TEXAS TRANSPORTATION INSTITUTETHE TEXAS A&M UNIVERSITY SYSTEM

COLLEGE STATION, TEXAS

TransportationInstitute

Texas

Emissions of Mexican-Domiciled

Heavy-Duty Diesel Trucks Using

Alternative Fuels

Sponsored by the Alamo Area Council of Governments

With Funding from the EPA Region 6

October 2007

Emissions of Mexican-Domiciled Heavy-Duty

Diesel Trucks Using Alternative Fuels

By

*Josias Zietsman, Ph.D., P.E., *Mohamadreza Farzaneh, Ph.D., **John M. Storey, Ph.D.,

*Juan C. Villa, *Mark Ojah, *Doh-Won Lee, Ph.D., and ***Peter Bella

* Texas Transportation Institute

** Oak Ridge National Laboratory

*** Alamo Area Council of Governments

Sponsored by

Alamo Area Council of Governments with funding from EPA Region 6

October 2007

TEXAS TRANSPORTATION INSTITUTE

The Texas A&M University System

College Station, Texas 77843-3135

4

iii

TABLE OF CONTENTS

1. Introduction ............................................................................................................................... 1 1.1 Purpose of the Study ............................................................................................................. 1

1.2 Background ........................................................................................................................... 1

U.S.-Mexico Cross Border Trucking: Regulations and Status ............................................... 2

1.3 Cross-Border Trucking Process ............................................................................................ 4

FAST Program ........................................................................................................................ 4

1.4 Potential for Trucking beyond the U.S. Commercial Zone .................................................. 5

1.5 Non-Attainment Challenges .................................................................................................. 6

1.6 Alternative Fuels ................................................................................................................... 6

1.7 Overview of Testing Procedure ............................................................................................ 7

2. Study Methodology ................................................................................................................... 9 2.1 Test Equipment and Procedure ............................................................................................. 9

Gaseous Emissions Measurement ........................................................................................... 9

PM Measurement .................................................................................................................. 10

MSATs .................................................................................................................................. 13

2.2 Test Protocol ....................................................................................................................... 14

Emissions Measurement ....................................................................................................... 14

Fuel Purging .......................................................................................................................... 15

2.3 Vehicle Fleet Profile and Sample Selection........................................................................ 16

2.4 Test Load ............................................................................................................................ 18

2.5 Test Site .............................................................................................................................. 18

2.6 Drive Cycle Development................................................................................................... 19

Drayage Drive Cycle............................................................................................................. 20

Long-Haul Drive Cycle......................................................................................................... 20

Drive Cycle Replication ........................................................................................................ 21

2.7 Data Handling ..................................................................................................................... 22

Data Conversion.................................................................................................................... 22

Data Extraction ..................................................................................................................... 23

Data Cleaning........................................................................................................................ 23

2.8 Fuel Analysis ...................................................................................................................... 24

3. Results ...................................................................................................................................... 27 3.1 Idle Tests ............................................................................................................................. 28

Gaseous Emissions Results ................................................................................................... 28

PM Emissions Results........................................................................................................... 33

MSAT Analysis .................................................................................................................... 35

Discussion of Idling Emissions Results ................................................................................ 38

3.2 On-Road Tests .................................................................................................................... 39

Gaseous Emissions Results ................................................................................................... 39

PM Emissions Results........................................................................................................... 40

4. Conclusions .............................................................................................................................. 43 Potential for Trucking beyond the U.S. Commercial Zone ...................................................... 43

Emissions Testing ..................................................................................................................... 43

Test Protocol ......................................................................................................................... 43

NOx Emissions ..................................................................................................................... 43

iv

HC Emissions........................................................................................................................ 43

CO Emissions........................................................................................................................ 44

CO2 Emissions ...................................................................................................................... 44

PM Emissions ....................................................................................................................... 44

5. Recommendations ................................................................................................................... 48

6. Acknowledgements ................................................................................................................. 50

APPENDIX A .............................................................................................................................. 52

APPENDIX B .............................................................................................................................. 57

APPENDIX C .............................................................................................................................. 66

v

LIST OF FIGURES

Figure 1. Northbound Commercial Border Crossing Process. ....................................................... 4

Figure 2. SEMTECH-DS PEMS unit on the left and installation in the trailer on the right......... 10

Figure 3. Installed OEM-2100 Montana CATI Unit. ................................................................... 11

Figure 4. Exhaust flow meter installations. .................................................................................. 12

Figure 5. Relationship Between MSATs and Diesel-Related Compounds. ................................. 13

Figure 6. Flow Chart of the Test Protocol. ................................................................................... 14

Figure 7. Fuel Purging Procedure and Auxiliary Fuel Tank. ........................................................ 15

Figure 8. Drayage Truck Age Frequency Based on 2006 TTI Survey. ........................................ 16

Figure 9. The Loaded Trailer Used for Testing On-Road Emissions. .......................................... 18

Figure 10. Equipment and Loaded Trailer at Test Site, Laredo, Texas. ....................................... 18

Figure 11. Satellite Image of Test Area. ....................................................................................... 19

Figure 12. Laredo’s Drayage Drive Cycle. ................................................................................... 20

Figure 13. Long-haul Drive Cycle. ............................................................................................... 21

Figure 14. Drive Cycle Replication. ............................................................................................. 21

Figure 15. Proper Alignment of Time Alignment Graph. ............................................................ 22

Figure 16. Improper Alignment of Time Alignment Graph. ........................................................ 22

Figure 17. Fuel Showing Contaminants. ...................................................................................... 26

Figure 18. Gaseous Emissions Results for Low-Idling Test at 600 rpm. ..................................... 29

Figure 19. Gaseous Emissions Results for High-Idling Test at 1200 rpm.................................... 30

Figure 20. PM Emissions from Mexican Trucks. ......................................................................... 33

Figure 21. Diesel PM Emissions for the Laredo trucks. ............................................................... 34

Figure 22. Formaldehyde and Acetaldehyde Emissions for all 10 Laredo Trucks. ...................... 36

Figure 23. Formaldehyde and Acetaldehyde Emissions by Model Year...................................... 37

Figure 24. Drayage Cycle — Emissions Rates and Emissions Index........................................... 41

Figure 25. Long-Haul Cycle — Emissions Rates and Emissions Index....................................... 42

LIST OF TABLES

Table 1. Information on Test Vehicles and Emissions Standards. ............................................... 17

Table 2. Test Vehicle Details. ....................................................................................................... 17

Table 3. Specifications of the Tested Fuels. ................................................................................. 25

Table 4. PM Emissions Results. ................................................................................................... 35

1

1. Introduction

1.1 Purpose of the Study

The majority of truck crossings from Mexico into the U.S. occur at Ports of Entry (POEs) in

Texas. The U.S.-Mexico border is scheduled to be opened to transnational trucking in the near

future. When this occurs, it will create new long-haul transportation opportunities for Mexican-

domiciled motor carriers.

Mexican heavy-duty diesel trucks currently engaged in border drayage or domestic Mexican

long-haul service may be used to transport goods to multi-modal transportation hubs or other

facilities in San Antonio, Houston, or beyond. It is, therefore, important to consider appropriate

emissions reduction strategies for such trucks to ensure that their emissions impacts on

nonattainment, early action compact, and near nonattainment areas are minimized. This study

focuses on one such strategy; the use alternative fuels to power heavy-duty diesel trucks.

The overall goal of this study was to quantify emissions produced by Mexican trucks operating

on standard diesel and alternative fuels. The following tasks were conducted to achieve this goal.

Assess the likelihood that Mexican drayage and long-haul trucks will operate beyond the

current border commercial zone if, and when, this is permitted.

Determine the fleet profiles (makes, models, and age) of Mexican drayage and long-haul

trucks expected to operate in the U.S.

Identify the driving patterns (drive cycles) of these drayage and long-haul trucks.

Measure the emissions impact of using conventional Mexican diesel and alternative fuels

such as ultra-low sulfur diesel (ULSD fuel) and biodiesel fuel.

Document the findings, conclusions, and recommendations.

Vehicle testing was conducted near the Colombia Commercial Bridge, just outside of Laredo,

Texas. A sample of five Mexican drayage trucks and five Mexican long-haul trucks were

selected for testing. Each truck was subjected to long-haul and drayage drive cycles while

operating with three different fuel types and pulling a trailer that had been loaded to a specified

weight. Emissions data was collected using portable emissions measurement system (PEMS)

equipment.

1.2 Background

Over 5 million trucks crossed from Mexico into the U.S. in 2005. Whether measured by weight

or value, U.S.-Mexico surface freight transportation is dominated by the truck mode. The need to

measure pollutants emitted by Mexican trucks stems in part from the planned liberalization of

U.S.-Mexico cross-border trucking regulations.

Currently, the operation of Mexican motor carriers in the U.S. is confined to a narrow

commercial zone that generally extends up to 20 miles beyond the border (the extent of the

commercial zone depends on the size of the border community). This restriction is one of the

fundamental reasons why Mexican truck shipments into the U.S. are required to use a drayage or

transfer tractor. Drayage trucks pick up northbound trailers on the Mexico side of the border and

2

shuttle them into the U.S. commercial zone. There, they are transferred to a U.S. carrier that

delivers them to the final destination. Over the years, this inefficient border crossing process has

been the subject of considerable debate and litigation. The following section provides a concise

summary of regulatory developments with respect to direct Mexico-U.S trucking.

U.S.-Mexico Cross Border Trucking: Regulations and Status

Changes to the North American Freed Trade Agreement (NAFTA) trucking provisions were

intended to streamline the complex, costly, and time-consuming process of using drayage trucks

to transport cargo a short distance across the U.S.-Mexico border. By removing regulatory

barriers, seamless and efficient one-carrier trucking operations such as those between the U.S.

and Canada were envisioned. Restrictions on long-haul trucking between Mexico and U.S.

border states were to be phased out beginning in December of 1995. By 2000, reciprocal

nationwide trucking access was to be authorized. Implementation of these provisions has been

postponed on multiple occasions and for a variety of reasons.

In 1995, the U.S. Congress upheld the moratorium on direct long-haul trucking from Mexico to

the U.S., arguing that Mexico’s truck safety regulations could not adequately ensure the safety of

its commercial drivers and carriers. Less stringent safety regulations and enforcement practices

in Mexico were deemed a potential safety risk to the U.S. public. Continuation of the moratorium

in subsequent years led the Mexican government to request that a NAFTA arbitration panel rule

on the matter.

In 2001, the arbitration panel concluded that Mexico’s less rigorous truck safety inspection

system was inadequate justification for the U.S.’ blanket refusal to allow Mexican carriers to

operate beyond the U.S. commercial zone. However, it also declared that a more comprehensive

application process for Mexican carriers applying to operate in the U.S. was acceptable in light

of disparate U.S. and Mexican truck laws, regulations, and procedures.

In the fall of 2001, a newly-elected U.S. administration vowed to comply with the panel’s

findings. Its proposed action plan called for the creation of separate application processes for

Mexican motor carriers seeking to continue operating within the U.S. commercial zone (OP-2

authority) and those seeking authority to travel beyond the U.S. commercial zone to cities such

as San Antonio and Houston (OP-1 authority). Additionally, it mandated the development of an

enhanced monitoring system and enforcement regime to ensure that Mexican carriers operating

anywhere in the U.S. would be in compliance with local laws and regulations. These

recommendations were intended to prepare U.S. agencies for the opening the border to qualified

Mexican carriers by January 2002.

Readiness assessments conducted by the U.S. Department of Transportation (U.S. DOT)

Inspector General and other public agencies identified several deficiencies in the U.S.’

preparedness to accommodate Mexican long-haul movements. However, by November 2002,

these concerns were largely addressed and the moratorium on Mexican trucking beyond the U.S.

commercial zone was officially lifted. However, legal challenges by unions, non-profit

organizations, and trucking associations in the U.S. were subsequently launched and continued to

delay the opening of the southwest border. These groups contended that the U.S. government did

3

not conduct an adequate environmental review to assess the impact of liberalized cross-border

trucking regulations on U.S. air quality.

In January 2003, the 9th Circuit Court of Appeals in California ruled that the U.S. government’s

decision to allow direct U.S.-Mexico trucking was ―arbitrary, capricious and disregarded

established environmental laws.‖ The ruling required further environmental reviews to be

conducted prior to the implementation of liberalized cross-border trucking regulations between

the U.S. and Mexico. Although more detailed environmental studies were initiated, they were

halted in June 2004 when the U.S. Supreme Court overturned the 9th Circuit Court of Appeals’

decision and paved the way for Mexican motor carriers to apply for operating authority beyond

the U.S. commercial zone.

Despite this ruling, direct trucking from the interior of Mexico to cities such as San Antonio and

Houston has yet to become established. The remaining regulatory obstacle was a sovereignty

dispute between the countries. To qualify for OP-1 authority, U.S. law requires that Mexican

trucks and drivers be certified by U.S. regulatory personnel at their facilities in Mexico. The

Mexican government’s refusal to approve these inspections left the issue at a stalemate for two-

and-one-half additional years.

On February 23, 2007, the U.S. and Mexican governments announced that they had reached a

resolution to the cross-border trucking impasse. The agreement calls for a one-year pilot project

involving up to 100 Mexican and 100 U.S. trucking firms that wish to engage in direct long-haul

movements across the border and beyond the commercial zone. Mexican carriers must undergo

safety audits by U.S. inspectors in Mexico; meet all safety, environmental, insurance, homeland

security, and other regulations imposed on U.S. trucking firms; and pay all applicable U.S. state

and federal taxes and registration fees. Mexican truckers must also pass a safety review to travel

beyond the U.S. commercial zone. This includes verification of their driving history, commercial

driver’s license, medical certificate, and compliance with hours-of-service regulations.

According to the U.S. DOT, direct door-to-door international movements are expected to begin

in May 2007. The pilot project will be evaluated after one year, at which time a decision

regarding the future of the initiative will be made.

Delays in the implementation of NAFTA’s trucking provisions have provided an opportunity to

measure the potential emissions impact that Mexican trucks might have if they travel to cities in

Texas. While the provisional operating authority has made a gradual shift toward these types of

movements possible, the extent to which Mexican carriers will choose to pursue cross-border

authority also depends on a number of private-sector considerations.

4

1.3 Cross-Border Trucking Process

The current border crossing process requires a shipper in Mexico to file shipment data with both

Mexican and U.S. agencies, prepare paper and electronic documents, and contract a drayage firm

to transport the goods from one country to the other. After the driver, drayage tractor, and cargo

begin the actual border crossing process, the movement is subject to inspections at three

inspection areas:

Mexican export lot;

U.S. federal compound; and

state safety inspection facility.

Figure 1 illustrates the main activities in the northbound border crossing process.

Figure 1. Northbound Commercial Border Crossing Process.

FAST Program

One program that can potentially expedite the border crossing process and, therefore, might

facilitate cross-border movements of long-haul Mexican trucks is the Free and Secure Trade

(FAST) initiative. The Department of Homeland Security (DHS) and Customs and Border

Protection (CBP) have implemented several security programs at U.S. land ports of entry. The

FAST initiative is designed to provide incentives for supply chain security by offering expedited

clearance to carriers and importers enrolled in the Customs Trade Partnership Against Terrorism

(C-TPAT). FAST shipments use a special booth and FAST-only lane at the international bridges.

Non-FAST–certified movements do not adhere to C-TPAT security protocol and take longer to

5

process. These movements are also expected to experience secondary inspections and potential

unloading of the trailer for detailed inspection.

The time required for a shipment to make the complete trip from the yard or the manufacturing

plant in Mexico to the exit of the state inspection facility in the U.S. depends on a variety of

factors, including: secondary inspections, number of inspection booths in service, traffic

volumes, time of day, nature of cargo, and C-TPAT/FAST certification. There is duplication

with regard to safety inspections, as U.S. federal and state agencies perform similar safety-

related revisions of every truck and driver that crosses from Mexico into the U.S.

1.4 Potential for Trucking beyond the U.S. Commercial Zone

Through an examination of Mexican and U.S. trucking practices and a series of interviews with

Mexican trucking interests engaged in the transport of NAFTA freight (custom brokers, drayage

companies, and 10 long-haul trucking companies), the study team determined that most Mexican

long-haul carriers do not currently cross their trucks into the U.S. commercial zone and would be

reluctant to change that aspect of their operations. Many Mexican drayage firms currently

crossing the border do not intend on pursuing contracts beyond the U.S. commercial zone, even

if such movements are permitted. The following issues were cited by these groups as reasons

why they are reluctant to apply for operating authority to send their vehicles and drivers into the

U.S. interior.

1. Business inertia: Current service alliances between Mexican and U.S. trucking firms

enable firms in each country to focus on their own market. The lack of an established

sales presence in the U.S. on the part of Mexican carriers may reduce their backhaul

opportunities beyond the U.S. commercial zone. The U.S. and Mexico also have different

accounting systems and trucking business practices. While often costly, time consuming,

and inefficient for the customer, the status quo border-crossing system serves the interests

of many carriers. The inertia of current business practices is perceived to be strong and

may require several years to change.

2. Influence of third parties: Third parties such as customs brokers and freight forwarders

can wield substantial influence over shippers and the logistics of cross-border

movements. If these stakeholders feel their interests are threatened by a liberalization of

cross-border trucking provisions, they may try to prevent adoption of them.

3. Concerns about law enforcement: Mexican fleet owners feel that their vehicles and

drivers would be targeted by local U.S. law enforcement beyond the U.S. commercial

zone.

4. Loss of drivers: The U.S. long-haul trucking industry has suffered from acute driver

shortages in recent years. Mexican fleet owners fear that their drivers, who are

accustomed to working long hours for little pay, may be lured away by relatively

attractive pay and working conditions in the U.S. trucking industry.

5. Border delays: Mexican carriers with late model trucks cannot afford to idle their

expensive assets in border bottlenecks and congestion.

6. Higher operating costs: Insurance and other operating costs are higher in the U.S. and

represent an obstacle to Mexican carriers trying to enter this market.

6

7. Higher equipment costs: Higher interest rates in Mexico prevent Mexican fleet owners

from making the equipment investments they feel are necessary to operate competitively

in the U.S. market.

8. Application process: Some Mexican carriers are discouraged from applying for cross-

border operating authority by a lengthy, rigorous, and potentially costly application,

audit, and documentation process that they may not pass.

9. Language barriers: Language or cultural barriers may preclude or dissuade some

Mexican drivers from applying for operating authority beyond the U.S. commercial zone.

10. Potential maintenance costs: Mexican drayage operations typically utilize older

vehicles, which may be susceptible to costly maintenance if they break down while

abroad.

These and related issues were considered by the study team, and a subset of fleet owners who

have applied for or expressed an interest in obtaining authorization from the U.S. Federal Motor

Carrier Safety Administration (FMCSA) to operate beyond the U.S. commercial zone were

identified.

1.5 Non-Attainment Challenges

When examining the cross–border trucking between Mexico and Texas, the San Antonio region

is of particular significance. Because it is a major multi-modal hub that is relatively close to the

border region, it may be a feasible destination for Mexican motor carriers interested in cross-

border operations. The San Antonio area is in ―deferred‖ non-attainment status for the National

Ambient Air Quality Standards’ (NAAQS) eight-hour ozone standards. The deferral of non-

attainment status is the result of a 2002 Early Action Compact (EAC) between the local

governments in the San Antonio region working together as the Air Improvement Resources

(AIR) Committee of the Alamo Area Council of Governments (AACOG), the US Environmental

Protection Agency (EPA) and the Texas Council on Environmental Quality (TCEQ). The EAC

allows the San Antonio region time until the end of December 2007 to achieve the stricter eight-

hour ozone standards set by the NAAQS.

Under these circumstances, it is possible that Mexican trucks that do not have strict emissions

controls may have an adverse effect on the air quality in the San Antonio region. Thus

quantification of the emissions of ozone precursors and other pollutants is of special relevance.

Emissions control strategies such as low emission alternative fuels for Mexican trucks crossing

into the U.S. can play a positive role in addressing air quality concerns in the San Antonio area.

1.6 Alternative Fuels

Another concern raised by cross-border trucking is related to the quality of fuel sold in Mexico

as compared to fuels used in the U.S. Due to the diesel prices trend in the US-Mexico border

region1 (Figure A.2 in Appendix A), it is reasonable to assume that Mexican trucks engaged in

cross-border trucking would make use of fuel sold in Mexico. However, this may result in a

change in emissions quality that could be offset using a different fuel mix. Thus, this study

measures the emissions for Mexican trucks using three types of fuel – the standard diesel

1 Mexican Department of Property and Public Credit, Nota Technica Sobre Los Combustibles de Ultra Bajo Azufre,

November 2006.

7

available in Mexico, ULSD fuel (mandated by the U.S. Environmental Protection Agency [EPA]

for use in 2007 and later model trucks in the U.S.), and a biodiesel mix (20 percent biodiesel fuel

and 80 percent ULSD fuel). Detailed description of the fuels used is provided later in this

document.

1.7 Overview of Testing Procedure

The procedure involved testing emissions of carbon monoxide (CO), carbon dioxide (CO2),

oxides of nitrogen (NO and NO2 – collectively referred to as NOx), total hydrocarbons (THC),

and particulate matter (PM). Sampling was also performed for mobile-source air toxics

(MSATS) under idling conditions. The existing vehicle fleet participating in cross-border

trucking was first profiled and a representative sample of trucks was selected. Testing was

conducted for the three different fuel types on the selected trucks following pre-determined drive

cycles. The research team used two PEMS units for the testing, which was conducted at the

Colombia Border Bridge near Laredo. The remainder of the report is divided into chapters that

describe the study methodology, results, and conclusions and recommendations.

9

2. Study Methodology

2.1 Test Equipment and Procedure

The research team used two types of PEMS units for the testing. A SEMTECH-DS unit was used

to measure gaseous emissions such as CO, CO2, NOx, and THC, while an OEM-2100

―Montana‖ System was used for measuring PM. For measuring PM during the idling tests, a

Tapered Element Oscillating Microbalance (TEOM) deployed by Oak Ridge National

Laboratory (ORNL) was used. For air toxics during the idle tests, Solid Phase Extraction (SPE)

cartridges were used.

Gaseous Emissions Measurement

The SEMTECH-DS unit includes a set of gas analyzers, an engine diagnostic scanner, a Global

Position System (GPS), an exhaust flow meter, and embedded software.

The gas analyzers measure the concentrations of NOx (nitric oxide, NO, and nitrogen dioxide,

NO2), THC, CO, CO2, and oxygen (O2) in the vehicle exhaust. The engine scanner was

connected to the vehicle engine control module (ECM) via a vehicle interface (VI) (where

available) and provided vehicle speed, engine speed (RPM), torque, and fuel flow. The

SEMTECH-DS uses the Garmin International, Inc.’s GPS receiver model GPS-16 HVS to track

the route, elevation, and ground speed of the vehicle on a second-by-second basis.

The SEMTECH-DS uses the SEMTECH electronic exhaust flow meter (EFM) to measure the

vehicle exhaust flow. Its post-processor application software uses this exhaust mass flow

information to calculate exhaust mass emissions for all measured exhaust gases. The

SEMTECH-DS uses embedded software, which controls the connection to the external

computers via a wireless or Ethernet connection to provide the real-time control of the

instrument. A Panasonic Toughbook laptop was used to connect to the SEMTECH-DS via

Ethernet and to control the unit. Figure 2 shows the SEMTECH-DS PEMS unit as well as how it

was installed in the test trailer.

10

Figure 2. SEMTECH-DS PEMS unit on the left and installation in the trailer on the right.

PM Measurement

The PEMS unit used to collect PM was the OEM-2100 ―Montana‖ system manufactured by

Clean Air Technologies International, Inc. (CATI). The OEM-2100 system is comprised of gas

analyzers, a PM measurement system, an engine diagnostic scanner, a GPS, and an on-board

computer. For this study only the PM measurement system was used. The PM measurement

capability includes a laser light scattering detector and a sample conditioning system. The PM

mass concentrations were converted from the light scattering scales internally using present

parameters by the CATI unit. Using the exhaust flow rates produced by the SEMETCH-DS unit,

PM mass emissions rates are calculated from the concentrations.

It should be noted that engine exhaust particles generally have three different size ranges: 3-30

nm, 30-500 nm, and > 500 nm (or, 0.5 μm). Most particles produced in a diesel engine have

particle sizes of 0.5 μm or less2. This size is comparable to the PM-2.5 (2.5 μm or less) particle

size as regulated by the EPA3.

Figure 3 shows a photo of the CATI PEMS unit.

2 Kittleson, et.al. ―On-Road Evaluation of Two Diesel Exhaust After-treatment Devices.‖ Journal of Aerosol

Science. 37:1140-1151, 2006. 3 U.S. EPA, http://epa.gov/air/criteria.html, accessed 4/24/2007.

11

Figure 3. Installed OEM-2100 Montana CATI Unit.

In addition to the transient PM measurements obtained using the CATI PEMS unit, the ORNL

team also collected PM sampling during idling modes. All ORNL’s PM and MSAT (aldehyde)

samples were obtained by diluting the exhaust with a microdilution system used in previous

studies on idling trucks.4 The exhaust was transferred through a 15-inch long, heated (250 °C)

line to the microdilution tunnel from a probe in the outlet of the SEMTECH-DS exhaust flow

meter.

To determine dilution ratio, NOx measurements were made for both the raw and diluted exhaust.

The dilution ratio was maintained at 8:1 through the testing to enable the collection of samples

relatively quickly. Filters still required 15 minutes of sampling, however, to accumulate enough

mass for measurement. Compressed air for the dilution tunnel was obtained by compressing the

outside air with an oil-less air compressor, then drying and HEPA-filtering the air with a

membrane dryer before it reached the microdilution tunnel.

Both a continuous and integrated approach was used to measure PM. For continuous

measurements, the TEOM (Thermo Scientific Model 1105) was used to measure the diluted

exhaust for PM mass. Flows were set to 2.5 lpm. For each condition, PM was collected on a pre-

weighed 70mm Teflon™-coated quartz fiber filter (Pall EMFAB TX40) for 15 minutes at a flow

rate of ~50 lpm. The exposed filters were returned to ORNL, re-equilibrated in the weighing

chamber and re-weighed.

4 Zietsman, J., J.C. Villa, T.L. Forrest, and J.M. Storey. Mexican Truck Idling Emissions at the El Paso - Ciudad

Juarez Border Location. Southwest Region University Transportation Center, The Texas A&M University System,

College Station, Texas, 2005.

12

Figure 4 shows the exhaust flow meter installation. It shows the PEMS sampling line and

sampling cart with microdilution tunnel and TEOM.

Figure 4. Exhaust flow meter installations.

PEMS

Sampling Line

Heated Line to

Dilution Tunnel

Microdilution Tunnel

TEOM

13

MSATs

MSATs have become increasingly important in recent years as states and air quality districts are

now forced to address them along with other criteria pollutants. The EPA has identified 21

MSATs, and the following figure illustrates the interrelationship between individual compounds

that are MSATs and the classes of substances also listed as MSATs.

Figure 5 shows the subset (of the 21 MSAT compounds identified by EPA) that were measured

or attempted to be measured in this study.

Figure 5. Relationship Between MSATs and Diesel-Related Compounds.

(Compounds marked with an asterisk were measured in this study)

As shown in Figure 5 this study focused on diesel PM, formaldehyde, and acetaldehyde. These

MSATs are very heavily associated with truck traffic, and in particular, large numbers of idling

trucks. To simulate typical idle conditions, while still enabling MSAT sampling, two idle speed

conditions were measured – low idle and high idle. The main focus was on idling because it is

anticipated that this mode creates the highest levels of MSATs and can most effectively be

addressed with possible emissions reduction strategies.

MSATs were measured for idling conditions, with a warm engine. Fuel changes were performed

such that two idle runs could be done sequentially, and the exhaust temperature was allowed to

cool after the previous cruise.

Waters DNPH SPE cartridges (no.WAT37500) were used to collect samples for aldehyde

analysis from the diluted exhaust. Flow rate was set to 1 lpm. Samples were taken for 15

minutes, for a total of 15 l/cartridge. The cartridges were eluted immediately after sampling with

3 ml of acetonitrile, and the effluents stored in a refrigerator for later analysis by high

performance liquid chromatography (HPLC) using the analytical method provided by Waters.

MSATs

Formaldehyde,

Acetaldehyde*

Acrolein*

1,3 Butadiene

Semivolatile organics

Benzene,

Naphthalene

POM (polycyclic

organic matter)

PAHs

Diesel PM*

Volatile organics

Particulate Matter (PM)

Diesel Exhaust Organic Gases Metals

14

2.2 Test Protocol

Emissions Measurement

The study team developed a test protocol that would provide the best opportunity to test

emissions differences resulting from using different fuel types. The effect of fuel mix was

captured by driving the test vehicles equipped with each fuel mix according to the developed

drayage and long-haul drive cycles. To maintain consistency between each run, a professional

truck driver drove the vehicle for all test runs. Each test scenario included two runs and for each

run the emissions, engine, and speed data were collected on a second-by-second basis. In

addition to the road tests, each vehicle was tested in two different idle modes — low idle at 600

to 700 rpm, and high idle at 1200 rpm.

Figure 6 shows a flow diagram illustrating the test protocol used. Each on-road test scenario was

repeated two times resulting in 210 total tests including the idle tests (10 trucks × 3 fuels × [2

runs × 2 cycles + 3 idle] = 210).

Figure 6. Flow Chart of the Test Protocol.

Test Scenarios

Drayage Cycle 1

B20 Biodiesel

PEMEX Max Sulfur 500 ppm

ULSD Max Sulfur 15 ppm

Long-haul

Tru

cks

Drayage Cycle 2

Long-haul Cycle 1

Long-haul Cycle 2

LH 01** LH 02 LH 03 LH 04 LH 05

Low Idle

High Idle

* D 01: Drayage Truck 1

** LH 01: Long-haul Truck 1

Drayage

Tru

cks

D05* D 01* D04* D03* D 02*

Testing Process for All Trucks

15

Fuel Purging

Because each truck was tested with three different fuel types, a fuel purging procedure was used

to ensure that the truck engine and fuel system were completely purged of one fuel type before

the truck was tested using the next fuel type. In a regular diesel engine set-up, there is a two-way

connection between the fuel tank and the engine. An inlet line brings fuel from the fuel tank to

the engine, and a return line from the engine takes unconsumed fuel back into the tank for re-

circulation.

In the test set-up, the fuel tank was intercepted by an auxiliary fuel tank. The fuel purging was

performed by running approximately two gallons of the new fuel through the fuel system and

having the outlet line dump the fuel into a separate container. After enough of the new fuel

circulated through the system, all the old fuel was replaced with the new fuel. After the purging

was completed, the outlet connection was restored to the auxiliary fuel tank and the vehicle was

ready for testing. This purging procedure was repeated every time the test fuel was changed.

Figure 7 shows the location of the auxiliary fuel tank as well as the inlet and return lines.

Figure 7. Fuel Purging Procedure and Auxiliary Fuel Tank.

Auxiliary Fuel

Tank

Fuel Lines

16

2.3 Vehicle Fleet Profile and Sample Selection

Based on carrier interviews and the literature review, the research team determined that the fleet

of Mexican-domiciled trucks expected to travel to areas in Texas in a liberalized cross-border

trucking environment would be long-haul trucks, although drayage trucks might also participate

in movements to cities such as San Antonio. The team therefore decided to select a mix of long-

haul and drayage trucks. By testing drayage trucks in addition to long-haul trucks there is also an

opportunity to estimate the emissions impact of the border region as well as for longer distances.

The sample of test vehicles was based on existing fleets (percentage of trucks by model year)

obtained from Mexican long-haul companies interviewed by the study team, and a survey of

northbound drayage vehicles passing through the two commercial border crossing facilities at

Laredo. Figure 8 shows the 2006 survey data of the drayage truck age frequencies collected at

the Laredo border crossing.5 Figure 8 shows that 86 percent of the drayage tractors sampled were

model year 1990-2000, with mid-1990s models being the most prevalent. A survey performed by

researchers at University of California Davis6 in 2003 showed that only 8 percent of the surveyed

U.S.-domiciled trucks were older than 10 years (compared to 75 percent of surveyed Mexican-

domiciled trucks in this study). UC Davis researchers found that 69 percent of the U.S.-

domiciled trucks surveyed were four years old or newer. Figure A.1. in Appendix A explains the

results from both surveys.

0%

2%

4%

6%

8%

10%

12%

14%

16%

18%

1987

1988

1989

1990

1991

1992

1993

1994

1995

1996

1997

1998

1999

2000

2001

2002

2003

2004

2005

2006

Model year

Pro

po

rtio

n

Figure 8. Drayage Truck Age Frequency Based on 2006 TTI Survey.

5 TTI Survey. World Trade Bridge and Colombia Solidarity Bridge, 2006.

6 Lutset, N.P. et al. Heavy-Duty Truck Idling Characteristics: Results from a Nationwide Survey. Transportation

Research Record (1880), 29 – 38, 2004.

17

In addition to the model year distribution shown in Figure 8, the study team considered the

different emissions categories (periods during which heavy-duty diesel engine emissions

standards remained constant) in the selection of the testing sample. Finally, logistical

considerations such as securing Mexican trucks manufactured in specific years also influenced

the selection of test vehicles.

The EPA has set emissions standards for CO, HC, PM, and NOx for heavy-duty diesel trucks

based on the ―model year‖ or ―emissions category‖ of the vehicle. The trucks selected for

sampling represented as many emissions categories as possible. Table 1 presents the test trucks

classified by EPA’s emissions categories. The corresponding EPA emissions standards for each

category are also provided. Table 1 shows that all the categories were covered except model year

1991–1993.

Table 1. Information on Test Vehicles and Emissions Standards.

Emissions category/

Model Year Drayage

Long-

Haul

EPA Emissions Standard7 (g/bhp.hr)

HC CO PM NOx

1988-1990 0 1 1.3 15.5 0.6 6.0*

1991-1993 0 0 1.3 15.5 0.25 5.0

1994-1997 3 1 1.3 15.5 0.1 5.0

1998-2003 2 2 1.3 15.5 0.1 5.0

2004-2006 0 1 1.3 15.5 0.1 NOx+NMHC** = 2.4, or

NOx = 2.5 and NMHC=0.5

Total 5 5 * NOx standard for 1988 & 1989 model was 10.7

** NMHC – Non-Methane Hydrocarbons.

As noted in Table 1 the pool of test vehicles comprised of five long-haul trucks and five drayage

trucks. Detailed information regarding, make, model, and engine type is summarized in Table 2.

Table 2. Test Vehicle Details.

Drayage Trucks

Model year 1994 1995 1997 1999 2001

Truck Make International

Harvester

International

Harvester

International

Harvester Freightliner Freightliner

Engine Make DDC DDC Cummins Cummins Cummins

Displacement (L) 12.7 11.1 10.8 10.8 14.0

Long-haul Trucks

Model year 1990 1995 1999 2001 2004

Truck Make Kenworth Freightliner Freightliner Volvo Freightliner

Engine Make DDC DDC Cummins Cummins DDC

Displacement (L) 12.7 12.7 10.8 14.0 12.7

7 Diesel Net- http://www.dieselnet.com/standards/us/hd.html

18

2.4 Test Load

It was important to ensure that a consistent load was used between the various tests. For this

reason the same loaded trailer was used for every test. This trailer was loaded with rolls of paper

weighing approximately 35,000 pounds. The weight of the load, trailer, and tractor totaled

approximately 75,000 pounds, which is typical for both drayage and long-haul Mexican trucks.

Figure 9 shows a photo of the loaded trailer.

Figure 9. The Loaded Trailer Used for Testing On-Road Emissions.

2.5 Test Site

The general test site was the Colombia Commercial Bridge outside Laredo. Actual testing

occurred at two locations – the idling tests occurred inside the Department of Public Safety

(DPS) testing facility adjacent to the bridge and the transient (driving) tests occurred along a

section of the Camino Colombia Toll Road. The study team performed the installations and

stored the equipment at the DPS facility. Figure 10 shows the test sites with the instruments as

well as a test truck with the load.

Figure 10. Equipment and Loaded Trailer at Test Site, Laredo, Texas.

19

2.6 Drive Cycle Development

Because the driving characteristics of drayage and long-haul trucks are substantially different,

separate drive cycles were developed to each driving pattern.

The drive cycles were developed based on the following three criteria:

reflects typical drayage or long-haul driving conditions;

easy to follow; and

can be accomodated in the available test track.

The test track selected for this study was a 7.5 mile stretch of Camino Colombia Toll Road

between FM-1472 (Mines Road) and FM-3338 (Las Tiendas Road). The Camino Colombia Toll

Road is a 22-mile four-lane highway located north of Laredo and extends from I-35 (Mile

Marker 25) to FM-1472 (Mines Road). A toll plaza divides the study section into two

approximately equal segments – one from FM-1472 to the toll plaza with a length of 3.2 miles,

and the other from the toll plaza to FM-3338 with a length of 3.3 miles. Figure 11 shows the

study section on the map. The drayage drive cycles were conducted between FM-1472 and toll

plaza. The long-haul drive cycles were conducted between the toll plaza and FM 3338 as shown

in Figure 11. The methodology used to develop each portion of the drive cycle is described in the

next section.

Figure 11. Satellite Image of Test Area.

20

Drayage Drive Cycle

The purpose of this drive cycle was to capture the characteristics of the driving pattern for

drayage trucks from Mexico on northbound trips. Because there was no pre-existing information

on precise drayage driving patterns for these vehicles, GPS units were used to collect drive-cycle

information at the Laredo border. Three Mexican drayage trucks were equipped with GPS units

and drivers were instructed to turn on the units in the morning before they started driving and to

leave the unit on until they returned to the truck yard at the end of the day. The GPS units

recorded second-by-second speed (mph) and location (coordinate) data. The data were analyzed

and a representative drayage cycle was developed to addresses the critical driving components

during drayage trips – acceleration, deceleration, cruising, idling, and creep idling. The idle

period between each moving part of the drive cycles was set to 20 seconds to ensure stability

before the next phase began. Figure 12 shows the final drayage cycle developed for this study.

0

10

20

30

40

50

60

0 100 200 300 400 500 600 700

Time (s)

Sp

ee

d (

mp

h)

Border to Company

Company

to

CompanyBorder Crossing

1.56 mi

1.19 mi

0.29 mi

Figure 12. Laredo’s Drayage Drive Cycle.

Long-Haul Drive Cycle

The procedure used for developing the long-haul cycle was similar to the one used for the

drayage cycle. A long-haul truck driving from El Paso, Texas to Austin, Texas was equipped

with a GPS unit. It was found that the truck spent 93 percent of the time driving and 7 percent

idling. Figure 13 shows the final long-haul cycle developed for this study.

21

0

10

20

30

40

50

60

70

80

0 50 100 150 200 250 300

Time (s)

Sp

ee

d (

mp

h)

Figure 13. Long-haul Drive Cycle.

Drive Cycle Replication

The same professional driver was used to replicate the drive cycles. This was accomplished by

having a researcher accompany the driver and providing instructions on speeds that should be

reached at different points in time. It was also determined that this approach more closely

replicated actual driving patterns than having the driver follow exact speed profiles using

driver’s aid software. It was found that the cycles were replicated fairly well while the driver

used ―normal‖ driving behavior. Figure 14 shows an example of replicating the eastbound

drayage cycle for the same truck using the three different fuel types.

Figure 14. Drive Cycle Replication.

0

20

40

60

80

0 100 200 300 400 500 600 700Time (s)

Speed (

mph)

Drayage Cycle East Bound - ULSD

Drayage Cycle East Bound - B20

Drayage Cycle East Bound - PEMEX

22

2.7 Data Handling

This section explains the data post-processing procedure for information obtained from

SEMTEC-DS. This step is necessary to build a valid emissions database. The data screening

process includes raw data file conversion, data extraction, data synchronization, and data

cleaning.

Data Conversion

The data collected by the SEMTECH-DS were recorded in a XML file. The first step to use the

data was to convert the XML files to appropriate comma separated (CSV) format, so that

spreadsheet and data analysis software could read the data. The SENSOR Tech Post Processor

software version 4.49 was used to convert the data to CSV format.

SEMTECH-DS collects data from multiple sources such as emissions from three gas analyzers,

exhaust flow from the flowmeter, ambient air conditions from the weather probe, engine data

from ECM or OBD II connections, and speed from the GPS unit. It is important to have proper

time alignment of the exhaust flow rate and the emissions concentrations because these

parameters are combined to compute mass emissions. Time alignment must be checked for each

vehicle as a part of the standard procedure. Figure 15 and Figure 16 show examples of proper

and improper time alignment graphs.

0

50

100

150

200

0 50 100 150 200

Time (s)

Ex

ha

us

t fl

ow

(S

CF

M)

0

2

4

6

8

10

12

14

CO

2 (

g/s

)

Exhaust flow

CO2

Figure 15. Proper Alignment of Time

Alignment Graph.

0

50

100

150

200

0 50 100 150 200

Time (s)

Ex

ha

us

t fl

ow

(S

CF

M)

0

2

4

6

8

10

12

14

CO

2 (

g/s

)

Exhaust flow

CO2

Figure 16. Improper Alignment of Time

Alignment Graph.

The software also converts the raw collected data to appropriate performance measures for

analysis including fuel-specific and distance-specific emissions rates. All the necessary

corrections due to the effect of ambient temperature and humidity are considered and applied by

the software. The data files recorded by the CATI PEMS unit are in CSV format and did not

require further conversions.

23

Data Extraction

After the data has been properly formatted, the required information can be extracted. The

converted data file contained more than 200 columns of information on a second-by-second

basis. Key elements in this database were extracted and used in this study:

engine speed (if an OBD II or ECM port was available);

exhaust flow rate (SCFM);

GPS time and second-by-second vehicle speed from GPS (mph);

emissions mass rate (grams per second [g/s])

fuel-specific emissions index (gallons per kilogram [g/kg] of fuel).

Another element of data used in the study was PM mass rate from the CATI unit. This unit

recorded the PM concentration in mg/m3. This information must be first time-aligned with

hydrocarbon emissions data from the SEMTECH-DS and then converted to mass rate using the

exhaust flow rates produced by the EFM.

Data Cleaning

The process of data cleaning consisted of removing unwanted portions of the second-by-second

data assembled in the data extraction step. This included removing excessive idle segments

between the moving segments. The idle period between each moving segment was set to 20

seconds with excessive idle data removed to maintain consistency between runs.

24

2.8 Fuel Analysis

The three fuel types used in this study included ULSD fuel provided by Valero, 20 percent blend

of soy-based biodiesel with the ULSD fuel, and a diesel fuel sourced from Mexico (PEMEX

fuel).

ULSD fuel describes EPA’s new standard for the sulfur content in on-road diesel fuel sold in the

U.S. beginning in October 2005. The EPA has set the allowable sulfur content for ULSD fuel to

a maximum of 15 parts per million (ppm), which is much lower than the previous standard for

on-highway low-sulfur diesel fuel(LSD, 500 ppm).8 The EPA has introduced a set of very

stringent emissions standards for diesel engines for model year 2007 and newer. To meet these

new standards, engine manufacturers have to use new emissions control technologies that are

intolerant to sulfur. These technologies include diesel particulate filters and NOx catalysts. The

introduction of ULSD fuel is intended to serve as a technology enabler to pave the way for these

advanced sulfur-sensitive exhaust emissions control devices. In addition to on-road diesel

engines, the EPA mandated the use of these advanced emissions control technologies and ULSD

fuel for marine diesel engines in 2014 and for locomotives in 2015. The EPA has speculated that

the combination of the new emissions control technologies and ULSD fuel will substantially

reduce PM and NOx emissions from diesel engines.9,10,11

Biodiesel fuel refers to a diesel-equivalent fuel derived from biological sources such as vegetable

or animal oils, and can be readily used in diesel powered engines with little or no modification.

Blends of 20 percent biodiesel fuel with 80 percent petroleum diesel fuel ( B20 fuel) are

considered the most common biodiesel fuel blend in the U.S. B20 fuel can be used in any diesel

engine without any modification. Some engine modification might be necessary with higher

percentages of biodiesel fuel. It is the only alternative fuel to have fully completed the health

effects testing requirements (Tier I and Tier II) of the 1990 Clean Air Act Amendments. In

recent years several experimental studies have investigated the impact of biodiesel fuel on the

pollutants from diesel-powered engines. These studies are not unanimous in their conclusions,

especially in terms of changes in NOx emissions due to using biodiesel fuel. Some studies

suggest that the use of biodiesel fuel may produce increases in NOx emissions concurrent with

reductions in other pollutants, promoting the need for additional research and studies.12,13

The diesel fuel referred to as PEMEX fuel in this study is the diesel produced and distributed in

Mexico by Petróleos Mexicanos (PEMEX). In 1938, the president of Mexico nationalized 17

foreign oil companies to create PEMEX, the largest Latin American petroleum company and a

major world exporter of fossil fuel. PEMEX engages in exploration, production, refining,

8 Wikipedia, Ultra-low sulfur diesel, http://en.wikipedia.org/wiki/Ultra_low_sulphur_diesel, accessed 4/4/2007.

9 New S15 (Ultra Low Sulfur Diesel -ULSD) Regulations,

http://www.chevron.com/products/prodserv/fuels/diesel/ulsd.shtml, accessed 4/4/2007. 10

Clean Diesel Fuel Alliance Information Center, http://www.clean-diesel.org/, accessed 4/4/2007. 11

Heavy-Duty Highway Diesel Program, http://www.epa.gov/otaq/highway-diesel/index.htm, accessed 4/4/2007. 12

Farzaneh, M., J. Zietsman, D. Perkinson, and D. Spillane. School Bus Biodiesel (B20) NOx Emissions Testing.

R08-04/05-TTI-2, Capital Area Council of Governments, Austin, Texas, 2006. 13

Kittleson, et.al. Influence of a Fuel Additive on the Performance and Emissions of a Medimu-Duty Diesel Engine.

SAE 9410015, Society of Automotive Engineers, Warrendal, Pennsylvaina, 1994.

25

transportation, storage, distribution, and sales of oil and natural gas.14

The sulfur content of

PEMEX fuel is regulated to be less than 500 ppm. There are some efforts by PEMEX to

introduce diesel fuel with the same standards as ULSD fuel. PEMEX is planning to provide the

ULSD compliant diesel in three phases: first in the U.S.-Mexico border region, then in the

metropolitan areas, and finally in the remainder of Mexico15

. It is uncertain exactly when the

ULSD PEMEX fuel will be available in the border region.

To ensure consistency, all diesel used in this study was purchased at the same time and stored in

the test area prior to testing. Complete analyses of the test fuels were performed by Southwest

Research Institute (SwRI) and the results are shown in Appendix C. Table 3 shows a summary of

the specification of the fuels used in this study. The table shows that the fuels were very similar

with the exception of sulfur content and in the case of the B20 fuel, heat of combustion.

Table 3. Specifications of the Tested Fuels.

Fuel Sulfur

(ppm)

Cetane

Index

Aromatics

(mass %)

Specific

Gravity

Net Heat of

Combustion

(btu/lb)

Energy

Content

(btu/gal)

Energy Content

Difference From

ULSD (%)

ULSD 9 47.5 26.7 0.8401 18416 129091 –

B20 8 48.1 NR* 0.8499 17852 126627 1.9

PEMEX 380 50.2 26.9 0.8306 18463 127900 0.9

*NR- Not recorded.

Because biodiesel fuel has lower energy content due to ~11 percent oxygen, the B20 fuel was

expected to result in lower fuel economy. Due to differences in the specific gravity and energy

content, B20 fuel should result in ~2 percent loss in fuel economy, and PEMEX fuel should

result in a 1 percent loss. The research team expects that these changes might be difficult to see

in the data due to the expected variability in the drive cycles.

From previous studies, the emissions differences that are expected from changes in fuel would

include lower PM, CO, and HC for the B20 fuel and possibly higher NOx from the B20 fuel. The

cause of the lower CO, HC, and PM is thought to be due to the oxygen content of the fuel. When

comparing the PEMEX fuel to the ULSD fuel, higher PM is expected from the PEMEX fuel due

to the higher sulfur level of the PEMEX fuel.

It was found during the purging process that the fuel that was circulated through the engine and

fuel system contained black particulate contaminants. It is possible that this black contaminant is

oil contained in the fuel system (it is known that Mexican truck drivers sometimes dispense oil

into the fuel tanks). Figure 17 shows a container on the left with clean fuel and one on the right

with fuel purged from a truck’s fuel system.

14

Answers.com, http://www.answers.com/topic/pemex. accessed 4/4/2007. 15

Secretariat of the Environment and Natural Resources. ULSF in the Border- Mexico Prospective, http://www.jac-

ccc.org/PDN-ARP/CAAAC/ULSF in the border Mexico perspective.pdf, 2005.

26

Figure 17. Fuel Showing Contaminants.

27

3. Results The dataset assembled in the data handling step can be analyzed using three different measures

of effectiveness.

Distance specific emission rates: describes the emissions rates per unit of distance

traveled (grams per mile [g/mi]). This effectiveness measure is not appropriate for idle

testing because the vehicles are stationary; i.e. the total distance traveled is zero.

Average time specific emissions rates: explains the average emissions rates for a testing

scenario per unit of time such as g/s or grams per hour (g/hr). This value is mostly suitable

for analyzing a single steady-state condition such as steady-state idle testing.

Emissions index: is the exhaust flow weighted average fuel specific emissions rate for a

specific cycle. It describes normalized amount of emissions per unit of fuel consumed by

the vehicle (g/kg fuel). This value is primarily used for comparing different fuels for the

same cycle.

The emissions index was suggested as a useful tool for comparing emissions from different test

configurations (fuels) by the manufacturer of the SEMTEC-DS. It was stated that the emission

index is a more robust measure of effectiveness for on-road emissions testing for comparing

different scenarios.

For this study, the distance specific emissions rate and the emissions index were used for on-road

drive cycle based tests and the time specific emissions rate was used for low- and high-idle

testing. The appropriate effectiveness measures were calculated for each run of the test scenarios.

On-road testing consisted of two cycles representing two different driving patterns — drayage

cycle and long-haul cycles. For each cycle, two tests were performed. The results presented in

this report are the averages of the values from the two runs of each cycle for a specific vehicle

and fuel. Since idling is a steady-state condition, each second of recorded data can be considered

as a repetition; therefore an average over the time of the test provides the mean value of the

effectiveness measure (time specific emission rate [g/hr]).

28

3.1 Idle Tests

Gaseous Emissions Results

The idling data was collected for the 10 trucks using two test modes, low idle (at 600-700 rpm)

and high idle (at about 1200 rpm). Air conditioning was kept off on the drayage trucks (this is

their normal mode of operation) and kept on for the long-haul trucks (provided it was

functioning). If trucks were unable to maintain steady high idle conditions, an operator held his

foot on the pedal, maintaining the higher engine speed. In general, it was found that the

emissions were very similar to U.S. trucks of the same era with very little visible smoke during

idle.16

The procedures used are further discussed in the ―MSAT Sample Collection and Analysis‖

section.

Figure 18 and Figure 19, respectively, illustrate the results of low-and high-idling emissions

testing.

16

Storey, J.M.E., et al. Particulate Matter and Aldehye Emissions From Idling Heavy-Duty Diesel Trucks. SAE

2003-01-0289, Society of Automotive Engineers, Warrendale, Pennsylvania, 2003.

29

0

2000

4000

6000

8000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Lo

w Id

le C

O2 (

g/h

r)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

20

40

60

80

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Lo

w Id

le C

O (

g/h

r)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

5

10

15

20

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Lo

w Id

le H

C (

g/h

r)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

50

100

150

200

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Lo

w Id

le N

Ox

(g

/hr)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

Figure 18. Gaseous Emissions Results for Low-Idling Test at 600 rpm.

30

0

5000

10000

15000

20000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Hig

h Id

le C

O2 (

g/h

r)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

50

100

150

200

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Hig

h Id

le C

O (

g/h

r)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

50

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Hig

h Id

le H

C (

g/h

r)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

50

100

150

200

250

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

Hig

h Id

le N

Ox

(g

/hr)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

Figure 19. Gaseous Emissions Results for High-Idling Test at 1200 rpm.

31

These figures show that for the majority of the trucks (8 out of 10) the CO2 emissions rates at

low idle do not show large changes with the different fuels. This is also the case for high idle

CO2 emissions. Although the absolute differences between fuels appear large, they are in the

same general range with differences less than 10 percent. The graphs in Figure 18 and Figure 19

illustrate that while idling the drayage trucks’ CO2 emissions are almost the same (at low idle) or

have no apparent correlation with truck age. However, it appears that for the long-haul trucks the

CO2 emissions rate is noticeably higher for trucks newer than 1999 than the older long-haul

trucks (35 percent-to-100 percent higher). A potential explanation for this result could be the fact

that the air conditioning units of long-haul trucks the model years 1995 and 1990 were not

operational, while the air conditioning was working on the newer long-haul trucks during the

tests. Low idle results show the same trend in general, although it seems that the impact of the

working air conditioning on low idle CO2 emissions is much smaller than for high idle (10

percent-to-40 percent higher CO2 for trucks with working air conditioning than those without a

working air conditioner).

Figures 18 and 19 also show the CO emissions results for drayage trucks. The B20 fuel shows a

decreasing (compared to the ULSD fuel) effect on the CO emissions rate at both idling tests (up

to 40 percent lower for both low and high idling). The PEMEX fuel shows the same trend with

up to 40 percent reduction for low idling and up to 35 percent reduction for high idling. The

long-haul trucks do not show a clear pattern of fuel impact on the CO emissions rates during

idling. Some trucks show an increase in the CO rate for a certain fuel and the others show no

difference or a decrease for the same fuel. Furthermore, the graphs show that a newer engine

does not appear to have a positive impact on CO emissions rates during idling as would be

expect. The results also are inconclusive about the impact of air conditioning on CO emissions

during idling. In general, the long-haul trucks tested had higher CO emissions rates than the

drayage trucks.

For the majority of trucks, the B20 fuel has caused 40 percent-to-10 percent reductions

(compared to ULSD fuel) in hydrocarbon (HC) emissions rates. The PEMEX fuel shows the

same trend (six trucks showed reductions) at idling conditions, with reductions of 30 percent-to-

10 percent for high idling and 33 percent-to-5 percent for low idling. Surprisingly, the results

suggest that the age is inversely related to HC emissions during idling. The highest emissions

rates belong to the newer vehicles and the older vehicles are producing less HC per unit of time.

This is possibly due to the higher fuel injection pressures of the newer trucks resulting in finer

fuel spray and lower PM, but higher HC due to unburned fuel escaping the combustion chamber

more easily under idle conditions.

With the exception of three trucks, the B20 fuel shows a slightly decreasing effect on NOx

emissions rates at both low and high idling conditions when compared to the ULSD fuel. In

general, there was a 2 percent-to-9 percent reduction at low idle and 1 percent-to-15 percent

reduction at high idle. The PEMEX fuel and B20 fuel also appear to have similar impact on NOx

emissions during idling; with 0.4 percent-to-19 percent reductions at low idle and 2.6 percent-to-

15 percent reductions at high idle. The engine age does not show an apparent impact on the NOx

emissions rates during idling. For example, the 2004 truck had almost the same or higher NOx

rate than the 1990 truck. The exhaust gas recirculation (EGR) system of the 2004 truck was

either malfunctioning or not installed.

32

In general, the gaseous emissions during idle suggest that at idling mode, the ULSD fuel does not

show an emissions benefit over the tested PEMEX fuel (sulfur content of 380 ppm) for the tested

fleet. It should be noted that the PEMEX fuel used has a higher cetane index as compared with

the ULSD fuel (50.2 versus 47.5). Previous studies have shown that higher cetane numbers can

increase NOx slightly and reduce CO and HC. All else being equal, higher cetane tends to

advance the ignition timing which causes a decrease these emissions and a slight increase in

NOx. The increase in NOx would be most obvious on the driving cycles where the engine is

under load.

The B20 fuel shows a reduction in CO, HC, and NOx emissions during idling. The B20 fuel has

no impact on CO2 rate, however, assuming the same energy content as the ULSD fuel, 20

percent of the CO2 from the B20 fuel is coming from a renewable source, which can be

considered a reduction. Air conditioning usage shows some impact on CO2 and NOx, although, it

does not show any noticeable effect on CO and HC.

33

PM Emissions Results

MSAT emissions, including formaldehyde, acetaldehyde, and diesel PM, were measured during

the idle tests only due to the requirement for dilution sampling.

The diesel PM emissions tended to decrease with age, especially when viewed in combination

with previously obtained data on nine older drayage trucks in El Paso.17

It may also be observed

that the emissions rate for PM is considerably below the EPA guidance for extended truck idling

emissions of 3.68 g/hr.18

(See Figure 20). The figure shows that emissions generally decrease

with truck age, with some exceptions.

0

0.5

1

1.5

2

2.5

1985 1987 1989 1990 1992 1994 1994 1995 1995 1996 1996 1997 1997 1998 1999 1999 2001 2001 2004

Truck year

PM

Em

iss

ion

s (

g/h

r)

Figure 20. PM Emissions from Mexican Trucks.

When fuel effects are examined, the influence of each fuel is less easy to be discerned. Figure 21

shows the emissions of the Laredo trucks as a function of fuel for both low-and high-idle rates.

For the low-speed idle, emissions decrease with the B20 fuel use and increase with the PEMEX

17

Zietsman, J., J.C. Villa, T.L. Forrest, and J.M. Storey. Mexican Truck Idling Emissions at the El Paso - Ciudad

Juarez Border Location. Southwest Region University Transportation Center, The Texas A&M University System,

College Station, Texas, 2005. 18

Guidance for Quantifying and Using Long Duration Truck Idling Emissions Reductions in State Implementation

Plans and Transportation Conformity. EPA420-B-04-001, U. S. Environmental Protection Agency, Washington,

D.C., 2004.

34

fuel, but the trend is opposite for the high-speed idle case. In previous studies of biodiesel fuel

blends, several groups have seen overall PM reduction compared with the base fuels. The higher

cetane number of the PEMEX fuel may contribute to its relatively neutral effect on PM

emissions, despite its higher sulfur level.

0

0.5

1

1.5

2

2.5

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

PM

em

iss

ion

s (

mg

/hr)

ULSD B20 Pemex

Low-Idle

Drayage Trucks

Long Haul Trucks

0

1

2

3

4

5

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

PM

em

iss

ion

s (

mg

/hr) ULSD B20 Pemex

High-Idle

Drayage Trucks Long Haul Trucks

Figure 21. Diesel PM Emissions for the Laredo trucks.

35

Table 4 illustrates the average values for the PM emissions. For the drayage trucks, biodiesel fuel

reduces PM under both low-and high-idle conditions. However, for the long-haul trucks,

biodiesel fuel results in the highest PM emissions. High-idle conditions tend to favor the

formation of soluble organic fraction (SOF), because the engine is operating at higher speed with

low or no load, and unburned fuel and lube can be entrained into the exhaust and become part of

the PM that is measured by the filter. In the same engine, biodiesel fuel, which consists of just a

few fairly high boiling components, tends to have higher SOF than regular diesel fuel. Thus, the

fraction of the PM that is solid may well be lower with the B20 fuel, even though the measured

PM, including the SOF is higher. Although time and budget did not allow for SOF extraction on

the filters, ORNL preserved the sample filters and is measuring the PM-SOF under a different

DOE-funded task and will share the results as soon as they become available.

Table 4. PM Emissions Results (mg/hr).

Idle speed ULSD B20 PEMEX

Drayage Low 0.43 0.33 0.49

High 1.48 1.31 1.37

Long-haul

Low 0.59 0.90 0.44

High 1.80 2.15 1.69

All Trucks

Low 0.51 0.62 0.47

High 1.64 1.73 1.53

MSAT Analysis

In addition to PM, measurements were made of formaldehyde and acetaldehyde in the diluted

exhaust. One truck in particular, Drayage Truck 1, a 1999 model, had much higher aldehyde

emissions than all of the other trucks. This trend was consistent across separate measurements of

fuels and engine speeds. This truck also showed evidence of a fuel pump problem after changing

the fuel system to the test fuel, resulting in the eventual replacement of the fuel pump. Figure 22

shows the formaldehyde and acetaldehyde data with the high-emitting truck and Figure 23 shows

the same data without it to facilitate comparisons.

The aldehydes are products of incomplete combustion, so they are generally higher at idle than

under load. With exception of the 1999 drayage truck, the emissions of formaldehyde and

acetaldehyde were low compared with earlier work at El Paso19

and idling U.S. trucks.20

19

Zietsman, J., J.C. Villa, T.L. Forrest, and J.M. Storey. Mexican Truck Idling Emissions at the El Paso - Ciudad

Juarez Border Location. Southwest Region University Transportation Center, The Texas A&M University System,

College Station, Texas, 2005. 20

Storey, J.M.E., et al. Particulate Matter and Aldehye Emissions From Idling Heavy-Duty Diesel Trucks. SAE

2003-01-0289, Society of Automotive Engineers, Warrendale, Pennsylvania, 2003.

36

0

1000

2000

3000

1990

1994

1995

1995

1997

1999

1999

2001

2001

2004

1990

1994

1995

1995

1997

1999

1999

2001

2001

2004

Fo

rma

lde

hy

de e

mis

sio

ns (

mg

/hr)

ULSD B20 PEMEX

Low-speed idle High-speed idle

0

1000

2000

3000

1990

1994

1995

1995

1997

1999

1999

2001

2001

2004

1990

1994

1995

1995

1997

1999

1999

2001

2001

2004

Ac

eta

lde

hy

de

em

iss

ion

s (

mg

/hr)

ULSD B20 PEMEX

Low-speed idle High-speed idle

Figure 22. Formaldehyde and Acetaldehyde Emissions for all 10 Laredo Trucks.

(Including Higher-Emitting Drayage Truck 1, a 1999 Model.)

37

0

200

400

600

800

1990

1994

1995

1995

1997

1999

1999

2001

2001

2004

1990

1994

1995

1995

1997

1999

1999

2001

2001

2004

Fo

rma

lde

hy

de e

mis

sio

ns (

mg

/hr)

ULSD B20 PEMEX

Low-speed idle High-speed idle

0

200

400

600

800

1990

1995

1997

1999

2001

1994

1995

1999

2001

2004

Aceta

ldeh

yd

e e

mis

sio

ns

(m

g/h

r) ULSD B20 PEMEX

Low-speed idle High-speed idle

Figure 23. Formaldehyde and Acetaldehyde Emissions by Model Year.

38

Discussion of Idling Emissions Results

Results from these studies did not confirm some of the study team’s original expectations of the

study design. There was an expectation that the change to the ULSD and B20 fuels would result

in significantly lower emissions, especially when compared to the PEMEX fuel. Earlier studies

have often shown an increase in NOx with biodiesel fuel usage. The idling results obtained in

this study showed very little change. Similarly, for the MSATs, the expectation was that the

―cleaner‖ ULSD fuel would have lower emissions than the PEMEX fuel. With the exception of

the 1999 truck identified earlier, trucks operating on the three test fuels, were cleaner than the

Mexican trucks tested in El Paso and the U.S. trucks tested in Aberdeen. The lack of difference

may be lost in the relatively low levels of emissions. Overall, one reason for the lower emissions

among the Laredo trucks could be the higher level of maintenance observed with these trucks as

opposed to the El Paso trucks.

Another potential rationale for the difference is the higher cetane index of the fuels. Higher

cetane will result in a more efficient burn, especially at idle, leading to lower emissions of partial

combustion products such as the aldehydes. The Pemex fuel has a very comparable cetane index

to the U.S. ULSD fuel (see Table 3). Because Mexico is planning to adopt the U.S. fuel standard,

at least in the border states, refinery processes are likely to become more similar, leading to

higher cetane fuels than would have been encountered in El Paso during the previous year or in

Aberdeen in 2002. Before the ULSD fuel regulations, average cetane index for on-road diesel

was 42-45 and it was expected that the El Paso fuel would have similar or lower cetane index

values.21

Furthermore, no clear trend was observed for the B20 fuel in terms of aldehyde

emissions. It was expected that the methyl ester would be a good candidate for increased

formaldehyde or acetaldehyde emissions, but that increase was not observed.

21

Owen, K. and T. Coley. Automotive Fuels Reference Book, 2nd

Edition. Society of Automotive Engineers,

Warrendale, Pennsylvania, p.391.

39

3.2 On-Road Tests

The results of on-road emissions testing are provided in the following figures. Figure 24 shows

the emissions index and the distance specific emissions rates for the drayage cycle testing while

Figure 25 provides the results for long-haul drive cycle testing. These results are also shown in

Appendix B in a tabular format. In Figure 24 and Figure 25, the graphs on the left side show the

emissions indices and the right side presents the distance specific emissions rates. The main

effectiveness measures are the distance specific emissions rate and emissions indices are only

used for verification purpose. The calculation of emissions index uses the molecular weight of

the pollutant. The particulate matter, which includes many different molecules, does not have a

unique molecular weight and, therefore, an emission index for PM can, therefore, not be

calculated. In addition, the on-road PM is derived from the CATI instrument, which uses light

scattering to determine PM concentration based on calibration with limited engines.

Gaseous Emissions Results

The emissions index for CO2 is based on the fuel flow derived from CO2 emissions, so the CO2

emissions index graph shows the excellent consistency of the CO2 measurement between fuels

and different trucks. This consistency shows that leaks were not an issue, and the instrument was

stable throughout the two-week experiment. However, there are differences in distance specific

emissions rates among the fuels for long-haul trucks due to the differing efficiencies of the truck

engines. Therefore, if more fuel is burned to cover the driving cycle, the mass of CO2 per mile

increases. From the fuels analysis, the B20 fuel has about 2.5 percent less carbon by weight than

the other fuels – this difference would translate into lower miles/gallon, but not CO2/mile.

The consistency between fuels for a given truck, though, shows the relative consistency of the

driving cycles for that truck. On average, the trucks showed excellent consistency on the driving

cycle, with the exception of the 1995 and 1999 long-haul trucks, which had 15 percent-to-20

percent differences in the CO2 emissions rates between fuels. The CO2 graphs also suggest that

air conditioning usage has an obvious impact on the CO2 emissions from the moving trucks.

Trucks with working air conditioning (1990 and 1995 model long-haul trucks) have higher

average CO2 emissions per unit of length (g/mi). The impact of air conditioning seems to be

greater for the long-haul cycle than for the drayage cycle. This difference may be the result of

having more stop-and-go driving with hard accelerations under drayage driving conditions, as

opposed to long-haul driving that is characterized by few stops.

With exception of two trucks for each cycle, the B20 fuel appears to reduce the average CO

emissions (from the ULSD fuel), notably a 14 percent-to-37 percent reduction in distance

specific rates for drayage cycle and a 4 percent-to-34 percent reduction for long-haul cycle. For

the majority of the trucks, CO emissions rates associated with the B20 fuel are the lowest among

the fuels. The PEMEX fuel also shows the same pattern; with a 5 percent-to-36 percent reduction

in distance specific rates for drayage cycle and a 3 percent-to-47 percent reduction for the long-

haul cycle. Although a CO reduction was expected with the B20 fuel, it is not clear why the

PEMEX fuel has this effect on CO emissions. Age does not show an obvious effect on long-haul

trucks’ CO emissions for either cycle. For the drayage trucks the two newest models have

substantially lower CO rates (g/mi) than the older ones. A comparison of the CO rates between

drayage and long-haul trucks suggests that on average long-haul trucks have lower CO

40

emissions. This may be the result of better maintenance on long-haul trucks. Furthermore, there

is no obvious correlation between air conditioning usage and changes in CO rates.

HC emissions results show trends similar to those for idling HC emissions. The B20 and

PEMEX fuels appear to cause substantial reductions in the HC emissions (from the ULSD fuel).

As was the case for CO, the B20 fuel appears to have the lowest emissions rate compared to the

other two fuels. Truck age seems to be inversely related to HC emissions rates with newer trucks

having higher HC emissions rates than the older ones.

In contrast to the idle test results, the B20 fuel appears to increase NOx emissions; with 1

percent-to-16.3 percent increases (from the ULSD fuel) for the drayage cycle and 1 percent-to-14

percent increases for the long-haul cycle. The PEMEX fuel also shows the same trend as the B20

fuel, with a slightly lower increase in the NOx emissions rates. Vehicle age does not appear to

have an effect on the NOx emissions from either drayage or long-haul cycles. Air conditioning

usage also does not show a correlation with changes in NOx emissions rates. The NOx rates for

the long-haul cycle are slightly higher than the rate for the drayage cycle, which has substantial

idling periods. Note that the results for the 2004 long-haul truck show no change from earlier

trucks.

PM Emissions Results

The distance specific PM results presented in Figure 24 and Figure 25 illustrate that for all the

trucks, the B20 fuel substantially reduces PM emissions as measured by the CATI device. The

reductions are between 13 percent-to-48 percent (from the ULSD fuel) for the drayage cycle and

15 percent-to-37 percent for the long-haul cycle. The PEMEX fuel shows a reduction in PM

emissions rate for the majority of the trucks; although the reductions are smaller than for the B20

fuel. The reductions of PM resulting from the PEMEX fuel are in the range of 1 percent-to-36

percent for the drayage cycle and 3 percent-to-27 percent for the long-haul cycle. For both

groups of trucks, the oldest trucks, which fall into pre-1995 category, have the highest PM rates.

Post-1995 trucks show mixed results regarding the impact of truck age on PM emissions. This

trend is mostly attributed to the fact that the EPA-set PM standards for diesel engines changed

for engines manufactured in 1994 and after from 0.25 g/bhp.hr for pre-1994 engines to 0.1

g/bhp.hr for post-1994 engines. This standard remained unchanged until recently when the new

PM level standard was set at 0.01 g/bhp.hr for engines manufactured in 2007 and after. Table 1

shows time line of EPA emissions standards for diesel engines manufactured before 2007. Air

conditioning usage does not have an apparent impact on PM emissions from the tested trucks.

The changes observed in PM emissions with the PEMEX fuel may be the result of fuel system

cleanliness. The order of fuel types tested was the ULSD fuel, followed by the B20 fuel, and the

PEMEX fuel. The disturbance and substitution of fuels described in the experimental section

may have resulted in the loosening and removal of deposits from the fuel system. Biodiesel fuel,

in particular, has a detergent effect. Thus, the emissions may be decreasing because the fuel

injection is behaving more similarly to original specifications. Another factor in the

improvement of the PEMEX fuel may be the increased cetane index, which in general, will

improve emissions.

41

0

1000

2000

3000

4000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

2 (

g/k

g f

ue

l)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

1000

2000

3000

4000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

2 (

g/m

i)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

(g

/kg

fu

el)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

(g

/mi)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

1

2

3

4

5

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

HC

(g

/kg

fu

el)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

1

2

3

4

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

HC

(g

/mi)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

50

60

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

NO

x (

g/k

g f

ue

l)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

50

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

NO

x (

g/m

i)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

250

500

750

1000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

PM

(m

g/m

i)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

Figure 24. Drayage Cycle — Emissions Rates and Emissions Index.

42

0

1000

2000

3000

4000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

2 (

g/k

g f

ue

l)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

1000

2000

3000

4000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

2 (

g/m

i)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

(g

/kg

fu

el)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

CO

(g

/mi)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

1

2

3

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

HC

(g

/kg

fu

el)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

1

2

3

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

HC

(g

/mi)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

50

60

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

NO

x (

g/k

g f

ue

l)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

10

20

30

40

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

NO

x (

g/m

i)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

0

250

500

750

1000

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

PM

(m

g/m

i)

ULSD B20 Pemex

Drayage Trucks Long Haul Trucks

Figure 25. Long-Haul Cycle — Emissions Rates and Emissions Index.

43

4. Conclusions

Potential for Trucking beyond the U.S. Commercial Zone

Through an examination of Mexican and U.S. trucking practices and a series of interviews with

Mexican trucking interests the study team found that most Mexican long-haul carriers do not

currently cross their trucks into the U.S. commercial zone and would be reluctant to change that

aspect of their operations. Many Mexican drayage firms currently crossing the border do not

intend on pursuing contracts beyond the U.S. commercial zone, even if such movements are

permitted.

Emissions Testing

Test Protocol

The study team tested five drayage and five long-haul trucks, all currently operating in Mexico.

The tested trucks ranged from model year 1990 to 2004 with engine displacements ranging from

10.8 to 14.0 liters. All the tested trucks were subject to two idling (low and high) and two on-

road (drayage and long-haul cycles) tests for three different fuels — ULSD (base fuel), biodiesel

mix (B20), and PEMEX diesel. Several emissions measurement devices including two portable

emissions measurement units, a filter system, and a TEOM unit were used to measure different

pollutants and toxics from the trucks in different modes of operation. The measured pollutants

were PM, NOx, HC, CO, and CO2. Additionally, two mobile source toxics, formaldehyde and

acetaldehyde, were also measured. The toxics were measured only for the idle mode, while the

pollutants were tested for all the operation modes.

NOx Emissions

It was found that for idling modes (low and high) the B20 and PEMEX fuels tend to decrease

NOx emissions slightly (compared to the ULSD fuel). For on-road modes (drayage and long-

haul cycles), both the B20 and PEMEX fuels seemed to increase NOx. There was no clear

correlation between vehicle age and NOx emissions rates. The impact of air conditioner usage on

NOx was mixed; with a notable impact in idle mode and no apparent effect for on-road tests.

HC Emissions

Both the B20 and PEMEX fuels reduced hydrocarbons emissions during all modes of operation

when compared to the ULSD fuel with the B20 fuel having the highest reduction. The age of the

trucks appeared to have an inverse effect (newer trucks showed higher emissions) on HC

emissions, which might be the result of finer fuel injection in newer diesel engines. The effect of

air conditioning usage on HC was not clear because of the mentioned inverse impact of age on

HC.

44

CO Emissions

Similar to HC emissions, the B20 and PEMEX fuels tended to decrease CO emissions compared

to the ULSD fuel for all operation modes. It was found having a newer engine does not appear to

have a positive impact on CO emissions rates in the idling mode as would be expected. The

results were mixed for on-road tests: no age impact was observed for long-haul trucks. Newer

drayage trucks had lower CO emissions than the older ones. There was no obvious correlation

between air conditioning usage and changes in CO rates.

CO2 Emissions

The results showed that the fuel type does not have an impact on the CO2 emissions. However, it

must be noted that 20 percent of the B20 fuel came from a renewable source. CO2 from this

portion can be considered as an emission benefit. Air conditioning appeared to have a notable

impact on CO2 emissions. The age of the trucks showed no apparent effect on CO2 emissions.

PM Emissions

The B20 fuel appeared to substantially reduce PM emissions (from the ULSD fuel) for the on-

road operational mode. The PEMEX fuel also seemed to reduce PM, but to a lesser extent. The

PEMEX fuel used had a higher cetane index as compared with the ULSD fuel (50.2 versus 47.5).

Previous studies have shown that higher cetane numbers can increase NOx slightly and reduce

CO and HC. All else equal, higher cetane tends to advance the ignition timing which causes a

decrease these emissions and a slight increase in NOx. The increase in NOx would be most

obvious on the driving cycles where the engine is under load. Additionally, the process to lower

the sulfur to develop the ULSD fuel could involve the addition of hydrogen that might result in

higher PM numbers. There is also a potential lubricity effect (contaminants in the fuel system

mixes into the fuel line) resulting in higher than expected emissions rates, especially for PM.

Pre-1995 trucks were found to have the highest on-road PM emissions rate, while the impact of

the vehicles’ age on PM for post-1995 trucks was not clear. Air conditioning usage did not show

a clear impact on on-road PM emissions.

In addition, with the exception of one vehicle, PM emissions were significantly lower in this

study than those observed for the drayage trucks in El Paso. Significant differences included:

more older vehicles in the El Paso study;

no fuel purge/fuel changes; and

fuel that may have been of lower quality.

Mobile Source Air Toxics

The formaldehyde and acetaldehyde emissions were significantly lower than observed previously

in idling trucks from the U.S. and Mexico. The higher cetane index of all three fuels may be

responsible for this observed reduction. No additional aldehyde emissions were detected from

the biodiesel fuel, despite its fuel oxygen. Because the new ultralow sulfur rules have improved

fuel quality in both the U.S. and Mexico, there is no reason to expect that ULSD or B20 fuels

would have a noticeable effect on the aldehyde MSAT emissions.

45

In general, the results of this study suggest that using the ULSD fuel instead of the PEMEX fuel

might not provide the expected emissions benefit. The results showed that for the tested fleet, the

ULSD fuel reduces NOx emissions as compared to the PEMEX fuel. On the other hand, the

ULSD fuel appeared to increase the CO, HC, and PM emissions in both drayage and long-haul

driving modes. In interpretation of these results, note that the introduction of the ULSD fuel has

been intended to serve as a technology enabler to pave the way for the advanced sulfur-sensitive

exhaust emissions control devices. In this context, it is the combination of the model year 2007

diesel engines, equipped with advanced emissions control devices, and the lower sulfur diesel

fuel that the EPA expects to result in reduced emissions to the atmosphere.

Possible Explanations for Lower Emissions of PEMEX in Some Instances

It should be noted that the PEMEX fuel used had a higher cetane index as compared with

ULSD (50.2 versus 47.5). Previous studies have shown that higher cetane numbers can

increase NOx slightly and reduce CO and HC. All else being equal, higher cetane tends

to advance the ignition timing which causes a decrease these emissions and a slight

increase in NOx. The increase in NOx would be most obvious on the driving cycles

where the engine is under load.

The process to lower the sulfur to develop ULSD could involve the addition of hydrogen

that might result in higher PM numbers.

There is a potential lubricity effect (contaminants in the fuel system mixes into the fuel

line) resulting in higher than expected emissions rates, especially for PM.

When a new fuel is introduced the timing and performance of the vehicle can be changed

slightly, potentially affecting emissions.

Final Observations

Biodiesel (B20) clearly produced the best results with reductions in CO, PM, and HC emissions.

There was no effect on CO2 emissions and the results for NOx were mixed with slight decreases

during idling and slight increases during driving.

46

48

5. Recommendations

The results of the study can be refined and then combined with the fleet characteristics to provide

a macroscopic emissions model to calculate the total emissions from trucks crossing the U.S.-

Mexico border. By incorporating data from other border crossings, the model can be used to

estimate emissions at all Texas border crossings. Such a model will be easy to apply and has the

flexibility to consider the impact of different effects such as seasonal variation, daily variations,

hourly variations, and even the impact of emissions control strategies.

At a more detailed level, the emissions data collected in this study also provides an opportunity

to develop a series of instantaneous emissions models. The flexibility of an instantaneous model

enables researchers to investigate the impact of different border crossings and different border

crossing systems on emissions. The development of such a model requires data from different

sources (emissions rates from this study and other studies, GPS-collected vehicle speed, road

profile, vehicle location, and engine speed) to be combined and analyzed according an existing

framework (e.g. VT-Micro or EPA’s MOVES).

A more comprehensive study of this nature would involve a larger sample size of trucks and a

fuel conditioning period. There is also some uncertainty about the actual fuel being used in

Mexico. It would be useful to develop a better understanding of fuel types used at different

locations in Mexico and to test the emissions impact of these fuels.

In addition to fuel types, there is a real need to understand the emissions impact of using various

retrofits and emissions reduction devices. The technologies identified under the SmartWay

program need to be tested during actual operating conditions.

50

6. Acknowledgements

The study team would like to acknowledge the following individuals without whom this project

would not have been possible:

Jim Yarbrough of the EPA Region 6 for his guidance and support.

Mario Salinas of Texas Department of Public Safety for making their facilities available

for our testing and assisting with obtaining approval to test Mexican trucks in the U.S.

Danny Magee of Texas Department of Transportation for allowing us to us the Toll Road

for testing and supporting us during the study.

Brian Beckman and Jeremy Dabbeekeh of Clean Air Technologies for operating the

Montana CATI unit during the study and converting the CATI PM data.

Edward Brackin of TTI for assisting with the PEMS data collection and fuel purging

A.J. Rand of TTI for assisting with the PEMS data collection and fuel purging

Lisa Nimocks of TTI for assisting with all the logistics for the study.

Miguel Angel Alceda of SET Logistics for providing assistance in securing Mexican

tractors and trailer to carry out the tests.

Jorge de la Concha of SET Logistics for providing invaluable assistance in coordinating

with Mexican drayage and long-haul trucking companies and securing driver availability

throughout the field tests.

Noberto Domingo and Mike Kass of Oak Ridge Nation Laboratory for assisting with the

PM and MSAT data collection.

Tara Ramani of TTI for assisting with the writing of this report.

APPENDIX A

53

54

0%

10%

20%

30%

40%

50%

60%

70%

80%

0 - 2 3 - 4 5 - 6 7 - 8 9 - 10 > 10

Tractor age (yr)

Pro

po

rtio

n

US Trucks (2003 UC Davis survey)

Mexican trucks (2006 TTI survey)

Figure A. 1. U.S. and Mexican Truck Age Frequency (UC Davis Survey 2003 and TTI

Survey 2006)

55

0

0.5

1

1.5

2

2.5

3

3.5

Jan.

2006

Feb.

2006

Mar.

2006

Apr.

2006

May

2006

Jun.

2006

Jul.

2006

Aug.

2006

Sep.

2006

Oct.

2006

Nov.

2006

Av

era

ge

die

se

l p

ric

e (

$/g

al)

Border region - US Side

Border region - Mexican Side

Laredo, TX

Figure A. 2. Comparative average diesel price at US-Mexico border region

57

APPENDIX B

59

Table B. 1. Gaseous Emissions Rates for Low Idling at 600 rpm. CO2 (g/hr)

Drayage Trucks Long-haul Trucks

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

4320 4572 4392 5076 4860 ULSD 4428 5904 4860 5652 5004

3960 4248 4392 4716 3816 B20 3960 4464 4932 5544 5544

3816 4392 4140 4392 4716 PEMEX 4032 5580 4752 5184 5184

CO (g/hr)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

34.2 29.16 25.56 26.40384 27.36 ULSD 43.56 53.64 21.6 35.28 46.44

19.08 22.32 20.16 28.05408 13.32 B20 24.12 54 33.48 37.8 52.2

21.96 24.12 20.52 24.25853 23.04 PEMEX 27 53.64 26.28 33.48 39.6

NOx (g/hr)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

92.88 109.44 90 81.72 96.48 ULSD 96.48 176.04 111.96 131.4 79.56

87.12 140.4 87.84 76.68 87.48 B20 90 118.8 106.92 183.24 93.96

86.4 132.48 80.28 75.96 95.4 PEMEX 96.12 157.68 103.68 106.56 95.76

HC (g/hr)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

5.4 3.96 7.56 12.6 13.68 ULSD 8.64 9.72 8.64 13.68 11.88

2.88 3.6 6.12 11.52 9.36 B20 6.12 14.76 7.2 14.4 13.68

3.96 3.6 7.92 12.6 14.76 PEMEX 7.56 8.28 8.28 15.12 7.92

60

Table B. 2. Gaseous Emissions Rates for High Idling at 1200 rpm. CO2 (g/hr)

Drayage Trucks Long-haul Trucks

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

9828 9036 12384 9252 11448 ULSD 9252 8928 12204 13536 14652

11124 8100 12204 9540 10152 B20 7452 7920 12924 14940 14220

9180 8460 11772 8352 11340 PEMEX 7632 7812 12564 14832 15876

CO (g/hr)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

119.52 88.2 96.12 99.72 89.64 ULSD 151.56 119.88 70.56 112.68 122.76

95.4 66.24 75.6 96.84 53.28 B20 85.68 146.52 113.04 104.4 126.72

84.6 72.36 73.8 60.48 77.4 PEMEX 79.56 108.72 98.64 128.16 121.32

NOx (g/hr)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

188.28 209.88 160.2 123.12 150.48 ULSD 154.8 214.56 198.72 198 196.92

203.4 197.28 153 121.32 141.48 B20 133.92 165.96 208.44 212.76 187.2

163.8 191.52 147.6 111.6 146.52 PEMEX 144 180.72 206.64 186.48 200.16

HC (g/hr)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

15.84 12.96 29.88 38.88 42.12 ULSD 30.24 19.08 27 39.24 27.72

12.96 11.52 23.04 32.4 34.56 B20 17.64 25.92 23.04 38.88 27.72

13.32 14.76 26.28 34.92 41.04 PEMEX 18.72 17.28 25.56 46.08 22.32

61

Table B. 3. Average Emissions Index for Drayage Drive Cycle. CO2 (g/kg fuel)

Drayage Trucks Long-haul Trucks

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

3007.8 3033.95 2994.85 2915.35 2797.5 ULSD 2763 2989.5 2943.9 2996.35 2918.8

2988.85 3038.4 2991.8 3057.4 2855.85 B20 2869.5 2876.9 2960 3039.85 2970.05

3014.65 3156.9 2976.55 2928.35 2869.65 PEMEX 2822.1 2903.25 3103 3011.9 2870.05

CO (g/kg fuel)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

25.3 29.4 36.84 15.61 7.43 ULSD 12.83 25.51 11.43 7.38 15.45

21.66 22.38 22.92 12.44 7.59 B20 10.78 19.47 8.09 7.92 11.82

23.82 24.33 32.22 13.26 8.46 PEMEX 11.09 20.61 9.31 7.94 12.07

NOx (g/kg fuel)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

30.69 34.98 32.29 24.54 26.3 ULSD 27.24 50.36 26.78 24.34 21.34

30.82 43.38 32.02 27.02 30.18 B20 28.76 50.97 28.56 25.19 23.16

30.63 41.51 31.18 25.26 26.05 PEMEX 27.36 51.11 30.58 23.75 22.03

HC (g/kg fuel)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

1.48 1.72 3.54 3.97 3.33 ULSD 2.39 1.49 2.81 3.2 2.87

0.8 1.88 2.64 2.21 2.84 B20 1.37 2.3 1.97 2.58 2.41

1.41 2.14 2.24 3.07 3.82 PEMEX 2.03 1.34 3.09 3.3 1.76

62

Table B. 4. Average Distance-Specific Emissions Rates for Drayage Drive Cycle. CO2 (g/mi)

Drayage Trucks Long-haul Trucks

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

2892.09 2989.1 3030.28 2786.99 2834.82 ULSD 3131.25 3057.36 2891.42 3630.35 3358.33

2786.31 2797.73 3045.07 2961.4 2665.82 B20 3261.14 2500.11 3126.99 3642.48 3505.48

2945.23 2906.85 2948.1 2798.58 2858.44 PEMEX 2962.97 2556.65 3541.4 3867.39 3403.21

CO (g/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

26.52 32.88 37.64 13.36 5.16 ULSD 14.63 25.73 9.32 6.72 14.88

22.88 22.71 25.83 10.45 4.54 B20 11.25 20.11 7.93 6.92 12.58

25.5 24.68 35.56 10.98 5.84 PEMEX 9.89 21.44 9.17 7.58 13.34

NOx (g/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

23.11 30.21 28.81 19.34 23.33 ULSD 24.48 45.5 21.09 25.62 21.47

22.68 32.88 29.21 22.02 24.99 B20 25.84 37.95 24.53 26.37 24.26

23.56 31.47 27.04 20.08 22.71 PEMEX 22.9 38.47 28.08 26.58 22.75

HC (g/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

0.79 0.88 2.12 2.04 2.11 ULSD 1.81 0.9 1.57 2.58 2.06

0.39 1.15 1.54 1.22 1.42 B20 0.92 1.27 1.33 2.04 1.9

0.72 1.26 1.32 1.75 2.34 PEMEX 1.33 0.66 2.36 3 1.3

PM (mg/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

767.13 484.85 594.93 362.79 394.41 ULSD 765.59 362.64 346.87 582.04 530.8

564.44 422.5 430.25 308.74 239.25 B20 453.15 292.27 288.81 298.31 445.84

645.26 447.84 508.8 322.72 407.54 PEMEX 488.74 247.48 414.5 573.78 395.15

63

Table B. 5. Average Emissions Index for Long-Haul Drive Cycle. CO2 (g/kg fuel)

Drayage Trucks Long-haul Trucks

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

3073.8 2979.45 3078.2 3117.15 2927.15 ULSD 2934.25 3059.05 2973 3081.7 2951

3070.6 2969.6 3020.15 3061.75 2952.7 B20 2964.55 2921.6 3095.75 3027.6 2996.35

3077.8 3085.41 3087.4 3055.75 2828.85 PEMEX 2986.4 2893.9 3106.3 3105.95 3014.05

CO (g/kg fuel)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

18.74 33.66 22.36 9.99 5.17 ULSD 9.95 21.53 11.46 4.32 10.28

17.96 22.73 17.15 10.13 4.51 B20 7.66 14.03 9.06 4.86 8.41

19.76 24.7 19.42 10.34 5 PEMEX 7.28 20.58 6.05 4.73 9.63

NOx (g/kg fuel)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

24.45 31.79 32.54 26.84 27.38 ULSD 21.76 49.4 23.11 25.12 21.93

24.35 34.74 30.95 28.34 29.63 B20 23.72 41.06 26.89 25.41 24.22

25.2 33.25 30.52 28.33 26.55 PEMEX 22.77 41.6 29.63 25.14 24.78

HC (g/kg fuel)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

0.58 0.82 1.48 1.82 1.66 ULSD 1.07 0.94 1.52 1.88 1.25

0.36 0.95 1.24 1.42 1.47 B20 0.84 0.77 1.34 1.67 1.16

0.57 1.08 1.45 1.75 1.76 PEMEX 1.05 0.63 1.51 1.69 0.99

64

Table B. 6. Average Distance-Specific Emissions Rates for Long-Haul Drive Cycle. CO2 (g/mi)

Drayage Trucks Long-haul Trucks

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

2488.06 2102.21 2569.84 2521.47 2260.24 ULSD 2871.11 2333.15 2584.19 3060.29 2923.04

2518.1 1977.06 2477.65 2362.74 2340.57 B20 2670.11 2093.29 2672.41 2884.47 2882.88

2472.53 2054.16 2423.2 2350.65 2265.97 PEMEX 2669.17 2114.69 2819.28 3287.63 2828.76

CO (g/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

15.34 24.5 19.08 7.28 2.97 ULSD 9.54 15.74 10.5 3.61 8.4

15.3 15.31 14.65 7.26 2.67 B20 6.27 11.17 8.44 3.81 6.93

16.15 16.65 17.03 7.71 2.99 PEMEX 5.62 17.01 5.01 4.22 8.18

NOx (g/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

17.12 21.23 25.54 20.6 19.99 ULSD 19.28 35.43 18.71 23.75 21.29

17.46 22.37 24.15 20.9 22.54 B20 18.9 27.69 21.34 23.2 22.21

17.62 21.41 22.6 20.86 20.62 PEMEX 17.88 27.63 25.79 25.64 21.71

HC (g/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

0.31 0.36 0.93 0.98 0.89 ULSD 0.8 0.41 0.99 1.39 0.88

0.19 0.39 0.76 0.78 0.79 B20 0.53 0.38 0.79 1.25 0.75

0.29 0.45 0.82 0.97 0.97 PEMEX 0.63 0.3 1.04 1.44 0.62

PM (mg/mi)

1994 1995 1997 1999 2001 1990 1995 1999 2001 2004

609.98 368.29 427.02 262.42 260.87 ULSD 516.42 235.47 303.94 393.98 325.66

490.21 250.64 298.49 222.87 203.76 B20 378.65 186.2 228.22 244.44 236.26

502.48 265.68 327.39 236.3 222.95 PEMEX 376.09 229.51 223.1 308.78 297.32

65

66

APPENDIX C

68

69

70