compressors, locomotives, passenger ferries, and other on-road, off-road and non-road applications. All the previously listed findings were demonstrated; in addition, it was noticed that extended idling of engines can have a significant impact on the emissions during subsequent operation.

Also, PEMS testing identified several engine “anomalies” where fuel-specific NOx emissions were two to three times higher than expected during some modes of operation, suggesting deliberate alterations of the engine control unit (ECU) settings. Such data set can be readily used for developing emissions inventories, as well as to evaluate various improvements in engines, fuels, exhaust after-treatment and other areas. (Data collected on “conventional” fleets then serves as “baseline” data to which various improvements are compared.) This data set can also be examined for compliance with not-to-exceed (NTE) and in-use emissions standards, which are ‘US-based’ emission standards that require on-road testing.

PEMS Accuracy, Measurement Errors

The question often arises as to the target accuracy of PEMS. As PEMS are typically limited in size, weight and power consumption, it is often difficult for PEMS to offer the same accuracy and variety of species measured as is possible with top of the line laboratory instrumentation. For this reason, objections were raised against using PEMS for compliance verification.

On the other hand, fleet emissions deduced from laboratory measurements can be subject to significant inaccuracies if the selected engines and operating conditions were not representative of the fleet, or if deliberate anomalies (i.e., dual mapping of the ECU) were not demonstrated during laboratory testing.

The question of how accurate a monitoring system needs to be therefore cannot be objectively answered, neither can a monitoring system be easily designed, without first considering the intended application of the system and the errors associated with different approaches.

It is expected that a variety of on-board systems will be designed, ranging from suitcase-sized PEMS to instrumented trailers towed behind the tested truck. The benefits of each approach need to be considered in light of other sources of errors associated with emissions monitoring, notably vehicle-to-vehicle differences, and the emissions variability within the vehicle itself. In other words, one needs to consider the total of:

1. The difference between what is measured and what is actually emitted during a test
2. The difference between what is emitted during the test and what the vehicle emits during its everyday duties
3. The difference between the emissions characteristics of the tested vehicle and the overall emissions levels of the entire fleet.

For example, when evaluating a benefit of cleaner fuels on a fleet of city buses, one needs to compare taking a bus out of service, installing a laboratory-grade monitoring system, loading it with sandbags and driving it on a simulated route against testing several buses on their regular routes, with passengers on board, using a simpler (and possibly less accurate) monitoring system.

Additional PEMS Criteria

Another important aspect that needs to be evaluated is the safety of using PEMS on public roadways. Extensions of the tailpipe, lines and cables extending far beyond the vehicle sides, lead-acid batteries located in the passenger compartment of a bus, sharp objects, hot components accessible to bystanders, equipment blocking emergency exits or interfering with the driver, loose components likely to be caught on moving parts, and other potential hazards need to be examined. Also, any modifications to or disassembly of the tested vehicle (i.e., drilling into the exhaust, removing intake air system) need to be examined for their acceptance by both fleet managers and drivers, especially on passenger-carrying vehicles. The source of power for PEMS is a concern, as only a limited amount of power can be extracted from the vehicle electrical system. Sealed lead-acid batteries, fuel cells and generators have been used as external power sources, each with a potential significant hazard when driven on the road. A PEMS also has to be practical. Installation time and the expertise level required to perform installation and to operate the PEMS will have a significant impact on the cost of the test, and on the number of vehicles tested. Versatility (ability to test different vehicles) may be important if testing dissimilar engines or vehicles. Total size, weight and transportability of the PEMS needs to be considered when testing at different locations, including any consumables such as calibration gases. Any restrictions on transport of hazardous materials (I.E.Flame ionization detector (FID) fuel or calibration gases) need to be taken into the account. The ability of the test crew to repair PEMS in the field using locally available resources can also be essential when testing away from the base. Thus, PEMS evaluation protocol should be expanded. In addition to the laboratory comparison testing, which is a measure of how accurately PEMS measures when operated in a laboratory, the accuracy and repeatability of PEMS should also be examined on the road, possibly while driving along a well-defined, repeatable route, or while driving chassis dynamometer cycles on a test track.

PEMS Suitability to Application

Ultimately, it should be demonstrated to show that a PEMS is suitable to the desired application. If the ultimate goal is to verify the compliance with in-use emissions requirements, a fleet of vehicles with known characteristics – including engines with dual-mapping and otherwise non-compliant engines – should be made available for testing. It should be then up to the PEMS manufacturers to practically demonstrate how these non-compliant vehicles can be identified using their system.

Testing Volume and Safe Repeatability

In order to achieve the required amount of ‘testing volume’ needed to validate real-world testing, three points must be considered:

1. System accuracy
2. Federal and/or state health and safety guidelines and/or standards
3. Economic viability based on the first two points.

Once a particular portable emissions system has been identified and pronounced as accurate, the next step is to ensure that the worker(s) are properly protected from work hazards associated with the task(s) being performed in the use of the testing equipment. For example, typical functions for a worker may be to transport the equipment to the jobsite (i.e. car, truck, train, or plane), carry the equipment to the jobsite, and lift the equipment into position.

Advantages of PEMS

On-road vehicle emissions testing is very different from the laboratory testing, bringing both considerable benefits and challenges: As the testing can take place during the regular operation of the tested vehicles, a large number of vehicles can be tested within a relatively short period of time and at relatively low cost. Engines than cannot be easily tested otherwise (i.e., ferry boat propulsion engines) can be tested. True real-world emissions data can be obtained. The instruments have to be small, lightweight, withstand difficult environment, and must not pose a safety hazard. Emissions data is subject to considerable variances, as real-world conditions are often neither well defined nor repeatable, and significant variances in emissions can exist even among otherwise identical engines. On-road emissions testing therefore requires a different mindset than the traditional approach of testing in the laboratory and using models to predict real-world performance. In the absence of established methods, use of PEMS requires careful, thoughtful, broad approach. This should be considered when designing, evaluating and selecting PEMS for the desired application.

From http://en.wikipedia.org/

Onboard refueling vapor recovery

Onboard Refueling Vapor Recovery (ORVR) is a vehicle emission control system that captures fuel vapors from the vehicle gas tank during refueling. The gas tank and fill pipe are designed so that when refueling the vehicle, fuel vapors in the gas tank travel to an activated carbon packed canister, which adsorbs the vapor. When the engine is in operation, it draws the gasoline vapors into the engine intake manifold to be used as fuel. ORVR has been mandated on all passenger cars in the United States since 2000 by the United States Environmental Protection Agency‎. The use of onboard vapor recovery is intended to make vapor recovery at gas stations obsolete.

From http://en.wikipedia.org/

Not-To-Exceed (NTE)

The Not-To-Exceed (NTE) standard recently promulgated by the United States Environmental Protection Agency (EPA) ensures that heavy-duty engine emissions are controlled over the full range of speed and load combinations commonly experienced in use. NTE establishes an area (the “NTE zone”) under the torque curve of an engine where emissions must not exceed a specified value for any of the regulated pollutants. The NTE test procedure does not involve a specific driving cycle of any specific length (mileage or time). Rather it involves driving of any type that could occur within the bounds of the NTE control area, including operation under steady-state or transient conditions and under varying ambient conditions. Emissions are averaged over a minimum time of thirty seconds and then compared to the applicable NTE emission limits.

Creation of NTE

NTE standards were created by the EPA as a result of a consent decree between the EPA and several major diesel engine manufacturers. These manufacturers included Caterpillar, Cummins, Detroit Diesel, Mack, Mack's parent company Renault Vehicles Industriels, and Volvo Truck Corp. These manufacturers were accused of violating the Clean Air Act by installing devices that defeat emission controls. As part of the resulting consent decree settlement with the EPA, these manufacturers were assessed heavy fines and were subjected to new emissions standards which included NTE.

Current requirements to achieve engine operation in the "NTE Zone"

When all of the following conditions are simultaneously met for at least 30 seconds, and engine is considered to be operating in the NTE zone.

1. Engine speed must be greater than 15% above idle speed
2. Engine torque must be greater than or equal to 30% of maximum torque.
3. Engine power must be greater than or equal to 30% of maximum power.
4. Vehicle altitude must be less than or equal to 5,500 feet (1,700 m).
5. Ambient temperature must be less than or equal to 100 °F (38 °C) at sea level to 86°F at 5,500 feet (1,700 m).
6. Brake specific fuel consumption ([BSFC) must be less than or equal to 105% of the minimum BSFC if an engine is not coupled to a multi-speed manual or automatic transmission.
7. Engine operation must be outside of any manufacturer petitioned exclusion zone.
8. Engine operation must be outside of any NTE region in which a manufacturer states that less than 5% of in-use time will be spent.
9. For Exhaust gas recirculation (EGR) equipped engines, the intake manifold temperature must be greater than or equal to 86-100 degrees Fahrenheit, depending upon intake manifold pressure.
10. For EGR-equipped engines, the engine coolant temperature must be greater than or equal to 125-140 degrees Fahrenheit, depending on intake manifold pressure.
11. Engine after treatment systems’ temperature must be greater than or equal to 250 degrees Celsius.

Visual representations of NTE Zone



Example NTE Control Area for Heavy-Duty Diesel Engine With 100% Operational Engine Speed Less Than 2400 rpm



Example NTE Control Area for HeavyDuty Diesel Engine With 100% Operational Engine Speed Greater Than 2400 rpm

Description

The NTE test, as defined in CFR 86.1370-2007, establishes an area (NTE control area) under the torque curve of an engine where emissions must not exceed a specified emission cap for a given pollutant. The NTE cap is set at 1.25 times the FTP emission limit as described in the subsection above. For 2005 model year heavy-duty engines, the NTE emission cap for NMHC plus NOx is 1.25 times 2.5 grams per brake horsepower-hour, or 3.125 grams per brake horsepower-hour. The basic NTE control area for diesel engines has three basic boundaries on the engine’s torque and speed map. The first is the upper boundary that is represented by an engine’s maximum torque at a given speed. The second boundary is 30 percent of maximum torque. Only operation above this boundary is included in the NTE control area. The third boundary is determined based on the lowest engine speed at 50 percent of maximum power and highest engine speed at 70 percent of maximum power. This engine speed is considered the “15 percent operational engine speed”. The fourth boundary is 30% of maximum power

Controversy and deficiency regarding NTE standards

Controversy

A controversial issue is the applicability of the NTE limits to the real-world driving. In order for NTE standards to apply, the engine needs to remain within the NTE zone (limits include operation at a minimum of 30% of rated power) for at least 30 seconds. Concerns arose that performing this action could prove to be difficult, as each time the driver removes the foot from the accelerator pedal, or shifts gears on vehicles with manual transmission, the engine leaves the NTE zone.

In urban or suburban driving, this happens relatively often, to the point that NTE standards are applicable only a very small portion of the operation or, in some cases, not at all. The probability of the engine remaining within the NTE zone for over 30 seconds also decreases with the advent of high-power engines. For example, if the power required to maintain a motorcoach or an over-the-road truck at highway cruising speed is somewhere around 150 hp (110 kW), the probability that a 475 hp (354 kW) engine will consistently operate at loads above 30%, without “dips” to lower power levels, can be relatively small.

These concerns were confirmed by studies carried out by West Virginia University (WVU) under the Consent Decrees. WVU found that “remaining for 30 seconds within the NTE zone can be quite difficult. The resulting low NTE availability poses a problem as many measurements within the NTE area have to be rejected along with those from outside the NTE area. The question arises if in this way all real-life emissions are sufficiently ‘well reflected’ in the NTE test results”

A second issue of concern in the same vein is a case when an engine is compliant within the NTE zone, but exhibits elevated NOx at power levels just outside the NTE zone, or at idle. For reasons such as this the Working Group On Off Cycle Emissions is studying whether an extension of the NTE zone is rational as they ponder if there are spots on the engine map (outside of the NTE zone) that have a significant contribution in real life emissions. Their preliminary findings echo those of WVU as they found that the time of engine operation in the NTE zone is rather low.

EPA admitted deficiencies

According to the US EPA there are technical limitations of NTE under limited operating conditions which have caused the EPA to “carve-out” (see graphs above) certain portions of the NTE zone to allow for these deficiencies. Excerpts as follows:

“NTE zone was defined by a desire to have a homogeneous emissions limit. Carve-outs within that zone exclude certain areas of operation from NTE consideration or limit how much emissions from that operation can contribute to an NTE result, deficiencies allow temporary exceedences of the NTE standards due to technical limitations under limited operating conditions. The idea is not to hold the manufacturer responsible for NTE compliance during modes where the engine is not capable of operating or where it is not technically feasible to meet the NTE standards.”

Regarding the particulate matter “carve-out”

"PM-specific region is “carved out” of the NTE control area. The PM specific area of exclusion is generally in the area under the torque curve, where engine speeds are high and engine torque is low, and can vary in shape depending upon several speed-related criteria and calculations detailed in the regulations. Controlling PM in this range of operation presents fundamental technical challenges which we believe can not be overcome in the 2004 time frame. Specifically, the cylinder pressures created under these high speed and low load conditions are often insufficient to prevent lube oil from being ingested into the combustion chamber. High levels of PM emissions are the result. Furthermore, we do not believe that these engines spend a significant portion of their operating time in this limited speed and torque range"

Lawsuits and settlement

Lawsuits

In 2001, five separate lawsuits were filed against the US EPA by the Engine Manufacturers Association (EMA) and several individual trucking industry entities (such as International Truck and Engine Corporation). Each of those lawsuits challenged the legality and technological feasibility of certain engine emission control standards in EPA regulations now referred to as NTE requirements. In their challenge, EMA stated that to determine whether an engine meets a primary emission standard, engines are tested and assessed using a standardized 20-minute emissions laboratory test known as the Federal Test Procedure. The NTE, by contrast, has no specified test procedure and potentially could apply over an almost infinite number of test conditions. This, in the manufacturers’ view, made it virtually impossible to ensure total compliance with the NTE—since there is no real or practical way to test an engine under all conceivable conditions—and so made the NTE both unlawful (the CAA authorizes EPA to adopt engine standards AND accompanying test procedures) and technically infeasible.

Settlement

On June 3, 2003, the parties finalized a settlement of their disputes pertaining to the NTE standards. The parties agreed upon a detailed outline for a future regulation that would require a manufacturer-run heavy-duty in-use NTE testing (“HDIUT”) program for diesel-fueled engines and vehicles. One section of the outline stated:

“The NTE Threshold will be the NTE standard, including the margins built into the existing regulations, plus additional margin to account for in-use measurement accuracy. This additional margin shall be determined by the measurement processes and methodologies to be developed and approved by EPA/CARB/EMA. This margin will be structured to encourage instrument manufacturers to develop more and more accurate instruments in the future.”

HDIUT and Portable Emissions Measurement Systems (PEMS)

The ultimate objective of the new HDIUT program is to allow for a significant streamlining of engine certification if a truly robust in-use emissions testing program proves feasible and cost effective. Time-consuming and expensive laboratory assessments of engines could then give way to real-world, real-time emissions assessments that efficiently provides more relevant data.

Basically, the HDIUT is an industry agreed to manufacturer run, in-use, on-road testing program. It builds upon the original NTE standard. It is designed to focus on compliance in the real world, and relies on emissions testing, utilizing Portable Emissions Measurement Systems (PEMS) with NOx, HC, CO and PM being the pollutants to be measured. Measurement Accuracy Margins are being established to account for the emissions measurement variability associated with the PEMS in-use.

From http://en.wikipedia.org/

Mobile Emission Reduction Credit (MERC)

A Mobile Emission Reduction Credit (MERC) is an emission reduction credit generated within the transportation sector. The term “Mobile Sources” refers to motor vehicles, engines, and equipment that move, or can be moved, from place to place. Mobile sources include vehicles that operate on roads and highways ("on-road" or "highway" vehicles), as well as nonroad vehicles, engines, and equipment. Examples of mobile sources are passenger cars, light trucks, large trucks, buses, motorcycles, earth-moving equipment, nonroad recreational vehicles (such as dirt bikes and snowmobiles), farm and construction equipment, cranes, lawn and garden power tools, marine engines, ships, railroad locomotives, and airplanes. In California, mobile sources account for about 60 percent of all ozone forming emissions and for over 90 percent of all carbon monoxide (CO) emissions from all sources.

Background

Government agencies worldwide have struggled with finding new and innovative approaches to address the growing problem of air pollution and global warming. Experts in the field have recognized the importance of developing solutions to reduce greenhouse gas (GHG) emissions. Most proposed strategies to mitigate global climate change focus on reducing the dominant source of GHG emissions to the atmosphere - combustion of fossil fuels, which releases carbon dioxide. Carbon dioxide emissions represent about 84 percent of total U.S. GHG emissions. In the United States, most carbon dioxide (98 percent) is emitted as a result of the combustion of fossil fuels; consequently, carbon dioxide emissions and energy use are highly correlated.

General Emission Reduction Strategies

The two main approaches that have been developed to address this problem include a command-and-control regulatory system and Emissions credit trading. Three broad types of Emissions credit trading programs have emerged: reduction credit, averaging, and cap-and-trade programs. In such programs, a central authority, such as an air pollution control district or a government agency, sets limits or "caps" on certain pollutants. Companies or fleets of vehicles that intend to exceed these limits may buy emission reduction credits (ERCs) from entities that are able to remain below the designated limits. This transfer is usually referred to as a trade.

International Approach to Emission Reduction Credits

Emission trading is contemplated on an international level. The Kyoto Protocol is an agreement made under the United Nations Framework Convention on Climate Change (UNFCCC). The Kyoto Protocol binds ratifying nations to a similar system, with the UNFCCC setting caps for each nation, and utilizes a Clean Development Mechanism (CDM) system. The primary reduction strategy under the Kyoto Protocol is a trading system that essentially makes carbon credits a commodity like oil or gas.

United States Approach to Emission Reduction Credits

The United States (which did not ratify the Kyoto Protocol) has the most experience with domestic emissions trading markets. The Clean Air Act (1970) is a federal law that requires the United States Environmental Protection Agency (EPA) to develop and enforce regulations to protect the general public from exposure to airborne contaminants that are known to be hazardous to human health. The Clean Air Act (1990) or Clean Air Act amendments of 1990 authorized the use of market-based approaches such as emission trading to assist states in attaining and maintaining air quality for all criteria pollutants. EPA's subsequent interpretive rulings expressly allow owners of new sources to obtain emission credits from other companies that operate facilities located in the same air quality control region. To implement an emissions offset program, many states have developed regulations allowing sources to register their emissions reduction credits as ERCs that can be sold to companies required to offset emissions from new or modified sources. Brokerage companies typically handle sales between companies having surplus ERCs and those wanting to acquire such credits.

All commonly accepted ERCs in the United States must meet each of five criteria before they can be certified by the relevant regulatory authority as an ERC. Namely, the emission reduction must be real, permanent over the period of credit generation, quantifiable, enforceable, and surplus to emission reductions that are already needed to comply with an existing requirement (local, state, or Federal) or air quality plan. These criteria are intended to ensure that the emission reduction is a permanent reduction from the emissions that would otherwise be allowed to offset the permanent increase in emissions from the new or expanding source.

Steps to Create a MERC

The steps involved to create a MERC are as follows:

1. Identifying an emissions reduction technology for a pollutant
2. Identifying a mobile source
3. Utilize a Portable Emissions Measurement System to measure emissions of the pollutant and take first measurements of the pollutant from the mobile source
4. Analyze the measurements to develop a baseline emissions amount
5. Apply the emissions reduction technology to the mobile source to provide a modified mobile source
6. Connect the Portable Emissions Measurement System to the modified mobile source and take second measurements of the modified mobile source
7. Analyze the second measurements to develop a modified emissions amount
8. Quantify the mobile emissions reduction produced by the emissions reduction technology
9. Convert the mobile emissions reduction into a tradable commodity

Monetization of a MERC

The process of converting the mobile emissions reduction into a tradable commodity consists of converting the reduction or a portion of the reduction of emissions into at least one tradable credit, and marketing and monetizing the credit. This is followed by receiving information to identify a customer account, assigning the mobile emissions reduction to the customer account, calculating a MERC from the mobile emissions reduction, and crediting the MERC to the customer account. What follows is the exchanging the of MERC in the customer account for monetary assets this includes the following steps:

1. Debiting the MERC from the customer account
2. Receiving information to identify a second customer or purchaser
3. Calculating an emissions amount of the pollutant for the purchaser
4. Assigning a liability value to the emissions amount for the purchaser
5. Accepting payment from the purchaser
6. Using the payment to purchase at least one MERC for the purchaser
7. Crediting the MERC as assets against the liability value assigned to the second customer for the emissions amount, whereby the emissions amount and the liability value in the second customer account is reduced accordingly

Target Pollutants of Mobile Emission Reduction Credits

At present, the pollutant may be selected from a group consisting of nitrogen oxides (NOx), carbon monoxides (CO), carbon dioxides (CO2), hydrocarbons (HC), sulfur oxides (SOx), particulate matter (PM) and volatile organic compounds (VOCs). The emissions reduction technology may be selected from a group consisting of alternative fuels, vehicle repairs, vehicle replacements, vehicle retrofits and hybrid engines. The mobile source may be selected from a group consisting of passenger cars, light trucks, large trucks, buses, motorcycles, off-road recreational vehicles, farm equipment, construction equipment, lawn and garden equipment, marine engines, aircraft, locomotives and water vessels.

From http://en.wikipedia.org/

Idle reduction

Idle reduction is type of automobile emissions control aimed at reducing the amount of energy wasted by an idling vehicle. When a vehicle's engine is not being used to move the vehicle, it can be shut off entirely—thereby conserving fuel and reducing emissions—while other functions like accessories and lighting are powered by an electrical source other than the alternator. Each year, long-duration idling of truck and locomotive engines emits 11 million tons of carbon dioxide, 200,000 tons of oxides of nitrogen, and 5,000 tons of particulate matter into the air.

Idle reduction is particularly significant for vehicles in heavy traffic and trucks at the estimated 5,000 truck stops in the US. Many hybrid electric vehicles employ idle reduction to achieve better fuel economy in traffic. America's fleet of around 500,000 long-haul trucks consumes over a billion gallons (3.8×109 l; 830 million imp gal) of diesel fuel per year. Services such as IdleAire and Shorepower provide power at truck stops to resting truckers who would otherwise need to continue idling during mandatory breaks. Because the United States Department of Transportation mandates that truckers rest for 10 hours after driving for 11 hours, truckers might park at truck stops for several hours. Often they idle their engines during this rest time to provide their sleeper compartments with air conditioning or heating or to run electrical appliances such as refrigerators or televisions. There are other technologies that can reduce the use of fuel to heat or cool the cab when the vehicle is traditionally idling overnight. These can be battery or fuel powered but in either case, use less fuel, do no harm to the vehicle's engine, and add far fewer or even no additional emissions into the atmosphere.

From http://en.wikipedia.org/

FutureGen

FutureGen is a US government project announced by President George W. Bush in 2003; its initial plan involved the construction of a near zero-emissions coal-fueled power plant to produce hydrogen and electricity while using carbon capture and storage.

In December 2007, Mattoon Township, Coles County, Illinois northwest of Mattoon, Illinois was chosen as the site for the plant from among four finalists in Illinois and Texas. On January 29, 2008, the Department of Energy announced a restructuring of the FutureGen project, which was claimed necessary due to rising costs. In June 2008, the government announced a call for proposals to elicit commercial involvement in the restructuring.

Original project

The original incarnation of FutureGen was as a public-private partnership to build the world's first near zero-emissions coal-fueled power plant. The 275-megawatt plant would be intended to prove the feasibility of producing electricity and hydrogen from coal while capturing and permanently storing carbon dioxide underground. The Alliance intended to build the plant in Mattoon Township, Coles County, Illinois northwest of Mattoon, Illinois, subject to necessary approvals (issuing a “Record of Decision”) by the Department of Energy (DOE) as part of the National Environmental Policy Act (NEPA) process.

FutureGen was to be designed, developed and operated by the FutureGen Industrial Alliance, a non-profit consortium of coal mining and electric utility companies formed to partner with the DOE on the FutureGen project. The project was still in the development stage when its funding was cancelled in January 2008. The Alliance decision of the location of the host site, subject to DOE's completing NEPA environmental reviews, was announced in December 2007 after a two-year bidding and review process. Construction was scheduled to begin in 2009, with full-scale plant operations to begin in 2012.

The estimated gross project cost, including construction and operations, and excluding offsetting revenue, was $1.8 billion. The project was governed by a legally binding cooperative agreement between DOE and the Alliance. Under the agreement, DOE was to provide 74% of the project’s cost, with private industry contributing the other 26%. The DOE also planned to solicit the financial support and participation of international governments in the FutureGen project, since by 2020 more than 60% of man-made greenhouse gas emissions are expected to come from developing countries. Foreign financial support was to offset a portion of DOE’s cost-share. As of January 2008, the foreign governments of China, India, Australia, South Korea, and Japan had expressed interest in participating and sharing the cost of the project.

FutureGen was to sequester carbon dioxide emissions at a rate of one million metric tons per year for four years, which is the scale a Massachusetts Institute of Technology (MIT) report cites as appropriate for proving sequestration. The MIT report also states that “the priority objective with respect to coal should be the successful large-scale demonstration of the technical, economic, and environmental performance of the technologies that make up all of the major components of a large-scale integrated CCS system — capture, transportation and storage.” An injection field test similar to this was done in Norway.

In March 2009 Washington Post reported that U.S. Secretary of Energy Steven Chu expressed support for continuing the project using stimulus funds (after some changes that have not yet been specified) and making it a part of a larger portfolio of research plants developed in collaboration with other countries.

From http://en.wikipedia.org/

Emisstar

Emisstar LLC is an environmental consulting practice focused on mobile emissions technology, policy, and implementation. Considering business and public health, the company focuses on reducing and controlling air pollutants from mobile sources using technology and minding relevant policy impacts and implications. Headquartered in Austin, Texas, but with offices in New Hampshire, New York and California, the firm's services range in scope from regional to national, offering clients in both the public and private sectors with in-depth of knowledge clean air markets and insight into many levels of emissions-related areas of industry and government.

Practice areas and services

Emisstar offers services that aim to reduce emissions through grant programs, project management, applied technology while also finding opportunities for diversification, penetration, and expansion in clean air markets. The company's practice areas, as listed on their website:

Sustainable Transportation Services: Creating multi-phase plans for transportation and logistics oriented businesses that reduce an organization's carbon footprint and emissions such as greenhouse gases while using technologies that increase efficiency while creating fuel savings encompasses Emisstar's Sustainable Transportation Services. Emisstar helps clients obtain U.S. Environmental Protection Agency SmartWay certification through the implementation of the program's Action Plan, including model calculations and guide development.

Strategic Advisory Services: Emisstar constantly monitors clean air markets, to identify and predict opportunities for market penetration, development and expansion. By assessing the impact of emissions-related legal regulations, Emisstar can relay the relevant impacts to paying clientele.

Advanced Vehicle Technology: Harnessing available and original technology, Emisstar provides emissions solutions and technology demonstrations for onroad, nonroad, marine and locomotive vehicles and equipment including exhaust aftertreatment retrofits and idle reduction in addition to biodiesel and alternative fuels.

Environmental Compliance Services: Emisstar helps clients meet environmental regulatory compliance standards as set by organizations like the California Air Resources Board (CARB), the EPA and the Mine Safety and Health Administration (MSHA).

Incentive Program Guidance: Guiding clients through the constantly-changing rules of State and Federal incentive guidance grant programs (such as the Texas Emissions Reductions Program

) represents a significant portion of the company's services. Emisstar helps clients receive grant funding for vehicle and equipment upgrades, retrofits, and replacements, as well as renewable and clean energy projects.

Project Management: With special concentration on vehicular retrofits, Emisstar puts into effect extensive projects utilizing relationships with dealers and lawmakers with the company's own technical know-how.

Testing Services: Emisstar provides engine and chassis tests through a network of U.S. laboratory-based facilities as well as on-board, Portable Emissions Measurement System (PEMS) to evaluate environmental performance through measured emissions. These tests can help evaluate the environmental performance of alternative and biodisel fuels, renewable energy and emission-reducing technologies and provide independent third-party verification of vehicle and greenhouse gas emissions.

Projects and Areas of Focus

NYMTC: The New York Metropolitan Transportation Council commissioned Emisstar to create a plan that would reduce diesel particulate matter and nitrogen oxide emissions in the New York City area. Emisstar recommended several measures, including fleet modernization and retrofits, idle reduction support, and use of biodiesel fuel in conjunction with diesel particulate filters while also suggesting funding options.

TERP: The Texas Emissions Reduction Program (TERP) seeks to reduce nitrogen oxide emissions in non-attainment areas through upgrades, retrofits, or replacement of dirty diesel equipment. Emisstar helps clients apply for TERP grants after assessing fleets, performing emissions calculations, and preparing applications while offering guidance through the program's required scrappage and reimbursement phases.

New York City Best Available Technology Project Recognized as the first official implementation of the best technology practices stipulated under New York Local Law 77, Emisstar retrofitted nonroad, heavy duty construction equipment at the Croton Water Treatment Project in the Bronx, New York. This project implements Diesel Particulate Filters, Active and Passive Diesel Particulate Filters, and Selective Catalytic Reduction technologies.

Clean Diesel Technology Nonroad Field Demonstration Program In a partnership with Southern Research Institute (SRI), Emisstar implemented a diesel retrofit project for the New York Metropolitan Area (NYMA) using CARB and EPA verfified particulate matter and nitrogen-oxides emission control technologies. Emisstar evaluated and ranked these technologies through in-use emissions testing of nonroad equipment.

From http://en.wikipedia.org/

Emission intensity

An emission intensity is the average emission rate of a given pollutant from a given source relative to the intensity of a specific activity; for example grams of carbon dioxide released per megajoule of energy produced, or the ratio of greenhouse gas emissions produced to GDP. Emission intensities are used to derive estimates of air pollutant or greenhouse gas emissions based on the amount of fuel combusted, the number of animals in animal husbandry, on industrial production levels, distances traveled or similar activity data. Emission intensities may also be used to compare the environmental impact of different fuels or activities. The related terms emission factor and carbon intensity are often used interchangeably, but "factors" exclude aggregate activities such as GDP, and "carbon" excludes other pollutants.

From http://en.wikipedia.org/

Demand Responsive Transit Exchange

Just as in financial world there are stock exchanges, Commodities Exchanges and Bond Exchanges, there also now exists a Demand Responsive Transit Exchange.

A DRT Exchange exists to provide a measure of liquidity in the transit markets, which will better serve all participants.

A Demand Responsive Transit Market is a system for effecting the purchase and sale of transit fulfillment using supply and demand to eventually set the price. Wholesale transactions in transit can then be cleared and settled by the Demand Responsive Transit Exchange Operator or a special-purpose independent entity charged exclusively with that function.

Much in the same way as the electricity market became deregulated and allowed for innovation in financial instruments, a full feldged DRT Exchange will allow many new innovations to flourish.

History of the Demand Responsive Transit Exchange

The concept of the DRT Exchange was first coined by technology thinktank Crane Dragon, after having noticed that mathematical models for Credit Contagion also similaly described the event where 2 people who do not know each other travel to and from the same general localities at around the same time each day. They are closely correlated in their transit behaviour but do not know it. Much in the same way as when a large company files for bankruptcy, there are many other companies who will be adversely affected even if on the surface they seem to be unrelated. A matrix to represent these correlations would assist greatly in risk management.

From http://en.wikipedia.org/

Cement kiln

Cement kilns are used for the pyroprocessing stage of manufacture of Portland and other types of hydraulic cement, in which calcium carbonate reacts with silica-bearing minerals to form a mixture of calcium silicates. Over a billion tonnes of cement are made per year, and cement kilns are the heart of this production process: their capacity usually define the capacity of the cement plant. As the main energy-consuming and greenhouse-gas–emitting stage of cement manufacture, improvement of their efficiency has been the central concern of cement manufacturing technology.

From http://en.wikipedia.org/

Carbon monitoring

Carbon dioxide monitoring refers to tracking how much carbon dioxide is produced by particular activity at a particular point in time. For example, it may refer to tracking carbon dioxide emissions from land use change, such as deforestation or agriculture, or from burning fossil fuels, whether in a power plant, automobile, or other device. Because carbon dioxide is the most common of the greenhouse gasses causing global warming, monitoring carbon emissions is widely seen as crucial to any effort to reduce emissions and thereby slow climate change. Monitoring carbon emissions is key to the cap-and-trade program currently being used in Europe, and will be necessary for any such program that may be launched in the United States. The lack of reliable sources of consistent data on carbon emissions is a significant barrier to efforts to reduce emissions. Sources of such emissions data include:

Carbon Monitoring for Action (CARMA)- An online database provided by the Center for Global Development, that includes plant-level emissions for more than 50,000 power plants and 4,000 power companies around the world, as well as the total emissions from power generation of countries, provinces (or states), and localities. Carbon emissions from power generation account for about 25 to 30 percent of all global CO2 emissions. Similar databases do not yet exist for other emissions sources.

From http://en.wikipedia.org/

AP 42 Compilation of Air Pollutant Emission Factors

The AP 42 Compilation of Air Pollutant Emission Factors, was first published by the U.S. Public Health Service in 1968. In 1972, it was revised and issued as the second edition by the U.S. Environmental Protection Agency (EPA). In 1985, the subsequent fourth edition was split into two volumes. Volume I includes stationary point and area source emission factors, and Volume II includes mobile source emission factors. Volume I is currently in its fifth edition and is available on the Internet. Volume II is no longer maintained as such, but roadway air dispersion models for estimating emissions from onroad vehicles and from non-road vehicles and mobile equipment are also available on the Internet.

In routine common usage, Volume I of the emission factor compilation is very often referred to as simply AP 42.

Introduction

Air pollutant emission factors are representative values that attempt to relate the quantity of a pollutant released to the ambient air with an activity associated with the release of that pollutant. These factors are usually expressed as the weight of pollutant divided by a unit weight, volume, distance, or duration of the activity emitting the pollutant (e.g., kilograms of particulate emitted per megagram of coal burned). Such factors facilitate estimation of emissions from various sources of air pollution. In most cases, these factors are simply averages of all available data of acceptable quality, and are generally assumed to be representative of long-term averages.

The equation for the estimation of emissions before emission reduction controls are applied is:

E = A × EF

and for emissions after reduction controls are applied:

E = A × EF × (1-ER/100)

where:
E = emissions, in units of pollutant per unit of time
A = activity rate, in units of weight, volume, distance or duration per unit of time
EF = emission factor, in units of pollutant per unit of weight, volume, distance or duration)
ER = overall emission reduction efficiency, in %

Emission factors are used by atmospheric dispersion modelers and others to determine the amount of air pollutants being emitted from sources within industrial facilities.

Chapters in AP 42, Volume I, Fifth Edition

Chapter 1 External Combustion Sources
Chapter 2 Solid Waste Disposal
Chapter 3 Stationary Internal Combustion Sources
Chapter 4 Evaporation Loss Sources
Chapter 5 Petroleum Industry
Chapter 6 Organic Chemical Process Industry
Chapter 7 Liquid Storage Tanks
Chapter 8 Inorganic Chemical Industry
Chapter 9 Food and Agricultural Industries
Chapter 10 Wood Products Industry
Chapter 11 Mineral Products Industry
Chapter 12 Metallurgical Industry
Chapter 13 Miscellaneous Sources
Chapter 14 Greenhouse Gas Biogenic Sources
Chapter 15 Ordnance Detonation
Appendix A Miscellaneous Data & Conversion Factors
Appendix B.1
Particle Size Distribution Data and Sized Emission Factors
for Selected Sources
Appendix B.2 Generalized Particle Size Distributions
Appendix C.1 Procedures for Sampling Surface/Bulk Dust Loading
Appendix C.2
Procedures for Laboratory Analysis of Surface/Bulk Dust
Loading Samples

Chapter 5, Section 5.1 "Petroleum Refining" discusses the air pollutant emissions from the equipment in the various refinery processing units as well as from the auxiliary steam-generating boilers, furnaces and engines, and Table 5.1.1 includes the pertinent emission factors. Table 5.1.2 includes the emission factors for the fugitive air pollutant emissions from the large wet cooling towers in refineries and from the oil/water separators used in treating refinery wastewater.

The fugitive air pollutant emission factors from relief valves, piping valves, open-ended piping lines or drains, piping flanges, sample connections, and seals on pump and compressor shafts are discussed and included the report EPA-458/R-95-017, "Protocol for Equipment Leak Emission Estimates" which is included in the Chapter 5 section of AP 42. That report includes the emission factors developed by the EPA for petroleum refineries and for the synthetic organic chemical industry (SOCMI).

In most cases, the emission factors in Chapter 5 are included for both uncontrolled conditions before emission reduction controls are implemented and controlled conditions after specified emission reduction methods are implemented.

Chapter 7 "Liquid Storage Tanks" is devoted to the methodology for calculating the emissions losses from the six basic tank designs used for organic liquid storage: fixed roof (vertical and horizontal), external floating roof, domed external (or covered) floating roof, internal floating roof, variable vapor space, and pressure (low and high). The methodology in Chapter 7 was developed by the American Petroleum Institute in collaboration with the EPA.

The EPA has developed a software program named "TANKS" which performs the Chapter 7 methodology for calculating emission losses from storage tanks. The program's installer file along with a user manual, and the source code are available on the Internet.

Chapters 5 and 7 discussed above are illustrative of the type of information contained in the other chapters of AP 42. It should also be noted that many of the fugitive emission factors in Chapter 5 and the emissions calculation methodology in Chapter 7 and the TANKS program also apply to many other industrial categories besides the petroleum industry.

Estimating Air Emissions associated with Fossil Fuels and Stored Materials

The only emissions monitored are those associated with the burning of fossil fuels and the storage of some materials which generate toxic emissions. kWh are not monitored for emissions, and the discussion in this section does not address electricity.

There are three ways to monitor emissions of air contaminants:

* Annual or Biannual stack tests. This is a very expensive option.
* Continual Emissions Monitoring systems (CEM systems). This is also an expensive option.
* Parametric Monitoring, also known as AP42. This method converts fuel and electricity usage into emissions amounts using EPA emissions factors. This is the least expensive and most common method.
* The EPA usually will accept emissions data gathered using the AP42 method. However these emissions factors are averages and are based upon older less efficient equipment and may err on the high side. As a result some may choose alternative methods of tracking emissions. AP42 Emissions Factors for fossil fuels can be downloaded from the EPA website.

Estimating Air Emissions associated with Electricity Usage

The EPA does not offer AP42 factors that convert kWh into emissions. Although the generation of electricity is often associated with pollutants fouling the air, this is not always the case. Electricity generation using Nuclear, Solar, Wind and Hydro does not pollute the air at all. Depending upon the hour of the day, the electricity used by an office building may come from Coal and Natural Gas which foul the air, or Nuclear, Solar or Hydro, which do not.

There are a few lists of emissions factors that convert kWh into likely amounts of emissions. The Department of Energy offers emissions factors that convert electricity into emissions. However, the Leonardo Academy produced a more substantial list of emissions (CO2, VOCs, NOX, CO, SO2, PM10, Mercury, Cadmium and Lead) factors for the EPA in 1998, that Leonardo updates yearly using EPA Data. These emission factors are listed by State. Although there is no consensus on statewide emissions factors for electricity, reasonable estimates can be found using these factors.

From http://en.wikipedia.org/

10:10

10:10 is a British climate change campaign for a 10% reduction in carbon emissions in 2010. The project aims to demonstrate public support, apply pressure to the government to commit to national cuts, and set a precedent for the UN Climate Change Conference in Copenhagen in December. The Guardian reports it has attracted diverse support from 35,000 individuals, businesses and organisations, such as Gordon Brown, Microsoft UK, local councils, universities, and The Guardian newspaper.

It was founded in September 2009 by Franny Armstrong, director of The Age of Stupid, with the aim of capturing the public imagination using individual action in a way similar to the Make Poverty History campaign.

Background

After producing climate change film Age of Stupid, Armstrong recollects being asked by people what they should do themselves for climate sustainability. 10:10 aims to further and demonstrate a cultural change towards environmental sustainability. This is being done in preparation for the UN Climate Change Conference in Copenhagen in December of this year. By documenting public support for UK cuts, Armstrong aims to "break the deadlock" of shifting carbon culpability in the directions of major players abroad.

Support

The campaign has attracted the support of major and diverse public figures and organisations, described by the Guardian as from a "cross-section" of UK society. On 18 October, the campaign had 35,000 individual supporters, 1,200 businesses and 850 other bodies including schools and hospitals. There had also been heavy media coverage around the launch date, and there have been regular articles about the campaign's progress published by The Guardian.

Politicians

The entire British cabinet, consisting of Gordon Brown and his senior ministers, committed to reduce their personal emissions by 10% in 2010, with David Cameron, the Conservative front bench, and Liberal Democrat leader Nick Clegg pledging equal support to the cause.

Since the Party conference season in 2009 when Nick Clegg and Ed Milliband urged the members of the Liberal Democrats and Labour party respectively to commit to the 10:10 cause, support within the political sphere has been steadily growing and to date over 150 Members of Parliament (MPs) have signed up. 10:10 also counts amongst its supporters 53 local councils, three British Embassies, nine Members of the Scottish Parliament (MSPs) and five Members of the European Parliament (MEPs).

On October 21, 2009 the Liberal Democrats put an Opposition Day motion before the House of Commons that sought to commit the entire UK government and public sector to the 10:10 campaign. The motion was defeated by 297 votes to 226 under heavy pressure from the government, but an amendment was passed that committed an additional £20m to help government departments to further reduce their emissions.

Celebrities

Dozens of high-profile individuals have signed up to the scheme. They include chefs Delia Smith and Hugh Fearnley-Whittingstall, fashion designers Vivienne Westwood and Stella McCartney, TV & radio presenters Kevin McCloud and Sara Cox, writers Ian McEwan, Alain de Botton, Carol Ann Duffy and Simon Armitage, artist Anish Kapoor, comedian Rory Bremner, and actors Peter Capaldi, Samantha Morton and Colin Firth.

Individuals involved in politics who support 10:10 include climate change expert Nicholas Stern, former London mayor Ken Livingstone, leading sociologist Anthony Giddens, Liberty director Shami Chakrabarti, socialite and environmentalist Zac Goldsmith, and established campaigner Peter Tatchell.

Educational bodies

The 350 educational institutions signed up consist of large variety of groups, including primary schools and students' unions, as well as names such as King's College London, the University of Edinburgh,, the University of Liverpool, the University of Westminster, the Science Museum and the Tate Modern art gallery.

Companies

These include Royal Mail, Microsoft, Tottenham Hotspur football club, the British Medical Journal, O2, the FTSE-100 listed insurance company Aviva and commercial property company Land Securities, B&Q, Bafta, Adidas, Pret A Manger, and the Guardian newspaper, which is engaged in a special partnership with the scheme.

Other organisations

These include several NHS trusts, Cheshire Police Constabulary, the Women's Institute the government Environment Agency watchdog, and the British Fashion Council. Faith groups have shown interest in the campaign, with the entire Methodist Church of Great Britain in support, and Quakers in Britain encouraging its members to sign up "as a matter of urgency".



Launch

On September 1, 2009, the campaign was launched at Tate Modern, London. Many high profile organisations and individuals had joined the advance sign-up and some of these were present at the launch. Stornoway and Reverend and the Makers played a free gig, which was compered by Sara Cox. Guests were able to sign up to the campaign using a bank of laptops and the first 3000 were given a free 10:10 tag. In addition, guests were given champagne donated by delivery-only supermarket Ocado, a 10:10 signatory.

Methods

The project has produced different guidance on how to cut emissions for individuals, businesses, educational bodies and other organisations. The Guardian has also published articles from various groups and people on how they plan to cut their emissions.

Action for individuals includes fewer plane journeys and lower heating, as well as changing light bulbs, replacing old fridges and freezers and turning appliances off. Supporters also have the suggestion to drive less, eat local and in-season fruit & veg (rather than meat or dairy), to buy long-lasting or second hand goods, as well as repairing and re-using old belongings, avoiding unnecessary packaging or products, cooking only what is needed, and reducing water usage.

The Royal Mail bid has become controversial, due to plans of an increase in its vehicles at the expense of foot or cycle transport, and its decision six years ago to halt railway transport of mail.

Tags

Like the white bands of the Make Poverty History campaign, 10:10 supporters can buy special tags to show their support. These tags are made from aluminium reclaimed from scrap aeroplanes. 150,000 have been produced from the plane involved in Flight 9, which was taken out of service. In addition to the small, personal tags, a larger version was produced for wall mounting.

From http://en.wikipedia.org/